Reactors Filters. Catalogue LV

Transcription

1 Reactors Filters Catalogue LV

2 Related catalogues Contents Low-Voltage Controlgear for Industry Order No.: E86060-K1002-A101-A Power Distribution Products and Systems for Power Distribution Order No.: E86060-K1801-A101-A LV 10 LV 30 Contactors and contactor assemblies Semiconductor controlgear, soft starters, controllers Circuit-breakers Overload relays Load feeders Switch disconnectors and fuses SIMIREL Time, monitoring, coupling relays and converters Control and signalling devices BETA electrical installation technology: Selected products SIGUARD safety systems SIDAC-T transformers SIDAC-S power supplies ALPHA FIX terminal blocks BETA protect installation equipment Communicationcapable circuit-breakers Compact circuit-breakers (MCCB) Open-type circuit-breakers (ACB) SENTRIC switch disconnectors and fuse switch disconnector Switchgear, distribution systems and cabinets SIDAC Reactors and Filters Order No.: E86060-K2803-A101-A Industrial Communication Industrial Communication for Automation and Drives Order No.: E86060-K6710-A101-B LV 60 Commutating reactors for converters Mains reactors for frequency converters Iron-core output reactors Ferrite output reactors Iron-core smoothing reactor Smoothing air-core reactors Filter reactors Application-specific reactors Radio interference suppression filters dv/dt filters Sinewave filters IK PI Industrial Ethernet to IEEE PROFINET Industrial Mobile Communication PROFIBUS to IEC 61158/EN SIMATIC ET 200 distributed I/O AS-Interface Remote operation with SINAUT ST7 Routers ECOFAST system Sensor Technology Factory Automation Sensors Order No.: E86060-K8310-A101-A FS 10 BERO proximity switches SIGUARD optical safety sensors MOBY identification systems SIMATIC Machine Vision Automation & Drives The Offline Mall for A&D Order No.: E86060-D4001-A110-C A&D Mall Internet: automation/mall CA 01 All products from Automation and Drives, including the products from the catalogues listed above. All products from Automation and Drives, including the products from the catalogues listed above. Registered trademarks Technical Assistance All product designations may be trademarks or product names of Siemens AG or supplier companies whose use by third parties for their own purposes could violate the rights of the owners. Further information about low-voltage controlgear is available on the Internet at: Tel.: +49 (9 11) Fax: +49 (9 11)

3 SIDAC Reactors and Filters Catalogue LV Introduction 1 Commutation Reactors for Converters Mains Reactors for Frequency Converters 2 3 Supersedes: Catalogue LV /2005 The products in this catalogue are also included in the CD-ROM catalogue CA 01 Order No.: E86060-D4001-A110-C Please contact your local Siemens office Siemens AG 2005 The products and systems contained in this catalogue are all manufactured according to a TÜV-certified quality management system (TÜV = German Technical Inspectorate) to DIN EN ISO 9001 (certificate registration no ). The TÜV certificate is recognised in all IQ Net countries. s SIDAC Filters SIDAC Reactors SIDAC Reactors and Filters Iron-core Output Reactors Ferrite Output Reactors Iron-core Smoothing Reactors Smoothing Air-core Reactors Filter Reactors Application-specific Reactors Radio Interference Suppression Filters dv/dt Filters Sinewave Filters Specification Sheets Accessories Configuration Notes Components for Converters Annex 17

4 Explanations Delivery Times (DT) } Preferred type A 2 working days B 1 week C 3 weeks D 6 weeks X On request Preferred types are device types that are immediately available ex warehouse, i.e. are dispatched within 24 hours. Normal order quantities of products are generally delivered within the specified delivery times on receipt of your order at our office. However, actual delivery times may vary under certain circumstances. The delivery times apply ex ramp at Siemens AG (products that are ready to dispatch). The transit times depend on the destination and type of shipping. Standard delivery time within Germany is 1 day. We are constantly optimising our delivery times; the delivery times specified here are as of 11/2004. You can find up-to-the minute information on our delivery services athttp:// Price unit (PU) Packaging size (PS) The price unit stipulates the number of items, sets or meters are received for the specified price and weight. The packaging size specifies the number of, e.g. items, sets or meters contained in the outer packaging. It is only possible to order the quantity contained in a packaging size or a multiple thereof! For information on multi-unit and recyclable packaging see Annex. Price group (PG) Each product is assigned to a price group. Weight The specified weight in kg refers to the price unit (PU). Dimensions All dimensions are in mm. Standards DIN EN (IEC 61558), DIN VDE 0532 The German standard DIN EN with VDE classification VDE 0570 represents the German version of the international standard IEC (Safety of power transformers, power supply units and similar), and since 1st August 2003 partially supersedes the old standard VDE 0550 and fully supersedes VDE These amendments saw a considerable tightening of the production and test conditions for reactors. Changes brought about by amendments to the standard Reactors for general use are now made with increased creepages and clearances, and higher test voltages. Furthermore, all reactors must include references to the protective elements that protect them against shortcircuits and overloads. Designation of the rated current according to EN 61558: I Ln and specification of the maximum permissible continuous thermal current I thmax These amendments to the standard, and the accompanying changes to the product, have made it necessary to add a suffix to the order no. Please refer to the conversion list "Old Order No. - New Order No." in the Annex for the new number. 2 Siemens LV

5 Introduction 1 1/2 Welcome to Automation and Drives 1/4 Totally Integrated Automation - Innovations for more productivity 1/6 Totally Integrated Power - Energy distribution and management from one source 1/8 Low-voltage, controls and distribution Basis for advanced solutions 1/10 The first choice in drive and converter technology SIDAC reactors and filters 1/12 SIDAC reactors 1/17 SIDAC filters Siemens LV

6 Welcome to Automation and Drives We would like to welcome you to Automation and Drives and our comprehensive range of products, systems, solutions and services for production and process automation and building technology worldwide. With Totally Integrated Automation and Totally Integrated Power, we deliver solution platforms based on standards that offer you a considerable savings potential. Discover the world of our technology now. If you need more detailed information, please contact one of your regional Siemens partners. They will be glad to assist you. 1/2

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8 Ethernet Totally Integrated Automation innovations for more productivity With the launch of Totally Integrated Automation, we were the first ones on the market to consistently implement the trend from equipment to an integrated automation solution, and have continuously improved the system ever since. Whether your industry is process- and production-oriented or a hybrid, Totally Integrated Automation is a unique "common solution" platform that covers all the sectors. Totally Integrated Automation is an integrated platform for the entire production line - from receiving to technical processing ERP Enterprise Resource Planning Ethernet MES Manufacturing Execution Systems Ethernet Production Order Management Production Operations Recording Material Management Equipment Management Control SIMATIC NET Industrial Communication SINAUT Telecontrol System SIMATIC Software SIMATIC Machine Vision Industrial Industrial Ethernet Safety Integrated Industrial Wireless Communication/ MOBIC PROCESS FIELD PROFIBUS PC-based Automation AS-Interface GAMMA instabus Building Technology Micro-Automation and Actuator-Sensor Interface Level ECOFAST IP65 Decentral Automation System 1/4

9 and production areas to shipping. Thanks to the system-oriented engineering environment, integrated, open communications as well as intelligent diagnostics options, your plant now benefits in every phase of the life cycle. In fact, to this day we are the only company worldwide that can offer a control system based on an integrated platform for both the production and process industry. SIMATIC IT Framework Production Modeler Plant Information Management Detailed Production Scheduling Product Specification Management System Laboratory Information Management System SIMATIC Controller/ Automation System SINUMERIK Numeric Control SIMOTION Motion Control System SIMATIC HMI Human Machine Interface SENTRON Circuit Breakers SIMATIC Distributed I/O SIMATIC PCS 7 Process Control System Field Instrumentation/ Analytics SIMOCODE-DP Motor Protection and Control Sensor Technology IQ-Sense HART SIWAREX Weighing Technology PROFIBUS PA SIMODRIVE SINAMICS Drive Systems/ SINAMICS 1/5

10 Totally Integrated Power energy distribution and management from one source Totally Integrated Power by Siemens offers integrated solutions for energy distribution in functional and industrial buildings covering everything from medium-high voltage to power outlets. Totally Integrated Power is based on integration in planning and configuration as well as coordinated products and systems. In addition, it features communications and software modules for connecting power distribution systems to industrial automation and building automation, thereby offering a substantial savings potential. Communications HMI Load Graphs Prognoses management Process/production automation U I cos o P W PROCESS FIELD BUS Products and systems 110 kv Planning and configuration 1/6

11 DATE: EMPLOYEE COST CENTER PAY PERIOD BEGINNING PAY PERIOD ENDING DATE SUN MON TUE WED THUR FRI SAT SUN TOTAL IN OUT IN OUT OVERTIME TOTAL HOURS DATE SUN MON TUE WED THUR FRI SAT SUN TOTAL IN OUT IN OUT OVERTIME TOTAL HOURS DATE SUN MON TUE WED THUR FRI SAT SUN TOTAL IN OUT IN OUT OVERTIME TOTAL HOURS CODES V=VACATION H=HOLIDAY S=SICK REGULAR HOLIDAY OTHER OVER THE HOURS SICK VACATION TIME & ONE-HALF Message/ error management Maintenance Substation Distribution Maintenance task Selective protection Protocols Power quality Cost center Building automation Hall 1 Air conditioning system checkup Distribution 3 Replacing circuit breaker contacts Infeed II Replacing meters central ON OFF local ON OFF tripped instabus EIB 1/7

12 Low-voltage, controls and distribution Basis for advanced solutions These days, it's hard to imagine daily life without electricity. Expertise and innovative thinking in the field of electrical switching and installation technology is an essential requirement for ensuring that our use of electricity in the industrial and building management systems sector is safe and user-friendly. We at Siemens have been meeting these requirements for more than 110 years and we are constantly developing new products innovations that make the use of electricity increasingly safer and more cost effective. 1/8

13 The low-voltage, control and distribution systems from Siemens offer a comprehensive and innovative range of products covering switching devices for load feeders or power distribution, through control and signalling devices, to complete cabinet systems. Furthermore, we can also offer totally optimised systems by bundling our product range with multi-functional, uniform concepts, such as Totally Integrated Power, Safety Integrated and ECOFAST. All in all, we can provide you with innovative components for switching and electrical installation technology which utilise state-of-the-art features such as integration and communication as the basis for advanced and uniform solutions which provide you with many benefits. 1/9

14 The first choice in drive and converter technology SIDAC reactors and filters These days, modern machines and industrial processes are inconceivable without variable-speed drives. However, machines and industrial plants with a high degree of automation are particularly susceptible to radio interference voltages and deviations in the system voltage due to sinusoidal curves, generated (for example) by high-speed semiconductors in converters. Compliance with current standards and regulations ensure: SIDAC reactors and filters When it comes to smoothing currents, for example in drive systems, or when interference signals need to be suppressed, the rugged and reliable components of the SIDAC reactor and SIDAC filter series are always first choice. Used worldwide, they provide solutions for tasks in both drive and traffic engineering, as well as control cabinet and plant engineering. High quality products and the certificates required for international application guarantee maximum customer satisfaction in all industrial sectors. SIDAC components that are cost-effective and technically optimised ensure the consistent configuration of drive systems and control cabinets in the field of Low-Voltage, Controls and Distribution. Comprehensive standard stock range Short delivery times Small, compact and light design of all devices User-friendly and space-saving supporting solutions For assistance in assigning reactors and filters to Siemens drives, please refer to the relevant drive system catalogues CE marking The majority are UL-approved, reactors U cu, filters U 1/10

15 SIDAC reactors Commutation reactors for converters Mains reactors for frequency converters Smoothing reactors for DC drives Filter reactors for p.f. correction equipment Output reactors for frequency converters Models available: Single or three-phase reactors Air-core reactors, iron-core reactors, ferrite reactors and sintered metal reactors Rated voltages 690 V AC 4EP/4EM 1000 V AC 4EU 3.6 kv max. for customised applications Performance range: kva 3 A to 1640 A Reactors in Iso class H not fully utilised, i.e. can handle a continuous overload of 6% High linearity of inductance SIDAC filters Radio interference suppression filters Combination filters dv/dt filters Sinewave filters Versions for use on the line and motor-side of frequency converters Input voltage ranges Single-phase V Three-phase V Can be used for drive power of 2.2 kw to 800 kw Currents 4 A to 860 A 1/11

16 SIDAC reactors SIDAC reactors key components in drive systems Along with transformers, reactors are classic components of electrical engineering and are indispensable in modern heavy current engineering and power electronics. For the suppression of mains-borne interferences in AC or three-phase systems and the smoothing of currents in DC circuits: SIDAC AC and DC reactors from Siemens are the specialists. As motor and commutation reactors in drive systems for locomotives and railcars and water-cooled valve reactors for HVDC systems in power distribution. A reactor is a device that comprises one or more windings with a frequency-dependent resistance that operates in accordance with the principle of self-induction. A magnetising current generates a magnetic field that either passes through a magnetically reactive core or through air. Reactors are used to reduce current peaks or current harmonics. They are mainly used in AC and DC drive systems, in the fields of power supply and transmission and in plant and equipment technology. A distinction is made between reactors according to their application and design. Commutation reactors 4EM, 4EP and 4EU commutation reactors (line reactors, mains reactors) for converters are installed in rectifier and converter assemblies (connection B2 and B6) in the line-side supply cable. Alternating current flows through them. Commutation reactors are used to limit lineside voltage drops during commutation (commutation is the current transition from one phase to another) of the converter (DIN VDE 0160 and EN 50178). The reactor also limits the rate of voltage rise dv/dt at the thyristors used by limiting the rate of current rise di/dt. Features 4EU series up to approx. 50 kva, Iso class H not fully utilised, i.e. can handle a continuous overload of 6% Small and light design CUUS approval Up to 50 A using SIGUT connection method Comprehensive standard stock range Three-phase mains reactors 4EP and 4EU three-phase mains reactors for frequency converters are used in the lineside supply cable. Alternating currents flow through them with the mains frequency as the fundamental component. The reactors limit the circuit feedback that occurs in the form of harmonics. They also reduce the alternating currents and the frequencies caused by the switching of the input rectifier in the DC link capacitors. Compared to commutation reactors, mains reactors are designed to handle significantly higher harmonic loads. Mains reactors are also characterised by a much higher linearity in the inductance curve (L=f(I)). Features 4EU series up to approx. 50 kva, Iso class H not fully utilised, i.e. can handle a continuous overload of 6% Small and light design CUUS approval Up to 50 A using SIGUT connection method Comprehensive standard stock range High linearity in the inductance curve 1/12

17 Output reactors (iron-core) Output reactors are used on the load side of frequency converters and motor currents flow through them. They compensate capacitive charge-reversal currents with long cables and, in the case of long motor cables, limit the dv/dt at the motor terminals. This enables the use of longer motor supply cables: m shielded motor cable m unshielded motor cable. Use of iron-core output reactors: Drives with standard and trans-standard asynchronous motors and a rated motor frequency (field weakening frequency) of up to 87 Hz and a maximum frequency of 200 Hz Drives with reluctance motors or permanently excited synchronous motors with a maximum frequency of 120 Hz. Features Reduction in voltage gradient dv/dt at the motor supply terminals Longer motor supply cables can be used Reduction in current peaks from the capacitive charge-reversal currents and therefore optimum utilisation of the converter capacity Higher operational reliability Compact design Output reactors (ferrite) Due to their special material characteristics, the standard catalogue ferrite reactor types can be operated at higher converter output frequencies of up to 600 Hz. Can be used with clock frequencies of up to 16 khz. Features Expanded field of application: f max =600 Hz and clock frequencies of up to max. 16 khz Reduction in voltage gradient dv/dt at the motor supply terminals Longer motor supply cables can be used Reduction in current peaks from the capacitive charge-reversal currents and therefore optimum utilisation of the converter capacity Higher operational reliability Compact design Filter reactors 4EP and 4EU filter reactors for p.f. compensation are connected to the series resonant circuit using capacitors. These series resonant circuits are used to compensate inductive reactive power. The series resonant circuit is set to a specific resonant frequency to achieve targeted compensation of currents with a harmonic content by connecting the filter reactor with capacitors to form a series resonant circuit. Features High linearity in the inductance curve Inductive rating for I eff, can handle permanent thermal overload of 1.05 x I eff Standard design with temperature switch CUUS approval Up to 4EP44: angle bracket according to EN 60852, allows the use of screwdrivers Long service life due to high-quality materials 1/13

18 Smoothing reactors for DC drives Smoothing reactors are used on the DC side of converter sets. Direct current flows through them. Smoothing reactors are used to limit the alternating current superimposed on the direct current to a pre-defined value. Smoothing reactors are used as: series reactors in converter-fed DC motors, for smoothing the DC link current in indirect current and voltage converters, for the DC side decoupling of converter sections for converter connections with higher pulsating circuit feedback, for reducing the ripple limit, for limiting the circulating currents in circuits carrying circulating currents and for limiting the current increase rate using high-speed DC circuit breakers for the selective disconnection of fault currents. Depending on the inductance curve required, smoothing reactors are constructed as 4EM and 4ET iron-core reactors or 4PK aircore reactors. Features 4ET series Iso class H not fully utilised, i.e. can handle a continuous overload of 6% Small and light design CUUS approval Up to 50 A using SIGUT connection method Supports cage clamp connection method Comprehensive standard range Short delivery times Smoothing air-core reactors 4PK smoothing air-core reactors (natural air cooling, energy content E from 380 Ws kws) are used in the DC circuit of converter units. These are primarily used to limit the current rise in the event of faults, especially in the case of through-conductions. They cause the high-speed DC circuit-breakers in the electric circuit to interrupt the rising fault current early enough to prevent the fuses in the thyristor branches from responding. Features Constant inductance regardless of load High short-circuit strength Low weight thanks to aluminium windings Up to 2 reactors can be piggy-backed 1/14

19 Sintered metal reactors Sintered metal reactors for three-phase supplies comprise three mutually independent single-phase reactors. They are installed in the main supply line of converters and alternating currents at the line frequency, and the harmonics generated by the converter flow through them. Sintered metal reactors can be used as individual components in the input or output circuit of frequency converters. Sintered metal reactors are always used where interference suppression is required from the low to high frequency range, as well as a commutation reactor. The special material characteristics enable excellent interference suppression of frequencies up to 150 khz. The closed design of the pot-type cores reduces radiation-linked interferences to a minimum, thus enabling non-critical installation of reactors in close proximity to electronic devices. Applications are found in the area of controlled rectifier/regenerative units that operate in high-frequency systems. Interference suppression in converter connections for uninterruptible power supplies is also cost-effective. Features Excellent RF characteristics for higher saturation induction High initial inductance Excellent EMC behaviour Low-cost combination of interference suppression reactor and commutation reactor. Railway reactors These include reactors for use in electrical railcars. These reactors are used in trams, subway trains and modern high-speed railcars. The components have been specially designed and manufactured for the harsh environmental conditions that prevail during railway operation. This includes increased requirements in terms of resistance to extreme climates, humidity and pollutants in the atmosphere. All reactors comply with the mechanical requirements demanded of them with regard to the permanent vibrations during railway operation. Application For many decades, Siemens reactors have been used in railway networks around the world. The know how gained in this field is constantly available to our customers for the development of new products. Application examples: On-board power supply network containers with transformer, reactor and selector switch are used in the supply of the onboard power for different infeed conditions. Acceptor circuit reactors are used to smooth the DC link voltage and reduce the harmonics in the DC link. Chopper reactors limit the current gradient of the pulsed chopper current and the short-circuit currents. Rod core reactors as a component of the line filter for overvoltage protection and to limit the line harmonics or DC link harmonic currents 1/15

20 Selection aid Which problem needs solving? SIDAC reactors AC drive systems Reduction of load current peaks, output/input circuit Reduction of voltage gradient dv/dt at the motor terminals Reduction of EMC problems between outer conductors (output/input) Reduction of EMC problems between outer conductors and ground (output/input) Use of unshielded motor cable also possible Reduction of commutation notches and limiting of the rate of current rise in the input circuit Reduction of commutation reactive power Attenuation of radio interference voltages and reduction of high frequency circuit feedback Reduction of mains-borne electromagnetic emission and its influence Output reactors Commutation/ Output reactors with mains reactors integrated radio interference suppression filters Commutating reactors with integrated radio interference suppression filters DC-link reactors Sintered metal reactors Customised designs For specification sheets for customised reactors and filters, see "Specification sheets". Accessories For terminal covers offering protection against accidental contact with free bar connections (DIN VDE ) see "Accessories". Connection terminals Connection terminals are mounted for rated currents up to 50 A (in the case of 4EM ironcore smoothing reactors: up to 40 A). They offer finger-touch protection according to DIN VDE The cable cross-sections that can be connected are specified in "Configuration notes" under dimensional drawings. Flat terminations are installed for reactors with rated currents > 50 A. For dimensions of the flat terminations, please refer to the dimensional drawings under "Configuration notes". Dimensional drawings/technical specifications Dimensions and dimensional drawings of the reactors can be found under "Configuration notes". Special data for the reactors are entered in the "Selection and ordering data" section. The permissible mounting position for each reactor type is specified in the dimensional drawings. 1/16

