Introduction to Syfer Technology

Transcription

1 Surface Mount Solder-in eramic Threaded Hermetic eramic Metallised Film Discoidal and Planar Arrays Special s and Assemblies s for Hi-Rel Applications

2 Introduction to Technology Technology Limited is a global company dedicated to the manufacture of ceramic based electronic components. has been producing Multilayer eramic apacitors for over 25 years and its employees are committed to providing customers with high quality products together with a fast, friendly and flexible service from a state-of-the-art facility. Production process At the core of s ceramic manufacturing technology is the Wet Process. This fully integrated computer-controlled manufacturing operation is in a clean room environment, and offers unique advantages in the manufacture of filter products. This has resulted in being a world leader in the manufacture of EMI filters, discoidal capacitors and planar arrays. Our multilayer ceramic manufacturing facility and filter assembly facility holds a number of internationally recognised approvals including ISO 9001:2008, IS :2004 and OHSAS 18001:2007. is also an ESA (European Space Agency) and NASA approved source. Specific product approvals/qualifications include IEQ E, UL, TÜV and AE-Q200. Products s excellence in ceramic materials technology, combined with EMI filter expertise, has enabled us to offer an unrivalled range of EMI filter products including: Surface Mount filters including: Feedthrough hip capacitors Surface Mount filters Surface Mount Pi filters X2Y - Integrated Passive omponents Solder-in filters eramic Threaded filters Hermetic eramic filters Metallised Film filters Discoidal capacitors Planar capacitor and Planar Varistor Arrays Special filter assembly capability Benefits Surface Mount EMI filters High capacitance, high voltage, high current Pi filters Flexiap termination an option AE-Q200 qualifications EMI filters Use of and 0G/NP0 ceramics - no Z5U High capacitance values, high voltage Use of self-healing plastic film material High frequency performance to 10GHz X2Y Available with Flexiap termination AE-Q200 and medical implantable Available in surface mount, panel mount and planar array versions Discoidal capacitors Small sizes, high capacitance values, high voltage capability ustom sizes available Varistor discoidal options Planar arrays Mechanical superiority, tighter mechanical tolerances High voltage capability, mixed capacitance values NASA approved Available in capacitor, varistor, inductor and X2Y formats Multiway filter assemblies an use either discoidal capacitor elements or planar arrays Full custom design facility Other products Multilayer ceramic chip capacitors High voltage MLs Protectiap capacitors Flexiap capacitors with flexible terminations Stackiap capacitors lass X and Y SMD Safety ertified capacitors Radial leaded capacitors AE-Q200 qualified capacitors IEQ E approved capacitors apacitors for space applications High Q capacitors Non-magnetic capacitors 3 terminal EMI chips X2Y Integrated Passive omponents Ultra-low ESR capacitors

3 ontents - The EMI Specialist Introduction to EMI s General introduction Quick Reference Guide The need for EMI filters Explanation of common terms Factors affecting Insertion Loss hoice of ceramic dielectric material Panel mount EMI filters - Application considerations MIL-STD-461 and EMI s - ommon misconceptions Installation of filters Surface Mount EMI filters Introduction Insertion Loss E01 and E07 feedthrough capacitors and Pi filter ranges X2Y Integrated Passive omponent Packaging information EMI filters Introduction to EMI filters Insertion Loss Solder-in EMI filters eramic Threaded EMI filters Surface Mount Solder-in eramic Threaded Hermetic eramic Metallised Film Hermetic eramic EMI filters L- and Pi filters Metallised Film EMI filters, L-, T and Pi configurations Feedthrough capacitors Discoidal and Planar Arrays Special filters and Assemblies s for Hi-Rel applications 93 Additional Resources 94 Product Safety Information 95 Additional Resources Discoidal and Planar Arrays Special filters and Assemblies s for Hi-Rel Applications

4 Introduction to EMI s Quick Reference Guide Surface Mount Range Mounting Description ircuit apacitance Range Page E01 Surface Mount 300mA EMI chip. Sizes 0603, 0805, 1206 & pF - 200nF 17/18 E07 Surface Mount 1A to 3A rated EMI chip. Sizes 0603, 0805, 1206, 1806 & pF to 1.8µF 17/18 SBSPP Surface Mount 1A rated Pi filter. Size 1206 Pi 22pF - 150nF 19 SBSG Surface Mount 10A rated filter. Size nF - 220nF 20 SBSGP Surface Mount 5A rated Pi filter. Size 1812 Pi 1.0nF - 220nF 21 SBSM Surface Mount 20A rated filter. Size nF - 470nF 22 SBSMP Surface Mount 10A rated Pi filter. Size 2220 Pi 1.0nF - 470nF 23 E03 Surface Mount Balanced Line chips (X2Y) 10pF - 1.2µF 24/25 Solder-in Range Mounting Description ircuit apacitance Range Page SFSS Solder Discoidal F/T capacitor with leads. 2.3 to 8.75mm body diameter 10pF - 3.3µF 31 SFSR Solder 2.8mm body diameter 10pF - 47nF 32 SFST Solder 3.25mm body diameter 10pF - 100nF 33 SFSU Solder 5.6mm body diameter 10pF - 680nF 34 eramic Threaded Range Mounting Description ircuit apacitance Range Page SFAA 4-40 UN lass 2A thread 4.0mm hexagonal head 10pF - 150nF 35 SFAB 6-32 UN lass 2A thread 4.0mm hexagonal head 10pF - 150nF 36 SFABL 6-32 UN lass 2A thread 4.0mm hexagonal head L- 10pF - 150nF 37 SFAJ M3 x 0.5-6g thread 4.0mm hexagonal head 10pF - 150nF 38 SFAJL M3 x 0.5-6g thread 4.0mm hexagonal head L- 10pF - 150nF 39 SFAK M3.5 x 0.6-6g thread 4.0mm hexagonal head 10pF - 150nF 40 SFAKL M3.5 x 0.6-6g thread 4.0mm hexagonal head L- 10pF - 150nF 41 SFAKT M3.5 x 0.6-6g thread 4.0mm hexagonal head T 10pF - 150nF 42 SFB 8-32 UN lass 2A thread 4.75mm hexagonal head 10pF - 150nF 43 SFBL 8-32 UN lass 2A thread 4.75mm hexagonal head L- 10pF - 150nF 44 SFBP 8-32 UN lass 2A thread 4.75mm hexagonal head Pi 20pF - 94nF 45 SFBD UNEF lass 2A thread 4.75mm hexagonal head / 6.35mm flange 10pF - 150nF 46 SFBDL UNEF lass 2A thread 4.75mm hexagonal head / 6.35mm flange L- 10pF - 150nF 47 SFBDP UNEF lass 2A thread 4.75mm hexagonal head / 6.35mm flange Pi 20pF - 300nF 48 SFBDT UNEF lass 2A thread 4.75mm hexagonal head / 6.35mm flange T 10pF - 150nF 49 SFBL M4 x 0.7-6g thread 4.75mm hexagonal head 10pF - 150nF 50 SFBLL M4 x 0.7-6g thread 4.75mm hexagonal head L- 10pF - 150nF 51 SFBLP M4 x 0.7-6g thread 4.75mm hexagonal head Pi 20pF - 94nF 52 SFBM M5 x 0.8-6g thread 4.75mm hexagonal head / 6.35mm flange 10pF - 150nF 53 SFBML M5 x 0.8-6g thread 4.75mm hexagonal head / 6.35mm flange L- 10pF - 150nF 54 4 Quick Reference Guide

5 Quick Reference Guide eramic Threaded Introduction to EMI s Range Mounting Description ircuit apacitance Range Page SFBMP M5 x 0.8-6g thread 4.75mm hexagonal head / 6.35mm flange Pi 20pF - 300nF 55 SFBMT M5 x 0.8-6g thread 4.75mm hexagonal head / 6.35mm flange T 10pF - 150nF 56 SFD UNEF lass 2A thread 6.35mm hexagonal head 10pF - 680nF 57 SFDL UNEF lass 2A thread 6.35mm hexagonal head L- 10pF - 680nF 58 SFDP UNEF lass 2A thread 6.35mm hexagonal head Pi 20pF - 300nF 59 SFM M5 x 0.8-6g thread 6.35mm hexagonal head 10pF - 680nF 60 SFML M5 x 0.8-6g thread 6.35mm hexagonal head L- 10pF - 680nF 61 SFDPP M8 x g thread 10mm hexagonal head Pi 9.4nF - 940nF 62 SFJG ¼-28 UNF lass 2A thread 9.8mm round head 100pF - 3.3µF 63 SFJGL ¼-28 UNF lass 2A thread 9.8mm round head L- 100pF - 3.3µF 64 SFJGP ¼-28 UNF lass 2A thread 9.8mm round head Pi 660pF - 6.6µF 65 SFJN M6 x g thread 9.8mm round head 100pF - 3.3µF 66 SFJNL M6 x g thread 9.8mm round head L- 100pF - 3.3µF 67 SFKB 6-32 UN lass 2A thread 4.4mm round head 10pF - 150nF 68 SFKBL 6-32 UN lass 2A thread 4.4mm round head L- 10pF - 150nF 69 SFKK M3.5 x 0.6-6g thread 4.4mm round head 10pF - 150nF 70 SFKKL M3.5 x 0.6-6g thread 4.4mm round head L- 10pF - 150nF 71 SFKKT M3.5 x 0.6-6g thread 4.4mm round head T 10pF - 150nF 72 SFLM M5 x 0.8-6g thread 6.0mm round head 10pF - 150nF 73 SFLML M5 x 0.8-6g thread 6.0mm round head L- 10pF - 150nF 74 SFLMP M5 x 0.8-6g thread 6.0mm round head Pi 20pF - 300nF 75 SFLMT M5 x 0.8-6g thread 6.0mm round head T 10pF - 150nF 76 SFTM M5 x 0.8-6g thread 6.35mm hexagonal head 10pF - 150nF 77 SFUM M5 x 0.8-6g thread 6.0mm round head 10pF - 150nF 78 SFJEB ¼-28 UNF lass 2A thread Balanced Line EMI X2Y 4.7nF - 100nF 79 Hermetic eramic Range Mounting Description ircuit apacitance Range Page SLS*P ¼-28 UNF lass 2A thread (5.08mm A/F) 9.78mm round head Pi 2.8µF 80 SLO** ¼-28 UNF lass 2A thread (5.75mm A/F) 8.33mm round head L- & Pi 20nF - 200nF 81 Metallised Film Range Mounting Description ircuit apacitance Range Page SLDL* M12 x 1 thread : 17mm fixing nut 32A. 20mm round head : M4 spindle & Pi 4.7nF - 14µF 82 SLG** M16 x 1 thread : 22mm fixing nut 63/100A. 25mm round head : M6 spindle & Pi 10nF - 22µF 83 SLKN* M20 x 1 thread : 27mm fixing nut 100A. 32mm round head : M8 spindle & Pi 47nF - 40µF 84 SLVR* M24 x 1 thread : 27mm fixing nut 200A. 38mm round head : M10 spindle & Pi 100nF - 65µF 85 SLEK M16 x 1 thread : 19mm fixing nut 20A. 15mm round head : M3 5nF - 12µF 86 SLMN M25 x 1 thread : 30mm fixing nut 100A. 26mm round head : M6 100nF - 40µF 87 Quick Reference Guide 5

6 Introduction to EMI s The need for EMI s The use of electronic equipment is ever-increasing, with greater likelihood of interference from other pieces of equipment. Added to this, circuits with lower power levels that are more easily disturbed means that equipment is increasingly in need of protection from EMI (electromagnetic interference). To meet legislation such as the EU Directive on EM, in addition to other international regulations such as F, EMI filtering is now an essential element of equipment design. Introducing screening measures, eg to the case or cables, may suffice in many instances, but some form of low-pass filtering will often be required. Faraday age Faraday age protects against radiated interference Fig 1 2 ircuit Radiated interference Faraday age The ideal way of protecting a piece of equipment or circuit from EMI is to totally enclose it in a metal (or conductive) box. This screened enclosure is called a Faraday age. Radiated interference is thus prevented from adversely affecting it (Fig 1). EMI source Equipment affected by EMI Input/output cabling In reality however, most pieces of equipment require input and/ or output connections, perhaps power cables or signal and control lines. The cables providing these connections can act as antennae, able to pick up interference and also to radiate it (Fig 2). Any cable or wire going in through the equipment case can introduce electrical noise, and also radiate it internally onto other wires and circuits. Similarly, it can provide a path to the outside from any noise generated internally, which can also then be radiated and may in turn adversely affect other equipment. 1. Interference can enter a piece of equipment directly through the cabling (conducted interference). 2. Radiated interference can travel directly to the affected equipment. 3. Interference can exit an EMI source via a cable, subsequently to be radiated from the cable and to the affected equipment. 4. Interference can be radiated from an EMI source and then picked up by a cable entering the affected equipment. location - filters To prevent interference entering or leaving a piece of equipment, feedthrough EMI filters can be mounted in the wall of a shielded case. Any incoming or outgoing cables would then pass through the filters. Power or wanted signals pass through the filters unaffected, whilst higher frequency interference is removed. While the screened case protects against radiated interference, the feedthrough filters protect against conducted interference. The integrity of the equipment is thus assured (Fig 3). location - Surface Mount filters Where there is no suitable bulkhead for mounting the filters, pcb types can be used (Fig 4). While this can be an effective method of filtering, it should be noted that in general the insertion loss performance can be reduced at higher frequencies, unless additional screening measures are taken. Good design practices such as short tracks, short connections, close proximity to input and good grounding will help improve insertion loss performance. Modes of propagation of EMI onducted interference Panel mounting feedthrough filters or filter connector onducted interference input Radiated interference Feedthrough filters remove conducted interference and provide ultimate performance Radiated interference output Pcb mounting filters Surface mount filters remove conducted interference, performance reduced due to radiated interference Fig 2 Fig 3 Fig 4 6 The need for EMI s

7 Explanation of common terms onducted Interference Interference transmitted along a conductor/cable. Protection is provided by a series component. If a feedthrough filter is used to remove conducted interference, and mounted in the wall of a shielded compartment, it provides effective filtering while maintaining the screening integrity. It should be noted that the filter will reduce both emissions and susceptibility. ut-off Frequency/3dB point The frequency at which filters start to become effective. Generally taken to be at the 3dB point of the attenuation curve. Anything on the line below this frequency will be unaffected. The higher the capacitance of the filter the lower the cut-off, and vice versa. It will also vary depending on source and load impedances. Low-pass A filter that lets through dc and low frequency signals, while attenuating (unwanted) high frequency noise. A panel mounted filter that will pass the signal from one side of the wall of a shielded box (or Faraday age ) to the other (it feeds the signal through the panel). For effective operation, the filter input and output should be screened from each other, ie there should ideally be no apertures in the panel. Introduction to EMI s EM ElectroMagnetic compatibility. A situation wherein two pieces of electrical or electronic equipment are able to function in the same environment without adversely affecting, or being affected by, each other. EMI ElectroMagnetic interference. A broad term covering a wide range of electrical disturbances, natural and man-made, from dc to GHz frequencies and beyond. Sources of disturbance may include radar transmitters, motors, computer clocks, lightning, electrostatic discharge and many other phenomena. onducted Emissions Signals, unwanted (interference) or otherwise from a piece of equipment. Radiated Interference Interference transmitted in free air. Protection is provided by shielding, but if filters are not used to protect against conducted emissions, the unfiltered lines can act as aerials radiating interference outside the shielded cage. Panel mounting feedthrough filters Surface Mount A filter that is suitable for surface mounting on PBs. It offers improved filtering compared to standard MLs, ease of assembly and savings on board space compared to a combination of discrete filter elements. performance at higher frequencies is reduced compared to panel mount types, unless additional shielding measures are taken (see page 10). Susceptibility The extent to which a piece of equipment is vulnerable to interference emitted from another piece of equipment. ESD Electrostatic discharge. ESD can result in damage through excessive voltage spikes. We can offer assistance on whether our products can meet specific ESD test requirements. Insertion Loss At a given frequency, the insertion loss of a feedthrough suppression capacitor or filter connected into a given transmission system. Working ontinuous operating voltage. This can potentially be across the entire operating temperature range. X2Y Integrated passive component with extremely low self inductance for filtering and de-coupling. For filtering applications: Defined as the ratio of voltages appearing across the line immediately beyond the point of insertion, before and after insertion. As measured herein, insertion loss is represented as the ratio of input voltage required to obtain constant output voltage, with and without the component, in the specified 50W system. This ratio is expressed in decibels (db) as follows: A A Insertion loss = 20 log E 1 E 2 B B Where: E 1 = The output voltage of the signal generator with the component in the circuit. E 2 = The output voltage of the signal generator with the component not in the circuit. When testing is conducted with a network/spectrum analyser, the equipment usually maintains a constant output voltage and can be set to record the output to input voltage ratio in decibels. For de-coupling applications: SIGNAL 1 RETURN 1 Explanation of common terms 7

8 Introduction to EMI s Factors affecting Insertion Loss The insertion loss performance is used to aid filter selection by showing signal attenuation at any given frequency. However, it can only ever be a guide as actual performance in service will vary depending on the overall circuit characteristics. Insertion loss is determined by: configuration Source/load impedances The load current (which can cause ferrite saturation) eramic dielectric materials. The capacitance change will be affected by applied voltage, temperature and the age of the part Earthing impedance Shielding integrity onfiguration A number of different electrical configurations are available in feedthrough filters, including the common types shown opposite. A single element filter (a capacitor or an inductor) theoretically provides an insertion loss characteristic of 20dB per decade, a dual element filter (capacitor/inductor) 40dB per decade whilst a triple element filter (Pi or T configuration) theoretically yields 60dB per decade. In practise, the insertion loss curves do not exactly match the predictions, and the data sheets should be consulted for the realistic figure. The choice of electrical configuration is made primarily on the source and load impedances and may also be influenced by the level of attenuation required at various frequencies. This is a feedthrough capacitor with low self inductance. It shunts high frequency noise to ground and is suitable for use with a high impedance source and load. L- This is a feedthrough filter with an inductive element in combination with a capacitor. It is commonly used in a circuit with a low impedance source and a high impedance load (or vice versa). The inductive element should face the low impedance. Pi THREAD L- -L Pi This is a feedthrough filter with 2 capacitors and an inductive element between them. Ideally, it should be used where both source and load impedances are high. T This is a feedthrough filter with 2 series inductive elements separated by one feedthrough capacitor. It is suitable for use where both source and load impedances are low. Multi-element filters These filters contain more than 3 elements, for example L--L--L filters. The addition of further elements increases the steepness of the insertion loss curve. T THREAD Source and Load Impedances Insertion loss figures are normally published for a 50W source and 50W load circuit. In practise the impedance values will probably be very different, which could result in either an increase or decrease in insertion loss. The electrical configuration of the filter (the capacitor/inductor combination) should be chosen to optimise the filter performance for that particular source/load impedance situation. An estimate of insertion loss for source and load impedances other than 50Ω may be possible. Please contact our Sales Office. Load urrent For filters which include ferrite inductors, the insertion loss under load current may be less than that with no load. This is because the ferrite material saturates with current. The reduction in insertion loss depends on the current and the characteristics of the particular ferrite material. In extreme cases the ferrite will become ineffective and insertion loss will appear to be the same as for a filter. For further information contact the Sales Office. Attenuation urve A plot of insertion loss versus frequency on a logarithmic scale. Insertion Loss (db) Frequency (MHz) 8 Factors affecting Insertion Loss

9 hoice of ceramic dielectric material When choosing a filter, it is important to be aware of the different performance characteristics that may be available from different categories of ceramic materials employed in their capacitors. Generally, stability of dielectric constant (and therefore filter capacitance value), with respect to some operational and environmental parameters, deteriorates with increasing dielectric constant. Specific factors which affect dielectric constant are temperature, voltage, frequency and time (ageing). The three main classifications of ceramic dielectric employed in the manufacture of EMI filters are generally referred to as ultra stable (0G/NP0), stable () and general purpose (Z5U, Y5V or X7W). 0G/NP0 Most parameters for materials in this dielectric classification remain unaffected by temperature, voltage, frequency or time. Stabilities are measured in terms of parts per million but dielectric constants are relatively low (10 to 100). This is a classification for materials which are relatively stable with respect to temperature, voltage, frequency and time. Typical dielectric constants would be of the order 2,000 to 4,000, enabling the achievement of far higher capacitance values for a given size of capacitor than can be gained from 0G/NP0 materials. If the voltage coefficient (V) is critical, are also able to offer parts with BX (2X1) and BZ (21) V characteristics. Refer to the factory for further details. Z5U/Y5V/X7W These are classifications for materials which are severely restricted and performance under applied voltage may be seriously compromised. A summary of the specifications of these materials follows. Please note that uses only the higher performance 0G/NP0 and in its standard ranges. Introduction to EMI s Summary of ceramic dielectric characteristics 0G/NP0 Z5U Y5V X7W EIA dielectric classification Ultra stable Stable General purpose temperature range -55º to +125º -55º to +125º Maximum capacitance change over temperature range (no voltage applied) Ageing characteristics -10º to +85º -30º to +85º -55º to +125º 0 ±30 ppm/ ±15% % % % Zero <2% per time decade 6% per time decade 6% per time decade 6% per time decade Spread of capacitance values The capacitance of a ceramic capacitor can change as a result of a change in temperature, applied voltage and age. Please note that this potential change can lead to a significant drop in filtering performance. onsider the typical performance of 5,000pF filter capacitors, offered in standard dielectric classifications, operating at a voltage of 100Vdc at 85, at an age of 10,000 hours. The final capacitance value can fall within the range of values (see chart below), taking into account the ageing process and effects of temperature and voltage as shown in the chart above. It is clear that the capacitance can change as a result of an increase (or decrease) in temperature, applied voltage and as a result of ageing. If the capacitance has reduced, so too will the insertion loss performance. 9000pF negligible change 5750pF to 3500pF 6100pF to 1000pF 6100pF to 500pF 8540pF to 250pF 8000pF 7000pF 6000pF 5000pF Nominal 4000pF 3000pF 2000pF 1000pF only uses these two dielectrics 0pF 0G/NP0 Z5U Y5V X7W hoice of ceramic dielectric material 9

10 Introduction to EMI s EMI s - Application considerations Thread size or head size? What s the crucial factor in spacing The thread size has no relevance to the mounting pitch, but can influence cost. Very small threads are harder to work with, but offer little or no gain over larger thread sizes. If close mounting pitch is important, change instead to a round body. Mounted using modified screwdriver blades, this of component removes the need to allow space for mounting sockets and allow components to be mounted almost touching each other. offer a full range of round head filter types - SFKB, SFKK, SFLM and SFUM. Special requirements can also be considered. Schematic showing the pitch improvement that can be gained with round head filters compared to traditional hexagon heads. Hermetic seals vs resin seals Resin sealed filters have epoxy encapsulants injected into the cavities either side of the filter elements. The purpose of the resin is to ruggedise the assembly, supporting the pins and sealing the ceramic to prevent reliability issues such as moisture ingress. Poor encapsulants can be susceptible to cracking away from the metalwork due to temperature change. This can then allow moisture ingress which can result in reliability concerns. They can also exert a force on the ceramic which can result in cracking causing electrical failure. MIL or Space specifications generally do not demand resin sealed filters be tested for immersion or accelerated damp heat testing. resin sealed filters use a very high purity, highly filled, epoxy encapsulant with a very low co-efficient of thermal expansion very closely matched to the expansion co-efficient of the ceramic and other materials used in the construction. These characteristics enable filters to be thermally cycled with very little stress being applied to the ceramic elements and with reduced risk of cracking allowing moisture ingress. ertain filters have successfully passed immersion and accelerated damp heat testing. Screw mount hermetic filters generally have glass to metal seals soldered into place instead of conventional resin seals. They are better than resin sealed filters in applications where outgassing is critical, or where the environment is particularly harsh. MIL or Space specifications generally do require hermetically sealed filters be tested for immersion or accelerated damp heat testing. Unless fitted with sealing rings, they will not normally provide a gas seal between either side of the mounting bulkhead the seal is to protect the internal capacitor elements. are must be taken when using the filters, as the exposed solder joints can reflow, compromising the seal effectiveness, if too high a temperature is applied to the end terminals. Solder mount hermetic filters may create a gas seal between either side of the bulkhead, but this is more dependent on the sealing capabilities of the solder joint mounting the filter rather than the filter seal. Usually, solder mount filters only have a glass seal on one side of the filter body, with the other end resin sealed. Test plans are normally the same as those for resin sealed filters. Hermetically sealed solder mount filters are only normally required in applications where one end of the filter will be exposed to harsh environments, or where outgassing is critical on one side of the panel. Discoidal capacitor vs tubular capacitor The original panel mount filters used single layer tubular capacitors. There is one major advantage of this type of capacitor - it lends itself to very easy Pi filter construction. For this reason, Pi filters have tended to be considered the optimum filter configuration. As performance demands increased, higher capacitance values were required. High K, unstable (Z5U / Y5V see page 7) dielectrics and multilayer tubes began to be used. These use buried layer electrodes within the tube walls, but the reduced dielectric thickness resulted in lower voltage withstand capability. The unstable dielectrics result in poor performance over the voltage and temperature ranges. Tubular capacitors have one major flaw - the thin ceramic walls make them very prone to cracking causing electrical failures. As ML chip capabilities developed, the discoidal capacitor appeared in filters. These devices use ML chip technology to produce a very low inductance (low ESL / low ESR) capacitor giving improved performance and higher capacitance and voltage ranges (higher capacitance per unit voltage). They are physically much stronger and robust than tubes. Most panel mount filters use discoidal capacitors for optimum mechanical strength and high quality or 0G/NP0 dielectric materials for optimum electrical performance. However, there are other dielectric materials used in the manufacture of filters. Tube based filters Disc based filters Tubular capacitor Advantages heap. Suited to Pi filter manufacture. Robust. High capacitance., L-, & T circuits easy. Very high capacitance Pi filters possible. Tight tolerance possible. Vc characteristics possible. Multilayer discoidal capacitor Seal Seal Disadvantages Low capacitance only, not robust easily cracked multilayer tubes = higher capacitance but low voltage. Low capacitance Pi filters, relatively expensive. Typical construction of a Pi filter using tubular capacitors. Seal Typical construction of a Pi filter using multilayer discoidal capacitors. Seal 10 EMI s - Application considerations