21 SIDAC filters Voltage Current System Without reactor/filter Autotransformer With output reactor Converter with rectifier/ regenerative unit Commutation reactor With dv/dt filter Commutation reactor with integrated line filter Line filter System With sinewave filter PD60_00044 Use and benefits of the filter components in the drive system SIDAC filters key components in drive systems dv/dt filters, voltage limiting filters dv/dt filters comprise a limiter circuit and a reactor, or just a reactor. The filter is installed at the output of frequency converters and the motor currents flow through the reactor. By connecting the filter to the three-phase system at the output of the frequency converter, transient voltage peaks are reduced and the voltage gradients in the motor winding are reduced to non-critical values of less than 500 V/µs. If long motor cables are used, the dv/dt filter also reduces capacitive load current peaks resulting from the capacitance per unit length of motor cable. Sinewave filters The sinewave filter is installed at the output of frequency converters and motor currents flow through the reactor. The frequency converter output variables are filtered in such a way that it produces an almost sinusoidal motor voltage and an absolutely sinusoidal motor current. Stray losses in the motor are reduced and the motor runs significantly quieter. If long motor cables are used, the sinewave filter also reduces the load current peaks caused by cable capacities. 1/17

22 EX(d) motors can be converter-fed if sinewave filter is used. Operation with an unshielded motor cable is almost completely unrestricted. Radio interference suppression filters, combination filters (radio interference suppression filter + output/input reactor) as a supporting solution Radio interference suppression filters for frequency converters are fitted in the line-side supply leads in order to attenuate mains-borne radio interference voltages. If special demands are made on the dv/dt values at the motor supply terminals, an output reactor can also be fitted to the housing. Using a radio interference suppression filter ensures compliance with interference suppression level A or B to EN (depending on customer requirements). It is also possible to use significantly longer motor supply cables in compliance with the limit values of EN By using a combination filter comprising radio interference suppression filter and output reactor, it is also possible to increase the length of the even further motor cable while still maintaining the required level of radio interference suppression. Combining the radio interference suppression filter with an input reactor allows the circuit feedback to be reduced still further, thus enhancing the interference immunity of the frequency converter. Selection aid Which problem needs solving? With the comprehensive range of SIDAC filter components, a solution can always be found! SIDAC filters dv/dt filter Sinewave filter Reduction of load current peak output/input circuit Reduction of voltage gradient dv/dt at the motor terminals Sine-wave radiated noise filter Radio interference suppression filter Output reactor with integrated radio interference suppression filter Limiting of overvoltage due to line reflection Generation of sinusoidal motor terminal voltage and currents Reduction of stray losses in the motor Reduction of motor noise Reduction of EMC problems between outer conductors (output/input) Reduction of EMC problems between outer conductors and ground (output/input) Use of unshielded motor cable also possible Reduction of commutation notches and limiting of the rate of current rise in the input circuit Reduction of commutation reactive power Attenuation of radio interference voltages and reduction of high frequency circuit feedback Reduction of mains-borne electromagnetic emission and its influence Commutating reactor with integrated radio interference suppression filter 1/18

23 SIDAC Commutation Reactors for Converters 2 Single-phase reactors 2/2 Application 2/2 Technical specifications 2/3 Selection and ordering data Three-phase reactors 2/5 Application 2/5 Technical specifications 2/6 Selection and ordering data Siemens LV

24 SIDAC Commutation Reactors for Converters 2 Single-phase reactors Application nc Single-phase 4EM commutation reactors for converters are used with two-pulse bridge converters as line reactors in the line-side supply cable. Alternating current flows through them. They are used to limit line-side voltage drops during commutation of the converter. The reactor also limits the rate of voltage rise dv/dt at the thyristors used by limiting the rate of current rise di/dt. There are different reactor series. u D ~ 2% with the following supply voltage: 230 V AC u D ~ 4% with the following supply voltage: 230 V AC, 400 V The data is valid for mains frequency f = 50 Hz Single-phase commutation reactor for converters Technical specifications Recommended supply voltage U N Rated alternating current I Ln Maximum continuous thermal current I thmax See "Selection and ordering data" table Peak current I Lmax Permissible continuous direct current with downstream two-pulse bridge converter (I dn = I thmax ¼ 1.0) Inductance per phase Core losses P Fe at f = 50 Hz Winding losses P W Weight Degree of protection IP00 according to DIN VDE /EN Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation (for site altitudes up to 2000 m above sea level) Permissible ambient temperature during operation Deviation of the permissible alternating current from the rated alternating current I Ln at coolant temperatures ž +40 C Temperature classes Site altitude Deviation of the permissible alternating current from the rated alternating current I Ln at site altitudes >1000 m above sea level 690 V AC at U N ˆ 500 V for 4EM with terminals 600 V AC at U N ˆ 500 V for 4EM according to UL Type 4EM: -25 C to +70 C See "Configuration notes" t a 40 C/B ˆ 1000 m above sea level See "Configuration notes" Standards/approvals The reactors comply with EN The reactors are UL recognised under Guide No. XQNX2 and File No. E103902, as well as cul approved under Guide No. XQNX8 File No. E (applies to reactors with U N ˆ 600 V according to UL) Storage temperature -25 C to +55 C Transport temperature -25 C to +70 C Permissible humidity rating Humidity 5% to 95% occasional condensation permissible 2/2 Siemens LV

25 SIDAC Commutation Reactors for Converters Selection and ordering data Overview I thmax = I Lmax Single-phase reactors nc 2 Maximum continuous thermal current I thmax A Rated current I Ln A Maximum continuous direct current 1) I dn A Reference voltage drop of reactor u D for I thmax and U N Order No. Order No. Order No. u D = 2% 230 V AC u D = 4% 230 V AC u D = 4% 400 V AC EM CB EM CB EM CB00 4EM CB EM CB00 4EM CB00 4EM CB EM CB00 4EM CB00 4EM CB EM CB00 4EM CB00 4EM CB EM CB00 4EM CB00 4EM CB EM CB00 4EM CB EM CB EM CB00 4EM CB00 4EM CB EM CB00 4EM CB00 4EM CB EM CB EM CB00 4EM CB EM CB EM CB00 4EM CB EM CB EM CB00 4EM CB EM CB00 4EM CB00 4EM CB EM CB00 4EM CB EM CB00 4EM CB00 4EM CB EM CB00 4EM CB00 4EM CB EM CB00 4EM CB00 4EM CB EM CB00 4EM CB00 4EM CB00 1) For downstream two-pulse bridge converters: Reactors with higher rated currents on request Siemens LV /3

26 SIDAC Commutation Reactors for Converters 2 Single-phase reactors I thmax = I Lmax nc Maximum continuous thermal current Rated Maximum current 1) continuous direct current 2) Inductance Core losses Winding losses Connections 3) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln I dn L x P FE P W A A A mh W W kg kg kg 1 AC 230 V 50 Hz, u D ~ 4.4 V 2% reference voltage drop for I thmax and U N T C 4EM CB T B 4EM CB T C 4EM CB T } 4EM CB T } 4EM CB T C 4EM CB T B 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T B 4EM CB T B 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T B 4EM CB AC 230 V 50 Hz, u D ~ 8.8 V 4% reference voltage drop for I thmax and U N T } 4EM CB T } 4EM CB T } 4EM CB T C 4EM CB T } 4EM CB T C 4EM CB T } 4EM CB T } 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T B 4EM CB T } 4EM CB T C 4EM CB T C 4EM CB T B 4EM CB T B 4EM CB T C 4EM CB T C 4EM CB AC 400 V 50 Hz, u D ~ 15.2 V 4% reference voltage drop for I thmax and U N T } 4EM CB T } 4EM CB T C 4EM CB T B 4EM CB T } 4EM CB T } 4EM CB T C 4EM CB T C 4EM CB T } 4EM CB T } 4EM CB T C 4EM CB T } 4EM CB T C 4EM CB T } 4EM CB T C 4EM CB T C 4EM CB Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz) 2) For downstream two-pulse bridge converters: Reactors with higher rated currents on request 3) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 2/4 Siemens LV

27 SIDAC Commutation Reactors for Converters Application Three-phase commutation reactors for converters Three-phase reactors nc Commutation reactors for converters are used for B6 and B6C connections of converter assemblies in the line-side supply cable. They are used to limit line-side voltage drops during commutation of the converter. The reactor also limits the rate of voltage rise dv/dt at the thyristors used by limiting the rate of current rise di/dt. Commutation reactors can also be used for decoupling converter sets operating in parallel. There are different reactor series. I thmax = 0.8 I Lmax ("80% reactors") with u D ~ 4% for the following supply voltages: 3 AC 400 V, 3 AC 500 V, 3 AC 690 V, 3 AC 750 V I thmax =I Lmax ("100% reactors") with u D ~ 2% for the following supply voltages: 3 AC 400 V, 3 AC 690 V, 3 AC 830 V and with u D ~ 4% for the following supply voltages: 3 AC 400 V, 3 AC 500 V, 3 AC 690 V, 3 AC 750 V The data is valid for line frequency f = 50 Hz. 2 Technical specifications Recommended supply voltage U N Rated alternating current I Ln Maximum continuous thermal current I thmax See "Selection and ordering data" table Peak current I Lmax Maximum continuous direct current with downstream six-pulse bridge converter (I dn = I thmax ¼ 1.225) Inductance per phase Core losses P Fe at f = 50 Hz Winding losses P W Weight Degree of protection IP00 according to DIN VDE /EN Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation (for site altitudes up to 2000 m above sea level) Permissible ambient temperature during operation Deviation of the permissible alternating current from rated alternating current I Ln at coolant temperatures ž +40 C Temperature classes Site altitude Deviation of the permissible alternating current from rated alternating current I Ln at site altitudes >1000 m above sea level Operation with varying load Operation at 60 Hz 690 V AC at U N ˆ 500 V for 4EP with terminals 1000 V AC at U N ˆ 830 V for 4EP, 4EU24 to 4EU43 with flat terminations Type 4EP: -25 C to +70 C Type 4EU: -25 C to +80 C See "Configuration notes" Type 4EP: t a 40 C/B Type 4EU: t a 40 C/H (utilisation according to F for applications according to EN 61558) Type 4EU: temperature class H (for applications according to UL) ˆ 1000 m above sea level See "Configuration notes" Rating on request I Ln (60 Hz) = 0.9 I Ln (50 Hz) Standards/approvals The reactors comply with EN (type 4EU45 to 4EU51: DIN VDE 0532) The reactors are UL recognised under Guide No. XQNX2 and File No. E103902, as well as cul approved under Guide No. XQNX8 File No. E (applies to reactors with U N ˆ 600 V according to UL) Storage temperature -25 C to +55 C Transport temperature -25 C to +70 C Permissible humidity rating Humidity 5% to 95% occasional condensation permissible Siemens LV /5

28 SIDAC Commutation Reactors for Converters 2 Three-phase reactors Selection and ordering data nc 1) Overview I thmax = I Lmax Max. continuous Rated current Max. continuous thermal current 3) direct current 2) I thmax A I Ln A I dn A Reference voltage drop of reactor u D = 2% for I thmax and U N Order No. Order No. Order No. 3 AC 400 V 50 Hz 3 AC 690 V 50 Hz 3 AC 830 V 50 Hz EP DS EP DS EP DS EP DS EP DS EP DS EP DS EP DS EP DS EP DS EP DS EP DS EP DS EU BC00-0A 4EU BE00-0A EU AN00 3) EU BD00-0A 1) All reactors with U N ˆ 600 V according to UL 3) Reactors according to VDE 0532: I thmax = rated current 2) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 2/6 Siemens LV

29 SIDAC Commutation Reactors for Converters Three-phase reactors I thmax = I Lmax nc 1) 2 Max. Rated continuous current thermal current 4) I thmax A I Ln A 1) All reactors with U N ˆ 600 V according to UL 2) Reference voltage drop of reactor u D ~ 4% for I Ln and U N = 575 V Max. Reference voltage drop of reactor u D = 4% for I thmax and U N continuous direct current 3) I dn A Order No. Order No. Order No. Order No. 3 AC 400 V 50 Hz 3 AC 500 V 50 Hz 3 AC 690 V 50 Hz 3 AC 750 V 50 Hz EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EU AA00-0AA EP DS00 4EU AA00-0AA EU AA00-0AA0 4EU AA00-0AA EU AA00-0AA0 4EU AA00-0AA EU AA00-0AA0 4EU AA00-0AA EU AA00-0AA0 4EU AA00-0AA EU AA00-0AA0 4EU AA00-0AA EU AA00-0AA0 4EU AA00-0AA EU AA00-0AA0 4EU AA00-0AA0 4EU AA00-0AA0 4EU CA00-0AA EU AA00-0AA0 4EU AA00-0AA0 4EU AA00-0AA0 4EU CA00-0AA EU AA00-0AA0 4EU AA00-0AA0 4EU BA00-0AA0 4EU BA00-0AA EU AA00-0AA0 4EU AA00-0AA0 4EU BA00-0AA0 4EU BA00-0AA EU AA00-0AA0 4EU AA00-0AA0 4EU BA00-0AA0 4EU BA00-0AA EU AA00-0AA0 4EU AA00-0AA0 4EU BA00-0AA0 4EU BA00-0AA EU AA00-0AA0 4EU AA00-0AA0 4EU BA00-0AA0 4EU AA00-0A EU AA00-0AA0 4EU AA00-0AA0 4EU AA00-0A 4EU BA00-0A EU AA00-0AA0 4EU AA00-0AA0 4EU AA00-0A 4EU BA00-0A EU AA00-0AA0 4EU BA00-0AA0 4EU AA00-0A 4EU BA00-0A EU AA00-0AA0 4EU AA00-0A 4EU AA00-0A 4EU BA00-0A EU AA00-1BA0 4EU AA00-0A 4EU BA00-0A 4EU BA00-0A EU AA00-1BA0 4EU AA00-0A 4EU BA00-0A 4EU AA00 4) EU AA00-0A 4EU AA00-0A 4EU AA00 4) 4EU AA00 4) EU AA00-0A 4EU AA00-0A 4EU AA00 4) 4EU AA00 4) EU AX00 4) EU BB00-0A 4EU AM00 4) 2) EU AL00 4) 4EU AA00 4) 2) 4EU AA00 4) 3) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 4) Reactors according to VDE 0532: I thmax = rated current Siemens LV /7

30 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = 0.8 I Lmax nc 1) Max. Rated Peak continuous current current thermal current 5) I thmax A I Ln A I Lmax A 1) All reactors with U N ˆ 600 V according to UL 2) Reference voltage drop of reactor u D ~ 4% for I Ln and U N = 575 V 3) For downstream six-pulse bridge converters: Reactors with higher rated currents on request Max. Reference voltage drop of reactor u D = 4% for I thmax and U N continuous direct current 3) I dn Order No. Order No. Order No. Order No. A 3 AC 400 V 50 Hz 3 AC 500 V 50 Hz 3 AC 690 V 50 Hz 3 AC 750 V 50 Hz EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EP DS EP DS00 4EU AA00-0AA EP DS00 4EU BA00-0AA EP DS00 4EU BA00-0AA EU AA00-0AA0 4EU BA00-0AA EU AA00-0AA0 4EU BA00-0AA EU BA00-0AA0 4EU CA00-0AA EU BA00-0AA0 4EU CA00-0AA EU BA00-0AA0 4EU CA00-0AA EU BA00-0AA0 4EU CA00-0AA0 4EU DA00-1BA EU BA00-0AA0 4EU CA00-0AA0 4EU BA00-0AA EU BA00-0AA0 4EU CA00-0AA0 4EU CA00-0AA0 4EU CA00-0AA EU BA00-0AA0 4EU BA00-0AA0 4EU CA00-0AA0 4EU DA00-0AA EU BA00-0AA0 4EU BA00-0AA0 4EU DA00-0AA0 4EU DA00-0AA EU BA00-0AA0 4EU BA00-0AA0 4EU DA00-0AA0 4EU DA00-0AA EU BA00-0AA0 4EU CA00-0AA0 4EU DA00-0AA0 4EU DA00-1BA EU BA00-0AA0 4EU CA00-0AA0 4EU DA00-0AA0 4EU EA00-1BA EU BA00-0AA0 4EU CA00-0AA0 4EU DA00-0AA0 4EU CA00-0A EU CA00-0AA0 4EU CA00-0AA0 4EU BA00-0A 4EU CA00-0A EU CA00-0AA0 4EU CA00-1BA0 4EU CA00-0A 4EU DA00-0A EU CA00-1BA0 4EU BA00-0A 4EU DA00-0A 4EU DA00-0A EU CA00-1BA0 4EU BA00-0A 4EU DA00-0A 4EU DA00-0A EU BA00-0A 4EU CA00-0A 4EU DA00-0A 4EU BA EU AY00-0A EU BA00-0A 4EU CA00-0A 4EU DA00-0A 4EU BA00 5) EU AL00-0A 4EU AX00-0A 2) EU AW00-0A 4EU AK00 5) 2) 4EU AP00 5) 4) Load with I max permissible, occasional or periodic, if the effective current does not exceed the value I thmax 5) Reactors according to VDE 0532: I thmax = rated current 2/8 Siemens LV

31 SIDAC Commutation Reactors for Converters I thmax = I Lmax Three-phase reactors nc 2 Maximum continuous thermal current Rated Maximum current 1) continuous direct current 2) Inductance Core losses Winding losses Connections 3) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln I dn L x P FE P W A A A mh W W kg kg kg 3 AC 400 V 50 Hz, u D ~ 4.4 V 2% reference voltage drop for I thmax and U N T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T } 4EP DS T C 4EP DS T B 4EP DS F C 4EP DS F C 4EP DS F C 4EP DS F C 4EP DS Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz) 2) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 3) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" Siemens LV /9

32 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = I Lmax nc Max. continuous thermal current Core losses Winding losses Rated Max. continuouance Induct- current 1) direct current 2) Connections 3) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln I dn L x P FE P W A A A mh W W kg kg kg 3 AC 400 V 50 Hz, u D ~ 8.8 V 4% reference voltage drop for I thmax and U N T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T } 4EP DS T C 4EP DS T } 4EP DS T C 4EP DS T C 4EP DS F C 4EP DS F C 4EP DS F C 4EP DS F } 4EP DS F C 4EP DS F } 4EU AA00-0AA F } 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F } 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-1BA F C 4EU AA00-1BA F C 4EU AA00-0A F C 4EU AA00-0A F C 4EU BB00-0A ) F D 4EU AL Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz) 2) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 3) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 4) Reactors according to VDE 0532: I thmax = rated current 2/10 Siemens LV

33 SIDAC Commutation Reactors for Converters I thmax = I Lmax Three-phase reactors nc 2 Max. continuous thermal current Rated current 1) Max. continuous direct current 2) Core losses Winding losses Inductance Connections 3) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln I dn L x P FE P W A A A mh W W kg kg kg 3 AC 500 V 50 Hz, u D ~ 11.5 V 4% reference voltage drop for I thmax and U N T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T } 4EP DS T C 4EP DS F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU BA00-0AA F C 4EU AA00-0A F C 4EU AA00-0A F C 4EU AA00-0A F C 4EU AA00-0A F C 4EU AA00-0A Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz) 2) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 3) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" Siemens LV /11

34 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = I Lmax nc 4) Max. continuous thermal current Core losses Rated Max. continuouance Induct- current 1) direct current 2) Winding losses Connections 3) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln I dn L x P FE P W A A A mh W W kg kg kg 3 AC 575 V 50 Hz, u D ~ 13.0 V 4% reference voltage drop for I thmax and U N ) F D 4EU AM ) F D 4EU AA AC 690 V 50 Hz, u D ~ 7.8 V 2% reference voltage drop for I thmax and U N F C 4EU BC00-0A F C 4EU BD00-0A AC 690 V 50 Hz, u D ~ 15.0 V 4% reference voltage drop for I thmax and U N F C 4EU AA00-0AA F C 4EU AA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU AA00-0A F C 4EU AA00-0A F C 4EU AA00-0A F C 4EU AA00-0A F C 4EU BA00-0A F C 4EU BA00-0A ) F D 4EU AA ) F D 4EU AA ) F D 4EU AX ) F D 4EU AA Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz) 2) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 3) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 4) All reactors with U N ˆ 600 V according to UL 5) Reactors according to VDE 0532: I thmax = rated current 2/12 Siemens LV