11 MIL-STD-461 and EMI s - ommon misconceptions We routinely get filter enquiries that are typically quoting filters must meet the requirements MIL- STD-461 or filters must comply with MIL-STD-461. This is a complete mis-understanding of MIL-STD-461 and needs to be clarified with the customer. The following might be useful. The US MIL-STD-461 specification sets regulations for the control of electromagnetic interference emissions and susceptibility of equipment. It sets requirements for the levels of emissions allowed to be exported from electrical equipment and it also sets requirements as to the susceptibility levels of equipment from external noise sources. In addition it gives guidelines on measuring those features of the equipment. A piece of electrical equipment behaves as a source and will generate EMI. That EMI will be transmitted by conduction and radiation, and be incident upon a receiver (which may be another piece of electrical equipment or a test fixture). The level of the electromagnetic signature of the conducted emissions is determined by the characteristics of the equipment; e.g. SMPS s may be noisy, filament lights may be quiet. If the levels of emissions from the equipment exceed the limits set in MIL-STD-461, then they need to be attenuated by using an EMI filter. The performance of that filter across the frequency spectrum must be to allow the equipment emissions to be suppressed to a level low enough to allow the equipment to claim compliance with the limits of the specification. That filter performance requirement is determined by the electromagnetic signature of the equipment, and what limits are required to be achieved. The filter manufacturer of course can only get this information from the manufacturer of the equipment. Then the claim for compliance can normally be verified by test and measurement. This explains why no filter manufacturer can claim that their filters meet MIL-STD-461; it is not the filter which meets the specification, but the equipment or platform. The situation might be that a filter proposed is above specification requirement, and the equipment conforms to MIL-STD-461 very comfortably. On the other hand, equipment in the system may be so electromagnetically noisy that a proposed filter fails to support the equipment in meeting the limits of MIL-STD-461. are not able to guarantee that the incorporation of a particular filter into the lient s equipment will enable system compliance with the emissions limits of specification MIL-STD-461. All filter manufacturers catalogue their filter performance as insertion loss in a reference (normally 50Ω) impedance system. The filter manufacturer does not know the level of emissions associated with a piece of equipment, nor the real-world terminating impedances as presented to the filter. Hence the published filter insertion loss performance at/across a particular frequency range will not necessarily represent the equivalent attenuation of equipment emissions in application and the equipment manufacturer will need to conduct their own tests to determine the part is suitable and the filtered equipment meets the requirements of MIL-STD-461. In summary MIL-STD-461 is an equipment specification and cannot be applied to filters. We understand some filter manufacturers may be quoting MIL-STD-461 in their literature, but this is either lack of understanding of the specification, or salesmanship. It is the responsibility of the equipment manufacturer to meet MIL-STD-461, and no filter supplier can ever properly quote it. If we have a filter enquiry where the customer refers to MIL- STD-461, we need to ask exactly what level of attenuation they require. We can then suggest part numbers based on that detail, but ultimately they will need to test parts to determine if they are suitable. Professional EM test houses may be able to help suggesting requirements as well. Radiated emissions R are blocked by the casing design. onducted emissions & Radiated emissions as a result of conducted emissions are resolved by using appropriate filters in the case housing. To define the filter, the ratio of emissions to the requirements of MIL-STD-461 must be known. R Introduction to EMI s MIL-STD-461 and EMI s - ommon misconceptions 11

12 Introduction to EMI s Installation of s Surface Mount and Solder-in filters Solder pad layouts are included with the detailed information for each part. Recommended soldering profile See text for maximum temperature Temp Pre-heat Soak Gradual warm-up to reflow Do not thermal shock Reflow Natural cool down Do not force cool Soldering of filters The soldering process should be controlled such that the filter does not experience any thermal shocks which may induce thermal cracks in the ceramic dielectric. The pre-heat temperature rise of the filter should be kept to around 2 per second. In practice successful temperature rises tend to be in the region of 1.5 to 4 per second dependent upon substrate and components. The introduction of a soak after pre-heat can be useful as it allows temperature uniformity to be established across the substrate thus preventing substrate warping. The magnitude or direction of any warping may change on cooling, imposing damaging stresses upon the filter. ool Time E01, E03, E07 SBSP ranges are compatible with all standard solder types including lead-free, maximum temperature 260. For SBSG, SBSM and SFSS ranges, solder time should be minimised, and the temperature controlled to a maximum of 220. For SFSR, SFST and SFSU ranges the maximum temperature is 250. ooling to ambient temperature should be allowed to occur naturally. Natural cooling allows a gradual relaxation of thermal mismatch stresses in the solder joints. Draughts should be avoided. Forced air cooling can induce thermal breakage, and cleaning with cold fluids immediately after a soldering process may result in cracked filters. Note: The use of Flexiap terminations is strongly recommended to reduce the risk of mechanical cracking. Soldering to axial wire leads Soldering temperature The tip temperature of the iron should not exceed 300. Dwell time Dwell time should be 3-5 seconds maximum to minimise the risk of cracking the capacitor due to thermal shock. Heat sink Where possible, a heat sink should be used between the solder joint and the body, especially if longer dwell times are required. Bending or cropping of wire leads Bending or cropping of the filter terminations should not be carried out within 4mm (0.157 ) of the epoxy encapsulation, the wire should be supported when cropping. Soldering irons should not be used for mounting surface mount filters as they can result in thermal shock damage to the chip capacitor. A more comprehensive application note covering installation of all products is available on the website. 12 Installation of s

13 Installation of s Resin filled screw mounted EMI s General The ceramic capacitor, which is the heart of the filter, can be damaged by thermal and mechanical shock, as well as by overvoltage. are should be taken to minimise the risk of stress when mounting the filter to a panel and when soldering wire to the filter terminations. Mounting to hassis It is important to mount the filter to the bulkhead or panel using the recommended mounting torque, otherwise damage may be caused to the capacitor due to distortion of the case. When a threaded hole is to be utilised, the maximum mounting torque should be 50% of the specified figure which relates to unthreaded holes. For details of torque figures for each filter range, please see below. Tools Hexagonal devices should be assembled using a suitable socket. Round bodied filters may be fitted to the panel in one of two ways (and should not be fitted using pliers or other similar tools which may damage them): Round bodies with slotted tops are designed to be screwed in using a simple purpose-designed tool. Round bodies without slotted tops are intended to be inserted into slotted holes and retained with a nut. The thread has flats machined to engage with the flats in the hole. Grounding To ensure the proper operation of the filters, the filter body should be adequately grounded to the panel to allow an effective path for the interference. The use of locking adhesives is not recommended, but if used should be applied after the filter has been fitted. Minimum plate thickness Users should be aware that the majority of these filters have an undercut between the thread and the mounting flange of the body, equal to 1.5 x the pitch of the thread. Mounting into a panel thinner than this undercut length may result in problems with thread mating and filter position. It is recommended that a panel thicker than this undercut length be used wherever possible. Maximum plate thickness This is specified for each filter in order that the nut can be fully engaged even when using a washer. Soldering to axial wire leads Soldering temperature The tip temperature of the iron should not exceed 300. Dwell time Dwell time should be 3-5 seconds maximum to minimise the risk of cracking the capacitor due to thermal shock. Heat sink Where possible, a heat sink should be used between the solder joint and the body, especially if longer dwell times are required. Bending or cropping of wire leads Bending or cropping of the filter terminations should not be carried out within 4mm (0.157 ) of the epoxy encapsulation, the wire should be supported when cropping. RoHS ompliance All surface mount filters, resin sealed panel mount filters and power filters can be supplied fully RoHS compliant (2011/65/EU) through material exemption. Please contact our Sales Office for further details. are must be taken not to exceed the maximum soldering temperatures of surface mount parts. Standard hermetic sealed panel mount filters use SnPb solders as part of their assembly and are intended for exempt applications such as aerospace or military. Substitution of the SnPb solder with Pb free solders may be possible to create a RoHS compliant part, subject to quantities please refer to the Sales Office for more information. Hermetic panel mount EMI filters Tools All these devices should be mounted into appropriate shaped mounting holes. Use of the correct mounting hole will prevent the filter body from turning. Pliers or similar tools must not be used as these will cause damage to the body and risk damage to the hermetic seal or ceramic discoidal. All filters are supplied with appropriate nuts and washers. The nuts should be tightened using a suitable socket set to, or below, the maximum tightening torque as above. Thread design and mounting hole details All the hermetic filters incorporate thread run-outs which may need to be allowed for in panel design. Grounding To ensure the proper operation of the filters, the filter body should be adequately grounded to the panel to allow an effective path for the interference. The use of locking adhesives is not recommended, but if used should be applied after the filter has been fitted. Soldering to axial wire leads Soldering temperature The tip temperature of the iron should not exceed 300. Dwell time Dwell time should be 3-5 seconds maximum to minimise the risk of cracking the capacitor or seal due to thermal shock. Heat sink Where possible, a heat sink should be used between the solder joint and the body, especially if longer dwell times are required. Bending or cropping of wire leads Bending or cropping of the filter terminations should not be carried out as this is likely to result in damage to the glass seal. Introduction to EMI s Installation of s 13

14 Introduction to EMI s Introduction to Surface Mount EMI s Surface Mount s are designed to be mounted directly to printed circuit boards using conventional mounting techniques in the same way as standard ML s. Solder connections are made to each end (signal lines) and each side band (earth or ground). They are categorised into 3 distinct families: 1. E01 / E07 EMI hips (also known as 3-terminal chips) These use conventional ML manufacturing techniques to form a filter which is short circuit end-to-end and has a capacitance between the end terminals and the side (ground) terminals. The signal is carried through the internal electrodes. The current carrying capacity is defined by the cross section and number of the electrodes in the filter and is therefore linked with the capacitance of the filter. ompared to conventional 2-terminal ML devices the internal inductance between line and ground is reduced, giving improved attenuation. 2. Surface mount Pi / s Pi filters incorporate 2 capacitors and an inductor together to make a multi-element filter, giving sharper cut-off and better low frequency performance than straight filters. The range of SM Pi filters use conventional ML manufacturing techniques to form the capacitive element of the filter, but the inductive element is created separately either by means of a bead inductor placed over a through conductor pin, or by means of a buried layer surface mount inductor with the signal carried by the buried internal layers. urrent carrying capacity is defined by the characteristics of the conductor and is independent to the capacitance of the filter. 3. X2Y s X2Y filters are manufactured in the same way as conventional ML s but have a special internal architecture that results in ultra-low ESL (Equivalent Series Inductance) through opposing current flows in adjacent parallel plates. They are not feedthrough devices, but act as bypass filters so are not current limited - the only signal passing through the chip is the filtered noise to ground. They are ideal for twin-line applications such as motors, amplifier inputs or twisted pair (balanced line) applications, where they are fitted between the lines with the centre terminal taken to ground. Incorporating the capacitors in a single ceramic element eliminates any capacitance shift through temperature variation. 10 omparison of 3.3nF SM filter types 0-10 Loss (db) SBSPP -50 ML Feedthrough chip Frequency (MHz) 14 Introduction to Surface Mount EMI s

15 Insertion Loss Insertion Loss figures Insertion loss plots and figures supplied are typical only and are measured on 50Ω stripline open boards, 0.8mm thick FR4 with gold plated tracks. Solder pads are T bar with respect to the track and dimensionally match the recommendations given. The boards are mounted to brass support jigs for mechanical stability and electrical grounding. All measurements are taken using a Vector Network Analyser in a 50Ω system, no load. s mounted on open pcb Input track Pi-filter Output track Introduction to EMI s E01/E07 SBSP SBSG SBSM PB Earth track Improved shielding Signal track Signal track Signal track Signal track Faraday age It is important to recognise that the board material, thickness and layout, the plating finish, the grounding efficiency and the circuit impedances will all have an effect on the actual performance of the filter in operation. The effect of the board makes it difficult to directly compare parts unless the mounting details are defined. It is therefore important to test the filters in circuit to determine the performance level achieved. Effects of mounting method on Insertion Loss and Pi filters are mounted to PBs and soldered in identical manner to chip capacitors. Solder connections made to each end (signal lines) and each side band (earth track). Whilst SBSG, SBSM and SBSP filters can be mounted conventionally on PBs, they are also suitable for mounting in a wall or partition on a board. This greatly improves the screening between filter input and output, thereby enhancing the high frequency response. Input track PB Pi-filter Dirty area lean area Via Output track Ground plane The following insertion loss curves based on actual measurements, show the effect. It can be seen that the filters conventionally mounted exhibit a drop in attenuation at higher frequencies. Shielding methods maintain improved suppression characteristics to 1GHz and above Loss (db) Surface Mount 68nF Pi mounted on open stripline test board Surface Mount 68nF Pi mounted in shielding bulkhead 66nF Pi mounted on shielding bulkhead Frequency (MHz) Insertion Loss 15

16 SBSPP Insertion Loss Open Board Stripline jig. 50ohm System E01 & E07 Insertion Loss pF - 0G 22pF - 0G 47pF - 0G 100pF - 0G 470pF - 0G 2.2nF - 0G 2.2nF - 4.7nF - 10nF - 22nF - 100nF - 200nF - Loss (db) Loss (db) SBSPP 47pF SBSPP 220pF -50 SBSPP 2.2nF -60 SBSPP 10nF SBSPP 47nF SBSPP 150nF Frequency (MHz) Loss (db) Loss (db) SBSG 1.0nF -50 SBSGP 4.7nF -60 SBSG 10nF -60 SBSGP 10nF SBSG 47nF -70 SBSG 220nF SBSGP 47nF SBSGP 220nF Frequency (MHz) Frequency (MHz) See page 20 See page 21 SBSM Insertion Loss Open Board Stripline jig. 50ohm System SBSMP Insertion Loss Open Board Stripline jig. 50ohm System Loss (db) SBSM 1.5nF -50 SBSMP 4.7nF -60 SBSM 4.7nF -60 SBSMP 10nF SBSGP Insertion Loss Open Board Stripline jig. 50ohm System See page 19 SBSG Insertion Loss Open Board Stripline jig. 50ohm System Frequency (MHz) See page 17/18 Loss (db) Introduction to EMI s Insertion Loss - SM High urrent and Pi s SBSM 47nF -70 SBSM 470nF 1 10 Frequency (MHz) See page Insertion Loss - SM High urrent and Pi s SBSMP 68nF SBSMP 470nF 1 10 Frequency (MHz) See page

17 E01 & E07 feedthrough capacitors 0G/NP0 & The E01 and E07 ranges of feedthrough ML chip filters are 3 terminal chip devices designed to offer reduced inductance compared to conventional MLs when used in signal line filtering. The filtered signal passes through the chip internal electrodes and the noise is filtered to the grounded side contacts, resulting in reduced length noise transmission paths. Available in 0G/NP0 and dielectrics, with current ratings of 300mA, 1A, 2A, 3A and voltage ratings of 25Vdc to 200Vdc. Also available with Flexiap termination which is strongly recommended for new designs. ommonly used in automotive applications, a range qualified to AEQ-200 is also available. Surface Mount E01 300mA, E07 1A/2A/3A L E01 / E07 Recommended solder lands T W B2 B1 Earth track Signal track D B E A EMI chip Dimensions L W T B1 B ± 0.2 (0.063 ± 0.008) 0.8 ± 0.2 (0.003 ± 0.008) 0.5 ± 0.15 (0.02 ± 0.006) 0.3 ± 0.2 (0.012 ± 0.008) 0.2 ± 0.1 (0.008 ± 0.004) 2.0 ± 0.3 (0.079 ± 0.012) 1.25 ± 0.2 (0.049 ± 0.008) 1.0 ± 0.15 (0.039 ± 0.006) 0.60 ± 0.2 (0.024 ± 0.008) 0.3 ± 0.15 (0.012 ± 0.006) 3.2 ± 0.3 (0.126 ± 0.012) 1.6 ± 0.2 (0.063 ± 0.008) 1.1 ± 0.2 (0.043 ± 0.008) 0.95 ± 0.3 (0.037 ± 0.012) 0.5 ± 0.25 (0.02 ± 0.01) 4.5 ± 0.35 (0.177 ± 0.014) 1.6 ± 0.2 (0.063 ± 0.008) 1.1 ± 0.2 (0.043 ± 0.008) 1.4 ± 0.3 (0.055 ± 0.012) 0.5 ± 0.25 (0.02 ± 0.01) 4.5 ± 0.35 (0.177 ± 0.014) 3.2 ± 0.3 (0.126 ± 0.012) 2.0 ± 0.3 (0.079 ± 0.012) 1.45 ± 0.35 (0.055 ± 0.012) 0.75 ± 0.25 (0.02 ± 0.01) A 0.60 (0.024) 0.95 (0.037) 1.20 (0.047) 1.2 (0.047) 2.65 (0.104) B 0.60 (0.024) 0.90 (0.035) 0.90 (0.035) 1.40 (0.055) 1.40 (0.055) 0.40 (0.016) 0.30 (0.012) 0.60 (0.024) 0.80 (0.031) 0.80 (0.031) D 0.20 (0.008) 0.40 (0.016) 0.80 (0.031) 1.40 (0.055) 1.40 (0.055) E 0.40 (0.016) 0.75 (0.030) 1.0 (0.039) 1.0 (0.039) 2.05 (0.080) Notes: 1) All dimensions mm (inches). 2) Pad widths less than chip width gives improved mechanical performance. 3) The solder stencil should place 4 discrete solder pads. The unprinted distance between ground pads is shown as dim E. 4) Insulating the earth track underneath the filters is acceptable and can help avoid displacement of filter during soldering but can result in residue entrapment under the chip. E01 E07 hip Size Max urrent 300mA 300mA 300mA 300mA 1A 1A 2A 2A 3A Minimum and maximum capacitance values 25Vdc 50Vdc 100Vdc 200Vdc 0G/NP0 10pF-390pF 180pF-1.5nF 560pF-3.9nF 820pF-4.7nF 10pF-390pF 180pF-1.5nF 560pF-3.9nF 820pF-4.7nF - 2.7nF-18nF 470pF-100nF 5.6nF-330nF 3.9nF-560nF 2.7nF-18nF 820pF-100nF 10nF-330nF 22nF-560nF 560nF-1.8µF 0G/NP0 10pF-56pF 22pF-820pF 22pF-3.3nF 22pF-3.9nF 12pF-56pF 10pF-220pF 22pF-1nF 100pF-1.5nF - 2.7nF-12nF 560pF-68nF 4.7nF-220nF 3.3nF-330nF 2.7nF-12nF 1nF-68nF 10nF-220nF 22nF-330nF 330nF-1.5µF 0G/NP0-22pF-560pF 22pF-2.2nF 22pF-3.3nF - 10pF-120pF 22pF-560pF 100pF-680pF pF-27nF 1.8nF-100nF 3.3nF-180nF - 1nF-27nF 10nF-100nF 22nF-180nF 180nF-820nF 0G/NP pF-1.2nF 56pF-1nF pF-180pF 56pF-470pF nF-56nF 3.9nF-100nF nF-56nF 22nF-100nF 100nF-270nF Notes: 1) E01 ranges in red available as qualified AE-Q200. 2) E07 25Vdc 0G/NP and 1806 ranges in green, have maximum current of 1A. E01 & E07 feedthrough capacitors 17

18 E01 & E07 feedthrough capacitors Insertion Loss Typical open board insertion loss performance in 50Ω system Open Board Performance apacitance 0.1MHz 1MHz 10MHz 100MHz 1GHz Resonance Freq (MHz) approx. Surface Mount EMI chip 10pF pF pF pF pF pF pF pF pF pF pF pF pF nF nF nF nF nF nF nF nF nF nF nF nF nF nF nF nF nF nF Note: For Insertion Loss graph see page 16. Ordering Information - E01 & E07 feedthrough capacitors 1206 Y M X T E07 hip Size Termination apacitance in picofarads (pf) Tolerance Packaging J = Nickel Barrier (Tin) *Y = Flexiap (Tin - only) A = (Tin/Lead) Not RoHS compliant. *H = Flexiap (Tin/Lead) Not RoHS compliant. 025 = 25V 050 = 50V First digit is 0. Second and third digits are significant figures of The fourth digit is number of Example: 0103 = 10000pF. A = 0G/NP0 AE-Q200 = 0G/NP0 E = AE-Q200 X = T = 178mm (7 ) reel R = 330mm (13 ) reel B = Bulk E01 E07 Note: *Flexiap termination only available in material. Please contact our Sales Office for any special requirements. Reeled quantities 178mm (7 ) reel mm (13 ) reel E01 & E07 feedthrough capacitors

19 SBSPP Pi 0G/NP0 & Dimensions L 3.20±0.3 (0.126 ±0.012 ) W 1.65±0.3 (0.065 ±0.012 ) T 1.60±0.20 (0.063 ±0.008 ) B1 0.95±0.3 (0.037 ±0.012 ) B2 0.50±0.25 (0.020 ±0.010 ) Suggested mounting pad details E = Unprinted solder area between ground pads E B Product ode SBSPP M apacitance (±20%) 22pF (dc) (dc) Approximate Resonant Frequency (MHz) Typical No-Load Insertion Loss (db)* 0.1MHz 1MHz 10MHz 100MHz 1GHz SBSPP M 47pF SBSPP M 100pF 0G/NP SBSPP M 220pF SBSPP M 470pF SBSPP MX D 1.0nF A 1.20 (0.047 ) B 0.90 (0.035 ) 0.60 (0.024 ) D 0.80 (0.030 ) E 1.00 (0.039 ) F 2.90 (0.114 ) It is recommended that designers independently confirm pad dimensions are acceptable, particularly with respect to higher working voltages. A F T W L B2 B1 onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) Terminals & - End & Side onstruction Reeled quantities 1000hr Point 1A 10GW or 1000WF -55º to +125º 0.30µH (@ 1MHz) Sn plated over Flexiap Termination eramic Multi Layer hip apacitor Multi Layer Ferrite Bead Inductor onnection via Flexiap Termination 0.07g (0.0025oz) SBSPP MX 1.5nF SBSPP MX 2.2nF SBSPP MX 3.3nF SBSPP MX 4.7nF SBSPP MX 6.8nF SBSPP 178mm (7 ) reel 1500 SBSPP Surface Mount SBSPP MX 10nF SBSPP MX 15nF SBSPP MX 22nF SBSPP MX 33nF SBSPP MX 47nF SBSPP MX 68nF SBSPP MX 100nF SBSPP MX 150nF * Insertion Loss performance quoted is measured on an open FR4 board mounted on a brass backplane in a 50Ω system. Performance curves can be supplied on request. Performance in circuit is liable to be different and is affected by board material, track layout, grounding efficiency and circuit impedances. Shielding can be used to improve high frequency performance. Ordering Information - SBSPP range SB S P P M X B Board ase Surface Mount Size Size ode P (nominally 1206) configuration P = Pi (dc) apacitance in picofarads (pf) Tolerance Packaging 025 = 25V 050 = 50V Note: The addition of a 4-digit numerical suffix code can be used to denote changes to the standard part. Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. First digit is 0. Second and third digits are significant figures of zeros following Example: 0472 = 4700pF 0153 = 15000pF = 0G/NP0 X = T=178mm (7 ) reel R=330mm (13 ) reel B = Bulk SBSPP Surface Mount EMI s 19

20 SBSG Surface Mount Suggested mounting pad details E Dimensions L1 4.55±0.25 (0.179 ±0.010 ) L2 4.70±0.4 (0.185 ±0.015 ) W 3.20±0.2 (0.126 ±0.008 ) T 2.50±0.15 (0.098 ±0.006 ) B1 1.50±0.4 (0.059 ±0.015 ) B2 0.30±0.25 (0.012 ±0.010 ) E = Unprinted solder area between ground pads D B2 A F L2 L1 W B1 Tin plated solderable termination area Solder joint from filter manufacture A 2.65 (0.104 ) B 1.40 (0.055 ) 0.08 (0.031 ) D 1.40 (0.055 ) T onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) Terminals & - End Terminals & - Side Reflow Temperature 1000hr Point 10A 10GW or 1000WF -55º to +125º N/A SnAg solder over Sn Plate Sn Plated 220º max. eramic Multi Layer hip apacitor opper Alloy Through onductor Soldered End onnections 0.20g (0.007oz) B E 2.05 (0.080 ) F 5.80 (0.228 ) Reeled quantities SBSG 178mm (7 ) reel 500 It is recommended that designers independently confirm pad dimensions are acceptable, particularly with respect to higher working voltages. SBSG Product ode SBSG MX apacitance (±20%) 1.0nF (dc) (dc) Approximate Resonant Frequency (MHz) Typical No-Load Insertion Loss (db)* 0.1MHz 1MHz 10MHz 100MHz 1GHz SBSG MX 1.5nF SBSG MX 2.2nF SBSG MX 3.3nF SBSG MX 4.7nF SBSG MX 6.8nF SBSG MX 10nF SBSG MX 15nF SBSG MX 22nF SBSG MX 33nF SBSG MX 47nF SBSG MX 68nF SBSG MX 100nF SBSG MX 150nF SBSG MX 220nF * Insertion Loss performance quoted is measured on an open FR4 board mounted on a brass backplane in a 50Ω system. Performance curves can be supplied on request. Performance in circuit is liable to be different and is affected by board material, track layout, grounding efficiency and circuit impedances. Shielding can be used to improve high frequency performance. Ordering Information - SBSG range SB S G M X B Board ase Surface Mount Size configuration Size ode G = (nominally 1812) (dc) apacitance in picofarads (pf) Tolerance Packaging 050 = 50V Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. First digit is 0. Second and third digits are significant figures of zeros following Example: 0472 = 4700pF 0683 = 68000pF X = T = 178mm (7 ) reel R = 330mm (13 ) reel B = Bulk 20 SBSG Surface Mount EMI s