35 SIDAC Commutation Reactors for Converters Three-phase reactors I thmax = I Lmax nc 4) 2 Max. continuous thermal current Core losses Winding losses Rated Max. continuouance Induct- current 1) direct current 2) Connections 3) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln I dn L x P FE P W A A A mh W W kg kg kg 3 AC 750 V 50 Hz, u D ~ 17.3 V 4% reference voltage drop for I thmax and U N F C 4EU CA00-0AA F C 4EU CA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU AA00-0A F C 4EU BA00-0A F C 4EU BA00-0A F C 4EU BA00-0A F C 4EU BA00-0A F C 4EU BA00-0A ) F D 4EU AA ) F D 4EU AA ) F D 4EU AA AC 830 V 50 Hz, u D ~ 9.6 V 2% reference voltage drop for I thmax and U N F C 4EU BE00-0A ) F D 4EU AN Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz) 2) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 3) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 4) All reactors with U N ˆ 600 V according to UL 5) Reactors according to VDE 0532: I thmax = rated current Siemens LV /13

36 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = 0.8 I Lmax nc Max. continuous thermal current Rated current 1) Peak current 4) Max. continuous direct current 2) Core losses Inductance Windintions 3) Connec- losses T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln I Lmax I dn L x P FE P W A A A A mh W W kg kg kg 3 AC 400 V 50 Hz, u D ~ 8.8 V 4% reference voltage drop for I thmax and U N T } 4EP DS T C 4EP DS T } 4EP DS T B 4EP DS T } 4EP DS T C 4EP DS T } 4EP DS T } 4EP DS T C 4EP DS T } 4EP DS F } 4EP DS F } 4EP DS F C 4EP DS F } 4EP DS F } 4EP DS F } 4EP DS F C 4EU AA00-0AA F } 4EU AA00-0AA F } 4EU BA00-0AA F } 4EU BA00-0AA F C 4EU BA00-0AA F } 4EU BA00-0AA F C 4EU BA00-0AA F } 4EU BA00-0AA F } 4EU BA00-0AA F } 4EU BA00-0AA F C 4EU BA00-0AA F } 4EU BA00-0AA F C 4EU BA00-0AA F } 4EU BA00-0AA F } 4EU CA00-0AA F } 4EU CA00-0AA F C 4EU CA00-1BA F } 4EU CA00-1BA F C 4EU BA00-0A F C 4EU BA00-0A F D 4EU AL00-0A F C 4EU AW00-0A Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz) 2) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 3) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 4) Load with I Lmax permissible, occasional or periodic, if the effective current does not exceed the value I thmax. 2/14 Siemens LV

37 SIDAC Commutation Reactors for Converters I thmax = 0.8 I Lmax Three-phase reactors nc 2 Max. continuous thermal current Rated current 1) Peak current 4) Max. continuous direct current 2) Core losses Inductance Windintions 3) Connec- losses T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln I Lmax I dn L x P FE P W A A A A mh W W kg kg kg 3 AC 500 V 50 Hz, u D ~ 11.5 V 4% reference voltage drop for I thmax and U N T } 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T C 4EP DS T } 4EP DS F C 4EP DS F C 4EP DS F C 4EP DS F C 4EU AA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU BA00-0AA F C 4EU CA00-0AA F } 4EU CA00-0AA F C 4EU CA00-0AA F C 4EU CA00-0AA F C 4EU CA00-0AA F C 4EU CA00-0AA F C 4EU BA00-0AA F } 4EU BA00-0AA F C 4EU BA00-0AA F } 4EU CA00-0AA F C 4EU CA00-0AA F } 4EU CA00-0AA F C 4EU CA00-0AA F D 4EU CA00-1BA F C 4EU BA00-0A F C 4EU BA00-0A F C 4EU CA00-0A F C 4EU CA00-0A Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz) 2) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 3) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 4) Load with I Lmax permissible, occasional or periodic, if the effective current does not exceed the value I thmax. Siemens LV /15

38 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = 0.8 I Lmax nc 4) Max. continuous thermal current Rated current 1) Peak current 5) Max. continuous direct current 2) Core losses Inductance Windintions 3) Connec- losses T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Overall weight approx. I thmax I Ln I Lmax I dn L x P FE P W A A A A mh W W kg kg kg 3 AC 575 V 50 Hz, u D ~ 12.6 V 4% reference voltage drop for I thmax and U N F C 4EU AX00-0A ) F D 4EU AK AC 690 V 50 Hz, u D ~ 15.0 V 4% reference voltage drop for I thmax and U N F C 4EU DA00-1BA F C 4EU BA00-0AA F C 4EU CA00-0AA F C 4EU CA00-0AA F C 4EU DA00-0AA F C 4EU DA00-0AA F C 4EU DA00-0AA F C 4EU DA00-0AA F C 4EU DA00-0AA F C 4EU BA00-0A F C 4EU CA00-0A F C 4EU DA00-0A F C 4EU DA00-0A F C 4EU DA00-0A F C 4EU AY00-0A F C 4EU DA00-0A ) F D 4EU AP AC 750 V 50 Hz, u D ~ 17.3 V 4% reference voltage drop for I thmax and U N F C 4EU CA00-0AA F C 4EU DA00-0AA F C 4EU DA00-0AA F C 4EU DA00-0AA F C 4EU DA00-1BA F C 4EU EA00-1BA F C 4EU CA00-0A F C 4EU CA00-0A F C 4EU DA00-0A F C 4EU DA00-0A F C 4EU DA00-0A ) F D 4EU BA ) F D 4EU BA Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz) 2) For downstream six-pulse bridge converters: Reactors with higher rated currents on request 3) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 4) All reactors with U N ˆ 600 V according to UL 5) Load with I Lmax permissible, occasional or periodic, if the effective current does not exceed the value I thmax. 6) Reactors according to VDE 0532: I thmax = rated current 2/16 Siemens LV

39 SIDAC Mains Reactors for Frequency Converters 3 Three-phase reactors 3/2 Application 3/2 Technical specifications 3/3 Selection and ordering data Siemens LV

40 SIDAC Mains Reactors for Frequency Converters Three-phase reactors 3 Application nc Three-phase mains reactors for frequency converters are used in the line-side supply cable. Alternating currents flow through them with the mains frequency as the fundamental component. The reactors limit the circuit feedback that occurs in the form of harmonics. They also reduce the alternating currents and their frequencies caused by the switching of the input rectifier in the DC link capacitors. Two reactor series are available: Reactors with a reference voltage drop u D of ~ 2% for the operation of converters without power recovery. Reactors with a reference voltage drop u D of ~ 4% for operation with converters in combination with autotransformers with power recovery and for operation in systems with a u K power supply of < 1%. Mains reactors for frequency converters Technical specifications Recommended supply voltage U N See "Selection and ordering data" table Rated alternating current I Ln Maximum continuous thermal current I thmax Voltage drop Du per phase Inductance per phase mh Core losses P Fe at f = 50 Hz Winding losses P W Weight Degree of protection IP00 according to DIN VDE /EN Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation 4EP with terminals: 690 V AC (for site altitudes up to 2000 m above sea level) 4EP with flat termination and 4EU24 to 4EU43 (EN 61558): 1000 V AC Permissible ambient temperature during operation Deviation of the permissible alternating current from rated alternating current I Ln at coolant temperatures ž +40 C Temperature classes Site altitude Deviation of the permissible alternating current from rated alternating current I Ln at site altitudes >1000 m above sea level Operation with varying load 4EU45 to 4EU52 (DIN VDE 0532): with U N ˆ500 V for 4EP and 4EU: Type 4EP: -25 C to +70 C Type 4EU: -25 C to +80 C See "Configuration notes" 1100 V AC 600 V ACto c Type 4EP: t a 40 C/B Type 4EU: t a 40 C/H (utilisation according to F for applications according to EN 61558) Type 4EU: temperature class H (for applications according to c) ˆ 1000 m above sea level See "Configuration notes" Rating on request Standards/approvals The reactors comply with EN (type 4EU45 to 4EU52: DIN VDE 0532) The reactors are UL recognised under Guide No. XQNX2 and File No. E103902, as well as cul approved under Guide No. XQNX8 File No. E (applies to reactors with U N ˆ 600 V according to UL) Storage temperature -25 C to +55 C Transport temperature -25 C to +70 C Permissible humidity rating Humidity 5% to 95% occasional condensation permissible 3/2 Siemens LV

41 SIDAC Mains Reactors for Frequency Converters Three-phase reactors Selection and ordering data nc 1) Overview Max. continuous Rated current Reference voltage drop of reactor u D = 2% for I thmax and U N thermal current 2) I thmax A I Ln A 1) All reactors with U N ˆ 600 V according to UL Reactors with higher rated currents on request Order No. Order No. Order No. 3 AC 400 V 50 Hz 3 AC 500 V 50 Hz 3 AC 690 V 50 Hz 3 AC 480 V 60 Hz EP US EP US EP US EP US00 4EP US EP US EP US EP US EP US EP US00 4EP US EP US EP US EP US EP US EP US EP US00 4EP US EP US EP US00 4EP US EP US00 4EP US EP US00 4EP US00 4EP US EP US EP US00 4EP US EP US00 4EU UA00-0AA EP US00 4EU UA00-0AA EP US EP US00 4EU UA00-0AA EU UA00-0AA EU UA00-0AA0 4EU UA00-0AA0 4EU UB00-0AA EU UA00-0AA EU UA00-0AA0 4EU UA00-0AA EU UA00-0AA0 4EU UA00-0AA EU UA00-0AA0 4EU UA00-0AA EU UB00-0AA EU UA00-0AA0 4EU UA00-0AA0 4EU UA00-0AA EU UA00-0AA0 4EU UA00-1BA0 4EU UA00-0AA EU UA00-0AA EU UB00-0AA0 4EU UA00-0AA EU UA00-0AA0 4EU UB00-0AA0 4EU UC00-0AA EU UA00-1BA0 4EU UA00-0AA0 4EU UA00-0AA EU UA00-0AA0 4EU UA00-1BA EU UA00-0AA EU UB00-1BA0 4EU UA00-1BA0 4EU UA00-0A EU UB00-1BA0 4EU UA00-0A EU UC00-1BA0 4EU UB00-0A 4EU UB00-0A EU UB00-0A 4EU UB00-0A EU UB00-0A 4EU UB00-0A EU UC00-0A 4EU UB00-0A 4EU UA00 2) 2) Reactors according to VDE 0532: I thmax = rated current 3 Siemens LV /3

42 SIDAC Mains Reactors for Frequency Converters Three-phase reactors Overview nc 1) 3 Max. continuous Rated current Reference voltage drop of reactor u D = 4% for I thmax and U N thermal current 2) I thmax A I Ln A 1) All reactors with U N ˆ 600 V according to UL Reactors with higher rated currents on request 2) Reactors according to VDE 0532: I thmax = rated current Order No. Order No. Order No. 3 AC 400 V 50 Hz 3 AC 500 V 50 Hz 3 AC 690 V 50 Hz 3 AC 480 V 60 Hz EP US EP US00 4EP US EP US00 4EP US EP US00 4EP US EU UA00-0AA EU UA00-0AA0 4EU UB00-0AA EU UB00-0AA EU UB00-0AA EU UB00-0AA EU UB00-0AA EU UB00-0AA0 4EU UB00-0AA EU UB00-0AA EU UB00-0AA0 4EU UB00-0AA EU UB00-0AA0 4EU UB00-0AA EU UB00-0AA EU UA00-0AA EU UB00-0AA0 4EU UB00-0AA0 4EU UC00-0AA EU UA00-0AA EU UB00-0AA0 4EU UB00-0AA0 4EU UA00-0A EU UC00-0AA0 4EU UB00-1BA0 4EU UB00-0A EU UB00-0AA0 4EU UB00-0A 4EU UB00-0A EU UC00-1BA EU UA00-0A 4EU UA00-0A 4EU UA00-0A EU UB00-0A 4EU UA00-0A 4EU UA00 2) EU UB00-0A 4EU UA00 2) 4EU UA00 2) EU UA00 2) EU UB00-0A EU UB00-0A 4EU UA00 2) 4EU UA00 2) 3/4 Siemens LV

43 SIDAC Mains Reactors for Frequency Converters Three-phase reactors nc Maximum continuous thermal current Rated current Inductance Core losses 1) Winding losses Connections 2) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. 3 I thmax I Ln L x P FE P W A A mh W W kg kg kg 3 AC 400 V 50 Hz, u D ~ 4.4 V 2% reference voltage drop for I thmax and U N 3 AC 480 V 60 Hz, u D ~ 5.3 V 2% reference voltage drop for I thmax and U N T } 4EP US T } 4EP US T } 4EP US T } 4EP US T } 4EP US T } 4EP US T } 4EP US T C 4EP US T } 4EP US T } 4EP US T } 4EP US T C 4EP US F-Cu } 4EP US F-Cu } 4EP US F-Cu } 4EP US F-Cu C 4EP US F-Cu } 4EP US F-Cu } 4EP US F-Al } 4EU UA00-0AA F-Al } 4EU UA00-0AA F-Al } 4EU UA00-0AA F-Al } 4EU UA00-0AA F-Al } 4EU UB00-0AA F-Al } 4EU UA00-0AA F-Al } 4EU UA00-0AA F-Al C 4EU UB00-0AA F-Al } 4EU UA00-0AA F-Cu } 4EU UA00-1BA F-Al } 4EU UA00-0AA F-Cu } 4EU UB00-1BA F-Cu } 4EU UC00-1BA F-Cu C 4EU UB00-0A F-Cu D 4EU UC00-0A Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) At f = 60 Hz: P Fe60 = P Fe ) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" Siemens LV /5

44 SIDAC Mains Reactors for Frequency Converters Three-phase reactors nc 3 Max. continuous thermal current Rated current Inductance Core losses 1) Winding losses Connections 2) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln L x P FE P W A A mh W W kg kg kg 3 AC 400 V 50 Hz, u D ~ 8.8 V 4% reference voltage drop for I thmax and U N 3 AC 480 V 60 Hz, u D ~ 10.6 V 4% reference voltage drop for I thmax and U N T } 4EP US T } 4EP US T } 4EP US T C 4EP US F-Al } 4EU UA00-0AA F-Al C 4EU UB00-0AA F-Al } 4EU UB00-0AA F-Al } 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al } 4EU UA00-0AA F-Al C 4EU UB00-0AA F-Al } 4EU UA00-0AA F-Al } 4EU UB00-0AA F-Al C 4EU UC00-0AA F-Al C 4EU UB00-0AA F-Cu C 4EU UC00-1BA F-Cu C 4EU UA00-0A F-Cu D 4EU UB00-0A F-Cu C 4EU UB00-0A F-Cu C 4EU UB00-0A F-Cu C 4EU UB00-0A AC 500 V 50 Hz, u D ~ 5.7 V 2% reference voltage drop for I thmax and U N T } 4EP US T C 4EP US T } 4EP US T } 4EP US T } 4EP US T } 4EP US T } 4EP US T } 4EP US T C 4EP US T } 4EP US F-Cu } 4EP US F-Cu B 4EP US F-Cu } 4EP US F-Cu } 4EP US F-Al } 4EU UA00-0AA F-Al } 4EU UA00-0AA F-Al } 4EU UA00-0AA F-Al } 4EU UA00-0AA F-Al C 4EU UA00-0AA F-Cu } 4EU UA00-1BA F-Al C 4EU UA00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UA00-0AA F-Cu C 4EU UA00-0AA F-Cu D 4EU UA00-1BA F-Cu C 4EU UB00-1BA F-Cu C 4EU UB00-0A F-Cu C 4EU UB00-0A F-Cu C 4EU UB00-0A Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) At f = 60 Hz: P Fe60 = P Fe ) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 3/6 Siemens LV

45 SIDAC Mains Reactors for Frequency Converters Three-phase reactors nc Maximum continuous thermal current Rated current Inductance Core losses 1) Winding losses Connections 2) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. 3 I thmax I Ln L x P FE P W A A mh W W kg kg kg 3 AC 500 V 50 Hz, u D ~ 11.5 V 4% reference voltage drop for I thmax and U N T C 4EP US T C 4EP US T C 4EP US F-Al C 4EU UA00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Cu C 4EU UB00-1BA F-Cu C 4EU UB00-0A F-Cu C 4EU UA00-0A F-Cu C 4EU UA00-0A ) F-Cu D 4EU UA ) F-Cu D 4EU UA ) F-Cu D 4EU UA Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) At f = 60 Hz: P Fe60 = P Fe ) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 3) Reactors according to VDE 0532: I thmax = rated current Siemens LV /7

46 SIDAC Mains Reactors for Frequency Converters Three-phase reactors nc 3) 3 Maximum continuous thermal current Rated current Inductance Core losses 1) Winding losses Connections 2) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln L x P FE P W A A mh W W kg kg kg 3 AC 690 V 50 Hz, u D ~ 7.9 V 2% reference voltage drop for I thmax and U N F-Cu } 4EP US F-Al } 4EU UA00-0AA F-Al C 4EU UA00-0AA F-Al } 4EU UA00-0AA F-Al } 4EU UB00-0AA F-Al C 4EU UA00-0AA F-Al } 4EU UA00-0AA F-Al C 4EU UA00-0AA F-Al C 4EU UA00-0AA F-Al C 4EU UA00-0AA F-Al C 4EU UC00-0AA F-Al C 4EU UA00-0AA F-Cu C 4EU UA00-1BA F-Cu C 4EU UA00-0A F-Cu C 4EU UA00-0A F-Cu C 4EU UB00-0A F-Cu D 4EU UB00-0A F-Cu X 4EU UB00-0A ) F-Cu D 4EU UA AC 690 V 50 Hz, u D ~ 15.9 V 4% reference voltage drop for I thmax and U N F-Al C 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al C 4EU UC00-0AA F-Cu C 4EU UA00-0A F-Cu C 4EU UB00-0A F-Cu C 4EU UB00-0A F-Cu C 4EU UA00-0A ) F-Cu D 4EU UA ) F-Cu D 4EU UA ) F-Cu D 4EU UA ) F-Cu D 4EU UA Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) At f = 60 Hz: P Fe60 = P Fe ) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 3) All reactors with U N ˆ 600 V according to UL 4) Reactors according to VDE 0532: I thmax = rated current 3/8 Siemens LV

47 SIDAC Iron-core Output Reactors 4 Three-phase reactors 4/2 Application 4/2 Technical specifications 4/3 Selection and ordering data Siemens LV

48 SIDAC Iron-Core Output Reactors Three-phase reactors 4 Application nc Output reactors are used on the load side of frequency converters and motor currents flow through them. Output reactors compensate capacitive charge-reversal currents with long cables and, in the case of long motor cables, limit the dv/dt at the motor terminals. This enables the use of longer motor supply cables: m shielded motor cable m unshielded motor cable. Use of iron-core output reactors: Drives with standard and trans-standard asynchronous motors and a rated motor frequency (field weakening frequency) of up to 87 Hz and a maximum frequency of 200 Hz Drives with reluctance motors or permanently excited synchronous motors with a maximum frequency of 120 Hz. 4EU iron-core output reactors Technical specifications Recommended supply voltage U N Rated alternating current I Ln Inductance per phase mh Total power loss W Total weight kg Frequency See "Selection and ordering data" table Converter output frequency maximum 200 Hz Clock frequency of converter up to 8 khz Degree of protection IP00 according to DIN VDE /EN Terminal 4EP terminal, 4EU flat termination, see "Configuration notes", For terminal covers offering protection against accidental contact with flat terminations, see "Accessories" Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation (for site altitudes up to 2000 m above sea level) Permissible ambient temperature during operation Deviation of the permissible alternating current from rated alternating current I Ln at coolant temperatures ž +40 C Temperature classes Version with terminals: 690 V AC Version with flat terminations: 1000 V AC 0 C to +40 C See "Configuration notes" Type 4EP t a 40 C/F Type 4EU t a 40 C/H ˆ 1000 m above sea level See "Configuration notes" Site altitude Deviation of the permissible alternating current from rated alternating current I Ln (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN Dimensions Storage temperature Transport temperature Permissible humidity rating UL508: for types 4EP UL1561: for types 4EU See "Configuration notes" -25 C to +55 C -25 C to +70 C Humidity 5% to 95% occasional condensation permissible 4/2 Siemens LV