21 SBSGP Pi Suggested mounting pad details E Dimensions L1 4.55±0.25 (0.179 ±0.010 ) L2 5.25±0.4 (0.207 ±0.015 ) W 3.20±0.2 (0.126 ±0.008 ) T 2.50±0.15 (0.098 ±0.006 ) B1 1.50±0.4 (0.059 ±0.015 ) B2 0.30±0.25 (0.012 ±0.010 ) E = Unprinted solder area between ground pads B Product ode SBSGP MX D apacitance (±20%) 1.0nF A F A 2.65 (0.104 ) B 1.40 (0.055 ) 0.80 (0.031 ) D 1.40 (0.055 ) E 2.05 (0.080 ) F 5.80 (0.228 ) It is recommended that designers independently confirm pad dimensions are acceptable, particularly with respect to higher working voltages. B2 L2 L1 B1 W Tin plated solderable termination area Solder joint from filter manufacture T (dc) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) Terminals & - End Terminals & - Side Reflow Temperature onstruction Reeled quantities (dc) Approximate Resonant Frequency (MHz) 1000hr Point 5A 10GW or 1000WF -55º to +125º 0.7µH (@ 100kHz) SnAg solder over Sn Plate Sn Plated 220º max. eramic Multi Layer hip apacitor opper Alloy Through onductor Ferrite Bead Inductor Soldered End onnections 0.20g (0.007oz) Typical No-Load Insertion Loss (db)* 0.1MHz 1MHz 10MHz 100MHz 1GHz SBSGP MX 1.5nF SBSGP MX 2.2nF SBSGP MX 3.3nF SBSGP MX 4.7nF SBSGP MX 6.8nF SBSGP MX 10nF SBSGP MX 15nF SBSGP MX 22nF SBSGP MX 33nF SBSGP MX 47nF SBSGP MX 68nF SBSGP MX 100nF SBSGP MX 150nF SBSGP MX 220nF * Insertion Loss performance quoted is measured on an open FR4 board mounted on a brass backplane in a 50Ω system. Performance curves can be supplied on request. Performance in circuit is liable to be different and is affected by board material, track layout, grounding efficiency and circuit impedances. Shielding can be used to improve high frequency performance. SBSGP 178mm (7 ) reel 500 SBSGP Surface Mount Ordering Information - SBSGP range SB S G P M X B Board ase Surface Mount Size configuration Size ode G P = Pi (nominally 1812) (dc) apacitance in picofarads (pf) Tolerance Packaging 050 = 50V Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. First digit is 0. Second and third digits are significant figures of zeros following Example: 0472 = 4700pF 0683 = 68000pF X = T = 178mm (7 ) reel R = 330mm (13 ) reel B = Bulk SBSGP Surface Mount EMI s 21

22 SBSM Surface Mount Suggested mounting pad details E Dimensions L1 5.7±0.4 (0.224 ±0.015 ) L2 6.6±0.4 (0.260 ±0.015 ) W 5.0±0.4 (0.197 ±0.015 ) T 3.18±0.2 (0.125 ±0.008 ) B1 2.25±0.4 (0.088 ±0.015 ) B2 0.30±0.25 (0.012 ±0.010 ) E = Unprinted solder area between ground pads D B2 F A L2 L1 W T B1 Tin plated solderable termination area Solder joint from filter manufacture A (0.394 ) B 2.35 (0.093 ) 1.35 (0.053 ) D 2.00 (0.079 ) E 3.95 (0.156 ) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) Terminals & - End Terminals & - Side Reflow Temperature onstruction Reeled 1000hr Point 20A 10GW or 1000WF -55º to +125º N/A ( Section) Snu solder over Sn Plate Sn Plated 220º max. eramic Multi Layer hip apacitor opper Alloy Through onductor Soldered End onnections 0.65g (0.023oz) SBSM B F 7.80 (0.307 ) 178mm (7 ) reel 500 It is recommended that designers independently confirm pad dimensions are acceptable, particularly with respect to higher working voltages. SBSM Product ode SBSM MX apacitance (±20%) 1.0nF (dc) (dc) Approximate Resonant Frequency (MHz) Typical No-Load Insertion Loss (db)* 0.1MHz 1MHz 10MHz 100MHz 1GHz SBSM MX 1.5nF SBSM MX 2.2nF SBSM MX 3.3nF SBSM MX 4.7nF SBSM MX 6.8nF SBSM MX 10nF SBSM MX 15nF SBSM MX 22nF SBSM MX 33nF SBSM MX 47nF SBSM MX 68nF SBSM MX 100nF SBSM MX 150nF SBSM MX 220nF SBSM MX 330nF SBSM MX 470nF * Insertion Loss performance quoted is measured on an open FR4 board mounted on a brass backplane in a 50Ω system. Performance curves can be supplied on request. Performance in circuit is liable to be different and is affected by board material, track layout, grounding efficiency and circuit impedances. Shielding can be used to improve high frequency performance. Ordering Information - SBSM range SB S M M X B Board ase Surface Mount Size configuration Size ode M = (nominally 2220) (dc) apacitance in picofarads (pf) Tolerance Packaging 050 = 50V Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. First digit is 0. Second and third digits are significant figures of zeros following Example: 0472 = 4700pF 0683 = 68000pF X = T = 178mm (7 ) reel R = 330mm (13 ) reel B = Bulk 22 SBSM Surface Mount EMI s

23 SBSMP Pi Dimensions L1 5.7±0.4 (0.224 ±0.015 ) L2 6.6±0.4 (0.260 ±0.015 ) W 5.0±0.4 (0.197 ±0.015 ) T 3.18±0.2 (0.125 ±0.008 ) B1 2.25±0.4 (0.088 ±0.015 ) B2 0.30±0.25 (0.012 ±0.010 ) Suggested mounting pad details E = Unprinted solder area between ground pads E D B2 A F L2 L1 B1 W Tin plated solderable termination area Solder joint from filter manufacture A 5.00 (0.197 ) B 2.35 (0.093 ) 1.35 (0.053 ) D 2.00 (0.079 ) T onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) Terminals & - End Terminals & - Side Reflow Temperature onstruction 1000hr Point 10A 10GW or 1000WF -55º to +125º 0.22µH (@ 100kHz) Snu solder over Sn Plate Sn Plated 220º max. eramic Multi Layer hip apacitor opper Alloy Through onductor Ferrite Bead Inductor Soldered End onnections 0.6g (0.021oz) Surface Mount B E 3.95 (0.156 ) F 7.80 (0.307 ) Reeled quantities SBSMP 178mm (7 ) reel 500 It is recommended that designers independently confirm pad dimensions are acceptable, particularly with respect to higher working voltages. Product ode SBSMP MX apacitance (±20%) 1.0nF (dc) (dc) Approximate Resonant Frequency (MHz) Typical No-Load Insertion Loss (db)* 0.1MHz 1MHz 10MHz 100MHz 1GHz SBSMP MX 1.5nF SBSMP MX 2.2nF SBSMP MX 3.3nF SBSMP MX 4.7nF SBSMP MX 6.8nF SBSMP MX 10nF SBSMP MX 15nF SBSMP MX 22nF SBSMP MX 33nF SBSMP MX 47nF SBSM MX 68nF SBSMP MX 100nF SBSMP MX 150nF SBSMP MX 220nF SBSMP MX 330nF SBSMP MX 470nF * Insertion Loss performance quoted is measured on an open FR4 board mounted on a brass backplane in a 50Ω system. Performance curves can be supplied on request. Performance in circuit is liable to be different and is affected by board material, track layout, grounding efficiency and circuit impedances. Shielding can be used to improve high frequency performance. SBSMP Ordering Information - SBSMP range SB S M P M X B Board ase Surface Mount Size configuration Size ode M P = Pi (nominally 2220) (dc) apacitance in picofarads (pf) Tolerance Packaging 050 = 50V Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. First digit is 0. Second and third digits are significant figures of zeros following Example: 0472 = 4700pF 0683 = 68000pF X = T = 178mm (7 ) reel R = 330mm (13 ) reel B = Bulk SBSMP Surface Mount EMI s 23

24 X2Y - Integrated Passive omponent 0G/NP0 & Surface Mount The X2Y Integrated Passive omponent is a 3 terminal EMI chip device. When used in balanced line applications, the revolutionary design provides simultaneous line-to-line and line-toground filtering, using a single ceramic chip. In this way, differential and common mode filtering are provided in one device. For unbalanced applications, it provides ultra low ESL (equivalent series inductance). apable of replacing 2 or more conventional devices, it is ideal for balanced and unbalanced lines, twisted pairs and dc motors, in automotive, audio, sensor and other applications. Available in sizes from 0805 to 2220, these filters can prove invaluable in meeting stringent EM demands. Manufactured in the UK by Technology Limited under licence from X2Y Attenuators LL. or 0G/NP0 configuration Multiple capacitance apacitance measurement At 1000hr point Typical capacitance matching Better than 5% (down to 1% available on request) Temperature rating -55 to 125 Insulation resistance 100Gohms or 1000s (whichever is the less) withstand voltage <200V 2.5 times rated Volts for 5 secs 500V 1.5 times rated Volts for 5 secs harging current limited to 50mA Max. X2Y E03 hip size voltage 16Vdc 0G/NP Vdc 0G/NP0 560pF - 820pF 1.8nF - 3.3nF 6.8nF - 8.2nF 12nF - 15nF 22nF - 33nF 56nF - 68nF - 470nF 820nF 1.2µF 50Vdc 0G/NP0 390pF - 470pF 1.2nF - 1.5nF 4.7nF - 5.6nF 8.2nF - 10nF 18nF 18nF - 47nF 56nF - 220nF 180nF - 400nF 390nF - 680nF 560nF - 1.0µF 100Vdc 0G/NP0 10pF - 330pF 22pF - 1.0nF 100pF - 3.9nF 820pF - 6.8nF 1.0nF - 15nF 470pF - 15nF 1.5nF - 47nF 4.7nF - 150nF 8.2nF - 330nF 10nF - 470nF 200Vdc 0G/NP0-22pF - 1.0nF 100pF - 3.3nF 820pF - 5.6nF 1.0nF - 15nF - 820pF - 33nF 1.2nF - 120nF 2.7nF - 180nF 4.7nF - 470nF 500Vdc 0G/NP pF - 3.9nF 1.0nF - 10nF nF - 100nF 4.7nF - 180nF Notes: 1) For some lower capacitance parts, higher voltage rated parts may be supplied L 2.0±0.3 (0.08±0.012) 3.2±0.3 (0.126±0.012) 3.6±0.3 (0.14±0.012) 4.5±0.35 (0.18±0.014) 5.7±0.4 (0.22±0.016) L W 1.25±0.2 (0.05±0.008) 1.60±0.2 (0.063±0.008) 2.5±0.3 (0.1±0.012) 3.2±0.3 (0.126±0.012) 5.0±0.4 (0.2±0.016) T T 1.0±0.15 (0.04±0.006) B1 0.5±0.25 (0.02±0.01) 1.1±0.2 (0.043±0.008) 0.95±0.3 (0.037±0.012) 2.0 max. (0.08 max.) 1.20±0.3 (0.047±0.012) 2.1 max. (0.08 max.) 1.4±0.35 (0.06±0.014) 2.5 max. (0.1 max.) 2.25±0.4 (0.09±0.016) W B2 B1 B2 0.3±0.15 (0.012±0.006) 0.5±0.25 (0.02±0.01) 0.5±0.25 (0.02±0.01) 0.75±0.25 (0.03±0.01) 0.75±0.25 (0.03±0.01) Notes: 1) All dimensions mm (inches). 2) Pad widths less than chip width gives improved mechanical performance. 3) The solder stencil should place 4 discrete solder pads. The un-printed distance between ground pads is shown as dim E. 4) Insulating the earth track underneath the filters is acceptable and can help avoid displacement of filter during soldering but can result in residue entrapment under the chip. Recommended solder lands D A 0.95 (0.037) 1.2 (0.047) 2.05 (0.08) 2.65 (0.104) 4.15 (0.163) B E A B 0.9 (0.035) 0.9 (0.035) 1.0 (0.040) 1.4 (0.055) 1.4 (0.055) 0.3 (0.012) 0.6 (0.024) 0.7 (0.028) 0.8 (0.031) 1.2 (0.047) D 0.4 (0.016) 0.8 (0.031 ) 0.9 (0.035) 1.4 (0.055) 1.8 (0.071) E 0.75 (0.030) 1.0 (0.039) 1.85 (0.071) 2.05 (0.080) 3.95 (0.156) 24 X2Y - Integrated Passive omponent

25 X2Y - Integrated Passive omponent 0G/NP0 & AE-Q200 range (E03) - capacitance values hip size Vdc 100Vdc 0G/NP0 390pF - 470pF 1.2nF - 1.5nF 4.7nF - 5.6nF 8.2nF - 10nF 18nF - 33nF 56nF - 150nF 180nF - 330nF 390nF- 560nF 0G/NP0 10pF - 330pF 22pF - 1.0nF 100pF - 3.9nF 820pF - 6.8nF 470pF - 15nF 1.5nF - 47nF 4.7nF - 150nF 8.2nF - 330nF Surface Mount omponent Advantages Disadvantages Applications hip capacitor Industry standard Requires 1 per line High inductance apacitance matching problems By-pass Low frequency 3 terminal feedthrough Feedthrough Lower inductance urrent limited Feedthrough Unbalanced lines High frequency X2Y Integrated Passive omponent Very low inductance Replaces 2 (or 3) components Negates the effects of temperature, voltage and ageing Provides both common mode and differential mode attenuation an be used on balanced & unbalanced lines are must be taken to optimise circuit design By-pass Balanced lines High frequency dc electric motors Unbalanced lines Audio amplifiers ANBUS X2Y ing application Decoupling application INPUT 1 GROUND A 1 2 A SIGNAL 1 INPUT 2 B 1 B RETURN 1 Insertion loss (db) nF 27pF 100nF 100pF nF 400nF 470pF 1nF 680nF 10nF Frequency (MHz) Insertion loss (db) 0 470pF -10 1nF nF 10nF 100nF Frequency (MHz) Ordering Information - X2Y IP range 1812 Y M X T E03 hip Size Termination J = Nickel Barrier (Tin) *Y = Flexiap (Tin - only) A = (Tin/Lead) Not RoHS compliant. *H = Flexiap (Tin/Lead) Not RoHS compliant. 016 = 16V 025 = 25V 050 = 50V apacitance in picofarads (pf) 1 Tolerance Packaging First digit is 0. Second and third A = 0G/NP0 T = 178mm (7 ) X2Y digits are significant figures of AE-Q200 reel Integrated = 0G/NP0 R = 330mm Passive zeros (13 ) reel omponent following Example: 0334=330nF. Note: 1 = 2 2 (Tighter tolerances may be available on request). E = AE-Q200 X = B = Bulk Note: *Flexiap termination only available in material. Please contact the sales office for any special requirements. Reeled quantities 178mm (7 ) reel mm (13 ) reel X2Y - Integrated Passive omponent 25

26 Packaging information - SM s Tape and reel packing of surface mount EMI filters for automatic placement is in accordance with IE Reel dimensions mm (inches) Surface Mount Plastic carrier tape Product identifying label A 1.5(.06) min 20.2(0.795) min 13(0.512) ± 0.5(0.02) T 60(2.36) min G Top tape Embossment 8 or 12mm nominal 178mm (7 ) or 330mm (13 ) dia. reel Symbol Description 178mm reel 330mm reel Peel force The peel force of the top sealing tape is between 0.2 and 1.0 Newton at 180. The breaking force of the carrier and sealing tape in the direction of unreeling is greater than 10 Newtons. A Reel diameter 178 (7) 330 (13) G Reel inside width 8.4 (0.33) 12.4 (0.49) T Reel outside width 14.4 (0.56) max 18.4 (0.72) max Tape dimensions Feed direction T D 0 P 0 Sealing tape P 2 E K 0 B0 F W t 1 D 1 P 1 A 0 Embossment avity centre lines Dimensions mm (inches) Symbol Description 8mm tape 12mm tape A 0 B 0 K 0 Width of cavity Length of cavity Depth of cavity Dependent on chip size to minimise rotation W Width of tape 8.0 (0.315) 12.0 (0.472) F Distance between drive hole centres and cavity centres 3.5 (0.138) 5.5 (0.213) E Distance between drive hole centres and tape edge 1.75 (0.069) P 1 Distance between cavity centres 4.0 (0.156) 8.0 (0.315) P 2 Axial distance between drive hole centres and cavity centres 2.0 (0.079) P 0 Axial distance between drive hole centres 4.0 (0.156) D 0 Drive hole diameter 1.5 (0.059) D 1 Diameter of cavity piercing 1.0 (0.039) 1.5 (0.059) XT arrier tape thickness 0.3 (0.012) ±0.1 (0.004) 0.4 (0.016) ±0.1 (0.004) Xt 1 Top tape thickness 0.1 (0.004) max 26 Packaging information - SM s

27 Packaging information - SM s Missing components The number of missing components in the tape may not exceed 0.25% of the total quantity with not more than three consecutive components missing. This must be followed by at least six properly placed components. Identification Each reel is labelled with the following information: manufacturer, product code, capacitance, tolerance, rated voltage, dielectric type, batch number, date code and quantity of components. Leader and Trailer END 40 empty sealed length is embossments minimum quantity dependent TRAILER OMPONENTS 20 sealed embossments minimum LEADER 400mm min. START Surface Mount omponent orientation Tape and reeling is in accordance with IE part 3, which defines the packaging specifications of leadless components on continuous tapes. Notes: 1) IE states Ao < Bo (see Tape dimensions on page 44). T W Product identifying label Outer Packaging Outer carton dimensions mm (inches) max. Reel Size No. of reels L W T L 178 (7.0) (7.28) 185 (7.28) 25 (0.98) 178 (7.0) (7.48) 195 (7.76) 75 (2.95) 330 (13.0) (13.19) 335 (13.19) 25 (0.98) Note: Labelling of box and reel with bar codes (ode 39) available by arrangement. Reel quantities hip size SBSG SBSM SBSP Max. chip thickness 0.5mm 1.0mm 1.1mm 2.0mm 1.1mm 2.1mm 2.5mm 2.5mm 3.18mm 1.6mm Reel quantities 178mm (7 ) mm (13 ) / / / / Bulk packing - tubs hips are supplied in rigid re-sealable plastic tubs together with impact cushioning wadding. Tubs are labelled with the details: chip size, capacitance, tolerance, rated voltage, dielectric type, batch number, date code and quantity of components. Dimensions mm (inches) H 60 (2.36) H Product identifying label aution label D 50 (1.97) D Packaging information - SM s 27

28 Introduction to EMI filters Introduction to s filters are designed to be mounted into a wall or bulkhead that is forming a Faraday cage. The body of the filter acts as the ground connection and the lead pin carries the signal through the filter. All panel mount filters are true feedthrough devices incorporating discoidal capacitors for the maximum performance over the widest frequency range. Performance plots to 15GHz can be supplied on demand. The range of filters have the following advantages Robust construction Feedthrough designs (no chip or leaded 2 terminal capacitors) High / High capacitance Stable and Ultra-Stable 0G/NP0 dielectrics ircuit types include, L-, T and Pi as catalogue standards Multi-element configurations (e.g. L--L--L circuits) are also available as custom designs The panel mount range can be categorised into five distinct families: Family Part numbers Description Disc-on-pin filters Solder-in body filters Threaded ceramic based filters SFSS* SFSR SFST SFSU All other SF** part numbers The lowest cost option. Discoidal feedthrough capacitor mounted on a feedthrough pin. Designed to be solder mounted into panel. Exposed ceramic means care must be taken in handling and operating conditions. As above but with the added benefit of the capacitor being protected by a machined brass body and resin seal. Easier to use and offers greater protection to the ceramic component. Single or multi element filters mounted in threaded bodies and resin sealed. Most can be supplied with appropriate mounting hardware. A very wide range of options to suit most mechanical requirements. Screw-mount hermetic ceramic based filters SLS* SLO* As above, but with the resin replaced by compressive glass-to-metal hermetic seals. Designed for use in harsh environments where the resin seal would not be adequate. All parts are 100% tested for hermetic performance during manufacture. Screw-mount plastic film based high current filters All other SL part numbers Full feedthrough filters utilising self-healing plastic film wound capacitors instead of ceramic discoidals. or Pi filters with high current carrying capacity spindles. Very high current handling capability (to 300A) and higher capacitance than ceramic parts. All parts can be offered with additional Hi-Rel testing (for example burn-in). Please refer to factory. 28 Introduction to EMI s

29 Introduction to EMI filters Non-Hermetic s onstruction The non-hermetic panel mount filter ranges feature silver plated brass bodies and copper alloy pins. In all cases the capacitive element is a low ESR high performance discoidal ceramic multilayer device. Tin/lead metalwork plating is available as an option and tin can be considered but is not recommended due to the potential for tin whiskers. Non-standard finishes may incur additional charges or minimum order quantities.where applicable, sealing is by high purity glob top encapsulant, heat cured. Inductors Inductors are ferrite beads. These may suffer from saturation under full operating conditions. and urrent rating All voltage and current ratings are quoted over the full operating temperature range -55º to +125º. Allowance should be made for anticipated surge currents. Any voltage spike withstand requirements should be referred to the factory as they can have a serious effect on the reliability of the device. s with a dual dc/ac voltage rating are identified in the individual datasheets. Other filters may also be suitable for use under ac voltage conditions, please refer enquiries to the factory. In all cases where a filter is operated under ac conditions, current flow to ground through the capacitor and self-heating of the device will occur, dependent on the capacitance, frequency and voltage. It is the responsibility of the customer to determine if operation in application is acceptable. Hermetic s onstruction The hermetically sealed screw-in panel mount EMI SL range filters feature bright tin plated steel bodies and bright tin plated copper alloy conductors. In all cases the capacitive element is a low ESR high performance discoidal ceramic multilayer device. All parts are hermetically sealed to provide environmental protection to the internal elements with zero outgassing. The filters are 100% tested for sealing performance during manufacture. Plating All the hermetically sealed EMI filters are plated with bright tin after assembly. The internal surfaces are copper plated to prevent whisker growth inside the filter assembly. Alternative plating finishes (eg nickel/silver/gold/snpb) are available - please contact the factory to discuss your requirements. Rating The quoted voltage rating is the maximum dc voltage up to 125º. spikes can have a significant effect on the reliability of the filter and must be taken into account if anticipated. If in doubt, please contact the factory. s may also be suitable for use under ac voltage conditions, please refer enquiries to the factory. In all cases where a filter is operated under ac conditions, current flow to ground through the capacitor and self-heating of the device will occur, dependent on the capacitance, frequency and voltage. It is the responsibility of the customer to determine if operation in application is acceptable. urrent Rating All current ratings quoted are maximum continuous operating currents for temperatures up to 105º. Between 105º and 125º the current rating must be de-rated linearly from 100% quoted maximum to 60% quoted maximum. Allowance must be made for any anticipated surge currents. Resistor ertain filters are also available with a 4.7MΩ shunt resistor fitted in parallel to the capacitive element to prevent static charge and to ensure safe discharge of the capacitor. See data sheets for details. Metallised Film Feedthrough filters EMI Power filters designed for applications where currents up to several hundred amps are required. Utilising plastic film technology the range includes high ac and dc working voltage options along with parts designed and tested to meet the rigorous demands of EN132400/EN60950 safety specifications. Typical applications include: IT servers, telecoms base stations, MRI room equipment, power supplies, radar and military vehicles. s designed and tested to meet EN132400/EN60950 class Y2 and Y4 requirements are intended for use on mains supply systems or lower voltage lines where safety is important. This range includes dc and ac rated feedthrough filters with current ratings to 200A continuous. In addition to the standard range, certain items are tested to meet the requirements of EN & EN60950 class Y2 and class Y4 with respect to creepage and clearance and the higher and pulse test requirements. onstruction onstruction is solder-less for maximum reliability and all parts have nickel plated, threaded through conductors for ease of connection and reliable high current capacity. All use wound plastic self-healing feedthrough capacitors mounted in nickel plated bodies. Rating s with a dual dc/ac voltage rating are identified in the individual datasheets. Other filters may also be suitable for use under ac voltage conditions, please refer enquiries to the factory. In all cases where a filter is operated under ac conditions, current flow to ground through the capacitor and self-heating of the device will occur, dependent on the capacitance, frequency and voltage. It is the responsibility of the customer to determine if operation in application is acceptable. urrent Rating Each individual datasheet includes current derating information for higher operating temperatures. It is important that these derating curves are adhered to, as excessive current may seriously damage the internal capacitor element. Y2 Ratings and characteristics voltage 250Vac 50/60 Hz Test voltage 5000Vdc 2 seconds apacitor class (EN132400) Y2 current 10A to 100A Pulse test (EN132400) 5000V peak Insulation resistance: (within 1 minute) < 0.33μF, R > 15000MΩ > 0.33μF, R > 5000s (MΩμF) dc resistance < 6mΩ Temperature range -40º to +85º Insulating materials flammability rating UL94 V-0 Y4 Ratings and characteristics voltage Test voltage apacitor class (EN132400) current Pulse test (EN132400) 130Vac 50/60 Hz (Also 130Vdc) 2500Vdc 2 seconds Y4 10A to 100A 2500V peak Insulation resistance: (within 1 minute) < 0.33μF, R > 15000MΩ > 0.33μF, R > 5000s (MΩμF) dc resistance < 6mΩ Temperature range -40º to +85º Insulating materials flammability rating UL94 V-0 Safety are should be taken not to exceed the maximum rated voltage and current for the filter. All the filters in this catalogue are designed to operate at high currents/high voltages and may be fitted with high capacitances resulting in a potential electric shock hazard. energy may be stored for some time after switch off do not handle filters without first discharging and/or checking that the stored voltage is at a low level. Introduction to s Introduction to EMI s 29

30 Introduction to EMI filters Introduction to s Insertion Loss figures Insertion loss plots and figures supplied are typical only and are measured on in small cavity closed chambers to allow measurements to 10GHz for most s. Individual performance plots can be supplied on request. All feedthrough filters display a resonance at some point in the insertion loss sweep and this will be evident in any supplied plot - the Example curves Insertion Loss Loss (db) Pi Insertion Loss Loss (db) nF filter 68nF filter 330nF filter 3.3µF filter frequency and magnitude of these resonances varies with the design of the test chamber being used. All typical figures tabulated on the datasheets ignore these resonances. If a direct comparison test between components is required, we are happy to carry this out. All measurements are taken using a Vector Network Analyser in a 50Ω system, no load Frequency (MHz) 94nF Pi filter 6.6nF Pi filter 940nF Pi filter 6.6µF Pi filter Frequency (MHz) 30 Introduction to EMI s