49 SIDAC Iron-Core Output Reactors Three-phase reactors Selection and ordering data nc Max. continuous thermal current 1) ˆ 4kHz Max. continuous thermal current 8kHz Rated current Inductance Core losses Winding losses Connections 2) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I thmax I Ln L x P FE P W A A A mh W W kg kg kg 3 AC 500 V ± 5 % 200 Hz, maximum clock frequency up to 8 khz T B 4EP ES T B 4EP FS T B 4EP BS T B 4EP CS T B 4EP AS T B 4EP RS F B 4EU ED00-4BA F B 4EU EE00-4BA F B 4EU EF00-4BA F B 4EU EB00-4BA F B 4EU EC00-4BA F B 4EU ED00-4BA Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) With clock frequencies > 4 khz, it is possible to determine the current I thmax, depending on the clock frequency, using the following formula: I thmax = f(khz) = i 4kHz - (i 4kHz - i 8kHz )/4 x (8 - fclock [khz]) 2) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" Note: The following generic parameters apply, which must not be exceeded: Maximum motor cable length 200 m, shielded cable Maximum motor cable length 300 m, unshielded cable Maximum motor cable cross-sections for performance class: - up to 2.2 kw 1.5 mm², ->2.2kW ˆ 7.5kW/2.5mm² ->7.5kW ˆ 11 kw/4 mm² ->11kW ˆ 22 kw/10 mm² ->22kW ˆ 30 kw/16 mm² ->30kW ˆ 37 kw/25 mm² ->37kW ˆ 50 kw/35 mm² ->50kW ˆ 75 kw/70 mm² Maximum clock frequency 8 khz Maximum motor frequency of output reactor 200 Hz Maximum motor frequency of sinewave filter 100 Hz U N 3 AC 500 V +5% (+10% sinewave filter) If these do not meet your requirements, customised solutions are available. For further information contact: MD_Anfrage@brmr.siemens.de Siemens LV /3

50 SIDAC Iron-Core Output Reactors Notes 4 4/4 Siemens LV

51 SIDAC Ferrite Output Reactors 5 Three-phase reactors 5/2 Application 5/2 Technical specifications 5/3 Selection and ordering data Siemens LV

52 SIDAC Ferrite Output Reactors 5 Three-phase reactors Application Due to the special material characteristics, the ferrite reactors can be operated at higher converter output frequencies of up to 600 Hz. They can be used with clock frequencies of up to 16 khz. Output filter reactors compensate capacitive chargereversal currents for long cables and, in the case of longer motor cable lengths, limit the dv/dt at the motor terminals. This enables the use of longer motor supply cables. Use of ferrite output reactors: Drives with asynchronous motors and a rated motor frequency (field weakening frequency) of 200 Hz and a maximum frequency of 300 Hz Drives with reluctance or permanently excited synchronous motors with a maximum frequency of 600 Hz. Ferrite output reactor Technical specifications Recommended supply voltage U N Rated alternating current I Ln Maximum converter output frequency Performance range of the drive kw Inductance per phase mh Total power loss W Total weight kg Frequency See "Selection and ordering data" table Converter output frequency maximum 600 Hz Clock frequency of converter ˆ 16 khz Degree of protection IP00 according to DIN VDE /EN Terminal on request Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation (for site altitudes up to 2000 m above sea level) Permissible ambient temperature during operation Deviation of the permissible alternating current from rated alternating current I Ln at coolant temperatures ž +40 C Temperature classes Version with terminals: 690 V AC Version with flat terminations: 1000 V AC 0 C to +40 C See "Configuration notes" t a 40 C/B Natural air cooling (S) according to DIN ˆ 1000 m above sea level See "Configuration notes" Site altitude Deviation of the permissible alternating current from rated alternating current I Ln (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with VDE 0805 Dimensions on request Storage temperature -25 C to +55 C Transport temperature -25 C to +70 C Permissible humidity rating Humidity 5% to 95% occasional condensation permissible 5/2 Siemens LV

53 SIDAC Ferrite Output Reactors Three-phase reactors Selection and ordering data Max. continuous thermal current 6kHz 1) Max. continuous thermal current 16 khz Rated current Inductance Total losses Connections T = Terminal F = Flat termination DT Order No. Total weight per PU approx. I thmax I thmax I Ln L x P W A A A mh W kg 3 AC 460 V 600 Hz maximum clock frequency 6 to 16 khz T X on request T X on request T X on request T X on request T X on request T X on request T X on request T X on request T X on request T X on request ) When operated between 6 khz and 16 khz, the maximum continuous thermal current I thmax follows a linear interpolation. 5 The selection table provides an overview of our range of reactors. If you are interested in any of our products or need further assistance, please copy the query page provided under "Specification sheets". Enter the parameters of your specific requirement profile and send it to the address provided. We will get back to you as soon as possible. Note: This query page is also available on our home page at Siemens LV /3

54 SIDAC Ferrite Output Reactors Notes 5 5/4 Siemens LV

55 SIDAC Iron-core Smoothing Reactors 6 Single-phase reactors 6/2 Application 6/2 Technical specifications 6/3 Selection and ordering data Siemens LV

56 SIDAC Iron-Core Smoothing Reactors Single-phase reactors 6 Application 4ET/4EM iron-core smoothing reactors Technical specifications nc Smoothing reactors are used on the DC side of converter sets. Direct current flows through them. Iron-core smoothing reactors as series inductance for DC motors (series reactors, 4EM, 4ET series) Their use is necessary to achieve problem-free commutation and reduce motor losses when the DC ripple is too high for DC motors due to the converter connection used. The reactors have an almost constant inductance L up to the rated direct current I dn. Iron-core smoothing reactors with selectable inductance and current (4EM, 4ET series) These reactors enable individual adaptation to the smoothing requirements of the converter-fed consumers. A reactor is selected according to the required energy content E, which is determined from the required inductance (or inductance curve through the current) and the rated direct current I dn. By dimensioning the reactors accordingly, it is possible to achieve a range of different inductance curves. Maximum continuous thermal current I thmax Rated direct current I dn Inductance for I thmax Iron-core smoothing reactors as series inductance for DC motors See "Selection and ordering data" table Iron-core smoothing reactors with selectable inductance and current See "Selection and ordering data" table Energy content E at I thmax Connection of the winding with type 4ET Permissible ripple of superimposed alternating ˆ 30% ˆ 30% current Core losses P Fe /winding losses P W /weight See "Selection and ordering data" table See "Selection and ordering data" table Degree of protection IP00 according to DIN VDE / EN Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation (for site altitudes up to 2000 m above sea level) Reduction of the rated voltage for insulation (at site altitudes > 2000 m above sea level) Permissible ambient temperature during operation Deviation of permissible direct current from rated direct current I dn at coolant temperatures ž +40 C Type 4EM: Type 4ET with terminal: Type 4ET25 to 4ET45: Type 4ET47 to 4ET80: See "Configuration notes" Type 4EM: -25 C to +70 C Type 4ET: -25 C to +80 C See "Configuration notes" according to EN 690 V DC 800 V AC/DC 1000 V AC/DC 1150 V AC/DC according to c 600 V DC, 600 V DC, 600 V DC, 600 V DC (to 4ET54) Temperature classes Type 4EM: t a 40 C/B Type 4ET: Type 4ET: t a 40 C/H (utilisation according to F for applications according to EN) t a 40 C/H (for application according to c) Site altitude ˆ 1000 m above sea level Deviation of permissible direct current See "Configuration notes" from rated direct current I dn (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN (type 4ET47 to 4ET80: DIN VDE 0532). The reactors 4EM46 to 4ET54 are UL recognised under Guide No. XQNX2 and File No. E103902, as well as cul approved under Guide No. XQNX8 File No. E (applies to reactors with U N ˆ 600 V according to UL) Storage temperature -25 C to +55 C Transport temperature -25 C to +70 C Permissible humidity rating Humidity 5% to 95% occasional condensation permissible 6/2 Siemens LV

57 SIDAC Iron-Core Smoothing Reactors Single-phase reactors Selection and ordering data 4EM iron-core smoothing reactors as series inductance for DC motors nc Maximum continuous thermal current Rated direct current Inductance Parallel or Energy series connection of reactor content windings 1) Core losses Winding losses DT Order No. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln L x P = Parallel E P FE P W A A mh S = Series Ws W W kg kg 4EM iron-core smoothing reactors B 4EM CB D 4EM CB D 4EM CB B 4EM CB B 4EM CB B 4EM CB D 4EM CB B 4EM CB D 4EM CB B 4EM CB D 4EM CB B 4EM CB D 4EM CB C 4EM CB D 4EM CB } 4EM CB D 4EM CB D 4EM CB C 4EM CB D 4EM CB B 4EM CB D 4EM CB ET iron-core smoothing reactors S C 4ET AA00-0A P S C 4ET AA00-0A P S C 4ET AA00-0A P S C 4ET AA00-0A P S D 4ET AA00-0A P S C 4ET AA00-0A P S D 4ET AA00-0A P S D 4ET BA00-0A P S D 4ET AA00-0A P Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) The 4ET reactors comprise 2 coils, which can be switched parallel or in series, depending on application. This produces two different inductance values with different current carrying capacity. 6 Siemens LV /3

58 SIDAC Iron-Core Smoothing Reactors Single-phase reactors Iron-core smoothing reactors with selectable inductance and current nc 1) Energy content Max. possible rated direct current (standard version) Max. possible rated direct current 2) (plus surcharge) Losses DT Core section of Order No. 3) Weight per PU approx. 6 E I dn I dn P FE P W Ws A A W W kg 4EM iron-core smoothing reactors X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM ET iron-core smoothing reactors X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET X 4ET Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. 1) 4EM46 to 4ET54 - UL Recognised 2) Higher rated direct current I dn for reduced energy content on request 3) Additional technical specifications must be specified in plain text. The type designation will be added to the Order No. on the delivery note, so that you will know the exact order number if you want to re-order any items. For further information, see "Specification sheets", "Specification sheet for customised smoothing reactors, selectable inductance and current". us for advice and with your queries: MD_Anfrage@brmr.siemens.de 6/4 Siemens LV

59 SIDAC Smoothing Air-core Reactors 7 Single-phase reactors 7/2 Application 7/2 Technical specifications 7/3 Selection and ordering data Siemens LV

60 SIDAC Smoothing Air-Core Reactors Single-phase reactors Application n 4PK smoothing air-core reactors (natural air cooling, energy content E from 380 Ws to 1.9 kws) are used in the DC circuit of converter units. These are primarily used to limit the current rise in the event of faults, especially in the case of through-conductions. They cause the high-speed DC circuit-breakers in the electric circuit to interrupt the rising fault current fast enough to prevent the fuses in the thyristor branches from responding. 7 Smoothing air-core reactors Technical specifications Rated direct currenti dn See "Selection and ordering data" table Energy content E at I thmax Maximum rated direct currenti dn Power loss P Al for 4PK Weight Inductance for I dn on request Degree of protection IP00 according to DIN VDE /EN Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation 2 kv (for site altitudes up to 2000 m above sea level) Reduction of the rated voltage for insulation See "Configuration notes" (at site altitudes > 2000 m above sea level) Permissible ambient temperature during operation -25 C to +80 C Deviation of permissible direct current from See "Configuration notes" rated direct current I dn at coolant temperatures ž +40 C Temperature classes t a 40 C/F Site altitude ˆ 1000 m above sea level Deviation of permissible direct current from See "Configuration notes" rated direct current I dn (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with DIN VDE 0532 Storage temperature 25 C to + 55 C Transport temperature 25 C to + 70 C Permissible humidity rating Humidity 5% to 95% occasional condensation permissible Permissible short-circuit current 20 I dn for 1 s 7/2 Siemens LV

61 SIDAC Smoothing Air-Core Reactors Single-phase reactors Selection and ordering data n Energy content (max.) for I dn Rated direct current (max. standard version) Losses DT Core section of Order No. Weight per PU approx. E I dn P Al Ws A W kg 4PK smoothing air-core reactors X on request X on request X on request X on request Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. A reactor is selected according to the required energy content E, which is determined from the desired inductance and rated direct current I dn. Due to the design of the reactors, each has a specific maximum value for the rated direct current I dn (See "Selection and ordering data" table). The "Selection and ordering data" table provides an overview of the range of reactors. If you are interested in any of our products or need further assistance, please copy the query page provided under "Specification sheets". Enter the parameters of your specific requirement profile and send it to the address provided. We will get back to you as soon as possible. Note: This query page is also available on our home page at 7 Siemens LV /3

62 SIDAC Smoothing Air-Core Reactors Notes 7 7/4 Siemens LV

63 SIDAC Filter Reactors 8 Three-phase reactors 8/2 Application 8/2 Technical specifications 8/3 Selection and ordering data Siemens LV

64 SIDAC Filter Reactors Three-phase reactors Application nc Nowadays, more and more harmonics-generating consumers in our networks are operated with inductive load. These include fluorescent lamps, dimmers, variable-speed drives, three-phase bridge connections and rectifiers. This increases the harmonic loading and the total harmonic distortion of the supply system. The reactive power also increases energy costs and transmission losses, as well as the loading of transmission and distribution equipment. In combination with the feeding transformer and the mains inductance in the supply system, the capacitors required for load compensation create an oscillating circuit. This causes undefined resonance due to the harmonics which, in turn, can reinforce the harmonics. The use of filter reactors prevents this physical effect. Taking audio-frequency remote control operation into account, the filter reactors with the capacitors are set to a defined series resonant frequency. Filter reactors Technical specifications 8 Degree of protection IP00 according to DIN VDE /EN Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation (for site altitudes up to 2000 m above sea level) Version with terminals: 690 V AC Version with flat terminations: 1000 V AC All versions: 600 V AC for 4EP and 4EU according to UL Detuning factor 5.67%, 7%, 14% Performance range P n kvar Monitoring Temperature switch is integrated, contacts are fitted on terminals. Permissible ambient temperature during operation Type 4EP: -25 C to +70 C Type 4EU: -25 C to +80 C Deviation of the permissible alternating current from See "Configuration notes" rated alternating current I Ln at coolant temperatures ž +40 C Temperature classes Type 4EP: t a 40 C/B Type 4EU: t a 40 C/H Site altitude ˆ 1000 m above sea level Deviation of the permissible alternating current from See "Configuration notes" rated alternating current I Ln at site altitudes > 1000 m above sea level Standards/approvals The reactors comply with EN or VDE The reactors are UL recognised under Guide No. XQNX2 and File No. E103902, as well as cul approved under Guide No. XQNX8 File No. E (applies to reactors with U N ˆ 600 V according to UL) Storage temperatures -25 C to +55 C Transport temperatures -25 C to +70 C Permissible humidity rating Humidity 5% to 95% occasional condensation permissible 8/2 Siemens LV

65 SIDAC Filter Reactors Three-phase reactors Selection and ordering data U N = 3 AC 400 V 50 Hz, overload capability I thmax ) nc Maximum continuous thermal current Rated current Filter bank capacity Required Inductance capacity for capacitors in delta connection Total losses Connections 2) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln Q C C D L x P V A A kvar mf mh W kg kg kg Detuning factor p = 5.67%, L = constant to 1.82 I thmax, f RES = 210 Hz T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS F C 4EU MA08-4CA F C 4EU MA08-0AA F C 4EU MA08-0AA F C 4EU MA08-0AA F C 4EU MA08-0AA Detuning factor p = 7%, L = constant to 1.66 I thmax, f RES = 189 Hz T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS F C 4EU MA08-0AA F C 4EU MA08-0AA F C 4EU MA08-0AA F C 4EU MA08-0AA Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. Harmonic voltages taken into account: 106% mains overvoltage in the fundamental component (50 Hz) 0.5% of U N for 3rd harmonic (150 Hz) 5% of U N for 5th harmonic (250 Hz) 5% of U N for 7th harmonic (350 Hz) Further types on request 1) The current I thmax is the maximum continuous thermal current permitted. It applies to the aforementioned harmonic spectrum. In order to cope with a changing harmonic content, the reactor can be continuously overloaded with I thmax ) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" Siemens LV /3

66 SIDAC Filter Reactors Three-phase reactors U N = 3 AC 400 V 50 Hz, overload capability I thmax ) nc Maximum continuous thermal current Rated current Filter bank capacity Required Inductance capacity for capacitors in delta connection Total losses Connections 2) DT Order No. Al T = Terminal F = Flat termination weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln Q C C D L x P V A A kvar mf mh W kg kg kg Detuning factor p = 14%, L = constant to 1.4 I thmax, f RES = 134 Hz T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS T C 4EP MS F C 4EU MB08-4CA F C 4EU MA08-4CA F C 4EU MA08-0AA F C 4EU MB08-0AA F C 4EU MA08-0AA F C 4EU MA80-0A Package sizes for reactors; 1 item, i.e. 1 item or a multiple thereof can be ordered. Harmonic voltages taken into account: 106% mains overvoltage in the fundamental component (50 Hz) 0.5% of U N for 3rd harmonic (150 Hz) 5% of U N for 5th harmonic (250 Hz) 5% of U N for 7th harmonic (350 Hz) Further types on request 1) The current I thmax is the maximum continuous thermal current permitted. It applies to the aforementioned harmonic spectrum. In order to cope with a changing harmonic content, the reactor can be continuously overloaded with I thmax ) For terminal covers offering protection against accidental contact with flat terminations: see "Accessories" 8/4 Siemens LV

67 SIDAC Application-specific Reactors 9 Sintered metal interference suppression reactors Three-phase reactors 9/2 Application 9/2 Technical specifications Discharge reactors Three-phase reactors 9/3 Application 9/3 Technical specifications Footprint reactors Mains reactors for frequency converters Single-phase reactors 9/4 Application 9/4 Technical specifications Three-phase reactors 9/5 Application 9/5 Technical specifications DC-link reactors for frequency converters Single-phase reactors 9/6 Application 9/6 Technical specifications Iron-core output reactors for frequency converters Three-phase reactors 9/7 Application 9/7 Technical specifications Railway reactors Single and three-phase reactors 9/8 Application 9/8 Technical specifications Single-phase reactors 9/9 Application 9/9 Technical specifications Siemens LV

68 SIDAC Sintered Metal Interference Suppression Reactors Three-phase reactors Application n 9 Sintered metal reactor, three-phase Sintered metal reactors for three-phase supplies comprise three mutually independent single-phase reactors. They are installed in the main supply line of converters and alternating currents at the line frequency, and the harmonics generated by the converter flow through them. Sintered metal reactors are always used where interference suppression is required from the low to high frequency range, as well as a commutation reactor. The special material characteristics of these reactors enable excellent interference suppression for frequencies up to 150 khz. Technical specifications If you are interested in any of our products or need further assistance, please MD_Anfrage@brmr.siemens.de Sintered metal reactor, single-phase The closed design of the pot-type cores reduces radiationlinked interferences to a minimum, thus enabling non-critical installation of reactors in close proximity to electronic devices. Applications are found in the area of controlled rectifier/regenerative units that operate in high-frequency systems. Interference suppression in converter connections for uninterruptible power supplies is also cost-effective. As individual components, sintered metal reactors can be used as either input or output reactors. Recommended supply voltage U N 3 AC 400 V ± 10% to 690 V +6%, 10% Maximum converter output frequency 600 Hz Performance range P n kw Frequency Line frequency Hz ± 10% Degree of protection IP00 according to DIN VDE /EN Terminal Terminal or customised Rating of creepage distances and clearances Degree of soiling 1 according to DIN VDE 0110 Test voltage 2.5 kv AC Permissible ambient temperature during operation 25 C to +40 C, for reduced performance up to +55 C Temperature classes t a 40 C/H Site altitude ˆ1000 m above sea level Standards/approvals The reactors comply with EN Storage temperature -25 C to +55 C Transport temperature -25 C to +70 C Permissible humidity rating Low air temperature 0 C Condensation and ice formation excluded DIN IEC /04.90 Class 3K5 9/2 Siemens LV

69 SIDAC Discharge Reactors Three-phase reactors Application Discharge reactor 34 UVW U V W Discharge reactors for compensation equipment: Capacitor banks in p.f. compensation equipment can be connected and disconnected to and from the supply system as required. Connecting a supply system to a capacitor bank that is not fully discharged can cause mains overvoltages, which can damage connected devices. The capacitors must be discharged quickly following disconnection of a capacitor bank to allow rapid reconnection. In this case, discharge reactors offer significant advantages. The resulting losses are considerably lower when compared to the previously used discharge resistors. The ambient temperature rise is lower which has a positive effect on the service life of the phase shift capacitors. The discharge reactors meet the requirement for permanently installed and connected discharge devices as well as the requirement for short capacitor discharge times of just a few seconds. Due to high AC resistance, power losses during operation are lower than 1.8 W and therefore negligible. 72, PD30_00006a Dimensional drawing and circuit diagram Technical specifications Recommended supply voltage U N 3 AC 230 to 690 V Operating losses < 1.8 W No-load current < 4.5 ma Total weight 0.5 kg Frequency Hz Degree of protection IP40 according to DIN Terminal Terminals for 0.75 mm 2 to 2 x 2 mm 2 Inductance 230 V 730 mh 400 V 710 mh 525 V 670 mh 690 V 350 mh Discharge time 230 V less than 20 s for 50 kvar 400 V less than 20 s for 100 kvar Permissible discharges 1 x/(1 min (100 kvar)) Temperature classes t a 40 C/B Natural air cooling (S) according to DIN Standards/approvals The reactors comply with EN Dimensions See dimensional drawing Permissible ambient temperature during operation -25 C to +55 C (average over 24 h) Storage temperature -25 C to +70 C Installation Inside 9 Order No. 4EJ EG Supply voltage Capacitor bank output Discharge time 230 V up to 25 kvar up to 50 kvar up to 100 kvar < 10 s < 20 s < 40 s 400 V to 690 V up to 25 kvar up to 50 kvar up to 100 kvar < 5 s < 10 s < 20 s Siemens LV /3

70 SIDAC Footprint Reactors Mains Reactors for Frequency Converters Single-phase reactors Application Mains reactors for frequency converters n Mains reactors for frequency converters are installed in the lineside supply cable. The reactors limit the circuit feedback that occurs in the form of harmonics. They also limit the alternating currents with the frequencies determined by the switching of the input rectifier in the DC link capacitors. We recommend using 2% reactors if the mains inductance of the power supply is very small. Recommended system short-circuit power to apparent drive power > 33 : 1. All the reactors here can be customised by adapting the winding and the core air gaps. Technical specifications 9 Recommended supply voltage U N 1 AC 230 V ± 10% Rated alternating current I Ln A Test voltage 4 kv AC live parts against casing Reference voltage drop Du per phase 2%, 4% (application and type-specific) customised design for I Ln and f = 50 Hz or f = 60 Hz Performance range P n 0.75 to 11 kw, higher outputs on request Inductance per phase mh 0.57 to 9.5 mh (application and type-specific) Total power loss W on request Total weight kg on request Frequency Hz Degree of protection Assembly in zinc-plated steel housing in IP20 Terminal Line-side bushing terminals, free cable end for connection of frequency converter input, cable according to customer requirements Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation Version with terminals: 600 V AC (for site altitudes up to 2000 m above sea level) Permissible ambient temperature during operation -10 C to +50 C Deviation of the permissible alternating current from on request rated alternating current I Ln (at coolant temperatures ž+40 C) Temperature classes t a 50 C/F (B) Site altitude ˆ1000 m above sea level Deviation of the permissible alternating current from See "Configuration notes" rated alternating current I Ln (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN Electromagnetic compatibility according to EN , 3, 4 Vibration EN All reactors are built according to UL506, approval on request Dimensions Reactor casing with a maximum height of 50 mm for P n ˆ 11 kw. Further dimensions by separate agreement Storage temperature -20 C to +70 C Permissible humidity rating Relative humidity at +40 C to 95% Condensation not permissible If you are interested in any of our products or need further assistance, please MD_Anfrage@brmr.siemens.de 9/4 Siemens LV

71 SIDAC Footprint Reactors Mains Reactors for Frequency Converters Three-phase reactors Application n Mains reactors for frequency converters are installed in the lineside supply cable. Reactors limit the circuit feedback that occurs in the form of harmonics. They also limit the alternating currents with the frequencies determined by the switching of the input rectifier in the DC link capacitors. We recommend using 2% reactors if the mains inductance of the power supply is very small. Recommended system short-circuit power to apparent drive power > 33 : 1. All the reactors here can be customised by adapting the winding and the core air gaps. Mains reactors for frequency converters Technical specifications Recommended supply voltage U N 3 AC 600 V ± 10% Rated alternating current I Ln A Test voltage 4 kv AC live parts against casing Reference voltage drop Du per phase 2%, 4% (application and type-specific) customised design for I Ln and f = 50 Hz or f = 60 Hz Performance range of corresponding converter P n 0.75 to 75 kw, higher outputs on request Inductance per phase mh 0.07 mh to 11.5 mh (application-specific) Total power loss W on request Total weight kg on request Frequency Hz Degree of protection Assembly in zinc-plated steel housing in IP20 Terminal Line-side bushing terminals, free cable end for connection of frequency converter input, cable according to customer requirements Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation Version with terminals: 600 V AC (for site altitudes up to 2000 m above sea level) Permissible ambient temperature during operation -10 C to +50 C Deviation of the permissible alternating current from on request rated alternating current I Ln Temperature classes t a 50 C/F (B) Site altitude ˆ1000 m above sea level Deviation of the permissible alternating current from See "Configuration notes" rated alternating current I Ln (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN Electromagnetic compatibility according to EN ,3,4 Vibration EN All reactors are built according to UL506, approval on request Dimensions Reactor casing with a maximum height of 50 mm to P n = 22 kw, Maximum height of casing 60 mm to P n ˆ 75 kw. Further dimensions by separate agreement Storage temperature -20 C to +70 C Permissible humidity rating Relative humidity at +40 C to 95% Condensation not permissible If you are interested in any of our products or need further assistance, please MD_Anfrage@brmr.siemens.de 9 Siemens LV /5

72 SIDAC Footprint Reactors DC-Link Reactors for Frequency Converters Single-phase reactors Application DC-link reactors for frequency converters n DC-link reactors for frequency converters are installed after the input rectifier in the voltage link. The reactors limit the circuit feedback that occurs in the form of harmonics. They also reduce load current peaks in the DC link capacitors, which significantly reduces the load on the components in the DC link. This, in turn increases the service life of the converter. A DC-link reactor can either be permanently integrated in the DC link of the converter during its development, or it is fitted with terminals that permit connection of an additional inductance in the DC link. If they are the right size, DC-link reactors can be a suitable alternative to three-phase mains reactors. We recommend using them if the mains inductance of the power supply is very small. All the reactors here can be customised by adapting the winding and the core air gaps. Technical specifications 9 Recommended supply voltage U N 648 V DC ± 10%, 3 AC 480 V ± 10% Rated alternating current I Ln A Test voltage 4 kv AC live parts against casing Performance range of corresponding converter P n 0.25 mh to 10 mh (application and type specific) Inductance per phase mh 0.75 to 75 kw, higher outputs on request Total power loss W on request Total weight kg on request Frequency Hz ± 10% Degree of protection Assembly in zinc-plated steel housing in IP20 Terminal Shielded cable end for connection to the voltage link input, cable according to customer requirements Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation Version with terminals: 600 V AC (for site altitudes up to 2000 m above sea level) Permissible ambient temperature during operation -10 C to +50 C Deviation of the permissible alternating current from on request rated alternating current I Ln Temperature classes t a 50 C/F (B) Site altitude ˆ1000 m above sea level Deviation of the permissible alternating current from See "Configuration notes" rated alternating current I Ln (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN Electromagnetic compatibility according to EN ,3,4 Vibration EN All reactors are built according to UL506, approval on request Dimensions Reactor casing with a maximum height of 50 mm to P n = 22 kw, Maximum height of casing 60 mm to P n ˆ 75 kw. Further dimensions by separate agreement Storage temperature -20 C to +70 C Permissible humidity rating Relative humidity at +40 C to 95% Condensation not permissible If you are interested in any of our products or need further assistance, please MD_Anfrage@brmr.siemens.de 9/6 Siemens LV

73 SIDAC Footprint Reactors Iron-core Output Reactors for Frequency Converters Three-phase reactors Application Output reactors for frequency converters n Output filter reactors for frequency converters are installed at the converter output. The reactors compensate capacitive chargereversal currents in long cables and, in the case of long motor cables, limit the dv/dt at the motor terminals. The output reactors are used with standard asynchronous motors with a maximum frequency of 200 Hz - or with reluctant or permanently excited synchronous motors with a maximum frequency of 120 Hz. This supports operation with a maximum converter output frequency of f max = 400 Hz. It is not possible to generalise on the maximum permissible length of the motor supply cables required for the output reactors. Guidelines for shielded and unshielded motor cables lengths required for operation with output reactors: 300 m unshielded/200 m shielded cable. All the reactors here can be customised by adapting the winding and the core air gaps. Technical specifications Recommended supply voltage (converter output voltage) U N 3 AC 480 V ± 10% Rated alternating current I Ln A Test voltage 4 kv AC live parts against casing Performance range of corresponding converter P n 0.75 to 75 kw, higher outputs on request Inductance per phase mh to 2.6 mh (application-specific) Total power loss W on request Total weight kg on request Frequency f max = 400 Hz at converter output Clock frequency ˆ 4 khz Degree of protection Assembly in zinc-plated steel housing in IP20 Terminal Bushing terminals for the connection of motor supply cable, shielded cable end for connection to frequency converter output, cable according to customer requirements Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation Version with terminals: 600 V AC (for site altitudes up to 2000 m above sea level) Permissible ambient temperature during operation -10 C to +50 C Deviation of the permissible alternating current from on request rated alternating current I Ln Temperature classes t a 50 C/F Site altitude ˆ1000 m above sea level Deviation of the permissible alternating current from See "Configuration notes" rated alternating current I Ln (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN Electromagnetic compatibility according to EN ,3,4 Vibration EN All reactors are built according to UL506, approval on request Dimensions Reactor casing with a maximum height of 80 mm to P n ˆ 75 kw. Further dimensions by separate agreement Storage temperature -20 C to +70 C Permissible humidity rating Relative humidity at +40 C to 95% Condensation not permissible If you are interested in any of our products or need further assistance, please MD_Anfrage@brmr.siemens.de 9 Siemens LV /7

74 SIDAC Railway Reactors Single- and three-phase reactors Application On-board network container/acceptor circuit reactor/chopper reactor n These include reactors for use in electrical railcars. These reactors are used in trams, subway trains and modern high-speed railcars. The components have been specially designed and manufactured for the harsh environmental conditions that prevail during railway operation. This includes increased requirements in terms of resistance to extreme climates, humidity and pollutants in the atmosphere. All reactors comply with mechanical requirements with regard to permanent vibrations during railway operation. A key feature of these reactors is their low sound emission. On-board network containers with transformer, reactor and change-over switch are used to supply on-board power for different infeed conditions. Acceptor circuit reactors are used to smooth the DC link voltage and reduce the harmonics in the DC link Chopper reactors limit the current gradient of the clocked chopper current and the short-circuit currents. Rod core reactors as a component of the line filter for overvoltage protection and to limit the line harmonics or DC link harmonic currents Technical specifications 9 Rated alternating current I Ln from 450 to 3000 A System supply voltages available 15 kv AC 16 2 / 3 Hz 25 kv AC 50 Hz 1.5 kv DC Inductance per phase mh 0.3 mh to 16 mh, typical ratings 0.5 mh at 830 A with E = 139 Ws 2.0 mh at 3000 A with E = 9000 Ws 16.0 mh at 670 A with E = 3592 Ws Total power loss W on request Total weight kg on request Frequency Application-specific 33 1 / 3 Hz, 50 Hz, 100 Hz, Hz Degree of protection IP00, exposed to all weather factors Safety class I according to VDE 0106 Terminal Free cable, flat copper (application-related) Installation Hanging, underfloor (application-related) Cooling CF, forced air cooling Typically 10 to 12 m/s at 40 C Climatic conditions Loads due to "damp heat" and salt mist" DIN IEC Class 5C2 (chemically active materials) DIN IEC Class 5F2 (contaminated materials) DIN IEC Class 5S2 (mechanically active materials) Insulation up to 25 kv rated voltage for clearances in air 32 mm clearances in air (minimum value) 4000 V DC insulation rated voltage for creepage distances Permissible ambient temperature during operation -40 C to +40 C Temperature classes t a 40 C/F to t a 65 C/F, t a 55 C/H Mechanical load DIN IEC /06.90 Vibration, sinusoidal approx. 2 g DIN IEC 9/426/CDV Vibration wide-band noise DIN IEC /08.89 Shock UIC 566 Vibration and shock resistance Standards/approvals The reactors comply with VDE 0535, EN Dimensions on request Storage temperature -40 C to +80 C If you are interested in any of our products or need further assistance, please MD_Anfrage@brmr.siemens.de 9/8 Siemens LV

75 SIDAC Railway Reactors Application Air-core reactors Start of winding and end of winding, top 1 2 Technical specifications 25 PD30_00013 Single-phase reactors n Air-core reactors These include reactors for use in electrical railcars. These reactors are used in trams, subway trains and modern high-speed railcars. The components have been specially designed and manufactured for the harsh environmental conditions that prevail during railway operation. This includes increased requirements in terms of resistance to extreme climates, humidity and pollutants in the atmosphere. All reactors comply with mechanical requirements with regard to the permanent vibrations during railway operation. Air-core reactors are used as mains reactors in DC drive systems to smooth the motor current. The rates of current rise are limited in the event of faults, and through-conductions in particular. The aim is to prevent unacceptably high currents before any protective devices can be triggered. Rated alternating current I Ln System supply voltages available If you are interested in any of our products or need further assistance, please MD_Anfrage@brmr.siemens.de up to 600 A 2.3 kv DC Inductance per phase mh 9 mh to 17 mh, typical ratings 6 to 9 mh at 230 to 400 A with E = 230 Ws 17 mh for A Total power loss W on request Total weight kg on request Frequency DC applications, the aforementioned currents take into account a 30% ripple of the alternating current Degree of protection IP00, exposed to all weather factors Safety class I according to VDE 0106 Terminal Free cable, flat copper (application-related) Installation Hanging, underfloor (application-related) Cooling CF, forced air cooling Typically 10 to 12 m/s at 40 C Climatic conditions Load due to "damp heat" and "salt mist" DIN IEC Class 5C2 (chemically active materials) DIN IEC Class 5F2 (contaminated materials) DIN IEC Class 5S2 (mechanically active materials) DIN IEC Class 5K3 (climatic category) DIN IEC Class 5B2 (biologically active materials) Insulation up to 12 kv rated voltage for clearances in air >20 mm clearances in air (minimum value) 1900 V DC insulation rated voltage for creepage distances Permissible ambient temperature during operation -30 C to +70 C Temperature classes t a 60 C/H Mechanical load DIN IEC /06.90 Vibration sinusoidal approx. 2 g DIN IEC 9/426/CDV Vibration wide-band noise DIN IEC /08.89 Shock UIC 566 Vibration and shock resistance Standards/approvals The reactors comply with VDE 0535, EN60310 Dimensions on request Storage/transport temperature -40 C to +70 C 9 Siemens LV /9

76 SIDAC Railway Reactors Notes 9 9/10 Siemens LV

77 SIDAC Radio Interference Suppression Filters 10 Single-phase filters 10/2 Application 10/2 Technical specifications 10/3 Selection and ordering data Three-phase filters 10/2 Application 10/2 Technical specifications 10/4 Selection and ordering data Siemens LV

78 SIDAC Radio Interference Suppression Filters Single-phase filters, Three-phase filters Application Radio interference suppression filters for frequency converters are used in line-side supply cables for the purpose of attenuating grid-bound radio interference voltages. Using a radio interference suppression filter can achieve compliance with interference suppression level A or B according to EN It is also possible to use significantly longer motor supply cables in compliance with the limit values of EN In order to ensure optimum filter performance, we recommend that you do not exceed a maximum motor cable length of 50 m. As well as the standard single and three-phase filters, 4-phase filters are also available on request for the interference suppression of complete control cabinets. Customised modifications enable solutions that are optimally matched to the application. For example, using a combination filter (radio interference suppression filter and output reactor), it is possible to increase the length of the motor cable even further while still maintaining the required radio interference suppression level. Combining the radio interference suppression filter with an input reactor enables further reduction of circuit feedback. For further advice MD_Anfrage@brmr.siemens.de Radio interference suppression filters Technical specifications 10 Recommended supply voltage U N See "Selection and ordering data" table Rated alternating current I Ln Leakage current for U N and 50 Hz Drive power for 2 AC 230 V / 3 AC 400 V DC resistance mw Degree of protection Weight Frequency 50 Hz/60 Hz Test voltage 1770 V DC (2240 V), 2 s phase/phase 2700 V DC, 2 s phase/casing Permissible overload 1.5 I Ln for 3 mins. per hour or 2.5 I Ln for 30 s per hour Rated ambient temperature t a 40 C Climatic category 25/100/21 ( 25 C/+100 C/21 days moisture test) for filters 4EF AA EF AA10, 4EF AA10 the following applies: 25/85/21 ( 25 C/+85 C/21 days moisture test) Test according to EN Standards EN Approvals See "Selection and ordering data" table UL1283, CSA22.2 No are applied 10/2 Siemens LV

79 SIDAC Radio Interference Suppression Filters Single-phase filters Selection and ordering data Recommended filter class 1) Rated current Leakage current DC resistance Connection 2) Degree of protection Approvals DT Order No. Total weight approx. I Ln A I leak ma R type mw IP U cu q kg 1 AC 250 V 50/60 Hz for converters and chassis converters A 3) 10 < BsRKl 20 x 4) X C 4EF AA A 3) 20 < BsRKl 20 x 4) X C 4EF AA B 8 < BsRKl 20 C 4EF AA B 12 < BsRKl 20 C 4EF AA B 16 < BsRKl 20 C 4EF AA B 25 < BsRKl 20 C 4EF AA x available not available 1) Recommended filters for interference suppression according to EN 55011, Class A or Class B, EN In individual cases, compliance with EMC regulations must be ensured by means of an application-related measurement, which must be requested and ordered separately. When selecting the filter, the ratings of the converter must be taken into account. Always ensure correct installation of filters and additional sensible measures for compliance with the EMC Directive. 2) BsRKl: safe-to-touch modular terminal block 3) If a Class A radio interference suppression filter is already integrated in the converter, no further Class A radio interference suppression filters may be connected upstream. This would cause a malfunction of the converter system, which, in turn could damage components or even the converter itself. 4) Approval available shortly 10 Siemens LV /3

80 SIDAC Radio Interference Suppression Filters Three-phase filters 10 Recommended filter class 1) Rated current Leakage current DC resistance x available not available 1) Recommended filters for interference suppression according to EN 55011, Class A or Class B, EN In individual cases, compliance with EMC regulations must be ensured by means of an application-related measurement, which must be requested and ordered separately. When selecting the filter, the ratings of the converter must be taken into account. Always ensure correct installation of filters and additional sensible measures for compliance with the EMC Directive. 2) BsRKl: safe-to-touch modular terminal block BsRKl / fre: safe-to-touch modular terminal block / free ends F: flat termination 3) If a Class A radio interference suppression filter is already integrated in the converter, no further Class A radio interference suppression filters may be connected upstream. This would cause a malfunction of the converter system, which, in turn could damage components or even the converter itself. 4) 520 V unless stated otherwise in the table under I Ln 5) Rated voltage 3 AC 480 V 50/60 Hz 6) For operation according to UL U N = 500 V/290 V. Connection 2) Degree of protection Approvals DT Order No. Total weight approx. I Ln A I leak ma R type mw IP U cu q kg 3) 4) 3 AC 520 V 50/60 Hz for converters and chassis converters A 8 < BsRKl 20 X X X C 4EF AA A 16 < BsRKl 20 X X X C 4EF AA A 25 < BsRKl 20 X X X C 4EF AA A 36 < BsRKl 20 X X X C 4EF AA A 50 < BsRKl 20 X X X C 4EF AA A 66 < BsRKl 20 X X X C 4EF AA A 90 < BsRKl 20 X X X C 4EF AA A 120 < BsRKl 20 X X X C 4EF AA A 150 < BsRKl 20 X X X C 4EF AA A 220 5) < BsRKl / fre 20 X C 4EF AA A 250 < F 00 x 6) X C 4EF AA A 320 < F 00 x 6) X C 4EF AA A 400 < F 00 x 6) X C 4EF AA A 600 < F 00 x 6) X C 4EF AA A 1000 < F 00 x 6) X C 4EF AA A 1600 < F 00 C 4EF AA AC 480 V 50/60 Hz for converters and chassis converters B 8 < BsRKl / fre 20 C 4EF AA B 16 < BsRKl / fre 20 C 4EF AA B 25 < BsRKl / fre 20 C 4EF AA B 36 < BsRKl / fre 20 C 4EF AA B 50 < BsRKl / fre 20 C 4EF AA B 66 < BsRKl / fre 20 C 4EF AA B 90 < BsRKl / fre 20 C 4EF AA B 120 < BsRKl / fre 20 C 4EF AA B 150 < BsRKl / fre 20 C 4EF AA B 200 < BsRKl / fre 20 C 4EF AA /4 Siemens LV