31 SFSS 0G/NP0 & Discoidal apacitors with Leads Ordering Information - SFSS range SF S S M X 0 /0046 ØD Suffix ode 0 = Without /0066 /0096 /0046 /0097 ase Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers Solder S = Special (no case) PIN Ød 15.0 (0.590) = 32.0 (1.260) 2.00 (0.079) Standard dimensions shown. Lead lengths can be customised - Refer to factory (0.590) Suffix ode ap. Diameter (D) 2.3mm (0.091") 2.8mm (0.110") 3mm (0.118") 5mm (0.197") 8.75mm (0.344") Pin Diameter (d) 0.7mm (0.028") 0.7mm (0.028") 0.7mm (0.028") 0.7mm (0.028") 1.0mm (0.039") apacitance Tol. -20% +80% -20%+80% up to 47pF ±20% 68pF & above 050 = 50V 1K0 = 1kV 2K0 = 2kV 3K0 = 3kV -20%+80% up to 47pF ±20% 68pF & above First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF ±20% ±20% Max. urrent Rating 10A 10A 10A 10A 15A d.c. 50V 100V 200V 500V 50V 100V 200V 300V 500V 50V 100V 200V 300V 500V 50V 100V 200V 300V 500V 50V 100V 200V 300V 500V 1kV 2kV 3kV 10pF 0G 0G 15pF 0G 22pF 0G 0G 33pF 0G 47pF 0G 0G 68pF 0G 100pF 0G 0G 0G 150pF 0G 0G 220pF 0G 0G 0G 330pF 0G 0G 470pF 0G 680pF 0G 1.0nF 0G 1.5nF 2.2nF 3.3nF 4.7nF 6.8nF 10nF 15nF 22nF 33nF 47nF 68nF 100nF 150nF 220nF 330nF 470nF 680nF ap Value 1.0µF 1.5µF 2.2µF 3.3µF onfiguration apacitance 1000hr Point urrent Rating See Table Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicable Max Soldering Temperature 250 Temperature Rise Less than 4 per second Soldering Time 10 seconds maximum Solder Sn62/SA or equivalent Pin Material opper Alloy (silver plated) Withstand (D.W.V) D.W.V. D.W.V. 50Vdc 125Vdc 500Vdc 750Vdc 100Vdc 250Vdc 1000Vdc 1200Vdc 200Vdc 500Vdc 2000Vdc 2400Vdc 300Vdc 550Vdc 3000Vdc 3600Vdc Z = % = 0G/ NP0 X = Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values/test requirements. Please refer specific requests to the factory. SFSS Solder-in 31SFNO SFSS Solder-in

32 SFSR 0G/NP0 & SFSR Ø3.2 (0.126) 6.0 ± 1.0 (0.236) 0.25 (0.010) 9.0 ± 1.0 (0.354) Ø2.8 ± 0.1 (0.110) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 10A 10GW or 1000WF -55º to +125º Not Applicable PIN Ø 0.7 (0.028) 3.0 (0.118) Body Flange Diameter 3.2mm (0.126 ) Mounting Hole Diameter 3.0mm (0.118 ) Max Soldering Temperature 250 Temperature Rise Less than 4 per second Solder-in 2.8mm Body Diameter Epoxy Sealed Soldering Time Solder 10 seconds maximum Sn62/SA or equivalent 0.4g (0.015oz) Silver plate on copper undercoat Product ode apacitance ( %) Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFSR Z0 10pF SFSR Z0 22pF SFSR Z0 47pF 0G/NP *SFSR Z0 100pF SFSR Z0 220pF 500# SFSR ZX0 470pF *SFSR ZX0 1.0nF SFSR ZX0 2.2nF *SFSR ZX0 4.7nF *SFSR ZX0 10nF *SFSR ZX0 22nF *SFSR ZX0 47nF # Also rated for operation at 115Vac 400Hz. Self healing will occur - evaluation in situ recommended. * Recommended values. Ordering Information - SFSR range SF S R Z X 0 ase Dia. configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers Solder 2.8mm = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 32 SFSR Solder-in

33 SFST 0G/NP0 & Ø4.0 (0.157) 6.0 ± 1.0 (0.236) 0.5 (0.020) 9.0 ± 1.0 (0.354) Ø3.25 ± 0.1 (0.128) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 10A 10GW or 1000WF -55º to +125º Not Applicable SFST PIN Ø 0.7 (0.028) 2.8 (0.110) Body Flange Diameter 4.0mm (0.157 ) Mounting Hole Diameter 3.5mm (0.138 ) Max Soldering Temperature 250 Temperature Rise Less than 4 per second 3.25mm Body Diameter Epoxy Sealed Soldering Time Solder 10 seconds maximum Sn62/SA or equivalent 0.4g (0.015oz) Silver plate on copper undercoat Solder-in Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFST Z0 10pF -20% / +80% SFST Z0 15pF -20% / +80% SFST Z0 22pF -20% / +80% SFST Z0 33pF -20% / +80% SFST Z0 47pF -20% / +80% SFST M0 68pF G/NP0 *SFST M0 100pF SFST M0 150pF SFST M0 220pF SFST M0 330pF SFST M0 470pF 500# SFST M0 680pF SFST MX0 1.0nF *SFST MX0 1.5nF *SFST MX0 2.2nF *SFST MX0 3.3nF *SFST MX0 4.7nF SFST MX0 6.8nF *SFST MX0 10nF SFST MX0 15nF *SFST MX0 22nF *SFST MX0 33nF SFST MX0 47nF SFST MX0 68nF >70 SFST MX0 100nF >70 # Also rated for operation at 115Vac 400Hz. Self healing will occur - evaluation in situ recommended. * Recommended values. Ordering Information - SFST range SF S T M X 0 ase Dia. configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers Solder 3.25mm = 050 = 50V 300 = 300V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFST Solder-in 33

34 SFSU 0G/NP0 & SFSU Ø6.5 (0.256) 6.0 ± 1.0 (0.236) 0.5 (0.020) 9.0 ± 1.0 (0.354) Ø5.6 ± 0.1 (0.220) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 10A 10GW or 1000WF -55º to +125º Not Applicable Body Flange Temperature 6.5mm (0.256 ) Solder-in PIN Ø 0.7 (0.028) Solder Mount EMI 3.0 (0.118) Mounting Hole Diameter 5.8mm (0.228 ) Max. Soldering Temperature 250º Temperature Rise Less than 4º per second Soldering Time 10 seconds maximum Solder Sn62/SA or equivalent 0.7g (0.025oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFSU Z0 10pF -20% / +80% SFSU Z0 15pF -20% / +80% SFSU Z0 22pF -20% / +80% SFSU Z0 33pF -20% / +80% *SFSU Z0 47pF -20% / +80% *SFSU M0 68pF G/NP0 *SFSU M0 100pF SFSU M0 150pF *SFSU M0 220pF *SFSU M0 330pF *SFSU M0 470pF SFSU M0 680pF *SFSU MX0 1.0nF # 750 SFSU MX0 1.5nF *SFSU MX0 2.2nF SFSU MX0 3.3nF *SFSU MX0 4.7nF SFSU MX0 6.8nF *SFSU MX0 10nF *SFSU MX0 15nF *SFSU MX0 22nF SFSU MX0 33nF *SFSU MX0 47nF *SFSU MX0 68nF >70 *SFSU MX0 100nF >70 SFSU MX0 150nF >70 *SFSU MX0 220nF >70 SFSU MX0 330nF > *SFSU MX0 470nF >70 SFSU MX0 680nF >70 # Also rated for operation at 115Vac 400Hz. Self healing will occur - evaluation in situ recommended. * Recommended values. Ordering Information - SFSU range SF S U M X 0 ase Dia. configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers Solder 5.6mm = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 34 SFSU Solder-in

35 SFAA 0G/NP0 & 4.0mm (0.157) 15.0 ± 1.0 (0.591 ± 0.039) 3.2 (0.126) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 10A 10GW or 1000WF -55º to +125º Not Applicable SFAA PIN Ø 0.7 (0.028) Head (A/F) 4mm (0.157 ) Nut A/F Not Applicable Washer diameter Not Applicable Not Applicable 4-40 UN lass 2A Thread 4.0mm Hexagonal Head Mounting Hole Diameter Max. Panel Thickness 4-40 UN lass 2B tapped hole Not Applicable 0.5g (0.017oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS *SFAA Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFAA Z 15pF -20% / +80% SFAA Z 22pF -20% / +80% SFAA Z 33pF -20% / +80% *SFAA Z 47pF -20% / +80% G/NP0 *SFAA M 68pF *SFAA M 100pF SFAA M 150pF *SFAA M 220pF *SFAA M 330pF *SFAA MX 470pF # 750 SFAA MX 680pF *SFAA MX 1.0nF SFAA MX 1.5nF *SFAA MX 2.2nF SFAA MX 3.3nF *SFAA MX 4.7nF *SFAA MX 6.8nF *SFAA MX 10nF *SFAA MX 15nF *SFAA MX 22nF SFAA MX 33nF *SFAA MX 47nF SFAA MX 68nF >70 *SFAA MX 100nF >70 *SFAA MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFAA range SF A A M X O ase 4.0mm Hex Head Thread configuration 4-40 UN = 050 = 50V (dc) apacitance in picofarads (pf) Tolerance Hardware First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. = 0G/NP0 X = 0 = Without SFAA eramic Threaded 35

36 SFAB 0G/NP0 & SFAB 4.0mm (0.157) 15.0 ± 1.0 (0.591 ± 0.039) 3.2 (0.126) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 10A 10GW or 1000WF -55º to +125º Not Applicable PIN Ø 0.7 (0.028) Head (A/F) 4mm (0.157 ) Nut A/F 4.75mm (0.187 ) Washer diameter 6.9mm (0.272 ) 0.3Nm (2.65lbf in) max. if using nut 0.15Nm (1.32lbf in) max. into tapped hole 6-32 UN lass 2A Thread 4.0mm Hexagonal Head Mounting Hole Diameter 3.7mm ±0.1 (0.146 ±0.004 ) Max. Panel Thickness 3.2mm (0.126 ) 0.6g (0.02oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS *SFAB Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFAB Z 15pF -20% / +80% SFAB Z 22pF -20% / +80% SFAB Z 33pF -20% / +80% *SFAB Z 47pF -20% / +80% G/NP0 *SFAB M 68pF *SFAB M 100pF SFAB M 150pF *SFAB M 220pF *SFAB M 330pF *SFAB MX 470pF # 750 SFAB MX 680pF *SFAB MX 1.0nF SFAB MX 1.5nF *SFAB MX 2.2nF SFAB MX 3.3nF *SFAB MX 4.7nF SFAB MX 6.8nF *SFAB MX 10nF *SFAB MX 15nF *SFAB MX 22nF SFAB MX 33nF *SFAB MX 47nF SFAB MX 68nF >70 *SFAB MX 100nF >70 *SFAB MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFAB range SF A B M X 0 ase 4.0mm Hex Head Thread configuration 0-32 UN = 050 = 50V (dc) apacitance in picofarads (pf) Tolerance Hardware First digit is 0. Second and third digits are significant figures of capacitance code. zeros following Example: 0101 = 100pF 0332 = 3300pF Z = % Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. = 0G/NP0 X = 0 = Without 1 = With 36 SFAB eramic Threaded

37 SFABL THREAD L- 0G/NP0 & 4.0mm (0.157) 15.0 ± 1.0 (0.591 ± 0.039) 3.2 (0.126) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 50nH SFABL PIN Ø 0.7 (0.028) Head (A/F) 4.0mm (0.157 ) Nut A/F 4.75mm (0.187 ) Washer diameter 6.9mm (0.272 ) 0.3Nm (2.65lbf in) max. if using nut 0.15Nm (1.32lbf in) max. into tapped hole 6-32 UN lass 2A Thread 4.0mm Hexagonal Head Mounting Hole Diameter 3.7mm ±0.1 (0.146 ±0.004 ) Max. Panel Thickness 3.2mm (0.126 ) 0.6g (0.02oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS *SFABL Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFABL Z 15pF -20% / +80% SFABL Z 22pF -20% / +80% SFABL Z 33pF -20% / +80% *SFABL Z 47pF -20% / +80% G/NP0 *SFABL M 68pF *SFABL M 100pF SFABL M 150pF *SFABL M 220pF *SFABL M 330pF *SFABL MX 470pF # 750 SFABL MX 680pF *SFABL MX 1.0nF SFABL MX 1.5nF *SFABL MX 2.2nF SFABL MX 3.3nF *SFABL MX 4.7nF SFABL MX 6.8nF *SFABL MX 10nF *SFABL MX 15nF *SFABL MX 22nF SFABL MX 33nF *SFABL MX 47nF > SFABL MX 68nF >70 *SFABL MX 100nF >70 *SFABL MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information- SFABL range SF A B L M X 0 ase 4.0mm Hex Head Thread configuration 6-32 UN L = L- 050 = 50V (dc) apacitance in picofarads (pf) Tolerance Hardware First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. = 0G/NP0 X = 0 = Without 1 = With SFABL eramic Threaded 37

38 SFAJ 0G/NP0 & SFAJ 4.0mm (0.157) 15.0 ± 1.0 (0.591 ± 0.039) 3.2 (0.126) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 10A 10GW or 1000WF -55º to +125º Not Applicable PIN Ø 0.7 (0.028) Head (A/F) 4.0mm (0.157 ) Nut A/F 4.0mm (0.187 ) Washer diameter 6.9mm (0.272 ) 0.25Nm (2.21lbf in) max. if using nut 0.15Nm (1.32lbf in) max. into tapped hole M3 x 0.5-6g Thread 4.0mm Hexagonal Head Mounting Hole Diameter 3.15mm ±0.1 (0.124 ±0.004 ) Max. Panel Thickness 3.2mm (0.126 ) 0.5g (0.017oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS *SFAJ Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFAJ Z 15pF -20% / +80% SFAJ Z 22pF -20% / +80% SFAJ Z 33pF -20% / +80% *SFAJ Z 47pF -20% / +80% G/NP0 *SFAJ M 68pF *SFAJ M 100pF SFAJ M 150pF *SFAJ M 220pF *SFAJ M 330pF *SFAJ MX 470pF # 750 SFAJ MX 680pF *SFAJ MX 1.0nF SFAJ MX 1.5nF *SFAJ MX 2.2nF SFAJ MX 3.3nF *SFAJ MX 4.7nF *SFAJ MX 6.8nF *SFAJ MX 10nF *SFAJ MX 15nF *SFAJ MX 22nF SFAJ MX 33nF *SFAJ MX 47nF SFAJ MX 68nF >70 *SFAJ MX 100nF >70 *SFAJ MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFAJ range SF A J M X 0 ase 4.0mm Hex Head Thread configuration M3 = 050 = 50V (dc) apacitance in picofarads (pf) Tolerance Hardware First digit is 0. Second and third digits are significant figures of capacitance code. zeros following Example: 0101 = 100pF 0332 = 3300pF Z = % Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. = 0G/NP0 X = 0 = Without 1 = With 38 SFAJ eramic Threaded

39 SFAJL THREAD L- 0G/NP0 & 4.0mm (0.157) 15.0 ± 1.0 (0.591 ± 0.039) 3.2 (0.126) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 50nH SFAJL PIN Ø 0.7 (0.028) Head (A/F) 4.0mm (0.157 ) Nut A/F 4.0mm (0.157 ) Washer diameter 6.9mm (0.272 ) 0.25Nm (2.21lbf in) max. if using nut 0.15Nm (1.32lbf in) max. into tapped hole M3 x 0.5-6g Thread 4.0mm Hexagonal Head Mounting Hole Diameter 3.15mm ±0.1 (0.124 ±0.004 ) Max. Panel Thickness 3.2mm (0.126 ) 0.5g (0.017oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS *SFAJL Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFAJL Z 15pF -20% / +80% SFAJL Z 22pF -20% / +80% SFAJL Z 33pF -20% / +80% *SFAJL Z 47pF -20% / +80% G/NP0 *SFAJL M 68pF *SFAJL M 100pF SFAJL M 150pF *SFAJL M 220pF *SFAJL M 330pF *SFAJL MX 470pF # 750 SFAJL MX 680pF *SFAJL MX 1.0nF SFAJL MX 1.5nF *SFAJL MX 2.2nF SFAJL MX 3.3nF *SFAJL MX 4.7nF SFAJL MX 6.8nF *SFAJL MX 10nF *SFAJL MX 15nF *SFAJL MX 22nF SFAJL MX 33nF *SFAJL MX 47nF > SFAJL MX 68nF >70 *SFAJL MX 100nF >70 *SFAJL MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFAJL range SF A J L M X 1 ase 4.0mm Hex Head Thread configuration M3 L = L- 050 = 50V (dc) apacitance in picofarads (pf) Tolerance Hardware First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. = 0G/NP0 X = 0 = Without 1 = With SFAJL eramic Threaded 39

40 SFAK 0G/NP0 & SFAK 4.0 A/F (0.157) PIN Ø 0.7 (0.028) M3.5 x 0.6-6g Thread 4.0mm Hexagonal Head L1 ± 1.0 L2 ± (0.128) A SUFFIX A L1 L2 NONE / onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicable Head (A/F) 4.0mm (0.157 ) Nut A/F 4.75mm (0.187 ) Washer diameter 6.9mm (0.272 ) 0.35Nm (3.09lbf in) max. if using nut 0.18Nm (1.59lbf in) max. into tapped hole Mounting Hole Diameter 3.7mm ±0.1 (0.146 ±0.004 ) Max. Panel Thickness 3.25mm (0.128 ) 0.6g (0.02oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS *SFAK Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFAK Z 15pF -20% / +80% SFAK Z 22pF -20% / +80% SFAK Z 33pF -20% / +80% *SFAK Z 47pF -20% / +80% G/NP0 *SFAK M 68pF *SFAK M 100pF SFAK M 150pF *SFAK M 220pF *SFAK M 330pF *SFAK MX 470pF # 750 SFAK MX 680pF *SFAK MX 1.0nF SFAK MX 1.5nF *SFAK MX 2.2nF SFAK MX 3.3nF *SFAK MX 4.7nF *SFAK MX 6.8nF *SFAK MX 10nF *SFAK MX 15nF *SFAK MX 22nF SFAK MX 33nF *SFAK MX 47nF SFAK MX 68nF >70 *SFAK MX 100nF >70 *SFAK MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFAK range SF A K M 0 /0022 ase Thread configuration 4.0mm Hex Head (dc) M3.5 = 050 = 50V apacitance in picofarads (pf) First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Tolerance Hardware Suffix Z = % = 0G/NP0 X = 0 = Without 1 = With /0022= short thread & lead length (see drawing) Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 40 SFAK eramic Threaded

41 SFAKL THREAD L- 0G/NP0 & 4.0mm (0.157) 15.0 ± 1.0 (0.591 ± 0.039) 3.2 (0.126) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 50nH SFAKL PIN Ø 0.7 (0.028) Head (A/F) 4.0mm (0.157 ) Nut A/F 4.75mm (0.187 ) Washer diameter 6.9mm (0.272 ) 0.35Nm (3.09lbf in) max. if using nut 0.18Nm (1.59lbf in) max. into tapped hole M3.5 x 0.6-6g Thread 4.0mm Hexagonal Head Mounting Hole Diameter 3.7mm ±0.1 (0.146 ±0.004 ) Max. Panel Thickness 3.25mm (0.128 ) 0.6g (0.02oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS *SFAKL Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFAKL Z 15pF -20% / +80% SFAKL Z 22pF -20% / +80% SFAKL Z 33pF -20% / +80% *SFAKL Z 47pF -20% / +80% G/NP0 *SFAKL M 68pF *SFAKL M 100pF SFAKL M 150pF *SFAKL M 220pF *SFAKL M 330pF *SFAKL MX 470pF # 750 SFAKL MX 680pF *SFAKL MX 1.0nF SFAKL MX 1.5nF *SFAKL MX 2.2nF SFAKL MX 3.3nF *SFAKL MX 4.7nF SFAKL MX 6.8nF *SFAKL MX 10nF *SFAKL MX 15nF *SFAKL MX 22nF SFAKL MX 33nF *SFAKL MX 47nF > SFAKL MX 68nF >70 SFAKL MX 100nF >70 SFAKL MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFAKL range SF A B L M X 1 ase 4.0mm Hex Head Thread configuration M3.5 L = L- 050 = 50V (dc) apacitance in picofarads (pf) Tolerance Hardware First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. = 0G/NP0 X = 0 = Without 1 = With SFAKL eramic Threaded 41

42 SFAKT T 0G/NP0 & SFAKT 4.0 A/F (0.157) M3.5 x 0.6-6g Thread 4.0mm Hexagonal Head 16.0 ± ± (0.256) (0.157) PIN Ø 0.7 (0.028) 0.9 UNUT (0.035) onfiguration T apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 100nH Head (A/F) 4.0mm (0.157 ) Nut A/F 4.75mm (0.187 ) Washer diameter 6.9mm (0.272 ) 0.35Nm (3.09lbf in) max. if using nut 0.18Nm (1.59lbf in) max. into tapped hole Mounting Hole Diameter 3.7mm ±0.1 (0.146 ±0.004 ) Max. Panel Thickness 3.25mm (0.128 ) 0.6g (0.02oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS *SFAKT Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFAKT Z 15pF -20% / +80% SFAKT Z 22pF -20% / +80% SFAKT Z 33pF -20% / +80% *SFAKT Z 47pF -20% / +80% G/NP0 *SFAKT M 68pF *SFAKT M 100pF SFAKT M 150pF *SFAKT M 220pF *SFAKT M 330pF *SFAKT MX 470pF # 750 SFAKT MX 680pF *SFAKT MX 1.0nF SFAKT MX 1.5nF *SFAKT MX 2.2nF SFAKT MX 3.3nF *SFAKT MX 4.7nF SFAKT MX 6.8nF *SFAKT MX 10nF *SFAKT MX 15nF *SFAKT MX 22nF SFAKT MX 33nF >70 *SFAKT MX 47nF > SFAKT MX 68nF >70 *SFAKT MX 100nF >70 *SFAKT MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFAKT range SF A K T M X 0 ase 4.0mm Hex Head Thread configuration (dc) M3.5 T = T 050 = 50V apacitance in picofarads (pf) First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Tolerance Hardware Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 42 SFAKT eramic Threaded

43 SFB 0G/NP0 & 4.75mm (0.157) 15.0 ± 1.0 (0.591 ± 0.039) 3.2 (0.126) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 10A 10GW or 1000WF -55º to +125º Not Applicable SFB PIN Ø 0.7 (0.028) Head (A/F) 4.75mm (0.187 ) Nut A/F 6.35mm (0.250 ) Washer diameter 8mm (0.315 ) 0.5Nm (4.42lbf in) max. if using nut 0.25Nm (2.21lbf in) max. into tapped hole 8-32 UN lass 2A Thread 4.75mm Hexagonal Head Mounting Hole Diameter 4.4mm ±0.1 (0.173 ±0.004 ) Max. Panel Thickness 2.9mm (0.114 ) 1.2g (0.04oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS *SFB Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFB Z 15pF -20% / +80% SFB Z 22pF -20% / +80% SFB Z 33pF -20% / +80% *SFB Z 47pF -20% / +80% G/NP0 *SFB M 68pF *SFB M 100pF SFB M 150pF *SFB M 220pF *SFB M 330pF *SFB MX 470pF # 750 SFB MX 680pF *SFB MX 1.0nF SFB MX 1.5nF *SFB MX 2.2nF SFB MX 3.3nF *SFB MX 4.7nF SFB MX 6.8nF *SFB MX 10nF *SFB MX 15nF *SFB MX 22nF SFB MX 33nF *SFB MX 47nF SFB MX 68nF >70 *SFB MX 100nF >70 *SFB MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFB range SF B M X 0 ase 4.75mm Hex Head Thread configuration 8-32 UN = 050 = 50V (dc) apacitance in picofarads (pf) Tolerance Hardware First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. = 0G/NP0 X = 0 = Without 1 = With SFB eramic Threaded 43

44 SFBL THREAD L- 0G/NP0 & SFBL 4.75 A/F (0.187) 15.0 ± 1.0 (0.591 ± 0.039) 3.2 (0.126) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 50nH PIN Ø 0.7 (0.028) Head (A/F) 4.75mm (0.187 ) Nut A/F 6.35mm (0.250 ) Washer diameter 8mm (0.315 ) 0.5Nm (4.42lbf in) max. if using nut 0.25Nm (2.21lbf in) max. into tapped hole 8-32 UN lass 2A Thread 4.75mm Hexagonal Head Mounting Hole Diameter 4.4mm ±0.1 (0.173 ±0.004 ) Max. Panel Thickness 2.9mm (0.114 ) 1.2g (0.04oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS *SFBL Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFBL Z 15pF -20% / +80% SFBL Z 22pF -20% / +80% SFBL Z 33pF -20% / +80% *SFBL Z 47pF -20% / +80% G/NP0 *SFBL M 68pF *SFBL M 100pF SFBL M 150pF *SFBL M 220pF *SFBL M 330pF *SFBL MX 470pF # 750 SFBL MX 680pF *SFBL MX 1.0nF SFBL MX 1.5nF *SFBL MX 2.2nF SFBL MX 3.3nF *SFBL MX 4.7nF SFBL MX 6.8nF *SFBL MX 10nF *SFBL MX 15nF *SFBL MX 22nF SFBL MX 33nF *SFBL MX 47nF > SFBL MX 68nF >70 *SFBL MX 100nF >70 *SFBL MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFBL range SF B L M X 0 ase 4.75mm Hex Head Thread configuration (dc) 8-32 UN L = L- 050 = 50V apacitance in picofarads (pf) First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Tolerance Hardware Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 44 SFBL eramic Threaded

45 SFBP Pi 0G/NP0 & 4.75 A/F (0.187) 8-32 UN lass 2A Thread 4.75mm Hexagonal Head ± ± 1.0 (0.561±0.039) (0.699±0.039) PIN Ø 0.7 (0.028) (0.126) (0.236) onfiguration Pi apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 75nH Head (A/F) 4.75mm (0.187 ) Nut A/F 6.35mm (0.250 ) Washer diameter 8mm (0.315 ) 0.5Nm (4.42lbf in) max. if using nut 0.25Nm (2.21lbf in) max. into tapped hole Mounting Hole Diameter 4.4mm ±0.1 (0.173 ±0.004 ) Max. Panel Thickness 2.9mm (0.114 ) 1.2g (0.04oz) Silver plate on copper undercoat SFBP Product ode *SFBP Z apacitance -20/+80% 20pF Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFBP Z 44pF SFBP Z 94pF 0G/NP *SFBP Z 200pF SFBP Z 440pF 500# SFBP ZX 940pF *SFBP ZX 2nF SFBP ZX 4.4nF >70 *SFBP ZX 9.4nF >70 *SFBP ZX 20nF >70 *SFBP ZX 44nF >70 >70 *SFBP ZX 94nF >70 >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFBP range SF B P Z X 0 ase 4.75mm Hex Head Thread configuration 8-32 UN P = Pi 050 = 50V (dc) apacitance in picofarads (pf) Tolerance Hardware First digit is 0. Second and third digits are significant figures of Example: 0201 = 200pF 0943 = 94000pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFBP eramic Threaded 45

46 SFBD 0G/NP0 & SFBD Ø A/F (0.187) 15.0 ± ± 1.0 (0.591 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.157) (0.315) UNEF lass 2A Thread 4.75mm Hexagonal Head/6.35mm flange onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicable Body Flange Diameter 6.35mm (0.250 ) Head (A/F) 4.75mm (0.187 ) Nut A/F 7.92mm (0.312 ) Washer diameter 11.35mm (0.447 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.7mm ±0.1 (0.224 ±0.004 ) Max. Panel Thickness 4.9mm (0.193 ) 1.5g (0.05oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS *SFBD Z 10pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFBD Z 15pF -20% / +80% SFBD Z 22pF -20% / +80% SFBD Z 33pF -20% / +80% *SFBD Z 47pF -20% / +80% G/NP0 *SFBD M 68pF *SFBD M 100pF SFBD M 150pF *SFBD M 220pF *SFBD M 330pF *SFBD MX 470pF # 750 SFBD MX 680pF *SFBD MX 1.0nF SFBD MX 1.5nF *SFBD MX 2.2nF SFBD MX 3.3nF *SFBD MX 4.7nF SFBD MX 6.8nF *SFBD MX 10nF *SFBD MX 15nF *SFBD MX 22nF SFBD MX 33nF *SFBD MX 47nF SFBD MX 68nF >70 *SFBD MX 100nF >70 *SFBD MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFBD range SF B D M 0 ase 4.75mm Hex Head Thread UN configuration = (dc) 050 = 50V apacitance in picofarads (pf) First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Tolerance Hardware Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 46 SFBD eramic Threaded

47 SFBDL THREAD L- 0G/NP0 & 4.75 A/F (0.187) Ø ± ± 1.0 (0.591 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.157) (0.315) UNEF lass 2A Thread 4.75mm Hexagonal Head/6.35mm flange onfiguration L- apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 500nH Body Flange Diameter 6.35mm (0.250 ) Head (A/F) 4.75mm (0.187 ) Nut A/F 7.92mm (0.312 ) Washer diameter 11.35mm (0.447 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.7mm ±0.1 (0.224 ±0.004 ) Max. Panel Thickness 4.9mm (0.193 ) 1.5g (0.05oz) Silver plate on copper undercoat SFBDL Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFBDL Z 10pF -20% / +80% SFBDL Z 15pF -20% / +80% SFBDL Z 22pF -20% / +80% SFBDL Z 33pF -20% / +80% *SFBDL Z 47pF -20% / +80% G/NP0 *SFBDL M 68pF *SFBDL M 100pF SFBDL M 150pF *SFBDL M 220pF *SFBDL M 330pF *SFBDL MX 470pF # 750 SFBDL MX 680pF *SFBDL MX 1.0nF SFBDL MX 1.5nF *SFBDL MX 2.2nF SFBDL MX 3.3nF *SFBDL MX 4.7nF SFBDL MX 6.8nF *SFBDL MX 10nF *SFBDL MX 15nF *SFBDL MX 22nF SFBDL MX 33nF *SFBDL MX 47nF > SFBDL MX 68nF >70 *SFBDL MX 100nF >70 *SFBDL MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFBDL range SF B D L M X 0 ase 4.75mm Hex Head Thread UNEF configuration L = L- (dc) apacitance in picofarads (pf) Tolerance Hardware 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFBDL eramic Threaded 47

48 SFBDP Pi 0G/NP0 & SFBDP Ø A/F (0.187) 15.0 ± ± 1.0 (0.591 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.157) (0.315) UNEF lass 2A Thread 4.75mm Hexagonal Head/6.35mm flange onfiguration Pi apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 250nH Body Flange Diameter 6.35mm (0.250 ) Head (A/F) 4.75mm (0.187 ) Nut A/F 7.92mm (0.312 ) Washer diameter 11.35mm (0.447 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.7mm ±0.1 (0.224 ±0.004 ) Max. Panel Thickness 4.9mm (0.193 ) 1.5g (0.05oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS *SFBDP Z 20pF -20% / +80% Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFBDP Z 30pF -20% / +80% SFBDP Z 44pF -20% / +80% SFBDP Z 66pF -20% / +80% *SFBDP Z 94pF -20% / +80% G/NP0 *SFBDP M 136pF *SFBDP M 200pF SFBDP M 300pF *SFBDP M 440pF *SFBDP M 660pF *SFBDP MX 940pF # 750 SFBDP5001N36MX 1.36nF >70 *SFBDP MX 2nF >70 SFBDP MX 3nF >70 *SFBDP MX 4.4nF >70 SFBDP MX 6.6nF >70 *SFBDP MX 9.4nF >70 SFBDP50013N6MX 13.6nF >70 >70 *SFBDP MX 20nF >70 >70 *SFBDP MX 30nF >70 >70 *SFBDP MX 44nF >70 >70 SFBDP MX 66nF >70 >70 *SFBDP MX 94nF >70 > SFBDP200136NMX 136nF >70 >70 >70 *SFBDP MX 200nF >70 >70 >70 *SFBDP MX 300nF >70 >70 >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFBDP range SF B D P M X 0 ase 4.75mm Hex Head Thread UNEF configuration P = Pi (dc) 050 = 50V apacitance in picofarads (pf) First digit is 0. Second and third digits are significant figures of Example: 0201 = 200pF 0943 = 94000pF Tolerance Hardware Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 48 SFBDP eramic Threaded

49 SFBDT T 0G/NP0 & 4.75 A/F (0.187) Ø ± ± 1.0 (0.591 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.157) (0.315) UNEF lass 2A Thread 4.75mm Hexagonal Head/6.35mm flange onfiguration T apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 450nH Body Flange Diameter 6.35mm (0.250 ) Head (A/F) 4.75mm (0.187 ) Nut A/F 7.92mm (0.312 ) Washer diameter 11.35mm (0.447 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.7mm ±0.1 (0.224 ±0.004 ) Max. Panel Thickness 4.9mm (0.193 ) 1.5g (0.05oz) Silver plate on copper undercoat SFBDT Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFBDT Z 10pF -20% / +80% SFBDT Z 15pF -20% / +80% SFBDT Z 22pF -20% / +80% SFBDT Z 33pF -20% / +80% *SFBDT Z 47pF -20% / +80% G/NP0 *SFBDT M 68pF *SFBDT M 100pF SFBDT M 150pF *SFBDT M 220pF *SFBDT M 330pF *SFBDT MX 470pF # 750 SFBDT MX 680pF *SFBDT MX 1.0nF SFBDT MX 1.5nF *SFBDT MX 2.2nF SFBDT MX 3.3nF *SFBDT MX 4.7nF SFBDT MX 6.8nF *SFBDT MX 10nF *SFBDT MX 15nF *SFBDT MX 22nF SFBDT MX 33nF >70 *SFBDT MX 47nF > SFBDT MX 68nF >70 *SFBDT MX 100nF >70 *SFBDT MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFBDT range SF B D T M X 0 ase 4.75mm Hex Head Thread UNEF configuration T = T (dc) apacitance in picofarads (pf) Tolerance Hardware 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFBDT eramic Threaded 49

50 SFBL 0G/NP0 & SFBL 4.75 A/F (0.187) M4 x 0.7-6g Thread 4.75mm Hexagonal Head ± ± 1.0 (0.561 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.128) (0.236) onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) N/A Head (A/F) 4.75mm (0.187 ) Nut A/F 6.35mm (0.250 ) Washer diameter 8mm (0.315 ) 0.5Nm (4.42bf in) max. if using nut 0.25Nm (2.41lbf in) max. into tapped hole Mounting Hole Diameter 4.2mm ±0.1 (0.165 ±0.004 ) Max. Panel Thickness 2.9mm (0.114 ) 1.2g (0.04oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFBL Z 10pF -20% / +80% SFBL Z 15pF -20% / +80% SFBL Z 22pF -20% / +80% SFBL Z 33pF -20% / +80% *SFBL Z 47pF -20% / +80% G/NP0 *SFBL M 68pF *SFBL M 100pF SFBL M 150pF *SFBL M 220pF *SFBL M 330pF *SFBL MX 470pF # 750 SFBL MX 680pF *SFBL MX 1.0nF SFBL MX 1.5nF *SFBL MX 2.2nF SFBL MX 3.3nF *SFBL MX 4.7nF SFBL MX 6.8nF *SFBL MX 10nF *SFBL MX 15nF *SFBL MX 22nF SFBL MX 33nF *SFBL MX 47nF SFBL MX 68nF >70 *SFBL MX 100nF >70 *SFBL MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFBL range SF B L M X 0 ase 4.75mm Hex Head Thread configuration M4 = 050 = 50V (dc) apacitance in picofarads (pf) Tolerance Hardware First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 50 SFBL eramic Threaded

51 SFBLL THREAD L- 0G/NP0 & 4.75mm (0.157) 15.0 ± 1.0 (0.591 ± 0.039) 3.2 (0.126) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 50nH SFBLL PIN Ø 0.7 (0.028) Body Flange Diameter 4.75mm (0.187 ) Head (A/F) 6.0mm (0.236 ) Nut A/F 8.0mm (0.315 ) 0.5Nm (4.42lbf in) max. if using nut 0.25Nm (2.21lbf in) max. into tapped hole M4 x 0.7-6g Thread 4.75mm Hexagonal Head Mounting Hole Diameter 4.2mm ±0.1 (0.165 ±0.004 ) Max. Panel Thickness 2.9mm (0.114 ) 1.2g (0.04oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFBLL Z 10pF -20% / +80% SFBLL Z 15pF -20% / +80% SFBLL Z 22pF -20% / +80% SFBLL Z 33pF -20% / +80% *SFBLL Z 47pF -20% / +80% G/NP0 *SFBLL M 68pF *SFBLL M 100pF SFBLL M 150pF *SFBLL M 220pF *SFBLL M 330pF *SFBLL MX 470pF # 750 SFBLL MX 680pF *SFBLL MX 1.0nF SFBLL MX 1.5nF *SFBLL MX 2.2nF SFBLL MX 3.3nF *SFBLL MX 4.7nF SFBLL MX 6.8nF *SFBLL MX 10nF *SFBLL MX 15nF *SFBLL MX 22nF SFBLL MX 33nF *SFBLL MX 47nF > SFBLL MX 68nF >70 *SFBLL MX 100nF >70 *SFBLL MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFBLL range SF B L L M X 0 ase 4.75mm Hex Head Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M4 L = L- 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFBLL eramic Threaded 51

52 SFBLP Pi 0G/NP0 & SFBLP 4.75 A/F (0.187) M4 x 0.7-6g Thread 4.75mm Hexagonal Head ± ± 1.0 (0.561 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.128) (0.236) onfiguration Pi apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 75nH Head (A/F) 4.75mm (0.187 ) Nut A/F 6.0mm (0.236 ) Washer diameter 7.90mm (0.311 ) 0.5Nm (4.42lbf in) max. if using nut 0.25Nm (2.21lbf in) max. into tapped hole Mounting Hole Diameter 4.2mm ±0.1 (0.165 ±0.004 ) Max. Panel Thickness 2.9mm (0.114 ) 1.2g (0.04oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (-20%+80%) Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFBLP Z 20pF SFBLP Z 44pF SFBLP Z 94pF 0G/NP *SFBLP Z 200pF SFBLP Z 440pF 500# SFBLP ZX 940pF *SFBLP ZX 2nF SFBLP ZX 4.4nF >70 *SFBLP ZX 9.4nF >70 *SFBLP ZX 20nF >70 *SFBLP ZX 44nF >70 >70 *SFBLP ZX 94nF >70 >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFBLP range SF B L P Z X 0 ase 4.75mm Hex Head Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M4 P = Pi 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0201 = 200pF 0943 = 94000pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 52 SFBLP eramic Threaded

53 SFBM 0G/NP0 & Ø A/F (0.187) 15.0 ± ± 1.0 (0.591 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.157) (0.315) M5 x 0.8-6g Thread 4.75mm Hexagonal Head/6.35mm flange onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicable Body Flange Diameter 6.35mm (0.250 ) Head (A/F) 4.75mm (0.187 ) Nut A/F 6.0mm (0.236 ) Washer Diameter 9.1mm (0.358 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.2mm ±0.1 (0.205 ±0.004 ) Max. Panel Thickness 4.9mm (0.193 ) 1.5g (0.05oz) Silver plate on copper undercoat SFBM Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFBM Z 10pF -20% / +80% SFBM Z 15pF -20% / +80% SFBM Z 22pF -20% / +80% SFBM Z 33pF -20% / +80% *SFBM Z 47pF -20% / +80% G/NP0 *SFBM M 68pF *SFBM M 100pF SFBM M 150pF *SFBM M 220pF *SFBM M 330pF *SFBM MX 470pF # 750 SFBM MX 680pF *SFBM MX 1.0nF SFBM MX 1.5nF *SFBM MX 2.2nF SFBM MX 3.3nF *SFBM MX 4.7nF SFBM MX 6.8nF *SFBM MX 10nF *SFBM MX 15nF *SFBM MX 22nF SFBM MX 33nF *SFBM MX 47nF SFBM MX 68nF >70 *SFBM MX 100nF >70 *SFBM MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFBM range SF B M M X 0 ase 4.75mm Hex Head Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFBM eramic Threaded 53

54 SFBML THREAD L- 0G/NP0 & SFBML 4.75 A/F (0.187) Ø ± ± 1.0 (0.591 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.157) (0.315) M5 x 0.8-6g Thread 4.75mm Hexagonal Head/6.35mm flange onfiguration L- apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 500nH Body Flange Diameter 6.35mm (0.250 ) Head (A/F) 4.75mm (0.187 ) Nut A/F 6.0mm (0.236 ) Washer diameter 9.1mm (0.358 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.2mm ±0.1 (0.205 ±0.004 ) Max. Panel Thickness 4.9mm (0.193 ) 1.5g (0.05oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFBML Z 10pF -20% / +80% SFBML Z 15pF -20% / +80% SFBML Z 22pF -20% / +80% SFBML Z 33pF -20% / +80% *SFBML Z 47pF -20% / +80% G/NP0 *SFBML M 68pF *SFBML M 100pF SFBML M 150pF *SFBML M 220pF *SFBML M 330pF *SFBML MX 470pF # 750 SFBML MX 680pF *SFBML MX 1.0nF SFBML MX 1.5nF *SFBML MX 2.2nF SFBML MX 3.3nF *SFBML MX 4.7nF SFBML MX 6.8nF *SFBML MX 10nF *SFBML MX 15nF *SFBML MX 22nF SFBML MX 33nF *SFBML MX 47nF > SFBML MX 68nF >70 *SFBML MX 100nF >70 *SFBML MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFBML range SF B M L M X 0 ase 4.75mm Hex Head Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 L = L- 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 54 SFBML eramic Threaded

55 SFBMP Pi 0G/NP0 & Ø A/F (0.187) 15.0 ± ± 1.0 (0.591 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.157) (0.315) M5 x 0.8-6g Thread 4.75mm Hexagonal Head/6.35mm flange onfiguration Pi apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 250nH Body Flange Diameter 6.35mm (0.250 ) Head A/F 4.75mm (0.187 ) Nut A/F 6mm (0.236 ) Washer Diameter 9.1mm (0.358 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.2mm ± 0.1 (0.205 ± ) Max. Panel Thickness 4.9mm (0.193 ) 1.5g (0.05oz) Silver plate on copper undercoat SFBMP Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFBMP Z 20pF -20% / +80% SFBMP Z 30pF -20% / +80% SFBMP Z 44pF -20% / +80% SFBMP Z 66pF -20% / +80% *SFBMP Z 94pF -20% / +80% G/NP0 *SFBMP M 136pF *SFBMP M 200pF SFBMP M 300pF *SFBMP M 440pF *SFBMP M 660pF *SFBMP MX 940pF # 750 SFBMP5001N36MX 1.36nF >70 *SFBMP MX 2nF >70 SFBMP MX 3nF >70 *SFBMP MX 4.4nF >70 SFBMP MX 6.6nF >70 *SFBMP MX 9.4nF >70 SFBMP50013N6MX 13.6nF >70 >70 *SFBMP MX 20nF >70 >70 *SFBMP MX 30nF >70 >70 *SFBMP MX 44nF >70 >70 SFBMP MX 66nF >70 >70 *SFBMP MX 94nF >70 > SFBMP200136NMX 136nF >70 >70 >70 *SFBMP MX 200nF >70 >70 >70 *SFBMP MX 300nF >70 >70 >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFBMP range SF B M P M X 0 ase 4.75mm Hex Head Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 P = Pi 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0201 = 200pF 0943 = 94000pF Z = % = 0G/NP0 X = 0 = Without Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFBMP eramic Threaded 55

56 SFBMT T 0G/NP0 & SFBMT 4.75 A/F (0.187) Ø ± ± 1.0 (0.591 ± 0.039) (0.699 ± 0.039) PIN Ø 0.7 (0.028) (0.157) (0.315) M5 x 0.8-6g Thread 4.75mm Hexagonal Head/6.35mm flange onfiguration T apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 450nH Body Flange Diameter 6.35mm (0.250 ) Head (A/F) 4.75mm (0.187 ) Nut A/F 6.0mm (0.236 ) Washer diameter 9.1mm (0.358 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.2mm ±0.1 (0.205 ±0.004 ) Max. Panel Thickness 4.9mm (0.193 ) 1.5g (0.05oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFBMT Z 10pF -20% / +80% SFBMT Z 15pF -20% / +80% SFBMT Z 22pF -20% / +80% SFBMT Z 33pF -20% / +80% *SFBMT Z 47pF -20% / +80% G/NP0 *SFBMT M 68pF *SFBMT M 100pF SFBMT M 150pF *SFBMT M 220pF *SFBMT M 330pF *SFBMT MX 470pF # 750 SFBMT MX 680pF *SFBMT MX 1.0nF SFBMT MX 1.5nF *SFBMT MX 2.2nF SFBMT MX 3.3nF *SFBMT MX 4.7nF SFBMT MX 6.8nF *SFBMT MX 10nF *SFBMT MX 15nF *SFBMT MX 22nF SFBMT MX 33nF >70 *SFBMT MX 47nF > SFBMT MX 68nF >70 *SFBMT MX 100nF >70 *SFBMT MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFBMT range SF B M T M X 0 ase 4.75mm Hex head Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 T = T 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 56 SFBMT eramic Threaded

57 SFD 0G/NP0 & 6.35 A/F (0.250) 15.0 ± 1.0 (0.591 ± 0.039) PIN Ø 0.7 (0.028) 5.0 (0.197) UNEF lass 2A Thread 6.35mm Hexagonal Head 7.0 (0.276) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicable Head Diameter 6.35mm (0.250 ) Nut A/F 7.92mm (0.312 ) Washer Diameter 11.35mm (0.447 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.7mm ± 0.1 (0.224 ±0.004 ) Max. Panel Thickness 3.9mm (0.154 ) 1.8g (0.06oz) Silver plate on copper undercoat SFD Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFD Z 10pF -20% / +80% SFD Z 15pF -20% / +80% SFD Z 22pF -20% / +80% SFD Z 33pF -20% / +80% *SFD Z 47pF -20% / +80% G/NP0 *SFD M 68pF *SFD M 100pF SFD M 150pF *SFD M 220pF *SFD M 330pF *SFD MX 470pF SFD MX 680pF *SFD MX 1.0nF # 750 SFD MX 1.5nF *SFD MX 2.2nF SFD MX 3.3nF *SFD MX 4.7nF SFD MX 6.8nF *SFD MX 10nF *SFD MX 15nF *SFD MX 22nF SFD MX 33nF *SFD MX 47nF SFD MX 68nF >70 SFD MX 100nF >70 SFD MX 150nF >70 *SFD MX 220nF >70 SFD MX 330nF > *SFD MX 470nF >70 SFD MX 680nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFD range SF D M X 0 ase 6.35mm Hex Head Thread UNEF configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFD eramic Threaded 57

58 SFDL THREAD L- 0G/NP0 & SFDL 6.35 A/F (0.250) 15.0 ± 1.0 (0.591 ± 0.039) PIN Ø 0.7 (0.028) 5.0 (0.197) UNEF lass 2A Thread 6.35mm Hexagonal Head 7.0 (0.276) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration L- apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 500nH Head Diameter 6.35mm (0.250 ) Nut A/F 7.92mm (0.312 ) Washer Diameter 11.35mm (0.447 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.7mm ± 0.1 (0.224 ±0.004 ) Max. Panel Thickness 3.9mm (0.154 ) 1.8g (0.06oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFDL Z 10pF -20% / +80% SFDL Z 15pF -20% / +80% SFDL Z 22pF -20% / +80% SFDL Z 33pF -20% / +80% *SFDL Z 47pF -20% / +80% G/NP0 *SFDL M 68pF *SFDL M 100pF SFDL M 150pF *SFDL M 220pF *SFDL M 330pF *SFDL MX 470pF SFDL MX 680pF *SFDL MX 1.0nF # 750 SFDL MX 1.5nF *SFDL MX 2.2nF SFDL MX 3.3nF *SFDL MX 4.7nF SFDL MX 6.8nF *SFDL MX 10nF *SFDL MX 15nF *SFDL MX 22nF SFDL MX 33nF *SFDL MX 47nF >70 SFDL MX 68nF >70 SFDL MX 100nF >70 SFDL MX 150nF >70 *SFDL MX 220nF >70 SFDL MX 330nF > *SFDL MX 470nF >70 >70 SFDL MX 680nF >70 >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFDL range SF D L M 0 ase 6.35mm Hex Head Thread UNEF configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers L = L- 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 58 SFDL eramic Threaded

59 SFDP Pi 0G/NP0 & 6.35 A/F (0.250) 15.0 ± 1.0 (0.591 ± 0.039) PIN Ø 0.7 (0.028) 5.0 (0.197) UNEF lass 2A Thread 6.35mm Hexagonal Head 7.0 (0.276) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration Pi apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 250nH Head Diameter 6.35mm (0.250 ) Nut A/F 7.92mm (0.312 ) Washer Diameter 11.35mm (0.447 ) 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.7mm ± 0.1 (0.224 ±0.004 ) Max. Panel Thickness 3.9mm (0.154 ) 1.8g (0.06oz) Silver plate on copper undercoat SFDP Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFDP Z 20pF -20% / +80% 1 11 SFDP Z 30pF -20% / +80% 2 15 SFDP Z 44pF -20% / +80% 3 19 SFDP Z 66pF -20% / +80% 4 23 *SFDP Z 94pF -20% / +80% G/NP0 *SFDP M 136pF 8 35 *SFDP M 200pF SFDP M 300pF *SFDP M 440pF *SFDP M 660pF *SFDP MX 940pF # 750 SFDP5001N36MX 1.36nF 7 37 >70 *SFDP MX 2nF >70 SFDP MX 3nF >70 *SFDP MX 4.4nF >70 SFDP MX 6.6nF >70 *SFDP MX 9.4nF >70 SFDP50013N6MX 13.6nF 6 34 >70 >70 *SFDP MX 20nF 9 40 >70 >70 *SFDP MX 30nF >70 >70 *SFDP MX 44nF >70 >70 SFDP MX 66nF >70 >70 *SFDP MX 94nF >70 > SFDP200136NMX 136nF 8 25 >70 >70 >70 *SFDP MX 200nF >70 >70 >70 *SFDP MX 300nF >70 >70 >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFDP range SF D P M X 0 ase 6.35mm Hex Head Thread UNEF configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers Pi = Pi 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0201 = 200pF 0943 = 9400pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFDP eramic Threaded 59

60 SFM 0G/NP0 & SFM 6.35 A/F (0.250) 15.0 ± 1.0 (0.591 ± 0.039) PIN Ø 0.7 (0.028) 5.0 (0.197) 6.5 (0.256) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicaple Head Diameter 6.35mm (0.250 ) Nut A/F 6.0mm (0.236 ) Washer Diameter 9.1mm (0.358 ) M5 x 0.8-6g Thread 6.35mm Hexagonal Head 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.2mm ± 0.1 (0.205 ±0.004 ) Max. Panel Thickness 3.4mm (0.134 ) 1.8g (0.06oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFM Z 10pF -20% / +80% 4 SFM Z 15pF -20% / +80% 7 SFM Z 22pF -20% / +80% 10 SFM Z 33pF -20% / +80% 12 *SFM Z 47pF -20% / +80% G/NP0 *SFM M 68pF 2 18 *SFM M 100pF 4 22 SFM M 150pF 7 25 *SFM M 220pF *SFM M 330pF *SFM MX 470pF SFM MX 680pF *SFM MX 1.0nF # 750 SFM MX 1.5nF *SFM MX 2.2nF SFM MX 3.3nF *SFM MX 4.7nF SFM MX 6.8nF *SFM MX 10nF *SFM MX 15nF *SFM MX 22nF SFM MX 33nF *SFM MX 47nF SFM MX 68nF >70 SFM MX 100nF >70 SFM MX 150nF >70 *SFM MX 220nF >70 SFM MX 330nF > *SFM MX 470nF >70 SFM MX 680nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFM range SF M M 0 ase 6.35mm A/F Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 60 SFM eramic Threaded