81 SIDAC dv/dt Filters 11 Three-phase filters 11/2 Application 11/2 Technical specifications 11/3 Selection and ordering data Siemens LV

82 SIDAC dv/dt Filters Three-phase filters Application n dv/dt filters comprise a limiter circuit and a reactor, or just a reactor. The filter is installed at the output of frequency converters and the motor currents flow through the reactor. By connecting a filter to the three-phase system at the output of the frequency converter, transient voltage peaks are reduced and the voltage gradients in the motor winding are reduced to non-critical values of less than 500 V/ms. If long motor cables are used, the dv/dt filter also reduces capacitive load current peaks resulting from the capacitance per unit length of motor cable. Specifications for motor cable lengths: m shielded motor cable m unshielded motor cable dv/dt filter 11 Technical specifications s Recommended supply voltage U N 3 AC 500 V / 690 V Rated alternating current I Ln up to approx. 860 A Test voltage Depending on the version Performance range of the drive up to approx. 800 kw Total power loss W on request Total weight kg on request Frequency f max = 200 Hz at converter output Clock frequenciesˆ 4 khz Degree of protection IP00 according to DIN VDE /EN Safety class I according to DIN VDE /05.82 IEC 536/1976 Terminal Flat termination/terminals depend on the performance class Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Permissible ambient temperature during operation 0 C to +40 C Deviation of the permissible alternating current from on request rated alternating current I Ln (at coolant temperatures ž +40 C) Temperature classes depending on the version Site altitude ˆ1000 m above sea level Deviation of the permissible alternating current from See "Configuration notes" rated alternating current I Ln (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN Storage temperature -25 C to +55 C Transport temperature -25 C to +70 C Permissible humidity rating Humidity 5% to 95% occasional condensation permissible 11/2 Siemens LV

83 SIDAC dv/dt Filters Three-phase filters Selection and ordering data Maximum continuous thermal current 4kHz Rated current Connections T = Terminal F = Flat termination DT Core section of Order No. I thmax A I Ln A 3 AC 400 V /500 V 200 Hz, maximum clock frequency 4 khz T X on request T X on request 10 9 T X on request T X on request T X on request T X on request T X on request T X on request T X on request T X on request Higher currents available on request Queries: If you have any queries, please fill out the "Specification sheet for customised dv/dt filters". The specified data will enable us to provide a detailed offer. The offer will also contain details of delivery times and dimensions. 11 Siemens LV /3

84 SIDAC dv/dt Filters Notes 11 11/4 Siemens LV

85 SIDAC Sinewave Filters 12 Three-phase filters 12/2 Application 12/2 Technical specifications 12/3 Selection and ordering data Siemens LV

86 SIDAC Sinewave Filters Three-phase filters Application nc The sinewave filter is installed at the output of frequency converters and motor currents flow through the filter. The frequency converter output variables are filtered in such a way that it produces almost sinusoidal motor voltages and currents. Stray losses in the motor are reduced and the motor runs significantly quieter. If long motor cables are used, the sinewave filter also reduces the load current peaks caused by cable capacities. EX(d) motors can be converter-fed if a sinewave filter is used 1). Permissible motor cable lengths when using sinewave filters: m shielded motor cable m unshielded motor cable Sinewave filter 12 Technical specifications s Recommended supply voltage U N See "Selection and ordering data" table Rated alternating current I Ln Total power loss W Total weight kg Test voltage 3.6 kv DC live parts against casing Performance range of the drive 1.5 to 75 kw, higher outputs available on request Frequency f max = 100 Hz Clock frequency 4 khz ˆ 8 khz Degree of protection IP00 according to DIN VDE /EN Safe-to-touch terminals according to BGV A2 Safety class I according to DIN VDE /05.82 IEC 536/1976 Terminal Safe-to-touch terminals Rating of creepage distances and clearances Degree of soiling 2 according to DIN VDE 0110 Rated voltage for insulation 500 V AC (for site altitudes up to 1000 m above sea level) Permissible ambient temperature during operation 0 C to +40 C Deviation of the permissible alternating current from See "Configuration notes" rated alternating current I Ln (at coolant temperatures ž +40 C) Temperature classes t a 40 C/F or t a 40 C/H depending on the design ratings Site altitude ˆ1000 m above sea level Deviation of the permissible alternating current from See "Configuring aids" rated alternating current I Ln (at site altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN UL 508: Device assembly Storage temperature -25 C to +55 C Transport temperature -25 C to +70 C Permissible humidity rating Humidity 5% to 95% occasional condensation permissible 1) If a sinewave filter is placed upstream of the Ex(d) motor at the converter, please contact us to find out more about the operating conditions. 12/2 Siemens LV

87 SIDAC Sinewave Filters Three-phase filters Selection and ordering data Max. continuous thermal current Rated current Inductance Total losses Connections T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. Total weight per PU approx. I thmax I Ln L x P V A A mh W kg kg kg 3 AC 400/500 V AC + 10% 100 Hz, clock frequency 4 khz ˆ 8 khz T B 4EF GB T B 4EF GB T B 4EF GB T B 4EF GB T B 4EF GB T B 4EF GB T B 4EF GB T B 4EF GB T B 4EF GB T B 4EF GB Note: The following generic parameters apply, which must not be exceeded: Maximum motor cable length 200 m, shielded cable Maximum motor cable length 300 m, unshielded cable Maximum motor cable cross-sections for performance class: - up to 2.2 kw 1.5 mm², ->2.2kW ˆ 7.5kW/2.5mm² ->7.5kW ˆ 11 kw/4 mm² ->11kW ˆ 22 kw/10 mm² ->22kW ˆ 30 kw/16 mm² ->30kW ˆ 37 kw/25 mm² ->37kW ˆ 50 kw/35 mm² ->50kW ˆ 75 kw/70 mm² Maximum clock frequency 8 khz Maximum motor frequency of output reactor 200 Hz Maximum motor frequency of sinewave filter 100 Hz U N 3 AC 500 V +5% (+10% sinewave filter) If these do not meet your requirements, customised solutions are available. For further information contact: MD_Anfrage@brmr.siemens.de Operation of the drive in Ex(d) range: If a sinewave filter is placed upstream of the Ex(d) motor at the converter, please contact us to find out more about the operating conditions. 12 Siemens LV /3

88 SIDAC Sinewave Filters Notes 12 12/4 Siemens LV

89 SIDAC Specification Sheets 13 Query 13/2 Specification sheet for customised reactors 13/3 Specification sheet for customised smoothing reactors, selectable inductance and current 13/4 Specification sheet for customised radio interference suppression filters 13/4 Specification sheet for customised dv/dt filters 13/6 Specification sheet for customised sinewave DC reactors (smoothi DC-link reactors) L 1 [mh]: I d1 [A]: L 2 [mh]: I d2 [A]: I therm [A]: U sys [V]: Ripple DC 30 Siemens LV

90 SIDAC Specification Sheets Query Specification sheet for customised reactors Recipient Magnetronic Devices Fax: Tel: /-616/ Sender Company: Department: Name: City: Tel: Fax: Date: 3-phase Please specify all currents and voltages as r.m.s. DC reactors Commutation Output Filter reactors DC-link reactors) L 1 [mh]: U Dr [V]: L n [mh]: Qc [kvar]: I d1 [A]: u D [%]: P nmot [kw]: L n [mh]: L 2 [mh]: I n [A]: f max [Hz]: I n,eff [A]: I d2 [A]: I max [A]: U line [V]: U line [V]: I therm [A]: U line [V]: f clock1 [Hz]: f line [Hz]: U line [V]: f line [Hz]: I n1 [A]: Reactance [%]: Ripple Harmonics *) f clock2 [Hz]: Fundamental and harmonic component DC link I 1 [A]: f 1 [Hz]: I n2 [A]: U 1[%] = I 1[%] 300 I 2 [A]: f 2 [Hz]: f clock3 [Hz]: U 3[%] = I 3[%] 30 I 3 [A]: f 3 [Hz]: I n3 [A]: U 5[%] = I 5[%] = I 4 [A]: f 4 [Hz]: U 7[%] = I 7[%] = I 5 [A]: f 5 [Hz]: U 11[%] = I 11[%] = *) List other currents and frequencies below U 13[%] = I 13[%] = General Information Ambient temperature: Operating mode: Degree of protection: Continuous ON-time Footprint Varying load according to Acc. to customer specifications 13 Please enter any alternative or supplementary data on converters and motors: Converter Motor Rated power P n [kw]: P n [kw]: h: I noutput [A]: Operating load in [%] of P n : U N [V] = I n [A] = p.f.: = U DC link [V]: M = constant Permitted overload in [%] of I noutput : M ~ n 2 (fan, pump) r.p.m. n : r.p.m. operation : from: to: Special features/comments: Scheduled delivery date: No. of items: per annum/per order Target price: Dimensional Load Electrical data of 13/2 Siemens LV

91 SIDAC Specification Sheets Query Specification sheet for customised smoothing reactors, selectable inductance and current Recipient Magnetronic Devices Fax: Tel: /-616/ Sender Company: Department: Name: City: Tel: Fax: Date: Smoothing reactors with selectable inductance and current Please specify all currents and voltages as r.m.s. values! Iron-core smoothing reactors Iron-core smoothing reactors Smoothing air-core reactors Rated direct current I dn [A] Inductance [mh] I x = I dn L x = L 0 I x > I dn L x ˆL 0 for I dn Inductance L x [mh] for I x (I max ) Inductance L 0 [mh] for I d = 0A Connection of converter No-load voltage of converter U di [V] Line frequency f [Hz] Ambient temperature Additional information 1) mandatory mandatory mandatory 1) If you have any special requirements with regard to degree of soiling, reference voltage for the rating of insulation, etc., please enter in the Comments box Special features/comments: 13 Scheduled delivery date: No. of items: per annum/per order Target price: Dimensional Load Electrical data of Siemens LV /3

92 SIDAC Specification Sheets Query Specification sheet for customised radio interference suppression filters Recipient Magnetronic Devices Fax: Tel: /-616/ Sender Company: Department: Name: City: Tel: Fax: Date: Application: Please specify currents and voltages as r.m.s. Radio interference DIN EN suppression filters P nfu [kw]: Adherence to interference level: I n A Industry, DIN EN "Second environment" U line B Living and business, DIN EN "First environment" I deriv [ma]: f line [Hz]: Optional Commutation reactors: Optional Output u D = D = u D = % f max [Hz]: f clock [Hz]: Maximum desired length of motor supply cable Shielded Unshielded cable Cable type = Capacitance if known: L [mh/m]= C [nf/m] = General Information: Ambient temperature: Operating mode: Degree of protection: Continuous ON-time Footprint Varying load according to Acc. to customer specifications 13 Please enter any alternative or supplementary data on converters and motors: Converters Motor Rated power P n [kw]: P n [kw]: h: I noutput [A]: Operating load in [%] of P n : U n [V]: I n [A]: p. f.: U DC link [V]: M = constant Permitted overload in [%] of I noutput : M ~ n 2 (fan, pump) r.p.m. n : r.p.m. operation : from: to: Special features/comments: Scheduled delivery date: No. of items: per annum/per order Target price: Dimensional Load Electrical data of 13/4 Siemens LV

93 SIDAC Specification Sheets Query Specification sheet for customised dv/dt filters Recipient Magnetronic Devices Fax: Tel: /-616/ Sender Company: Department: Name: City: Tel: Fax: Date: Application: Please specify currents and voltages as r.m.s. dv/dt filters P nfu [kw]: I n [A]: U sys [V]: f max [Hz]: f clock [Hz]: Maximum desired length of motor supply cable Shielded Unshielded cable Cable type = Capacitance if known: L [mh/m]= C [nf/m] = General Information Ambient temperature: Operating mode: Degree of protection: Continuous ON-time Footprint Varying load according to Acc. to customer specifications Please enter any alternative or supplementary data on converters and motors: Converters Motor Rated power P n [kw]: P n [kw]: h: I noutput [A]: Operating load in [%] of P n : U n [V]: I n [A]: p. f.: U DC link [V]: M = constant Permitted overload in [%] of I noutput : M ~ n 2 (fan, pump) r.p.m. n : r.p.m. operation : from: to: 13 Special features/comments: Scheduled delivery date: No. of items: per annum/per order Target price: Dimensional Load Electrical data of Siemens LV /5

94 SIDAC Specification Sheets Query Specification sheet for customised sinewave filters Recipient Magnetronic Devices Fax: Tel: /-616/ Sender Company: Department: Name: City: Tel: Fax: Date: Application: Please specify currents and voltages as r.m.s. Sinewave filters P nfu [kw]: I n [A]: U line [V]: f max [Hz]: f clock [Hz]: Maximum desired length of motor supply cable Shielded Unshielded cable Cable type = Capacitance if known: L [mh/m]= C [nf/m] = General Information Ambient temperature: Operating mode: Degree of protection: Continuous ON-time Footprint Varying load according to Acc. to customer specifications 13 Please enter any alternative or supplementary data on converters and motors: Converters Motor Rated power P n [kw]: P n [kw]: h: I noutput [A]: Operating load in [%] of P n : U n [V]: I n [A]: p. f.: U DC link [V]: M = constant Permitted overload in [%] of I noutput : M ~ n 2 (fan, pump) r.p.m. n : r.p.m. operation : from: to: Special features/comments: Scheduled delivery date: No. of items: per annum/per order Target price: Dimensional Load Electrical data of 13/6 Siemens LV

95 SIDAC Accessories 14 Terminal covers 14/2 Selection and ordering data Siemens LV

96 SIDAC Accessories Terminal covers Selection and ordering data Version DT Order No. PS* Weight per PU approx. kg Terminal covers to protect against accidental contact with free bar connections (DIN VDE 0106 Part 100) The covers are suitable for all reactors and filters with 1-hole flat terminations. The assignment of the terminal covers to the reactors and filters can be carried out by the diameter of the flat connector hole, see "Configuration notes". Unless stated otherwise in the technical specifications, using the covers provides back-of-hand protection against accidental contact 3TX B with live parts according to BGV A2. Can be screwed onto free screw ends. Covers one rail connection (1 set = 6 items). M6 B 3TX B 1 set M8 B 3TX B 1 set M10 B 3TX B 1 set M12 D 3TX B 1 set /2 Siemens LV * This quantity or a multiple thereof can be ordered.

97 SIDAC Configuration Notes 15 Technical information 15/2 Reactors Commutation reactors for converters 15/4 Single-phase reactors 15/5 Three-phase reactors Iron-core output reactors 15/5 Three-phase reactors Mains reactors for frequency converters 15/8 Three-phase reactors Iron-core smoothing reactors 15/12 Single-phase reactors Smoothing air-core reactors 15/17 Single-phase reactors Filter reactors 15/18 Three-phase reactors Sinewave filters 15/19 Three-phase filters Radio interference suppression filters 15/20 Single-phase filters 15/22 Three-phase filters DA l 1 d 1 n 2 n 4 l 2 Siemens LV

98 SIDAC Configuration Notes Technical Information Reactors General Deviations of rated values at site altitudes > 1000 m Reduction of the rated voltage and rated current, depending on the site altitude and coolant temperature Max. permissible current 100 % EP series C 80 Coolant temperature 4EU series Deviation of the permissible direct current of rated direct current I dn, or permissible alternating current of rated alternating current I n (at coolant temperatures ž 40 C) Characteristic curve 74 applies to reactors 4EU, 4ET, 4PK Characteristic curve 72 applies to reactors 4EP, 4EM, 4EF11 Max. permissible current 100 % Deviation of permissible direct current of rated direct current I dn, or permissible alternating current of rated alternating current I n (at site altitudes > 1000 m above sea level) PD30_00054 PD30_ m 5000 Site altitude Inductance curve Commutating reactors and mains reactors Commutating reactors and mains reactors differ greatly with regard to the inductance curve. The inductance is almost constant through to the rated current I Ln, Mains reactors still have 90% of their rated inductance at a 1.6-fold rated current I Ln. Commutating reactors have a residual inductance of 60% at a 2.0-fold rated current I Ln. Typical inductance curves over the reactor current are shown in the following illustrations: N ' & $ " Typical curve of the inductance of a mains reactor over the reactor current N & $ " 2,! # % $! " 2,! # & Max. permissible rated voltage 100 % ! " Typical curve of the inductance of a commutating reactor over the reactor current m 5000 Site altitude Reduction of rated voltage for insulation (at site altitudes > 2000 m above sea level) PD30_ /2 Siemens LV

99 SIDAC Configuration Notes Technical Information Reactors Voltage drop D U or reference voltage drop u D In the case of three-phase reactors, the voltage drop D U per reactor phase when loaded with the maximum continuous thermal current I thmax and line frequency f =50Hz or 60Hz. The percent voltage drop u D can be calculated using the following formula: For converter connection B6 u D % U q100q 3 U N in % The inductance per reactor phase is as follows: % U Lx I qx thmax Recommended supply voltage U N, reference voltage drop u D and insulation rating The "Selection and ordering data" table specifies a recommended supply voltage U N for the reactors. The percent voltage drops u D assigned to the reactors apply to the relevant recommended supply voltage U N. The rated voltage for the insulation specified in the "Selection and ordering data" table also allows the use of reactors at voltages that deviate from the recommended supply voltage U N, but that are smaller or the same as the rated voltage of the insulation. The reference voltage drop u D then changes and can be calculated using the formula shown in the Section "Voltage drop D U or reference voltage drop u D ". A reactor with the reference voltage drop u D specified as a percent value has the same effect on the system as a transformer with the same u K. w =2p x f with f = line frequency (50 Hz or 60 Hz) 15 Siemens LV /3

100 SIDAC Configuration Notes Commutation Reactors for Converters Single-phase reactors Dimensional drawings e 1 PD30_00012 h 1 DA n 1 d 3 4EM (I Ln ˆ 20 A) n 2 d 1 d 2 l 2 n 1 b 1 n 2 Mounting holes 4EM (I Ln ˆ 20 A) 4EM (I Ln 22.4 to 40 A) Terminal 8WA9 200 Terminal RKW 110 or TRKSD 10 Cross-sections: solid: 0.5 mm 2 to 6 mm 2 Cross-sections: solid: 1 mm 2 to 16 mm 2 finely stranded: 1.5 mm 2 to 4 mm 2 finely stranded: 1 mm 2 to 10 mm 2 b d d d e h l n n Type Rated alternating current I Ln max 1 max 2 max 1 2 Rated alternating current for terminal connections, for user-defined arrangement of reactors 4EM46 up to 40 A M EM47 up to 40 A M EM48 up to 40 A M EM49 up to 40 A M EM50 up to 40 A M EM51 up to 40 A M EM52 up to 40 A M EM61 up to 40 A M e 2 PD30_00014 h 1 DA n 1 d 3 4EM (I Ln 22 to 50 A) n 2 d 1 d 2 l 2 n 1 b 1 n 2 Mounting holes 4EM (I Ln 22 to 50 A) Terminal 8WA1 204 Cross-sections: solid: 0.5 mm 2 to 6 mm 2 stranded: 10 mm 2 to 25 mm 2 finely stranded: 2.5 mm 2 to 16 mm 2 15 Type Rated alternating current I Ln b 1 d 1 d 2 d 3 e 2 max h 1 max l 2 max n 1 n 2 Rated alternating current for terminal connections, for user-defined arrangement of reactors 4EM49 22 to 50 A M EM50 22 to 50 A M EM51 22 to 50 A M EM53 22 to 50 A M EM61 22 to 50 A M EM62 22 to 50 A M /4 Siemens LV

101 SIDAC Configuration Notes Commutation Reactors for Converters/Iron-core Output Reactors Three-phase reactors DA l 1 e h DA l 1 e h d 1 d 2 d 1 d 2 n 2 n 4 l 2 n 1 n 3 b 1 n 2 n 4 l 2 n 1 n 3 b 1 4EP ˆ 40 A 4EP 41 A to 50 A Terminal RKW110 or TRKSD10 Terminal 8WA1 304 (for I Ln ˆ 40 A) (for I Ln = 41 to 50 A) Cross-sections: solid: 1 mm 2 to 16 mm 2 Cross-sections: solid: 1 mm 2 to 16 mm 2 finely stranded: 1 mm 2 to 10 mm 2 stranded: 10 mm 2 to 25 mm 2 finely stranded: 2.5 mm 2 to 16 mm 2 Ground stud M6 x 12 Corresponding ground terminal EK16/35 Cross-sections: solid: 2.5 mm 2 to 10 mm 2 Cross-sections: solid: 2.5 mm 2 to 16 mm 2 finely stranded: 4 mm 2 to 10 mm 2 finely stranded: 4 mm 2 to 16 mm 2 b d d d e h l l n n n n Type Rated alternating current I Ln Rated alternating currents for terminal connections 4EP36 up to 40 A M EP37 up to 40 A M EP38 up to 40 A M EP39 up to 40 A M EP40 up to 40 A M EP A M EP A M EP A M EP A M Arrangement of 4EP reactors: User-defined for commutating reactors For iron-core output reactors, see drawing 2,! & 2,! ' 15 = EHB M Permissible arrangement of iron-core output reactors, vertical = EHB M Permissible arrangement of iron-core output reactors, horizontal Siemens LV /5

102 he SIDAC Configuration Notes Commutation Reactors for Converters/Iron-core Output Reactors Three-phase reactors DA a l 1 DA a d 1 d 2 d 3 n 1 n 3 4EP > 51 A n 2 n 4 l 2 n 1 n 3 b 1 Mounting holes n 2 n 4 n 1 and n 2 mounting holes according to DIN n 3 and n 4 mounting holes according to EN Flat termination Type Rated alternating current I Ln b 1 d 1 d 2 d 3 e h l 1 l 2 n 1 n 2 n 3 n 4 Rated alternating currents for flat termination 4EP37 over 51 A M EP38 over 51 A M EP39 over 51 A M EP40 over 51 A M DA n 1 d 3 n 2 4EU24 to 4EU36 Mounting holes 15 Type b 1 d 1 d 2 d 3 e 1 max e 2 max e 3 max h max l 1 l 2 l 4 l 5 n 1 n 2 Ground for 4EU24 to 4EU36 with flat terminations, for arrangement of reactors on horizontal surfaces 4EU M M6 4EU M M6 4EU M M6 4EU30 (Cu) M M6 4EU M M6 4EU36 (Cu) M M8 4EU M M8 15/6 Siemens LV

103 SIDAC Configuration Notes Commutation Reactors for Converters/Iron-core Output Reactors Three-phase reactors l 4 DA a e l 1 h DA d 4 d 4 n 1 d 1 d 2 d 3 4EU39 to 4EU51 n 2 l 2 n 1 b 1 n 2 Mounting holes Type b 1 d 1 d 2 d 3 e 1 max e 2 max e 3 max h max l 1 l 2 l 4 l 5 n 1 n 2 Ground for 4EU39 to 4EU51 with flat terminations, for arrangement of reactors on horizontal surfaces 4EU M M6 4EU M M6 4EU M M6 4EU M M6 4EU M M12 4EU M M12 Version up to 1000 A Version > 1000 A Flat termination a 1 a 2 a 3 a 3 a 4 a 5 a 6 a 7 a 8 max. Al Cu for 4EU24 to 4EU36 with flat terminations, for arrangement of reactors on horizontal surfaces ˆ $ ˆ $ ˆ $ ˆ $ ˆ $ ˆ $ for 4EU39 to 4EU51 with flat terminations, for arrangement of reactors on horizontal surfaces ˆ $ ˆ $ ˆ $ ˆ $ ˆ $ ˆ $ ˆ $ Siemens LV /7

104 SIDAC Configuration Notes Mains Reactors for Frequency Converters Three-phase reactors DA l 1 e h DA l 1 e h d 1 d 2 d 1 d 2 n 2 n 4 l 2 n 1 n 3 b 1 n 2 n 4 l 2 n 1 n 3 b 1 4EP ˆ 35 A 4EP 40 A to 50 A Terminal 8WA9 200 Terminal 8WA1 304 (for I Ln ˆ 15 A) (for I Ln = 40 A to 50 A) Cross-sections: solid: 0.5 mm 2 to 6 mm 2 Cross-sections: solid: 1 mm 2 to 16 mm 2 finely stranded: 1.5 mm 2 to 4 mm 2 stranded: 10 mm 2 to 25 mm 2 finely stranded: 2.5 mm 2 to 16 mm 2 Terminal RKW110 or TRKSD10 Corresponding ground terminal EK16/35 (for I Ln ˆ 16 to 35.5 A) Cross-sections: solid: 2.5 mm 2 to 16 mm 2 Cross-sections: solid: 1 mm 2 to 16 mm 2 finely stranded: 4 mm 2 to 16 mm 2 finely stranded: 1 mm 2 to 10 mm 2 Ground stud M6 x 12 Cross-sections: solid: 2.5 mm 2 to 10 mm 2 finely stranded: 4 mm 2 to 10 mm 2 Type b 1 d 1 d 2 d 3 e h l 1 l 2 n 1 n 2 n 3 n 4 I Ln ˆ 35 A, terminal connections for user-defined arrangement of reactors 4EP M ) ) 4EP M ) 4EP M EP M EP M EP M EP M EP M EP M I Ln 40 A to 50 A, terminal connections for user-defined arrangement of reactors 4EP M EP M EP M EP M ) Fixing slot in the base centre 15 15/8 Siemens LV

105 he SIDAC Configuration Notes Mains Reactors for Frequency Converters Three-phase reactors DA a l 1 DA a d 1 d 2 d 3 n 1 n 3 n 2 n 4 l 2 n 1 n 3 b 1 n 2 n 4 4EP 51 A Mounting holes n 1 and n 2 mounting holes according to DIN n 3 and n 4 mounting holes according to EN Type b 1 d 1 d 2 d 3 e h l 1 l 2 n 1 n 2 n 3 n 4 I Ln 51 A, flat termination for user-defined arrangement of reactors 4EP M EP M EP M Flat termination I Ln a 1 a 2 a 3 a 4 a 5 Flat termination 51 to 80 A to 200 A Siemens LV /9

106 SIDAC Configuration Notes Mains Reactors for Frequency Converters Three-phase reactors DA n 1 d 3 4EU24 to 4EU36 n 2 Mounting holes Type b 1 d 1 d 2 d 3 e 1 max e 2 max e 3 max h max I 1 l 2 l 4 l 5 n 1 n 2 Ground for 4EU24 to 4EU36 with flat terminations, for arrangement of reactors on horizontal surfaces 4EU M M6 4EU M M6 4EU M M6 4EU M M6 4EU36 (Cu) M M8 4EU M M8 l 4 DA a e l 1 h DA d 4 d 4 n 1 d 1 d 2 d 3 4EU39 to 4EU51 n 2 l 2 n 1 b 1 n 2 Mounting holes Type b 1 d 1 d 2 d 3 e 1 max e 2 max e 3 max h max I 1 l 2 l 4 l 5 n 1 n 2 Ground for 4EU39 to 4EU52 with flat terminations, for arrangement of reactors on horizontal surfaces 4EU M M6 4EU M M6 4EU M M6 4EU M M6 4EU M M12 4EU M M /10 Siemens LV

107 SIDAC Configuration Notes Mains Reactors for Frequency Converters Three-phase reactors Version up to 1000 A Version > 1000 A Flat termination a 1 a 2 a 3 a 3 a 4 a 5 a 6 a 7 a 8 max Al Cu for 4EU24 to 4EU36, for arrangement of reactors on horizontal surfaces ˆ 80 A ˆ 200 A ˆ 315 A ˆ 800 A ˆ 1000 A ˆ 1600 A for 4EU39 to 4EU52, for arrangement of reactors on horizontal surfaces 45 A to 80 A A to 200 A A to 315 A A to 800 A A to 1000 A A to 1600 A Siemens LV /11

108 SIDAC Configuration Notes Iron-core Smoothing Reactors Single-phase reactors e 1 PD30_00012 h 1 DA n 1 d 3 4EM ˆ 40 A n 2 d 1 d 2 l 2 n 1 b 1 n 2 Mounting holes Terminal 8WA9 200 (for I dn = 21 A) Cross-sections: solid: 0.5 mm 2 to 6 mm 2 finely stranded: 0.5 mm 2 to 4 mm 2 Terminal RKW110 or TRKSD10 (for I dn = 22 A to 40 A) Cross-sections: solid: 1 mm 2 to 16 mm 2 finely stranded: 1 mm 2 to 10 mm 2 Type b 1 d 1 d 2 d 3 e 1 h 1 l 2 n 1 n 2 Rated direct current I dn ˆ40 A, with terminal connections, for user-defined arrangement of reactors 4EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M /12 Siemens LV

109 SIDAC Configuration Notes Iron-core Smoothing Reactors Single-phase reactors a 1 a 2 e 1 PD30_00015 d4 s 1 h 1 DA n 1 d 3 4EM > 40 A n 2 d 1 d 2 l 2 n 1 b 1 n 2 Mounting holes Type b 1 d 1 d 2 d 3 e 1 e 1 h 1 l 2 n 1 n 2 (up to 200 A) (up to 400 A) Rated direct current I dn > 40 A with flat terminations, for user-defined arrangement of reactors 4EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M EM M Rated current up to a 1 a 2 d 4 s 1 Flat termination 100 A A A Siemens LV /13

110 D SIDAC Configuration Notes Iron-core Smoothing Reactors Single-phase reactors " > >! " DA n 1 d > $ 2,! n 2 Version 4ET36 to 4ET47 (shown without terminals) Version 4ET25 to 4ET30 (shown without terminals) Mounting holes Terminal 8WA DG11 (for I dn = 21 A) b 3 = 30 mm Cross-sections: solid: 0.5 mm 2 to 6 mm 2 finely stranded: 0.5 mm 2 to 4 mm 2 Terminal 8WA DH11 (for I dn = 22 to 27 A) b 3 = 30 mm Cross-sections: solid: 0.75 mm 2 to 10 mm 2 finely stranded: 1.5 mm 2 to 6 mm 2 Terminal 8WA1 204 (for I dn = 20 to 50 A) b 3 = 38 mm Cross-sections: solid: 1.0 mm 2 to 16 mm 2 stranded: 10 mm 2 to 25 mm 2 finely stranded: 2.5 mm 2 to 16 mm 2 Type b 1 b 2 d 1 d 2 d 3 h l 1 l 2 l 4 n 1 n 2 b 3 Rated direct current I dn ˆ 50 A, with terminal connections, for arrangement on horizontal surfaces 4ET M See 4ET M terminals 4ET M above 4ET M ET M ET M ET M ET M /14 Siemens LV

111 D D SIDAC Configuration Notes Iron-core Smoothing Reactors Single-phase reactors " A " DA D! n 1 d Version 4ET36 to 4ET47 > $ 2,! Version 4ET25 to 4ET30 n 2 Mounting holes Type b 1 d 1 d 2 d 3 h h 2 h 3 l 1 l 2 l 4 n 1 n 2 e Rated direct current I dn > 50 A, for arrangement on horizontal surfaces 4ET M ET M ET M ET M ET M ET M ET M ET M Flat termination 4ET36 to 4ET47, 4ET25 to 4ET30 Rated current up to a 1 a 2 a 3 a 4 a 5 Flat termination 200 A A A DA n 1 d 3 4ET51 to 4ET65 n 2 Mounting holes Type b 1 b 2 d 1 d 3 h l 2 l 3 n 1 n 2 e Rated direct current I dn > 50 A, for arrangement on horizontal surfaces 4ET M ET M ET M ET M ET M ET M ET M ET M ET M ET M ET M ET M ET M Siemens LV /15

112 SIDAC Configuration Notes Iron-core Smoothing Reactors Single-phase reactors e h b 2 DA n 1 d 3 M16 n 1 l 2 l 1 d 1 n 2 b 1 DA n 2 4ET72 to 4ET80 Mounting holes Type b 1 b 2 d 1 d 3 h l 1 l 2 n 1 n 2 e Rated direct current I dn > 50 A, for arrangement on horizontal surfaces 4ET ET ET ET ET ET ET a) b) DA a 5 a 6 a 4 a 7 a 1 a 2 a 3 Rated current up to a 1 a 2 a 3 a 4 a 5 a 6 a 7 a) Flat termination 100 A A A A A A b) Flat termination 1250 A A c) Flat termination 2500 A a 5 c) DA a 7 a 4 a 1 a 6 a 2 a /16 Siemens LV

113 a 3 SIDAC Configuration Notes Smoothing Air-core Reactors Single-phase reactors Flat terminations a 1 a 2 h DA A DA A l 2 l DA ' d 1 d 2 l 1 l A DA A DA PK40, 4PK60 Type a 1 a 2 a 3 d 1 d 2 h l 1 l 2 4PK40 Position of connections as agreed PK60 with the customer Ironless zone Distance between two reactors axial 500 axial 500 radial 300 radial Siemens LV /17

114 SIDAC Configuration Notes Filter Reactors Three-phase reactors I eff < 15 A: Terminal 4 mm 2 15 A < I eff < 48 A: Terminal 10 mm 2 for user-defined arrangement of reactors 4EP37 to 4EP44 Type b 1 b 2 d 1 d 2 d 3 e max h max l 1 max l 2 n 1 n 2 n 3 n 4 4EP M EP M EP M EP M EP M EP M Version with terminal 10 mm 2 for arrangement of reactors on horizontal surfaces 4EU27 Type b 1 b 2 d 1 d 2 d 3 e max h max l 1 max l 2 l 4 n 1 n 2 4EU M Version with flat termination for arrangement of reactors on horizontal surfaces 15 4EU25 to 4EU39 Type b 1 b 2 d 1 d 2 d 3 e h l 1 l 2 l 4 n 1 n 2 4EU M EU M EU M EU M EU M /18 Siemens LV

115 SIDAC Configuration Notes Sinewave Filters Three-phase filters PE b 2 d n 3 n 4 h D 4EF11 (for drives from 1.5 kw to 7.5 kw) n 4 l 2 n 3 b 1 b PD30_ ,! $ " > > 4EF11 (for drives from 11 kw to 75.0 kw) Drawing example, solution with 3 capacitors possible whereby the outline dimensions do not change for filters with I thmax to b max b 1 b 2 max d h max l 2 n 3 n 4 Ground 4EF11 sinewave filter for drives with 1.5 kw to 7.5 kw drive power, user-defined arrangement 6 A M M6 10 A M M A M M6 for filters with I thmax to b max b 1 b 2 d h max l 2 l 4 max n 1 n 2 Ground 4EF11 sinewave filter for drive with 11 kw to 75 kw drive power, for arrangement of the filter on horizontal surfaces 26 A M M6 38 A M M6 48 A M M6 63 A M M6 90 A M M6 150 A M M8 15 Siemens LV /19

116 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase filters Typical circuit diagram LINE L LOAD L N N PD30_ EF AA00, 4EF AA00 Dimensions ,5 User-defined mounting Terminals 4 mm 2 PD30_ ,8 7, , PE M4x15 LINE Marking LOAD 60, , ,7 4EF AA00 Terminals 4 mm 2 PD30_ Marking LINE LOAD Terminals 4 mm User-defined mounting 24 PE M5x EF AA /20 Siemens LV

117 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase filters Typical circuit diagram LINE LOAD L L N N PD30_ EF AA00, 4EF AA00, 4EF AA00, 4EF AA00 Dimensions 20,5 32 max. 61max. User-defined mounting 144 max. 70 PD30_ max. 113 max. 31 max. L N PE LINE Marking LOAD L N PE Terminal blocks 4 mm 5,8 121 max. 4EF AA00, 4EF AA00, 4EF AA PD30_ max. User-defined mounting PE M6x max. 70 0,8 31 max. 86 max. 113 max. 15 PE N L1 LINE Marking LOAD L1 N PE Terminal block 10 mm max. 5, EF AA00 Siemens LV /21

118 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Typical circuit diagram LINE L1 LOAD L1 L2 L2 L3 L3 4EF AA EF AA10, 4EF AA10 PD30_00026 Dimensions 8 133,7 PE M4x Terminals 4 mm 2 PD30_ ,5 1, L1 L2 L3 Marking LINE LOAD L1' L2' L3' User-defined mounting EF AA10 9 PE M5x15 199,5 60 PD30_00038 Terminals 4 mm2 4,5 1, ,4 38 L1 L2 L3 LINE Marking LOAD L1' L2' L3' User-defined mounting EF AA /22 Siemens LV

119 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters 9 PE M5x15 199,5 8 PE M6x PD30_00050 Terminals 4 mm 2 1,5 4, PD30_00051 Terminals 10 mm2 4,5 1, ,4 38 4EF AA10 L1 L2 L3 LINE Marking LOAD L1' L2' L3' L1 L2 L3 LINE 4EF AA10, 4EF AA10 Marking L1' L2' LOAD L3' User-defined mounting User-defined mounting PE M6x ,5 35 Terminals 16 mm2 L1 L2 L3 LINE Marking LOAD PD30_00043 L1' L2' L3' 4,5 1,5 User-defined mounting EF AA PD30_00045 PE M10x Terminals 35 mm2 L1 L2 L3 L1' Marking L2' LINE LOAD L3' 6,5 60 User-defined mounting EF AA10 Siemens LV /23

120 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Typical circuit diagram LINE L1 LOAD L1 L2 L2 L3 L3 4EF AA EF AA10, 4EF AA10 PD30_00026 Dimensions PE M10x34 1, PD30_ Terminals 35 mm2 6,5 User-defined mounting L1 L2 L3 Marking LINE LOAD L1' L2' L3' EF AA10 Terminals 50 mm , PE M10x L1 L2 L Marking LINE LOAD L1' L2' L3' 6,5 65 PD30_00044 User-defined mounting 4EF AA10 15/24 Siemens LV

121 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Typical circuit diagram LINE L1 L2 L3 LOAD L1 L2 L3 PD30_ EF AA10 Dimensions Terminals 95 mm Strand End sleeve L3' 220 L2' L1' PE 4EF AA10 PE M10x35 L1 L2 L Marking LINE LOAD PD30_00031 Strand designation User-defined mounting 15 Siemens LV /25

122 #! # # SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Typical circuit diagram LINE L1 L2 L3 LOAD L1 L2 L3 PD30_ EF AA10, 4EF AA10 Dimensions!! " " ' # # ' # " ' % $ 2,!! '! " # = H E C 1 - ), $ $! # # % " ' % & $ 2,! "! % = H E C 1 - ),!! $ # ' 4EF AA10 User-defined mounting 4EF AA10, 4EF AA10 User-defined mounting " "! # ' # % & 15 " ' 2,! #! % = H E C 1 - ),! $ # ' User-defined mounting $! 4EF AA10 15/26 Siemens LV

123 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters " # & # # "! # $ "! % & ' % # " User-defined mounting " 2,! "! = H E C 1 - ),! "! 4EF AA10 ' ' " " # " & ' % # " User-defined mounting " 2,! "! = H E C 1 - ),!! # $ "! 4EF AA10 15 Siemens LV /27

124 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Typical circuit diagram LINE L1 L2 L3 LOAD L1 L2 L3 4EF AA10, 4EF AA10 PD30_00024 Dimensions Terminals 4 mm 2 Strand ,5 1 L3' L2' L1' PE PD30_00047 PE M6x25 L2 L1 L Marking LINE LOAD 6,5 End sleeve Strand designation User-defined mounting 4EF AA10, 4EF AA10 Typical circuit diagram LINE L1 L2 L3 LOAD L1 L2 L3 4EF AA10, 4EF AA EF AA10 PD30_00025 Dimensions Terminals 6 mm 2 Strand L3' 150 L2' L1' PE M6x25 L1 L2 L Marking LINE LOAD PE End sleeve Strand designation User-defined mounting 4EF AA10, 4EF AA10 PD30_ /28 Siemens LV

125 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Typical circuit diagram LINE L1 L2 L3 LOAD L1 L2 L3 4EF AA10, 4EF AA EF AA10 PD30_00025 Dimensions Terminals 16 mm Strand L3' 150 L2' 75 L1' PE PE M6x End sleeve Strand designation 315 L1 L2 L3 Marking LINE LOAD User-defined mounting PD30_ EF AA Terminals 2 25 mm Litze L3' 150 L2' ,5 1 L1' PE PE M10x35 L1 L2 L Marking LINE LOAD End sleeve Strand designation User-defined mounting 4EF AA10 PD30_ Siemens LV /29