61 SFML THREAD L- 0G/NP0 & 6.35 A/F (0.250) 15.0 ± 1.0 (0.591 ± 0.039) PIN Ø 0.7 (0.028) 5.0 (0.197) 6.5 (0.256) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration L- apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 500nH Head Diameter 6.35mm (0.250 ) SFML Nut A/F 6.0mm (0.236 ) Washer Diameter 9.1mm (0.358 ) M5 x 0.8-6g Thread 6.35mm Hexagonal Head 0.6Nm (5.31lbf in) max. if using nut 0.3Nm (2.65lbf in) max. into tapped hole Mounting Hole Diameter 5.2mm ± 0.1 (0.205 ±0.004 ) Max. Panel Thickness 3.4mm (0.134 ) 1.8g (0.06oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFML Z 10pF -20% / +80% SFML Z 15pF -20% / +80% SFML Z 22pF -20% / +80% SFML Z 33pF -20% / +80% *SFML Z 47pF -20% / +80% G/NP0 *SFML M 68pF *SFML M 100pF SFML M 150pF *SFML M 220pF *SFML M 330pF *SFML MX 470pF SFML MX 680pF *SFML MX 1.0nF # 750 SFML MX 1.5nF *SFML MX 2.2nF SFML MX 3.3nF *SFML MX 4.7nF SFML MX 6.8nF *SFML MX 10nF *SFML MX 15nF *SFML MX 22nF SFML MX 33nF *SFML MX 47nF >70 SFML MX 68nF >70 *SFML MX 100nF >70 SFML MX 150nF >70 *SFML MX 220nF >70 SFML MX 330nF > *SFML MX 470nF >70 >70 SFML MX 680nF >70 >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur - evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFML range SF M L M 0 ase 6.35mm A/F Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 L = L- 050 = 50Vdc dc dc dc First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without 1 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFML eramic Threaded 61

62 SFDPP Pi 0G/NP0 & SFDPP 10.0 A/F (0.394) PIN Ø 1.40 (0.055) M8 x g Thread 10mm Hexagonal Head 13.9 ± 1.0 (0.547 ± 0.039) 24.1 ± 1.0 (0.949 ± 1.0) (0.252) (0.437) onfiguration Pi apacitance 1000hr Point urrent Rating 20A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) 1µH Head A/F 10.0mm (0.393 ) Nut A/F 10.0mm (0.393 ) Washer Diameter 10.8mm (0.447 ) Lockwasher 1.0Nm (8.5lbf in) max. if using nut 0.5Nm (4.25lbf in) max. into tapped hole Mounting Hole Diameter 8.2mm ± 0.1 (0.323 ±0.004 ) Max. Panel Thickness 7.95mm (0.313 ) 6.2g (0.22oz) Silver plate on copper undercoat eramic Threaded Product ode SFDPP1K00942MX apacitance (±20%) 9.4nF Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz kV >70 SFDPP MX 200nF >70 >70 >70 SFDPP MX 940nF >70 >70 >70 Ordering Information - SFDPP range SF D P P M X 0 ase 10.0mm Hex Head Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M8 P = Pi 050 = 50V 1K0 = 1kV First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF X = 0 = Without 3 = With Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 62 SFDPP eramic Threaded

63 SFJG 0G/NP0 & Ø 9.78 Max (0.385) 15.0 ± 1.0 (0.591 ± 0.039) 4.57 (0.180) 17.0 ± 1.0 (0.669 ± 0.039) 4.83 (0.190) 5.08 (0.200) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 15A 10GW or 1000WF -55º to +125º Not Applicable SFJG PIN Ø 1.0 (0.039) THREAD RUN-OUT LESS THAN 1.25 IMPERFET THREADS Head Diameter 9.8mm (0.386 ) Nut A/F 7.92mm (0.312 ) Washer Diameter 11.35mm (0.447 ) 0.9Nm (7.97lbf in) max. ¼-28 UNF lass 2A Thread 9.8mm Round Head Mounting Hole Diameter A/F O.D. 6.7mm (0.264 ) O.D. 5.3mm (0.208 ) A/F Max. Panel Thickness 2.3mm (0.091 ) 3.0g (0.11oz) ** (see notes below) Silver plate on copper undercoat Product ode apacitance (±20%) Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFJG3K00101M 100pF SFJG3K00151M 150pF 3kV# 3.6kV SFJG3K00221M 220pF SFJG2K00331M 330pF 0G/NP SFJG2K00471M 470pF SFJG2K00681M 680pF SFJG2K00102M 1.0nF SFJG2K00152MX 1.5nF kV# 2.4kV SFJG2K00222MX 2.2nF *SFJG2K00332MX 3.3nF SFJG2K00472MX 4.7nF *SFJG2K00682MX 6.8nF SFJG2K00103MX 10nF SFJG1K00153MX 15nF SFJG1K00223MX 22nF *SFJG1K00333MX 33nF 1kV# 1.2kV SFJG1K00473MX 47nF *SFJG1K00683MX 68nF >70 SFJG MX 100nF >70 *SFJG MX 150nF >70 500# SFJG MX 220nF >70 *SFJG MX 330nF >70 SFJG MX 470nF >70 SFJG MX 680nF >70 *SFJG MX 1.0µF >70 >70 *SFJG MX 1.5µF >70 > *SFJG MX 2.2µF >70 >70 SFJG MX 3.3µF >70 >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur - evaluation in situ recommended. * Recommended values. eramic Threaded Ordering Information - SFJG range Note: Ordering code can have up to 4 additional digits on the end to denote special requirements SF J G M X 1 ase 9.78mm Max Dia. Thread ¼-28 UNF 5.08mm A/F configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers = 050 = 50V 300 = 300V 1K0 = 1kV 2K0 = 2kV 3K0 = 3kV First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF = 0G/NP0 X = 1 = Nut & Wavy Washer 3 = Nut & Toothed Lockwasher Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. ** Standard Option 90Sn/10Pb plating finish on all metalwork (body, pin, nut and wavy washer) specified by suffix code /0100. Please refer specific requests to the factory. SFJG eramic Threaded 63

64 SFJGL THREAD L- 0G/NP0 & SFJGL Ø 9.78 Max (0.385) 15.0 ± 1.0 (0.591 ± 0.039) 4.57 (0.180) 17.0 ± 1.0 (0.669 ± 0.039) 4.83 (0.190) 5.08 (0.200) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 15A 10GW or 1000WF -55º to +125º 1MHz PIN Ø 1.0 (0.039) THREAD RUN-OUT LESS THAN 1.25 IMPERFET THREADS Head Diameter 9.8mm (0.386 ) Nut A/F 7.92mm (0.312 ) Washer Diameter 11.35mm (0.447 ) 0.9Nm (7.97lbf in) max. ¼-28 UNF lass 2A Thread 9.8mm Round Head Mounting Hole Diameter A/F O.D. 6.7mm (0.264 ) O.D. 5.3mm (0.208 ) A/F Max. Panel Thickness 2.3mm (0.091 ) 3.0g (0.11oz) ** (see notes below) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) (dc) (dc) Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFJGL3K00101M 100pF 7 24 SFJGL3K00151M 150pF 3kV# 3.6kV SFJGL3K00221M 220pF SFJGL2K00331M 330pF 0G/NP SFJGL2K00471M 470pF SFJGL2K00681M 680pF SFJGL2K00102M 1.0nF SFJGL2K00152MX 1.5nF kV# 2.4kV SFJGL2K00222MX 2.2nF *SFJGL2K00332MX 3.3nF SFJGL2K00472MX 4.7nF *SFJGL2K00682MX 6.8nF *SFJGL2K00103MX 10nF SFJGL1K00153MX 15nF SFJGL1K00223MX 22nF *SFJGL1K00333MX 33nF 1kV# 1.2kV SFJGL1K00473MX 47nF >70 *SFJGL1K00683MX 68nF >70 SFJGL MX 100nF >70 *SFJGL MX 150nF >70 500# SFJGL MX 220nF >70 *SFJGL MX 330nF >70 SFJGL MX 470nF >70 SFJGL MX 680nF >70 >70 *SFJGL MX 1.0µF >70 >70 *SFJGL MX 1.5µF >70 > *SFJGL MX 2.2µF >70 >70 *SFJGL MX 3.3µF >70 >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur - evaluation in situ recommended. * Recommended values. Ordering Information - SFJGL range Note: Ordering code can have up to 4 additional digits on the end to denote special requirements SF J G L M X 1 ase 9.78mm Max Dia. Thread ¼-28 UNF 5.08mm A/F configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers L = L- 050 = 50V 300 = 300V 1K0 = 1kV 2K0 = 2kV 3K0 = 3kV First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. ** Standard Option 90Sn/10Pb plating finish on all metalwork (body, pin, nut and wavy washer) specified by suffix code /0100. Please refer specific requests to the factory. = 0G/NP0 X = 1 = Nut & Wavy Washer 3 = Nut & Toothed Lockwasher 64 SFJGL eramic Threaded

65 SFJGP Pi 0G/NP0 & Ø 10.1 Max (0.398) 25.4 ± 1.0 (1.0 ± 0.039) L 12.6 ± 1.0 (0.496 ± 0.039) 4.83 (0.190) 5.08 (0.200) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 15A 10GW or 1000WF -55º to +125º 1MHz SFJGP PIN Ø 1.0 (0.039) Head Diameter 9.8mm (0.386 ) Nut A/F 7.92mm (0.312 ) Washer Diameter 11.35mm (0.447 ) 0.9Nm (7.97lbf in) max. ¼-28 UNF lass 2A Thread 9.78mm Round Head Mounting Hole Diameter A/F O.D. 6.7mm (0.264 ) O.D. 5.3mm (0.208 ) A/F Max. Panel Thickness 2.3mm (0.091 ) 3.0g (0.11oz) Silver plate on copper undercoat Product ode apacitance (±20%) L (mm) [ ] Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFJGP2K00661M 660pF [0.7] SFJGP2K00941M 940pF [0.7] G/NP0 SFJGP2K01N36M 1.36nF [0.7] 7 37 >70 SFJGP2K00202M 2.0nF [0.7] >70 SFJGP2K00302MX 3.0nF [0.7] >70 2kV# 2.4kV SFJGP2K00442MX 4.4nF [0.7] >70 *SFJGP2K00662MX 6.6nF [0.7] >70 SFJGP2K00942MX 9.4nF [0.7] >70 *SFJGP2K013N6MX 13.6nF [0.7] 6 34 >70 >70 *SFJGP2K00203MX 20nF [0.7] 9 40 >70 >70 SFJGP1K00303MX 30nF [0.7] >70 >70 SFJGP1K00443MX 44nF [0.7] >70 >70 *SFJGP1K00663MX 66nF 1kV# 1.2kV [0.7] >70 >70 SFJGP1K00943MX 94nF [0.7] >70 >70 *SFJGP1K0136NMX 136nF [0.7] 8 25 >70 >70 >70 SFJGP MX 200nF [0.6] >70 >70 >70 500# *SFJGP MX 300nF [0.6] >70 >70 >70 SFJGP MX 440nF [0.6] >70 >70 >70 *SFJGP MX 660nF [0.6] >70 >70 >70 SFJGP MX 940nF [0.6] >70 >70 >70 SFJGP3001U36MX 1.36µF [0.6] >70 >70 >70 *SFJGP MX 2.0µF [0.6] >70 >70 >70 >70 *SFJGP MX 3.0µF [0.6] >70 >70 >70 > *SFJGP MX 4.4µF [0.6] >70 >70 >70 >70 SFJGP MX 6.6µF [0.6] >70 >70 >70 >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur - evaluation in situ recommended. * Recommended values. eramic Threaded Ordering Information - SFJGP range SF J G P M X 1 ase 10.1mm Max Dia. Thread ¼-28 UNF 5.08mm A/F configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers P = Pi 050 = 50V 300 = 300V 1K0 = 1kV 2K0 = 2kV First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF = 0G/NP0 X = 1 = Nut & Wavy Washer 3 = Nut & Toothed Lockwasher Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFJGP eramic Threaded 65

66 SFJN 0G/NP0 & SFJN Ø 9.8 (0.386) 15.0 ± 1.0 (0.591 ± 0.039) 4.57 (0.180) 17.0 ± 1.0 (0.669 ± 0.039) 4.83 (0.190) 5.0 (0.197) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 15A 10GW or 1000WF -55º to +125º Not Applicable PIN Ø 1.0 (0.039) Head Diameter 9.8mm (0.386 ) Nut A/F 8.0mm (0.315 ) Washer Diameter 11.35mm (0.447 ) 0.9Nm (7.97lbf in) max. M6 x g Thread 9.8mm Round Head Mounting Hole Diameter A/F O.D. 6.2mm (0.244 ) O.D. 5.3mm (0.208 ) A/F Max. Panel Thickness 2.9mm (0.114 ) 3.0g (0.11oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFJN3K00101M 100pF 4 22 SFJN3K00151M 150pF 3kV# 3.6kV 7 25 SFJN3K00221M 220pF SFJN2K00331M 330pF 0G/NP SFJN2K00471M 470pF SFJN2K00681M 680pF SFJN2K00102M 1.0nF SFJN2K00152MX 1.5nF kV# 2.4kV SFJN2K00222MX 2.2nF *SFJN2K00332MX 3.3nF SFJN2K00472MX 4.7nF *SFJN2K00682MX 6.8nF *SFJN2K00103MX 10nF SFJN1K00153MX 15nF SFJN1K00223MX 22nF *SFJN1K00333MX 33nF 1kV# 1.2kV SFJN1K00473MX 47nF *SFJN1K00683MX 68nF >70 SFJN MX 100nF >70 *SFJN MX 150nF >70 500# SFJN MX 220nF >70 *SFJN MX 330nF >70 SFJN MX 470nF >70 SFJN MX 680nF >70 *SFJN MX 1.0µF >70 >70 *SFJN MX 1.5µF >70 > * SFJN MX 2.2µF >70 >70 SFJN MX 3.3µF >70 >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur - evaluation in situ recommended. * Recommended values. Ordering Information - SFJN range SF J N M X 1 ase 9.8mm dia. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M6 = 050 = 50V 300 = 300V 1K0 = 1kV 2K0 = 2kV 3K0 = 3kV First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. = 0G/NP0 X = 0 = Without 1 = With 66 SFJN eramic Threaded

67 SFJNL THREAD L- 0G/NP0 & Ø 9.8 (0.386) 15.0 ± 1.0 (0.591 ± 0.039) 4.57 (0.180) 17.0 ± 1.0 (0.669 ± 0.039) 4.83 (0.190) 5.0 (0.197) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 15A 10GW or 1000WF -55º to +125º 500nH SFJNL PIN Ø 1.0 (0.039) Head Diameter 9.8mm (0.386 ) Nut A/F 8.0mm (0.315 ) Washer Diameter 11.35mm (0.447 ) 0.9Nm (7.97lbf in) max. M6 x g Thread 9.8mm Round Head Mounting Hole Diameter A/F O.D. 6.2mm (0.244 ) O.D. 5.3mm (0.208 ) A/F Max. Panel Thickness 2.9mm (0.114 ) 3.0g (0.11oz) Silver plate on copper undercoat Product ode apacitance (±20%) Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz SFJNL3K00101M 100pF 7 24 SFJNL3K00151M 150pF 3kV# 3.6kV SFJNL3K00221M 220pF SFJNL2K00331M 330pF 0G/NP SFJNL2K00471M 470pF SFJNL2K00681M 680pF SFJNL2K00102M 1.0nF SFJNL2K00152MX 1.5nF kV# 2.4kV SFJNL2K00222MX 2.2nF *SFJNL2K00332MX 3.3nF SFJNL2K00472MX 4.7nF *SFJNL2K00682MX 6.8nF *SFJNL2K00103MX 10nF SFJNL1K00153MX 15nF SFJNL1K00223MX 22nF *SFJNL1K00333MX 33nF 1kV# 1.2kV SFJNL1K00473MX 47nF >70 *SFJNL1K00683MX 68nF >70 SFJNL MX 100nF >70 *SFJNL MX 150nF >70 500# SFJNL MX 220nF >70 *SFJNL MX 330nF >70 SFJNL MX 470nF >70 SFJNL MX 680nF >70 >70 *SFJNL MX 1.0µF >70 >70 *SFJNL MX 1.5µF >70 > *SFJNL MX 2.2µF >70 >70 SFJNL MX 3.3µF >70 >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur - evaluation in situ recommended. * Recommended values. eramic Threaded Ordering Information - SFJNL range SF J N L M X 1 ase 9.8mm dia. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M6 L = L- 050 = 50V 300 = 300V 1K0 = 1kV 2K0 = 2kV 3K0 = 3kV First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. = 0G/NP0 X = 0 = Without 1 = With SFJNL eramic Threaded 67

68 SFKB 0G/NP0 & SFKB SLOT WIDTH 1.0 (0.039) Ø 4.4 (0.173) 15.0 ± 1.0 (0.591 ± 0.039) SLOT DEPTH 1.0 (0.039) 4.6 (0.181) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance 1000hr Point 10A 10GW or 1000WF -55º to +125º Not Applicable PIN Ø 0.7 (0.028) Head Diameter 4.4mm (0.173 ) Nut A/F N/a. For use in tapped hole Washer Diameter N/a 0.15Nm (1.32lbf in) max UN lass 2A Thread 4.4mm Round Head Mounting Hole Max. Panel Thickness 6-32 UN lass 2B N/a 0.8g (0.03oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFKB Z 10pF -20% / +80% 500# 4 SFKB Z 15pF -20% / +80% 500# 7 SFKB Z 22pF -20% / +80% 500# 10 SFKB Z 33pF -20% / +80% 500# 12 *SFKB Z 47pF -20% / +80% 500# G/NP0 *SFKB M 68pF 500# 2 18 *SFKB M 100pF 500# 4 22 SFKB M 150pF 500# 7 25 *SFKB M 220pF 500# *SFKB M 330pF 500# *SFKB MX 470pF 500# SFKB MX 680pF 500# *SFKB MX 1.0nF 500# SFKB MX 1.5nF 500# *SFKB MX 2.2nF 500# SFKB MX 3.3nF 500# *SFKB MX 4.7nF 500# SFKB MX 6.8nF 500# *SFKB MX 10nF 500# *SFKB MX 15nF 500# *SFKB MX 22nF 500# SFKB MX 33nF 500# *SFKB MX 47nF SFKB MX 68.0nF >70 *SFKB MX 100nF >70 *SFKB MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFKB range SF K B M 0 ase 4.4mm O.D. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers 6-32 UN = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Note: Installation tool available on request Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 68 SFKB eramic Threaded

69 SFKBL THREAD L- 0G/NP0 & SLOT WIDTH 1.0 (0.039) Ø 4.4 (0.173) 15.0 ± 1.0 (0.591 ± 0.039) SLOT DEPTH 1.0 (0.039) 4.6 (0.181) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 50nH SFKBL PIN Ø 0.7 (0.028) Head Diameter 4.4mm (0.173 ) Nut A/F N/a. For use in tapped hole Washer Diameter N/a 0.15Nm (1.32lbf in) max UN lass 2A Thread 4.4mm Round Head Mounting Hole Max. Panel Thickness 6-32 UN lass 2B N/a 0.8g (0.03oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz * SFKBL Z 10pF -20% / +80% 500# 6 SFKBL Z 15pF -20% / +80% 500# 9 SFKBL Z 22pF -20% / +80% 500# 12 SFKBL Z 33pF -20% / +80% 500# 1 15 * SFKBL Z 47pF -20% / +80% 500# G/NP0 * SFKBL M 68pF 500# 4 20 * SFKBL M 100pF 500# 7 24 SFKBL M 150pF 500# * SFKBL M 220pF 500# * SFKBL M 330pF 500# * SFKBL MX 470pF 500# SFKBL MX 680pF 500# * SFKBL MX 1.0nF 500# SFKBL MX 1.5nF 500# * SFKBL MX 2.2nF 500# SFKBL MX 3.3nF 500# * SFKBL MX 4.7nF 500# SFKBL MX 6.8nF 500# * SFKBL MX 10nF 500# * SFKBL MX 15nF 500# * SFKBL MX 22nF 500# SFKBL MX 33nF 500# * SFKBL MX 47nF > SFKBL MX 68nF >70 *SFKBL MX 100nF >70 *SFKBL MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFKBL range SF K B L M 0 ase 4.4mm O.D. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers 6-32 UN L = L- 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Note: Installation tool available on request Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFKBL eramic Threaded 69

70 SFKK 0G/NP0 & SFKK SLOT WIDTH 1.0 (0.039) Ø 4.4 (0.173) 15.0 ± 1.0 (0.591 ± 0.039) SLOT DEPTH 1.0 (0.039) PIN Ø 0.7 (0.028) 4.6 (0.181) 6.0 (0.236) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicable Head Diameter 4.4mm (0.173 ) Nut A/F N/a. For use in tapped hole Washer Diameter N/a 0.18Nm (1.59lbf in) max. M3.5 x 0.5-6g Thread 4.4mm Round Head Mounting Hole Max. Panel Thickness M3.5 x 0.5-6h N/a 0.8g (0.03oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFKK Z 10pF -20% / +80% 4 SFKK Z 15pF -20% / +80% 7 SFKK Z 22pF -20% / +80% 10 SFKK Z 33pF -20% / +80% 12 *SFKK Z 47pF -20% / +80% G/NP0 *SFKK M 68pF 2 18 *SFKK M 100pF 4 22 SFKK M 150pF 7 25 *SFKK M 220pF *SFKK M 330pF *SFKK MX 470pF # 750 SFKK MX 680pF *SFKK MX 1.0nF SFKK MX 1.5nF *SFKK MX 2.2nF SFKK MX 3.3nF *SFKK MX 4.7nF SFKK MX 6.8nF *SFKK MX 10nF *SFKK MX 15nF *SFKK MX 22nF SFKK MX 33nF *SFKK MX 47nF SFKK MX 68nF >70 *SFKK MX 100nF >70 * SFKK MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFKK range SF K K M 0 ase 4.4mm O.D. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M3.5 = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Note: Installation tool available on request Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 70 SFKK eramic Threaded

71 SFKKL THREAD TL- 0G/NP0 & SLOT WIDTH 1.0 (0.039) Ø 4.4 (0.173) 15.0 ± 1.0 (0.591 ± 0.039) 4.6 (0.181) SLOT DEPTH 1.0 (0.039) 17.0 ± 1.0 (0.669 ± 0.039) 6.0 (0.236) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 50nH SFKKL PIN Ø 0.7 (0.028) Head Diameter 4.4mm (0.173 ) Nut A/F N/A. For use in tapped hole Washer Diameter N/A 0.18Nm (1.59lbf in) max. M3.5 Thread x 0.5-6g Thread 4.4mm Round Head Mounting Hole M3.5 x 0.6-6h Max. Panel Thickness N/ 0.8g (0.03oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFKKL Z 10pF -20% / +80% 6 SFKKL Z 15pF -20% / +80% 9 SFKKL Z 22pF -20% / +80% 12 SFKKL Z 33pF -20% / +80% 1 15 *SFKKL Z 47pF -20% / +80% G/NP0 *SFKKL M 68pF 4 20 *SFKKL M 100pF 7 24 SFKKL M 150pF *SFKKL M 220pF *SFKKL M 330pF *SFKKL MX 470pF # 750 SFKKL MX 680pF *SFKKL MX 1.0nF SFKKL MX 1.5nF *SFKKL MX 2.2nF SFKKL MX 3.3nF *SFKKL MX 4.7nF SFKKL MX 6.8nF *SFKKL MX 10nF *SFKKL MX 15nF *SFKKL MX 22nF SFKKL MX 33nF *SFKKL MX 47nF > SFKKL MX 68nF >70 *SFKKL MX 100nF >70 *SFKKL MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFKKL range SF K K L M 0 ase 4.4mm O.D. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M3.5 L = L- 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Note: Installation tool available on request Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFKKL eramic Threaded 71

72 SFKKT T 0G/NP0 & SFKKT SLOT WIDTH 1.0 (0.039) Ø 4.4 (0.173) 15.0 ± 1.0 (0.591 ± 0.039) 7.5 (0.295) 3.5 (0.137) 17.0 ± 1.0 (0.669 ± 0.039) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 100nH SLOT DEPTH 1.0 (0.039) 0.9 U/UT (0.035) PIN Ø 0.7 (0.028) Head Diameter 4.4mm (0.173 ) Nut A/F N/A. For use in tapped hole Washer Diameter N/A 0.18Nm (1.59lbf in) max. M3.5 x 0.6-6g Thread 4.4mm Round Head Mounting Hole Max. Panel Thickness M3.5 x 0.5-6h N/A 0.8g (0.03oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFKKT Z 10pF -20% / +80% 9 SFKKT Z 15pF -20% / +80% 11 SFKKT Z 22pF -20% / +80% 1 14 SFKKT Z 33pF -20% / +80% 2 18 *SFKKT Z 47pF -20% / +80% G/NP0 *SFKKT M 68pF 6 23 *SFKKT M 100pF 9 27 SFKKT M 150pF *SFKKT M 220pF *SFKKT M 330pF *SFKKT MX 470pF # 750 SFKKT MX 680pF *SFKKT MX 1.0nF SFKKT MX 1.5nF *SFKKT MX 2.2nF SFKKT MX 3.3nF *SFKKT MX 4.7nF SFKKT MX 6.8nF *SFKKT MX 10nF *SFKKT MX 15nF *SFKKT MX 22nF SFKKT MX 33nF >70 *SFKKT MX 47nF > SFKKT MX 68nF >70 *SFKKT MX 100nF >70 *SFKKT MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFKKT range SF K K T M 0 ase 4.4mm O.D. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M3.5 T = T 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. * Mounting tool available. 72 SFKKT eramic Threaded

73 SFLM 0G/NP0 & SLOT WIDTH 1.0 (0.039) Ø 6.0 (0.236) 15.0 ± 1.0 (0.591 ± 0.039) 4.75 (0.187) SLOT DEPTH 1.0 (0.039) PIN Ø 0.7 (0.028) 17.0 ± 1.0 (0.669 ± 0.039) 8.0 (0.315) onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicable Head Diameter 6.0mm (0.236 ) Nut A/F N/A. For use in tapped hole SFLM Washer Diameter N/A 0.3Nm (2.65lbf in) max. M5 x 0.8-6g Thread 6.0mm Round Head Mounting Hole Max. Panel Thickness M5 x 0.8-6h N/A 2.0g (0.07oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFLM Z 10pF -20% / +80% 4 SFLM Z 15pF -20% / +80% 7 SFLM Z 22pF -20% / +80% 10 SFLM Z 33pF -20% / +80% 12 *SFLM Z 47pF -20% / +80% G/NP0 *SFLM M 68pF 2 18 *SFLM M 100pF 4 22 SFLM M 150pF 7 25 *SFLM M 220pF *SFLM M 330pF *SFLM MX 470pF # 750 SFLM MX 680pF *SFLM MX 1.0nF SFLM MX 1.5nF *SFLM MX 2.2nF SFLM MX 3.3nF *SFLM MX 4.7nF SFLM MX 6.8nF *SFLM MX 10nF *SFLM MX 15nF *SFLM MX 22nF SFLM MX 33nF *SFLM MX 47nF SFLM MX 68nF >70 *SFLM MX 100nF >70 *SFLM MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFLM range SF L M M 0 ase 6.0mm O.D. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Note: Installation tool available on request Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFLM eramic Threaded 73

74 SFLML THREAD L- 0G/NP0 & SFLML SLOT WIDTH 1.0 (0.039) Ø 6.0 (0.236) 15.0 ± 1.0 (0.591 ± 0.039) 4.75 (0.187) SLOT DEPTH 1.0 (0.039) 17.0 ± 1.0 (0.669 ± 0.039) 8.0 (0.315) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 500nH PIN Ø 0.7 (0.028) Head Diameter 6.0mm (0.236 ) Nut A/F N/A. For use in tapped hole Washer Diameter N/A 0.3Nm (2.65lbf in) max. M5 x 0.8-6g Thread 6.0mm Round Head Mounting Hole Max. Panel Thickness M5 x 0.8-6h N/A 2.0g (0.07oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFLML Z 10pF -20% / +80% 6 SFLML Z 15pF -20% / +80% 9 SFLML Z 22pF -20% / +80% 12 SFLML Z 33pF -20% / +80% 1 15 *SFLML Z 47pF -20% / +80% G/NP0 *SFLML M 68pF 4 20 *SFLML M 100pF 7 24 SFLML M 150pF *SFLML M 220pF *SFLML M 330pF *SFLML MX 470pF # 750 SFLML MX 680pF *SFLML MX 1.0nF SFLML MX 1.5nF *SFLML MX 2.2nF SFLML MX 3.3nF *SFLML MX 4.7nF SFLML MX 6.8nF *SFLML MX 10nF *SFLML MX 15nF *SFLML MX 22nF SFLML MX 33nF *SFLML MX 47nF > SFLML MX 68nF >70 *SFLML MX 100nF >70 *SFLML MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFLML range SF L M L M 0 ase 6.0mm O.D. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 L = L- 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Note: Installation tool available on request Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 74 SFLML eramic Threaded

75 SFLMP Pi 0G/NP0 & SLOT WIDTH 1.0 (0.039) Ø 6.0 (0.236) 15.0 ± 1.0 (0.591 ± 0.039) 4.75 (0.187) SLOT DEPTH 1.0 (0.039) 17.0 ± 1.0 (0.669 ± 0.039) 8.0 (0.315) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 250nH SFLMP PIN Ø 0.7 (0.028) Head Diameter 6.0mm (0.236 ) Nut A/F N/A. For use in tapped hole Washer Diameter N/A 0.3Nm (2.65lbf in) max. M5 x 0.8-6g Thread 6.0mm Round Head Mounting Hole Max. Panel Thickness M5 x 0.8-6h N/A 2.0g (0.07oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFLMP Z 20pF -20% / +80% 1 11 SFLMP Z 30pF -20% / +80% 2 15 SFLMP Z 44pF -20% / +80% 3 19 SFLMP Z 66pF -20% / +80% 4 23 *SFLMP Z 94pF -20% / +80% G/NP0 *SFLMP M 136pF 8 35 *SFLMP M 200pF SFLMP M 300pF *SFLMP M 440pF *SFLMP M 660pF *SFLMP MX 940pF # 750 SFLMP5001N36MX 1.36nF 7 37 >70 *SFLMP MX 2nF >70 SFLMP MX 3nF >70 *SFLMP MX 4.4nF >70 SFLMP MX 6.6nF >70 *SFLMP MX 9.4nF >70 SFLMP50013N6MX 13.6nF 6 34 >70 >70 *SFLMP MX 20nF 9 40 >70 >70 *SFLMP MX 30nF >70 >70 *SFLMP MX 44nF >70 >70 SFLMP MX 66nF >70 >70 *SFLMP MX 94nF >70 > SFLMP200136NMX 136nF 8 25 >70 >70 >70 *SFLMP MX 200nF >70 >70 >70 *SFLMP MX 300nF >70 >70 >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFLMP range SF L M P M X 0 ase 6.0mm O.D. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 P = Pi 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Note: Installation tool available on request Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFLMP eramic Threaded 75

76 SFLMT T 0G/NP0 & SFLMT SLOT WIDTH 1.0 (0.039) Ø 6.0 (0.236) 15.0 ± 1.0 (0.591 ± 0.039) 4.75 (0.187) SLOT DEPTH 1.0 (0.039) 17.0 ± 1.0 (0.669 ± 0.039) 8.0 (0.315) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) Ferrite Inductance (Typical) 1000hr Point 10A 10GW or 1000WF -55º to +125º 450nH PIN Ø 0.7 (0.028) Head Diameter 6.0mm (0.236 ) Nut A/F N/a. For use in tapped hole Washer Diameter N/a 0.3Nm (2.65lbf in) max. M5 x 0.8-6g Thread 6.0mm Round Head Mounting Hole Max. Panel Thickness M5 x 0.8-6h N/a 2.0g (0.07oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFLMT Z 10pF -20% / +80% 9 SFLMT Z 15pF -20% / +80% 11 SFLMT Z 22pF -20% / +80% 1 14 SFLMT Z 33pF -20% / +80% 2 18 *SFLMT Z 47pF -20% / +80% G/NP0 *SFLMT M 68pF 6 23 *SFLMT M 100pF 9 27 SFLMT M 150pF *SFLMT M 220pF *SFLMT M 330pF *SFLMT MX 470pF # 750 SFLMT MX 680pF *SFLMT MX 1.0nF SFLMT MX 1.5nF *SFLMT MX 2.2nF SFLMT MX 3.3nF *SFLMT MX 4.7nF SFLMT MX 6.8nF *SFLMT MX 10nF *SFLMT MX 15nF *SFLMT MX 22nF SFLMT MX 33nF >70 *SFLMT MX 47nF > *SFLMT MX 68nF >70 *SFLMT MX 100nF >70 *SFLMT MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self- heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFLMT range SF L M T M 0 ase 6.0mm O.D. Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers M5 T = T 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Z = % = 0G/NP0 X = 0 = Without Note: Installation tool available on request Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 76 SFLMT eramic Threaded

77 SFTM 0G/NP0 & 6.35 A/F (0.250) 15.0 ± 1.0 (0.591 ± 0.039) IN Ø 0.7 (0.028) 2.0 (0.079) 17.0 ± 1.0 (0.669 ± 0.039) 3.6 (0.142) onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicable Head A/F 6.35mm (0.250 ) SFTM Nut A/F N/A. For use in tapped hole Washer Diameter N/A Low Profile M5 x 0.8-6g Thread 6.35mm Hexagonal Head Mounting Hole Max. Panel Thickness 0.3Nm (2.65lbf in) max. M5 x 0.8-6h N/A 1.2g (0.04oz) Silver plate on copper undercoat Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFTM Z 10pF -20% / +80% 4 SFTM Z 15pF -20% / +80% 7 *SFTM Z 22pF -20% / +80% 10 *SFTM Z 33pF -20% / +80% 12 *SFTM Z 47pF -20% / +80% G/NP0 SFTM M 68pF 2 18 *SFTM M 100pF 4 22 *SFTM M 150pF 7 25 *SFTM MX 220pF SFTM MX 330pF # *SFTM MX 470pF SFTM MX 680pF *SFTM MX 1.0nF SFTM MX 1.5nF *SFTM MX 2.2nF SFTM MX 3.3nF *SFTM MX 4.7nF *SFTM MX 6.8nF *SFTM MX 10nF SFTM MX 15nF *SFTM MX 22nF SFTM MX 33nF *SFTM MX 47nF *SFTM MX 68nF >70 *SFTM MX 100nF >70 *SFTM MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. eramic Threaded Ordering Information - SFTM range SF T M M 0 ase 6.35mm Hex. Head Low Profile Thread configuration (dc) apacitance in picofarads (pf) M5 = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Tolerance Z = % = 0G/NP0 X = Nuts & Washers 0 = Without Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SFTM eramic Threaded 77

78 SFUM 0G/NP0 - SFUM SLOT WIDTH 1.0 (0.039) Ø 6.0 (0.236) 15.0 ± ± 1.0 (0.591 ± 0.039) (0.699 ± 0.039) 2.0 (0.079) 3.6 SLOT DEPTH (0.142) 1.0 (0.039) PIN Ø 0.7 (0.028) Low Profile M5 x 0.8-6g Thread 6.0mm Round Head onfiguration apacitance 1000hr Point urrent Rating 10A Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Ferrite Inductance (Typical) Not Applicable Head Diameter 6.0mm (0.236 ) Nut A/F N/A. For use in tapped hole Washer Diameter N/A 0.3Nm (2.65lbf in) max. Mounting Hole M5 x 0.8-6h Max. Panel Thickness N/A 1.2g (0.04oz) Silver plate on copper undercoat eramic Threaded Product ode apacitance (±20%) UOS Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz *SFUM Z 10pF -20% / +80% 4 SFUM Z 15pF -20% / +80% 7 SFUM Z 22pF -20% / +80% 10 SFUM Z 33pF -20% / +80% 12 *SFUM Z 47pF -20% / +80% G/NP0 *SFUM M 68pF 2 18 *SFUM M 100pF 4 22 SFUM M 150pF 7 25 *SFUM M 220pF *SFUM M 330pF *SFUM MX 470pF # 750 SFUM MX 680pF *SFUM MX 1.0nF SFUM MX 1.5nF *SFUM MX 2.2nF SFUM MX 3.3nF *SFUM MX 4.7nF SFUM MX 6.8nF *SFUM MX 10nF *SFUM MX 15nF *SFUM MX 22nF SFUM MX 33nF *SFUM MX 47nF SFUM MX 68nF >70 *SFUM MX 100nF >70 *SFUM MX 150nF >70 # Also rated for operation at 115Vac 400Hz. Self-heating will occur evaluation in situ recommended. * Recommended values. Also available in 0G/NP0. Ordering Information - SFUM range SF U M M 0 ase 6.0mm O.D. Low Profile Thread configuration (dc) apacitance in picofarads (pf) M5 = 050 = 50V First digit is 0. Second and third digits are significant figures of Example: 0101 = 100pF 0332 = 3300pF Tolerance Z = % = 0G/NP0 X = Nuts & Washers 0 = Without Note: Installation tool available on request Options include for example: change of finish / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. * Mounting tool available. 78 SFUM eramic Threaded

79 SFJEB A X2Y 1 2 A 1 B B Ø 9.8 (0.386) 15.0 ± 1.0 (0.591 ± 0.039) 4.57 (0.180) 17.0 ± 1.0 (0.669 ± 0.039) 4.83 (0.190) 5.3 (0.209) 2.00 (0.080) onfiguration apacitance Measurement Withstand See ircuit 1000hr Point -55º to +125º 200Vdc 500Vdc SFJEB Ø ) Head Diameter 9.8mm (0.386 ) Nut A/F 7.92mm (0.312 ) Washer Diameter 11.35mm (0.447 ) 0.9Nm (7.97lbf in) max. ¼-28 UNF Thread lass 2A thread Balanced Line EMI Range Mounting Hole Diameter A/F O.D. 6.7mm (0.264 ) O.D. 5.5mm (0.217 ) A/F Max. Panel Thickness 2.3mm (0.091 ) 3.0g (0.11oz) Silver plate on copper undercoat Product ode SFJEB MX1 SFJEB MX1 SFJEB MX1 SFJEB MX1 SFJEB MX1 apacitance (±20%) UOS 1 = 4.7nF 2 = 2.35nF 1 = 10nF 2 = 5nF 1 = 22nF 2 = 11nF 1 = 47nF 2 = 23.5nF 1 = 100nF 2 = 50nF Typical No-Load Insertion Loss (db) 0.01MHz 0.1MHz 1MHz 10MHz 100MHz 1GHz >70 eramic Threaded Ordering Information - SFJEB range SF J E B M X 1 ase Thread configuration (dc) apacitance in picofarads (pf) Tolerance Nuts & Washers 9.8mm O.D. ¼-28 UNF Balanced Line First digit is 0. Second and third digits are significant figures of (Standard) X = 1 = With Example: 0472 = 4700pF 0223 = 22000pF L- circuit optional - refer to factory Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SLJEB Hermetic eramic 79

80 SLS*P Pi Hermetically Sealed - Non RoHS compliant SLS*P 27 Across Ø9.78 flats (0.385 ) Ø2.60 (0.102 ) A Ø32 (1.26) 20.4 (0.80 ) L 4.50 (0.20 ) (0.177 ) M Mounting Thread (0.165 ) M8 Terminal Thread Ø1.20 (0.047 ) 5.00 (1.97 ) Resin fill (UL94 V-0) onfiguration Pi apacitance Measurement 1000hr Point urrent Rating See Table Insulation Resistance (IR) 10GW or 1000WF -55º to +125º Hermetic Seal Performance Head Diameter 9.78mm (0.385") Nut A/F 7.92mm (0.312") Washer Diameter 8.81mm (0.347") 0.9Nm (7.97lbf in) max. M20 ¼-28 x UNF 1 Thread class 2A thread (5.08mm A/F) 32mm 9.78mm Round Head : M8 Spindle Mounting Hole Diameter 6.7mm O.D., 5.3mm A/F (0.264 O.D., A/F) Max. Panel Thickness 2.3mm (0.091 ) 8.0g (0.28oz) A/F O.D. Tin plate Product ode apacitance (-0/+100%) urrent (A) Series Resistance (Ω) Minimum No-Load Insertion Loss (db) 30kHz 150kHz 300kHz 1MHz 10MHz 100MHz 1GHz SLSP PX SLSDP PX Hermetic eramic SLSEP PX µF SLSFP PX SLSGP PX SLSHP PX Other values may be available subject to minimum order quantities. Please refer to factory. Ordering Information - SLS*P range SLS H P P X 1 Hermetic Panel Mount urrent Rating = 0.5A D = 1A E = 3A F = 5A G = 8A H =10A configuration (dc) apacitance in picofarads (pf) P = Pi 080 = 80V First digit is 0. Second and third digits are significant figures of Example: 0285 = 2.8µF Tolerance P = -0 / +100% X = Nuts & Washers 1 = Nut & Wavy Washer Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. Hermetic 80 SLS*P Hermetic eramic

81 SLO** THREAD L- Pi Hermetically Sealed - Non RoHS compliant 27 Across Ø8.33 flats (0.328 ) Ø1.60 (0.063 ) A (0.74 ) L 4.17 (0.164 ) Ø32 (1.26) 5.75 (0.23 ) onfiguration apacitance Measurement urrent Rating Insulation Resistance (IR) L- or Pi 1000hr Point See Table 10GW or 1000WF -55º to +125º SLO** M Mounting Thread (0.174 ) M8 Terminal Thread 4.88 (1.92 ) Resin fill (UL94 V-0) Hermetic Seal Performance Head Diameter 8.33mm (0.385") Nut A/F 7.92mm (0.315 ) Washer Diameter 8.81mm (0.347 ) 0.9Nm (7.97lbf in) max. M20 ¼-28 x UNF 1 Thread class 2A thread (5.75mm A/F) 32mm 8.33mm Round Head : M8 Spindle Mounting Hole Diameter 6.7mm O.D., 5.9mm A/F (0.264 O.D., A/F) Max. Panel Thickness 2.3mm (0.091") 8.0g (0.28oz) A/F O.D. Tin plate Product ode ircuit apacitance (-0/+100%) urrent (A) Series Resistance (Ω) Max Minimum No-Load Insertion Loss (db) 30kHz 150kHz 300kHz 1MHz 10MHz 100MHz 1GHz SLODL PX1 20nF L SLOFL PX1 100nF SLOAP PX SLOBP PX1 40nF SLODP PX Pi SLOAP PX Hermetic eramic SLOBP PX1 200nF SLODP PX Other values may be available subject to minimum order quantities. Please refer to factory. All versions are available with a 4M7 discharge resistor fitted in parallel to the capacitor see ordering information below. Ordering Information - SLO** range SLO D P P X 1 Suffix Hermetic Panel Mount urrent Rating A = 0.3A B = 0.45A D = 1A F = 5A configuration (dc) apacitance in picofarads (pf) P = Pi L = L- First digit is 0. Second and third digits are significant figures of Example: 0203 = 20nF 0403 = 40nF 0204 = 200nF Tolerance P = -0 / +100% X = Nuts & Washers 1 = Nut & Wavy Washer R = 4M7 line to ground discharge resistor included /**** As required Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. Hermetic SLO** Hermetic eramic 81

82 SLDL* Pi Metallised Film 32A Self-Healing Feedthrough EMI - Including Y2/Y4 SLDL* 17 Across flats A L Ø20 (0.787) onfiguration apacitance Measurement urrent Rating Rating Pulse Test (as per EN132400) or Pi Nominal 32A Derate above 60º Ambient See Table. A ratings at 50Hz Y2 = 5kV peak Y4 = 2.5kV peak M12 Mounting Thread M4 Terminal Thread Resin fill (UL94 V-0) Insulation Resistance (IR) 15GW or 5000s (MWµF) -40º to +85º Head Diameter 20mm (0.787 ) Nut A/F 17mm (0.669 ) M12 x 1 Thread 20mm Round Head : M4 Spindle Through onductor onductor Tightening Torque Encapsulation 4Nm (35.40lbft in) max. M4 1.2Nm (10.62lbft in) max. Resin UL94V0 Nickel plate Product ode ircuit Length A Length L apacitance (±20%) Weight (g) Minimum Full Load Insertion Loss (db) 10kHz 30kHz 100kHz 300kHz 1MHz 10MHz 100MHz 1GHz SLDLA250472M1Y 4.7nF SLDLA250103M1Y Vac 10nF (Y2) SLDLA250473M1Y 47nF SLDLA130104M1Y 100nF 130Vac (Y4) Metallised Film SLDL M11 500nF 600Vdc SLDL M11 1µF 400Vdc SLDL M11 3µF 250Vdc SLDL M11 7µF 100Vdc SLDL M11 14µF 63Vdc SLDL M11 20µF 30Vdc SLDLPA250203M1Y nF 90 Pi SLDLPA130204M1Y nF Vac (Y2) 130Vac (Y4) 250Vac & 130Vac parts are dual 600Vdc. Other values may be available subject to minimum order quantities. Please refer to factory. urrent derating between 60º and 85º. For temp T. I = I ( 85 T)/ 25 T R Ordering Information - SLDL* range SLD L P A M 1 Y Suffix Plastic Film Panel Mount urrent Rating L = 32A configuration = P = Pi 063 = 63Vdc dc 250 = 250Vdc 400 = 400Vdc 600 = 600Vdc A13 = 130Vac A25 = 250Vac apacitance in picofarads (pf) First digit is 0. Second and third digits are significant figures of Example: 0203 = 20nF 0403 = 40nF 0204 = 200nF Tolerance 1 = Plastic Film Nuts & Washers Y = designed and tested to meet the requirements of EN & EN Hardware supplied - 1 = Nut & Wavy Washer /**** As required Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 82 SLDL* Metallised Film

83 SLG** Pi Metallised Film 63/100A Self-Healing Feedthrough EMI - Including Y2/Y4 22 Across flats A L M16 Mounting Thread M6 Terminal Thread Ø25 (0.984) Resin fill (UL94 V-0) onfiguration apacitance Measurement urrent Rating Rating Pulse Test (as per EN132400) Insulation Resistance (IR) or Pi Nominal M1Y = 63A Derate above 60º Ambient M11 = 100A (Derate above 50º) See Table. A ratings at 50Hz Y2 = 5kV peak Y4 = 2.5kV peak 15GW or 5000s (MWµF) -40º to +85º SLG** Head Diameter 25mm (0.984 ) Nut A/F 22mm (0.866 ) M16 x 1 Thread 25mm Round Head : M6 Spindle Through onductor onductor Tightening Torque Encapsulation 7Nm (61.96lbft in) max. M6 2.5Nm (22.13lbft in) max. Resin UL94V0 Nickel plate Product ode ircuit Length A Length L apacitance (±20%) Weight (g) Minimum Full Load Insertion Loss (db) 10kHz 30kHz 100kHz 300kHz 1MHz 10MHz 100MHz 1GHz SLGMA250103M1Y 10nF SLGMA250473M1Y 47nF 250Vac (Y2) SLGMA250104M1Y 100nF SLGN M11 800nF 600Vdc SLGN M11 2µF 400Vdc SLGN M11 4µF 250Vdc SLGN M11 12µF 100Vdc SLGN M11 22µF 63Vdc SLGMPA250943M1Y nF 200 Pi SLGMPA130204M1Y nF Vac (Y2) 130Vac (Y4) 250Vac & 130Vac parts are dual 600Vdc. Other values may be available subject to minimum order quantities. Please refer to factory. 100A SLGN - urrent derating between 50º and 85º. For temp T. IT = IR ( 85 T)/35 63A SLGM (Y2 / Y4) - urrent derating between 60º and 85º. I = I ( 85 T)/25 T R Metallised Film Ordering Information - SLG** range SLG M A M 1 Y Suffix Plastic Film Panel Mount urrent Rating M = 63A N = 100A configuration = P = Pi 063 = 63Vdc dc 250 = 250Vdc 400 = 400Vdc 600 = 600Vdc A13 = 130Vac A25 = 250Vac apacitance in picofarads (pf) First digit is 0. Second and third digits are significant figures of Example: 0203 = 20nF 0403 = 40nF 0204 = 200nF Tolerance 1 = Plastic Film Nuts & Washers Y = designed and tested to meet the requirements of EN & EN Hardware supplied - 1 = Nut & Wavy Washer Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. /**** As required SLG** Metallised Film 83

84 SLKN* Pi Metallised Film 100A Self-Healing Feedthrough EMI - Including Y2/Y4 SLKN* 27 Across flats A L M20 Mounting Thread M8 Terminal Thread Ø32 (1.26) Resin fill (UL94 V-0) onfiguration apacitance Measurement urrent Rating Rating Pulse Test (as per EN132400) Insulation Resistance (IR) or Pi Nominal 100A Derate above 60º Ambient See Table. A ratings at 50Hz Y2 = 5kV peak Y4 = 2.5kV peak 15GW or 5000s (MWµF) -40º to +85º Head Diameter 32mm (1.26 ) Nut A/F 27mm (1.06 ) M20 x 1 Thread 32mm Round Head : M8 Spindle Through onductor onductor Tightening Torque Encapsulation 10Nm (88.51lbft in) max. M8 5Nm (44.25lbft in) max. Resin UL94V0 Nickel plate Product ode ircuit Length A Length L apacitance (±20%) Weight (g) Minimum Full Load Insertion Loss (db) 10kHz 30kHz 100kHz 300kHz 1MHz 10MHz 100MHz 1GHz SLKNA250473M1Y 47nF Vac 5000 (Y2) SLKNA250104M1Y 100nF SLKNA130474M1Y 470nF SLKN M11 1µF 600Vdc SLKN M11 4µF 400Vdc Vac (Y4) SLKN M11 7µF 250Vdc SLKN M11 22µF 100Vdc Metallised Film SLKN M11 40µF 63Vdc Vac SLKNPA250204M1Y 200nF (Y2) Pi Vac SLKNPA130944M1Y 940nF (Y4) 250Vac & 130Vac parts are dual 600Vdc. Other values may be available subject to minimum order quantities. Please refer to factory. urrent derating between 60º and 85º. For temp T. I = I ( 85 T)/ 25 T R Ordering Information - SLKN* range SLK N P A M 1 Y Suffix Plastic Film Panel Mount urrent Rating N = 100A configuration = P = Pi 063 = 63Vdc dc 250 = 250Vdc 400 = 400Vdc 600 = 600Vdc A13 = 130Vac A25 = 250Vac apacitance in picofarads (pf) First digit is 0. Second and third digits are significant figures of Example: 0203 = 20nF 0403 = 40nF 0204 = 200nF Tolerance 1 = Plastic Film Nuts & Washers Y = designed and tested to meet the requirements of EN & EN Hardware supplied - 1 = Nut & Wavy Washer /**** As required Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 84 SLKN* Metallised Film

85 SLVR* Pi Metallised Film 200A Self-Healing Feedthrough EMI - Including Y2/Y4 27 Across flats A L M24 Mounting Thread M10 Terminal Thread Ø38 (1.50) Resin fill (UL94 V-0) onfiguration apacitance Measurement urrent Rating Rating Pulse Test (as per EN132400) Insulation Resistance (IR) or Pi Nominal 200A Derate above 60º Ambient See Table. A ratings at 50Hz Y2 = 5kV peak Y4 = 2.5kV peak 15GW or 5000s (MWµF) -40º to +85º SLVR* Head Diameter 38mm (1.50 ) Nut A/F 27mm (1.06 ) M24 x 1 Thread 38mm Round Head : M10 Spindle Through onductor onductor Tightening Torque Encapsulation 14Nm (123.9lbft in) max. M10 8Nm (70.81lbft in) max. Resin UL94V0 Nickel plate Product ode SLVRA250104M1Y SLVRA250224M1Y ircuit Length A Length L apacitance (±20%) 100nF 220nF Weight (g) 200 SLVRA130105M1Y µF Vac (Y2) 250Vac (Y2) 130Vac (Y4) Minimum Full Load Insertion Loss (db) 10kHz 30kHz 100kHz 300kHz 1MHz 10MHz 100MHz 1GHz SLVR M11 2µF 600Vdc SLVR M11 5µF 400Vdc SLVR M µF 250Vdc SLVR M11 33µF 100Vdc SLVR M11 65µF Vdc Vac SLVRPA250204M1Y 200nF (Y2) Pi Vac SLVRPA130944M1Y 940nF (Y4) 250Vac & 130Vac parts are dual 600Vdc. Other values may be available subject to minimum order quantities. Please refer to factory. urrent derating between 60º and 85º. For temp T. I = I ( 85 T)/ 25 T R Metallised Film Ordering Information - SLVR* range SLV R P A M 1 Y Suffix Plastic Film Panel Mount urrent Rating R = 200A configuration = P = Pi 063 = 63Vdc dc 250 = 250Vdc 400 = 400Vdc 600 = 600Vdc A13 = 130Vac A25 = 250Vac apacitance in picofarads (pf) First digit is 0. Second and third digits are significant figures of Example: 0203 = 20nF 0403 = 40nF 0204 = 200nF Tolerance 1 = Plastic Film Nuts & Washers Y = designed and tested to meet the requirements of EN & EN Hardware supplied - 1 = Nut & Wavy Washer /**** As required Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SLVR* Metallised Film 85

86 SLEK 20A Feedthrough capacitors RoHS compliant SLEK 27 Across flats Ø15 (0.59) max. A M3 terminals M16 x mounting L thread Ø32 (1.26) Resin fill both ends onfiguration urrent Rating Rating Insulation Resistance (IR) D Resistance 50º (see derating below) See Table. >100MW <1mW -55o to +85º M20 Mounting Thread 8 M8 22 Terminal (0.867) (0.315) Thread 36 (1.417) max. 50 (1.969) max. Ø20 (0.787) Resin fill (UL94 max. V-0) Head Diameter 20mm (0.787") Nut A/F 19mm (0.748") 7Nm (61.96lbf in) max. Through onductor M3 M16 M20 - x 1 Thread 20mm 32mm Round head Head : M3 M8 spindle Spindle onductor Tightening Torque Encapsulation Weight 0.5Nm (4.42lbf in) max. Use 2 spanners Resin UL94V0 Nickel plated brass 25g Typ. Product ode ircuit apacitance (±20%) Max. Leakage urrent 250V 50Hz Typical Insertion Loss (db) in 50 Ω system 10kHz 30kHz 100kHz 150kHz 300kHz 1MHz 10MHz 100MHz 1GHz SLEK M11 5nF SLEK M11 10nF SLEK M11 20nF SLEK M11 50nF V SLEK M11 80nF SLEK M11 100nF SLEK M11 200nF SLEK M11 300nF Metallised Film SLEK M11 800nF - 400V SLEK M11 1µF - 250V SLEK M11 2µF - 160V SLEK M11 4µF - 100V SLEK M11 5µF - 80V SLEK M11 7µF - 63V SLEK M11 12µF - 30Vdc Other values may be available subject to minimum order quantities. Please refer to factory. 600Vdc parts are dual rated at 250Vac. Order as a 600V part urrent derating between 50º and 85º. For temp T. I = I ( 85 T)/35 Ordering information - SLEK range T R SLE K M 1 1 Suffix ase current (A) configuration (dc) apacitance in picofarads (pf) apacitance tolerance Hardware /**** SLE K = 20A = filter 030 = 30V 063 = 63V 080 = 80V 160 = 160V 250 = 250V 400 = 400V 600 = 600V First digit is 0. Second and third digits are significant figures of Examples: 0203 = 20nF 0403 = 40nF 0204 = 200nF (Standard) 1 = Plastic Film 1 = Nut & crinkle washer As required Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. 86 SLEK Metallised Film

87 SLMN 100A Feedthrough capacitors RoHS compliant 27 Across flats Ø26 (1.024) max. M6 terminals M25 x 1.5 A mounting thread L (1.378) M20 Mounting (0.394) Thread (0.784) M8 Terminal Thread 85 (3.346) Resin fill Ø32 (1.26) both ends 23 A/F (0.906) Resin 27 filla/f (UL94 V-0) (1.063) onfiguration urrent Rating 50º (see derating below) Rating See Table. Insulation Resistance (IR) >100MΩ D Resistance <0.5mΩ -55o to +85o Head Diameter 27mm (1.063") Nut A/F 30mm (1.181") SLMN 14Nm (123.9lbf in) max. Through onductor M6 M20 M25 x Thread 32mm 27A/F Round Hex head Head : M6 : M8 spindle Spindle onductor Tightening Torque Encapsulation Weight 2.5Nm (22.13lbf in) max. Use 2 spanners. Resin UL94V0 Nickel plated brass 120g Typ. apacitance Value (±20%) ircuit apacitance (±20%) Max. Leakage urrent 250V 50Hz Typical Insertion Loss0 (db) in 50 Ω system 10kHz 30kHz 100kHz 300kHz 1MHz 10MHz 100MHz 1GHz SLMN M11 100nF SLMN M11 200nF SLMN M11 250nF V SLMN M11 500nF SLMN M11 1µF SLMN M11 2µF - 400V SLMN M11 4µF - 250V SLMN M11 6µF - 160V SLMN M11 14µF - 100V SLMN M11 18µF - 80V SLMN M11 25µF - 63V SLMN M11 40µF - 30V Other values may be available subject to minimum order quantities. Please refer to factory. 600Vdc parts are dual rated at 250Vac. Order as a 600V part urrent derating between 50º and 85º. For temp T. I = I ( 85 T)/ 35 T R Metallised Film Ordering information - SLMN range SLM N M 1 1 Suffix ase current (A) configuration (dc) apacitance in picofarads (pf) apacitance tolerance Hardware /**** SLM N = 100A = filter 030 = 30V 063 = 63V 080 = 80V 160 = 160V 250 = 250V 400 = 400V 600 = 600V First digit is 0. Second and third digits are significant figures of Examples: 0203 = 20nF 0403 = 40nF 0204 = 200nF (Standard) 1 = Plastic Film 1 = Nut & crinkle washer As required Options include for example: change of pin length / custom body dimensions or threads / alternative voltage rating / non-standard intermediate capacitance values / test requirements. Please refer specific requests to the factory. SLMN Metallised Film 87

88 Discoidal & Planar Arrays 0G/NP0 - - MOV Discoidal & Planar Arrays The multilayer planar array is an application specific multi capacitor array designed for use in multiway EMI filter circuits. Derived from discoidal capacitor theory, it provides capacitance between the outside perimeter and the internal through holes. The most common use of planar arrays is as the capacitor element in filter connectors, although they are also suitable in many other applications. s core wet manufacturing process and ceramic handling expertise allows components to be produced with mechanical precision and electrical accuracy, enabling a filter assembly to withstand the most rigorous of electrical specifications. This has resulted in s position as the manufacturer of choice for the filter connector industry. To date, have delivered in excess of 3,000 different designs of planar array. The quality and reliability of s planar arrays has been uniquely recognised by the approval of NASA for their use in the International Space Station. Mechanical With many years experience, have developed a comprehensive range of designs, including planform designs for the following connectors: ircular (MIL , MIL and similar) Arinc 404 and 600 D sub High Density D sub µd (MIL ) Special custom shapes and layouts can also be accommodated. omplex shapes including internal and external radii, multiple hole diameters and alignment guides can be considered. As a guide, can manufacture planars to a maximum of 3.18mm (0.125 ) thick and to a maximum of 100mm (4.0 ) diameter or square. Standard termination finish is gold plate over nickel for maximum electrical and mechanical performance. Options include conventional silver-palladium (AgPd) or silver-platinum (AgPt) fired terminations. Solderless assembly/compliant spring clip Solderless assembly of planars can be accommodated by the inclusion of compliant spring clips into the holes, allowing the array to be push fitted to through contact pins MIL STD MIL STD MIL STD 1560A 8-35 MIL STD 1560A Discoidal and Planar Arrays can supply a standard range of solder-in spring clips, or fit customer supplied compliant clips before shipping the finished array assembly. ontract assembly and technical back-up Having an EMI filter assembly line alongside the ceramic manufacturing area allows to offer unprecedented technical back-up and advice to planar array and discoidal customers. This can include design and handling advice and forensic analysis assistance. personnel have many years experience in the use of planar arrays, having been involved directly in the development of the technology from its inception. are also able to offer subcontract and prototype manufacturing services to planar customers and connector companies. 50 WAY D SUB MIL STD WAY D SUB MIL STD WAY ARIN 600 DOD STD WAY ARIN 404 MS WAY D SUB MIL STD WAY HIGH DENSITY D SUB MIL STD WAY µd MIL STD WAY SPEIAL 20T DOD STD 1842 SPEIAL 88 Discoidal & Planar Arrays

89 Discoidal capacitors 0G/NP0 - - MOV Discoidal capacitors are at the heart of many EMI filters. More robust and reliable than tubular capacitors, they offer higher capacitance options, with values up to several microfarads. In addition to standard configurations, is able to meet customers specific drawings in terms of electrical performance and mechanical design. Discoidal multilayer ceramic capacitors are of a configuration suitable for direct mounting into filters, onto bulkheads and hybrid circuits. Due to their geometry, they have excellent RF performance characteristics as well as very high self resonant frequencies. They are offered with a choice of 0G/NP0 or ceramic, or in MOV (metal oxide varistor) material for voltage protection applications. apacitance (nf) Fired eramic Terminations Metal Electrodes Typical capacitance vs disc size vs voltage Based on typical hole diameter of 0.8mm, and dielectric mm Ø 5mm Ø 3mm Ø voltage dc General Specification s: 0G/NP0,, MOV Mechanical: Outer diameter 2.0mm minimum Inner diameter 0.5mm minimum Minimum wall thickness requirements apply. Refer to factory. apacitance range: pf to µf apacitance tolerance: ±5%, ±10%, ±20%, -0%+100% : 50V to 3kVdc or higher Operating temperature range: -55 to +125 Termination options: Silver-palladium (AgPd), silver-platinum (AgPt), gold over nickel To reflect the unique custom nature of discoidals and planar arrays, we do not list a standard range. Please contact the sales office to discuss your specific requirements. Discoidals & Varistors Varistor Planar Arrays & Varistor Discoidals Discoidal and Planar Arrays Varistor planar arrays and varistor discoidals provide a dual function. The use of metal oxide based ceramic (MOV) provides the voltage protection, with bi-directional clamping, while the inherent capacitance, due to the multilayer construction, ensures effective lowpass EMI filtering up to at least 1GHz. Discoidal capacitors, Varistor Planar Arrays & Varistor Discoidals 89

90 Planar Arrays 0G/NP0 - Planar Arrays Only stable and ultra stable 0G/NP0 dielectrics used apacitance values from pf to µf High voltage capability - ( Withstand ) to 10kV Feedthrough low capacitance unterminated lines Grounded earth lines - maximum ground plane resistance specifications included Mix of capacitance values within planar up to a ratio of 400:1 within individual planar possible Mixed capacitance lines/no cap feedthrough lines/grounded earth lines available within single planar Quality All planars are tested for the following: apacitance Dissipation factor ( Withstand ) Insulation resistance Visual inspection Sample solderability and dimensional check 100% SAM (Scanning Acoustic Microscopy) testing is offered as an option on all planars intended for more critical applications. Graphs of typical maximum capacitance values against voltage for array thicknesses of (1.65mm), (2.54mm) and (3.18mm). µd planforms Max ap (pf) Max ap (pf) G/NP in Vdc in Vdc D-Sub planforms Max ap (pf) Max ap (pf) G/NP in Vdc in Vdc Discoidal and Planar Arrays Low density circular planforms Max ap (pf) Max ap (pf) OG/NP in Vdc in Vdc High density circular planforms Max ap (pf) Max ap (pf) G/NP in Vdc in Vdc 90 Planar Arrays

91 Special s and Assemblies Manufacturing to customer designs or working together with the customer to develop a solution to a problem, offer the ability to modify standard filter designs or develop custom designs to suit your application. Modifications to standard filters Special mechanical outline Typical examples: Lead lengths to suit Special thread options e.g. M5 x 0.5 6g Special lead forms e.g. headed pin/threaded contact Larger pin diameters Special body or pin finishes Special electrical testing Typical examples: Special test voltages e.g. 500Vac 50Hz test Special capacitance values 100% burn-in Higher current ratings possible Multiway filter assemblies From a simple panel fitted with our single line discrete filters to a complex custom designed Pi filter assembly, we offer a full design and manufacture service. Assemblies can be based around discoidal capacitors for maximum flexibility or planar arrays for optimum space utilisation. As an extension to our planar array range, we can offer soldered-in spring retaining clips for easy assembly into difficult applications such as hermetic sealed connectors and our extensive experience with filter connectors allows us to offer subcontract manufacturing to this industry sector. Example 1-4 way 22nF section planar based filter assembly. 2500Vdc, 100% tested. Supplied to sensor manufacturer for installation into commercial aerospace application. Example 2-85 way 1800pF L- section planar based filter assembly, fitted into mounting plate for easy assembly. Designed to fit specific space envelope for military aerospace application. Please contact our sales office to discuss your specific filtering requirement. We would be pleased to provide a technical and commercial proposal. Special s and Assemblies Special discrete filters to match your specific requirements Manufactured to fit the customers specific requirements, electrical characteristics and space envelope. We can offer design solutions to meet your requirement or develop customer designs into production reality. Example 1 - Battery terminal filter to meet precise environmental requirements and provide flat pin contact surface for connection to spring contacts on clip-on batteries. Designed to fit customers space envelope and meet specific electrical parameters. Example 2 - Special SFSS disc-on-pin decoupling stub filter for military application. ontact pin terminating inside discoidal and insulated from non pin side. Assembled with high melting point solder to allow customer to solder into panel. Special filters and Assemblies Special s and Assemblies 91

92 Metallised Film Specials Metallised Film Specials If standard designs have been used for prototypes or initial production, please talk to us about modifying the package to suit your requirements to improve cost and ease assembly. Prototypes can be arranged quickly and in small quantities to solve particular problems. Typical customisations include: Multi-Way Assemblies All the standard ranges of plastic film filters can also be supplied as multi-way assemblies to offer cost and space savings where several lines require filtering. Utilising the same internal piece parts as the standard filters, multiways offer the same high electrical performance as the single line filters but replacing the machined brass cases with a single formed magnetic stainless steel case reduces the cost per way even for low volumes. Additional cost savings are also made from reduced installation times and the use of standard mounting hardware. Overall size is reduced, allowing for a more compact design. If several filters of different types, values or circuits are required, it may be possible to incorporate these into a single multi-way housing. All assemblies are fully resin sealed (UL94-V0) and are designed to withstand harsh environments making them suitable for severe industrial and military applications. Standard assemblies include 2, 3, 4 and 8 ways but any number can be incorporated. Please contact sales for further details. Typical 2-way assembly Special filters and Assemblies Different housing design Special designs are available to suit any particular customer requirement. All standard filters are designed with round bodies and a single, large mounting nut as the optimum combination of cost and ease of mounting. Typical changes include full hexagonal bodies to enable fitting in tight spaces, or bodies with multiple mounting locations for critical vibration. entre mounting glands can be considered, although these are generally not preferred as they increase the required space for a particular filter. Note: P and U clamps are often requested - we can supply these, but advise against it as they can compromise the filtering performance by increasing the earth path resistance and inductance. For optimum performance all power filters should be mounted in a through bulkhead. Subject to volumes, lower cost body materials can be used. Multi-way assemblies can be supplied with custom shaped cases to fit specific locations or available area. can produce to design or from available envelope. Higher working voltages (to 1000Vdc typical) and higher current carrying capacities (to 500A typical) are available. 92 Metallised Film Specials

93 s for Hi-Rel Applications Introduction is experienced at providing products for the most demanding applications: Space - ESA and NASA projects Automotive - AE-Q200 qualified Military and ivil aviation Motorsports - F1 and World Rally Oil/Downhole/Industrial Rail Medical product qualifications include AE-Q200, ESA vendor approval and space grade planar arrays and filters. Special finishes (eg. Sn/Pb) are available for exempt applications such as military and space. Please contact our Sales Office for further details. Surface Mount s The surface mount filter (E01, E07), Pi filter (SBSPP) and X2Y Integrated Passive omponents (E03) are all available with Flexiap (standard solderable proprietary flexible epoxy polymer termination material). advantages Solves cracking problems caused by excessive mechanical stress The polymer allows greater degrees of Pcb deflection during de-panelisation, typically twice that of standard capacitors Permits more stress to be placed on components when using large through hole parts, eg. transformers, connectors, heatsinks More resistant to cracking due to temperature cycling No degradation in electrical performance apacitors with tin-lead termination are also available with Flexiap technology s for Hi-Rel Applications The following are qualified to AE-Q200: Surface Mount (E01 range) Integrated Passive omponent (E03 range) eramic based s Designed and manufactured to meet or exceed the requirements of MIL and MIL The test methods are in accordance with MIL STD 220 and MIL STD 202: Insertion loss Solderability Bump and vibration Temperature cycling Humidity Temperature rise under dc load Special test requirements can be accommodated e.g. 100% burn-in. Discoidals and Planar Arrays were instrumental in delivering the standard for space approved planar arrays which includes Scanning Acoustic Microscopy (SAM) testing. Metallised Film filters Plastic film filters are available/designed to meet the requirements of EN and EN60950, Y2 or Y4 ratings. Please refer to specific catalogue pages for more details. s for Hi-Rel Applications s for Hi-Rel Applications 93

94 Additional Resources Additional Resources Application Notes AN Flexiap termination Details of the Flexiap termination, which helps prevent mechanical cracking of multilayer chip capacitors. AN Solder alloy choice and stress release cracking in through hole ceramic capacitors Solder alloy considerations when using through hole ceramic capacitors to minimise stress cracking. AN X2Y Balanced Line EMI chip reliability and performance data X2Y omponent reliability and performance data. AN Suppression for D motors using X2Y The application of X2Y chips for EMI Suppression in D motors. AN Soldering/mounting chip capacitors, Radial Leaded capacitors and EMI filters This gives guidance to engineers and board designers on mounting and soldering products. AN Metal Oxide Varistor planar array Using MOV planar array technology for transient protection in filtered connectors. Technical Articles Surface Mount filter article An introduction to Surface Mount EMI filtering and some of the filter components available. Varistor planar article Affordable transient protection, using multilayer planar varistor arrays in filtered connectors. Advances in Surface Mount filtering technology New integrated passive components for EMI suppression filtering. Multilayer Varistor filters Truly multi-functional passive components. Flexiap article An introduction to Flexiap and how it reduces mechanical cracking on PB s. Surface Mount X2Y Technology The application of X2Y chips for EMI Suppression in stringent EM demands, particularly in automotive applications. Available Sample Kits A variety of sample kits are available from to help designers and EM engineers to select the most suitable component for any particular application. 115Vac 400Hz capacitors AE-Q200 capacitors Flexiap capacitors High Flexiap capacitors IEQ-E capacitors Integrated Passive omponents (X2Y) Non magnetic capacitors Protectiap capacitors Safety ertified capacitors Stackiap capacitors Surface Mount EMI s Ultra-low ESR capacitors Additional Resources Please see the website for further details, or contact the Sales Office directly. 94 Additional Resources

95 Product Safety Information Please read in conjunction with the product data. Failure to observe the ratings and the information on this sheet may result in a safety hazard. 1. Material ontent The electronic components described in this catalogue are not considered to be substances or preparations within the meaning of the hemicals Hazard Information and Packaging for Supply Regulations, and therefore there is no regulatory requirement to supply safety data sheets or hazard warning labels. However the following descriptions of the materials used may be useful when considering safety precautions and waste disposal methods. All chip capacitors, EMI chips and 1206 Pi filters fully comply with the WEEE (Waste and Electronic Equipment) and RoHS (Restriction of Hazardous Substances) Directives. Please see our application note on the.com website for further information. a. eramics: these are blends of oxides of Barium or Magnesium and Titanium, with smaller additions of oxides of Aluminium, Boron, Bismuth, alcium, obalt, Manganese, Niobium, Neodymium, Lead, Silicon, Tin, Zinc and Zirconium which are fired at high temperatures to give an insoluble reacted mass. b. Internal electrodes: these are combinations of precious metals, mainly Palladium and Silver, which are relatively inert. c. Terminations: these are combinations of precious metals, again mainly Palladium and Silver, which are fused to the ceramic body by a small amount of glass. The Flexiap termination contains Silver and Polymer and is totally lead free. The terminations may also be covered with electroplated layers of Nickel and Tin or Tin/Lead. d. Leaded product: Tinned copper or steel wires are attached to the capacitor terminations using Tin/Lead or Tin/Silver solder alloys. The parts are encapsulated with a cured epoxy resin which contains Antimony Trioxide as a fire retardant. e. product: The ceramic elements are soldered to copper based current carrying axial leads using solders of different alloys dependent on particular filter type. These solders are formed from the elements Tin, Silver, Indium, Lead and opper in varying proportions dependent on alloy used. If a filter body is present it will be manufactured from steel or copper alloy and soldered to the ceramic element using the same solder alloys as described above. All metal parts are electroplated with Nickel, Silver or Gold over a opper or Nickel undercoat. Ferrite beads consisting of Manganese Zinc Ferric Oxide and Nickel Zinc Ferric Oxide are used to increase inductance in L- and PI type filters. Encapsulants, are high purity epoxy resins with a synthetic fused silica filler. onductive epoxies containing silver particles may be used to form electrical connections. f. Stacked chip capacitors: These are joined using high temperature Tin/Lead/Silver solders or conductive epoxies containing silver particles. Lead frames, where used are copper alloy, electroplated with Silver over a opper or Nickel undercoat. 2. Failure Mode The normal failure mode of the component is to become short circuit. If there is then sufficient electrical power available the component will become extremely hot. Although the ceramic and metallic components of the capacitors are non-combustible, there is a danger of ignition of neighbouring combustible materials and the encapsulation (if present). The component materials of the capacitor may also be vaporised and give off toxic fumes. In the case of ML the component voltage ratings must not be exceeded and it is advisable to include current limiting in the circuit design. ircuits should be designed to fail safe under normal modes of failure. 4. Disposal It may be worthwhile refining scrap components to recover their precious metal content if there is a sufficient quantity available. In general the disposal of electronic equipment is covered by the EU directive on Waste and Electronic Equipment which lays down measures which aim to prevent waste electronic equipment and promote re-use, re-cycling and recovery. 5. Environmental onsiderations has eliminated the use of substances that are implicated in stratospheric ozone depletion as defined in the Montreal Protocol. In addition the use of VOs, which can lead to ozone formation in the troposphere, is reviewed with the object of minimising any emissions and eliminating the most harmful. Other elements of the company s activities are assessed to determine which areas should be given priority in order to minimise any environmental impacts. is approved to ISO apacitor Related Documents BS EN Generic Specification : fixed capacitors. E Sectional Specification : fixed multilayer ceramic chip capacitors. BS E Sectional Specification : fixed ceramic capacitors, type 1. BS E Sectional Specification : fixed ceramic capacitors, type 2. BS EN Packaging of components for automatic handling. BS EN Packaging of components for automatic handling. EIA-469- Destructive physical analysis of ceramic capacitors. 7. Related Documents MIL-F-15733G General specification for RFI filters and capacitors. MIL-F-28861B General specification for electromagnetic interference suppression filters and capacitors. MIL-STD-220A Method of insertion loss measurement. MIL-STD-202F Test methods for electronic and electrical component parts. BS 6299:1982 ISPR 17:1981 Measurement of the suppression characteristics of passive radio interference filters and suppression components. BS 2011:- Environmental testing. BS EN 60068:- Environmental testing. BS 2816:1989 Electroplated coatings of silver. BS 3382 Electroplated coatings of threaded components. Product Safety Information 3. Handling and Storage The components represent no health hazard when handled normally. However, during testing or circuit operation capacitors can become charged to high voltages, and may retain this charge even after the equipment is switched off. omponents must be discharged before being handled. are should be taken when handling components not to damage either the capacitor or any encapsulation so that the risk of failure is minimised. Ideally long term storage conditions should be temperature controlled between -5 and +40 and humidity controlled between 40 and 60% RH. The solderability of the component may be degraded by storage in contaminated environments. Additional Resources Product Safety Information 95

96 BS s Limited Dover House, Stirling Park, Bleriot Way, lifton Moor, York, YO30 4WU UK Phone: Fax: sales@bscfilters.com Laboratories, Inc 2777 Route 20 East, azenovia, NY USA Phone: Fax: sales@dilabs.com Dow-Key Microwave 4822 McGrath Street, Ventura, A USA Phone: Fax: askdk@dowkey.com opyright Technology Limited design - K&L Microwave 2250 Northwood Drive, Salisbury, MD USA Phone: Fax: sales@klmicrowave.com Novacap Anza Drive, Valencia, A USA Phone: Fax: info@novacap.com Pole/Zero orporation 5558 Union entre Drive, West hester, OH USA Phone: Fax: support@polezero.com Technology Limited Old Stoke Road, Arminghall, Norwich, NR14 8SQ UK Phone: Fax: sales@syfer.co.uk Voltronics orporation 2250 Northwood Drive, Salisbury, MD USA Phone: Fax: info@voltronicscorp.com 8818/14 eramic & Microwave Products (MP) designs, manufactures and sells special electronic components and systems, including highperformance filters, switches, capacitors and EMI and cosite signal interference solutions. Our products are used in military, space, telecom infrastructure, medical and industrial applications where function and reliability are crucial.