126 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters 80 2 Terminals 25 mm Strand L3' 200 L2' L1' PE EF AA10 PE M10x35 L1 L2 L Marking LINE LOAD PD30_00034 End sleeve Strand designation User-defined mounting Terminals 50 mm 2 Strand L3' L2' L1' PE 40 0, PE M10x35 L1 L2 L3 4EF AA10, 4EF AA Marking LINE LOAD PD30_ , End sleeve Strand designation User-defined mounting 110 Terminals 95 mm 2 Strand End sleeve L1' 220 L2' ,5 1 PE L3' 15 PE M10x Strand designation L1 L2 L3 Marking LINE LOAD 6, User-defined mounting 4EF AA10 PD30_ /30 Siemens LV

127 PD30_00059 SIDAC Components for Converters 16 Selection aids 16/2 Overview 16/2 Application 16/3 Technical specifications Configuration notes 16/6 Overview Power supply 3 AC Mains reactor Radio interference suppression filter AC frequency converter Output reactor Sinewave fil M ~ 3 AC Siemens LV

128 SIDAC Components for Converters Selection Aids Overview Power supply 3 AC Mains reactor Mains reactor Radio interference suppression filter AC frequency converter Radio interference suppression filter Output reactor Sinewave filter Output reactor PD30_00059 Sinewave filter ~ M 3 AC 16 Example: Components of a drive system A modern drive systems is an extremely complex system that must meet the highest demands, from the mains connection through to the motor. The frequency converter, which converts the system voltage to a three-phase system with variable frequency and permits motor operation with adjustable speed, is the key element. However, it is not enough just to select the right drive machine for the load cycle and a suitable frequency converter. As a rule, reactors and filters are essential for achieving optimum operation of a drive system. The catalogue LV60 contains all the components you require for your frequency converter. Application The reactor and filter components contained in the following assignment list are suitable for use with converters on standard asynchronous motors. If you have any queries regarding the use of reactor and filter components, please refer to the configuration examples in this chapter. These answer the most common questions regarding the assignment of components for converters: Why use reactors and filters? What information do we require for the selection of components for converters? How do I choose the right components for my drive system? When should I use which component in the converter system? Which reactor and which filter is the right one for my application? Please do not hesitate to contact us if you have any further questions or queries: MD_Anfrage@brmr.siemens.de Note: The following assignment list contains our recommendations on the best components for your converter. However, we can accept no liability for the use of components in your system. The components can be operated within the framework of the ratings specified on the rating plate. It is essential to ensure compliance with the restrictions specified in the technical specifications and the configuration notes of this catalogue. Failure to observe these restrictions may lead to malfunction of the converter system or even cause irreparable damage to individual components. The proper function of a converter system and all its components depends largely on the correct installation and commissioning of the components. For this purpose it is essential to read and observe the installation and commissioning instructions of the manufacturer. Failure to observe these instructions may lead to a malfunction of the converter system. 16/2 Siemens LV

129 SIDAC Components for Converters Technical specifications Selection Aids Three-phase mains reactors n a bc Motor output (typical) Mains reactor u D = 2% Power loss 50/60 Hz Max. continuous thermal current Mains reactor u D = 4% Power loss 50/60 Hz Max. continuous thermal current P motor at 400 V Order No. P V I thmax Order No. P V I thmax kw W A W A 50 Hz 400 V AC / 60 Hz 480 V AC EP US00 21/ EP US00 21/ EP US00 23/ EP US00 23/ EP US00 35/ EP US00 34/ EP US00 41/ EP US00 61/ EP US00 52/ EP US00 96/ EP US00 45/ EP US00 85/ EP US00 60/ EP US00 99/ EP US00 53/ EP US00 99/ EP US00 73/ EU UA00-0AA0 160/ EP US00 67/ EU UA00-0AA0 160/ EP US00 83/ EU UA00-0AA0 160/ EP US00 103/ EU UB00-0AA0 259/ EP US00 101/ EU UB00-0AA0 259/ EU UA00-0AA0 153/ EU UB00-0AA0 259/ EU UA00-0AA0 186/ EU UB00-0AA0 259/ EU UA00-0AA0 186/ EU UB00-0AA0 263/ EU UB00-0AA0 239/ EU UA00-0AA0 320/ EU UA00-0AA0 259/ EU UA00-0AA0 345/ EU UA00-0AA0 259/ EU UB00-0AA0 564/ EU UA00-0AA0 331/ EU UB00-0AA0 460/ EU UA00-1BA0 326/ EU UC00-1BA0 564/ EU UA00-0AA0 435/ For the complete range, see "Mains reactors for frequency converters". For further technical specifications see "Mains reactors for frequency converters". For terminal covers offering protection against accidental contact with flat terminations, see "Accessories". For configuration notes, such as dimensional drawings, mounting dimensions and connection dimensions, see "Configuration notes". 16 Siemens LV /3

130 SIDAC Components for Converters Selection Aids Three-phase radio interference suppression filters Motor output (typical) Radio interference suppression filter (A) Leakage current Max. continuous thermal current Radio interference suppression filter (B) Leakage current Max. continuous thermal current EMC filter EMC filter PD30_00060 PD30_00060 P motor at 400 V Recommended to achieve I ABL I thmax Recommended to achieve I ABL I thmax radio interference class A 1) 2) radio interference class B 2) kw Order No. ma A Order No. ma A 50/60 Hz 480 V/520 V AC 3) 2.2 4EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < EF AA10 < For the complete range, see "Radio interference suppression filters". For further technical specifications, see "Radio interference suppression filters". For configuration notes, such as dimensional drawings, mounting dimensions and connection dimensions, see "Configuration notes". 1) If a Class A radio interference suppression filter is already integrated in the converter, no further Class A radio interference suppression filters may be connected upstream. This would cause a malfunction of the converter system, which, in turn could damage components or even the converter itself. 2) Achievement of the radio interference class can only be verified within the overall system in conjunction with all the components used, e.g. according to EN (ISM devices). 3) For details on operational voltage, see Chapter "Radio interference suppression filters". Note: Radio interference suppression filters: The following generic parameters apply, which must not be exceeded: Maximum motor cable length 50 m If these do not meet your requirements, customised solutions are available. For further information contact: MD_Anfrage@brmr.siemens.de 16 16/4 Siemens LV

131 SIDAC Components for Converters Selection Aids Three-phase iron-core output reactors/ three-phase sinewave filters n a bc Motor output (typical) Iron-core output reactors Power loss Maximum continuous thermal current 4 khz 8 khz Sinewave filter Power loss Max. continuous thermal current P motor f clock 4 khz (8 khz) P V I thmax I thmax f clock 4 khz ˆ 8 khz P V I thmax at 400 V kw Order No. W A A Order No. W A 200 Hz 400 V/500 V AC + 5% 100 Hz 400 V/500 V AC + 10% EP ES EF GB EP ES EF GB EP ES EF GB EP FS EF GB EP BS EF GB EP CS EF GB EP CS EF GB EP AS EF GB EP RS EF GB EP RS EF GB EU ED00-4BA EF GB EU EE00-4BA EF GB EU EF00-4BA EF GB EU EB00-4BA EF GB EU EC00-4BA EF GB EU ED00-4BA EF GB For further technical specifications, see "Iron-core output reactors", or "Sinewave filters". For terminal covers offering protection against accidental contact with flat terminations, see "Accessories". For configuration notes, such as dimensional drawings, mounting dimensions and connection dimensions, see "Configuration notes". Note: Iron-core output reactors, sinewave filters: The following generic parameters apply, which must not be exceeded: Maximum motor cable length 200 m, shielded cable Maximum motor cable length 300 m, unshielded cable Maximum motor cable cross-sections for performance class: - up to 2.2 kw 1.5 mm², ->2.2kW ˆ 7.5kW/2.5mm² ->7.5kW ˆ 11 kw/4 mm² ->11kW ˆ 22 kw/10 mm² ->22kW ˆ 30 kw/16 mm² ->30kW ˆ 37 kw/25 mm² ->37kW ˆ 50 kw/35 mm² ->50kW ˆ 75 kw/70 mm² Maximum clock frequency 8 khz Maximum motor frequency of output reactor 200 Hz Maximum motor frequency of sinewave filter 100 Hz U N 3 AC 500 V +5% (+10% sinewave filter) If these do not meet your requirements, customised solutions are available. For further information contact: MD_Anfrage@brmr.siemens.de Note: Sinewave filters: Operation of the drive in Ex(d) range: If a sinewave filter is placed upstream of the Ex(d) motor at the converter, please contact us to find out more about the operating conditions. 16 Siemens LV /5

132 SIDAC Components for Converters Configuration Notes Overview Why use reactors and filters? Reactors and filters Reduce system harmonics Protect and save wear and tear of the converter Reduce the negative effects of converter feed on the motor, such as high voltage rising edges at the motor terminals or non-sinusoidal motor currents Using reactors and filters enables compliance with current standards and regulations, such as on circuit feedback. EN Electronic equipment for use in power installations EN Electromagnetic compatibility Part 3-2: Limits for harmonic current emissions EN Environment - Compatibility levels for low-frequency conducted disturbances and signalling in public low-voltage power supply systems. EN Adjustable speed electrical power drive systems Part 3: EMC product standard including specific test methods EN (draft) Limits for harmonic currents produced by equipment connected to public low-voltage systems with input current < 75 A per phase and which are subject to special terminal conditions What information do we require for the selection of components for converters? You require the following key data of the drive for further planning: Drive system Ratings Data source 1) System short-circuit power u K line =... % P Voltage (phase-to-phase) U line =... V P Frequency f =... Hz P Line current I line =... A U/P Input voltage U conv =... V U/P Rated converter output = P motor U drive power Clock frequency of the converter f clock =... khz U Rated output current I out =... A U Motor cable length l MC =... m P (shielded / unshielded) Motor output (rated output, P rat ) P motor =... kw P M 3~ Maximum motor frequency f max =... Hz P G_PD50_XX_00003a 1) The ratings can be taken or calculated from the project or plant data (P) or the converter data sheets (U). 16 The components used between the converter and the motor depend strongly on the following parameters: Motor cable length I MC, Clock frequency f clock, Motor frequency f max and Operational voltage. The output reactors and sinewave filters contained in the assignment tables are generally subject to the following generic parameters, which must not be exceeded: Maximum motor cable length 200 m, shielded cable Maximum motor cable length 300 m, unshielded cable Maximum motor cable cross-sections for performance class: - up to 2.2 kw 1.5 mm², ->2.2kW ˆ 7.5 kw/2.5 mm² ->7.5kW ˆ 11 kw/4 mm² ->11kW ˆ 22 kw/10 mm² ->22kW ˆ 30 kw/16 mm² ->30kW ˆ 37 kw/25 mm² ->37kW ˆ 50 kw/35 mm² ->50kW ˆ 75 kw/70 mm² Maximum clock frequency 8 khz Maximum motor frequency of output reactor 200 Hz Maximum motor frequency of sinewave filter 100 Hz U N 3 AC 500 V +5% (+10% sinewave filter) If these do not meet your requirements, customised solutions are available. For further information contact: MD_Anfrage@brmr.siemens.de 16/6 Siemens LV

133 SIDAC Components for Converters How do I choose the right components for my drive system? The selection of the components necessary for converters is described on the flow diagrams on the following pages. When should I use which component in the converter system? Components on the line-side of the frequency converter Configuration Notes - Line adaptation TN-system The conductive points of all electrical equipment must be linked to the earthed point of the supply system using PE conductors. IT-system IT systems are usually earthed. Outer conductors must not be directly earthed. U line matches U conv no Isolating transformer... Matching/autotransformer... all you transformer enquiries to: MD_Anfrage@brmr.siemens.de yes PD30_00061 No transformer required - Mains reactors for frequency converters Use of transformer 1) or u K -system >4% yes No mains reactor required No u K -system unknow or u K -system >1% < 4% yes 2% mains reactor 4EU... 4EP... No u K -system <1% 2) yes 4% mains reactor 4EU... 4EP... PD30_ ) Transformer directly assigned to the converter, u Kmin 3% 2) Apparent power of the upstream transformer S trans / P motor > Siemens LV /7

134 SIDAC Components for Converters Configuration Notes -Radio interference suppression filters No converter used in residential building or office? Yes Class B filter integrated in converter No Class B radio interference suppression filter 4EF15... Shielded motor cables required in order to comply with radio interference level B! Yes No radio interference suppression filter required No Industrial system with required radio interference level A Yes Is a Class A filter integrated in the converter 1) No Class A radio interference suppression filter 4EF15... PD30_00063 Yes No radio interference suppression filter required 1) If a Class A radio interference suppression filter is already integrated in the converter, no further Class A radio interference suppression filters may be connected upstream. This would cause a malfunction of the converter system, which, in turn could damage components or even the converter itself /8 Siemens LV

135 SIDAC Components for Converters Components on the load-side of the frequency converter - Selection of output reactor, sinewave filter Configuration Notes Is drive to be used in an Ex(d) range 1)? Yes 4EF11 sinewave filter... No Is drive to be used in the household, office or chemical industry 2)? Yes No is motor suitable for converters 3) No Yes Motor cable > 50 m shielded > 100 m unshielded No No iron-core output reactor or sinewave filter necessary G_PD30_DE_00064 Yes Iron-core output reactor 4EU... 4EP... 1) If a sinewave filter is placed upstream of the Ex(d) motor at the converter, please contact us to find out more about the operating conditions. 2) Household, office: low-noise, motor-driven, Chemistry: dv/dt ˆ 500 V/µs, total harmonic distortion < 10% 3) Siemens 1LA motors are suitable for converters. If there are no data on the dielectric properties of the motor, a sinewave filter should be used. 16 Siemens LV /9

136 SIDAC Components for Converters Configuration Notes Which reactor and which filter is the right one for my application? The correct reactors and filters for converters are assigned by Motor cable 200 m, shielded means of assignment lists. Motor electrically loads the output of the frequency converter Sample selection with project and converter data: with 25 kw System voltage 3 AC 400 V 50 Hz p.f. ~ 0.75 assumed 30 kw asynchronous motor at 30 kw frequency converter with f clock = 6 khz, 3 AC 400 V maximum 150 Hz Calculation of electrical values: values in bold print have been calculated P = U line x I out x»3 x p. f. I line I out x 1.1 I line dr I out x 0.9 Electrical load of the converter. Increased input current due to harmonics. I out calculated according to conversion of the formula Line current converter input without reactors and filters Using the reactor reduces the line current to at least 90% of the value without reactor Actual values 400 V x 48.1 A x»3 x 0.75 = 25 kw 48.1 A x 1.1 = 52.9 A 52.9 A x 0.9 = 47.6 A Max. values 400 V x 57.7 A x»3 x 0.75 = 30 kw 57.7 A x 1.1 = 63.5 A 63.5 A x 0.9 = 57.2 A Drive system M 3~ G_PD50_XX_00003a Converter data 1) Project data Calculated System short-circuit power u K line unknown Voltage (phase-to-phase) U line 400 V Frequency f 50/60 Hz 50 Hz Line current I line 63 A I line_reactor 47.6 A Input voltage U conv V 400 V Rated converter output = P motor 30 kw drive power Clock frequency of the converter f clock khz 6 khz Rated output current I out 60 A 400 V 4 khz I out 48.1 A Motor cable length I MC 200 m Motor output (rated output, P rat ) P motor 30 kw Maximum motor frequency f max 200 Hz 150 Hz Electrical load P elec 25 kw 1) Typical values of a standard converter, may vary from manufacturer to manufacturer /10 Siemens LV

137 SIDAC Components for Converters Configuration Notes According to the flow diagrams, the parameters specified in the sample selection produce the following recommended components: Components on the line-side of the frequency converter - Conditions: System short-circuit power unknown - which means: à Mains reactor for frequency converters à mains reactor u D = 2% Components on the load-side of the frequency converter - Conditions: No special operating conditions Motor is suitable for converters Motor cable length > 50 m (shielded) - The following is required: à iron-core output reactor The electric motor output 25 kw cannot be found in the selection table, the next largest output must be selected à 30 kw. Motor output (typical) Mains reactor u D = 2% Power loss 50/60 Hz Maximum continuous thermal current Mains reactor u D = 4% Power loss 50/60 Hz Max. continuous thermal current P motor P V I thmax P V I thmax at 400 V kw Order No. W A Order No. W A 50 Hz 400 V AC / 60 Hz 480 V AC EP US00 21/ EP US00 53/ EP US00 99/ EP US00 73/ EU UA00-0AA0 160/ EP US00 67/ EU UA00-0AA0 160/ EP US00 83/ EU UA00-0AA0 160/ EP US00 103/ EU UB00-0AA0 259/ Motor output (typical) Iron-core output reactor Power loss max. Maximum continuous thermal current 4 khz 8 khz Sinewave filters Power loss Max. continuous thermal current P motor f clock 4 khz (8 khz) P V I thmax I thmax f clock 4 khz ˆ 8 khz P V I thmax at 400 V kw Order No. W A A Order No. W A 200 Hz 400 V/500 V AC + 5% 100 Hz 400 V/500 V AC + 10% EP RS EF GB EU ED00-4BA EF GB EU EE00-4BA EF GB EU EF00-4BA EF GB EU EB00-4BA EF GB EU EC00-4BA EF GB EU ED00-4BA EF GB Calculation of the maximum permissible reactor current, deviating from I thmax at 4 khz. Taking as an example: 6 khz clock frequency of the converter: I thmax = f(khz) = i 4kHz (i 4kHz i 8kHz ) / 4 x (8 f clock [khz]) = f(6 khz) = 60 (60 54) / 4 x (8 6) = 57 A 16 Siemens LV /11

138 SIDAC Components for Converters Configuration Notes The ratings of the drive system must not exceed the technical product data within the bold borders. If a product assignment is not sufficiently unique, we recommend using the components of the next performance class up. Supply system 3 AC ~ M 3 AC line_reactor Mains reactor out Output reactor PD30_00065 The sample selection therefore produces the following components for the converter: Conditions: U line 3 AC 50 Hz 400 V, upstream system short-circuit power unknown I line_reactor (actual)= 47.6 A I line_reactor (max)= 57.2 A which means: mains reactor 4EP US00 U line 3 AC 400/480 V f max 50/60 Hz I thmax 63 A u D = 2% Conditions: f clock = 6 khz 200 m shielded motor cable I out (actual) = 48.1 A I out (max) = 57.7 A which means: iron-core output reactor 4EU EE00-4BA0 U line 3 AC 400/500 V f max 200 Hz I thmax 60 A / 54 A at f clock 4 khz / 8 khz Calculated: I thmax 57 A f clock 6 khz 200 / 300 m shielded / unshielded motor cable P electrical (actual)= 25 kw P motor (max) = 30 kw 16 16/12 Siemens LV

139 Annex 17 17/2 Ordering notes 17/4 Standards and approvals 17/8 Siemens contact 17/9 Service & support 17/10 Customer support 17/11 Index 17/12 Order number index 17/15 Conditions of sale and delivery Export regulations Siemens LV

140 Annex Ordering notes Logistics General Our logistics service ensures "quality from the time of ordering to delivery" regarding delivery service, communications and environmental protection. We concentrate on optimizing logistics processes by designing our infrastructure to customer requirements and implementing electronic order processing. Personal consulting, on-time delivery and limiting transport times to 1 day - within Germany - are essential to us. For this reason, we supply the preferred types marked with } from stock. The DIN-ISO-9001 approval and subsequent quality check are indispensable prerequisites for us. Electronic order processing is fast, cost-efficient and error-free. Please contact us if you want to benefit from these advantages. Packing, packing units The packaging in which our equipment is dispatched provides protection against dust and mechanical damage during transport thus ensuring that you receive our products in a perfect state. We select our packaging for maximum environmental compatibility and reusability (e.g. crumpled paper instead of polystyrene chips for protection during transport in packages up to 32 kg) and, in particular, with a view to reducing waste. With our multi-unit packaging, we offer you specific types of packaging that are both kind to the environment and tailored to your requirements: Your advantages at a glance: Lower ordering overhead Cost savings through uniform-type packaging: low/no disposal costs. Less time and personnel required thanks to short unpacking times. Delivery on time and direct to the production line reduces your inventories: Cost savings through reduction of storage area. Fast assembly thanks to supply in sets. Standardized Euro standard boxes corresponding to modules of the Euro range are suitable for most conveyor systems. Active contribution to environmental protection. Where nothing is stated to the contrary in the "Selection and ordering data" tables of this catalog, our products are supplied individually packed. For small parts/accessories, we offer you economical packing units as standard packs containing more than one item, e.g. 5, 10, 50 or 100 units. It is essential that whole number multiples of these quantities be ordered to ensure satisfactory quality of the products and problem-free order processing. The products are delivered in a neutral, white carton. The label includes warning notices, the CE mark, the open arrow recycling symbol, and product description information in English and German. In addition to the Order No. (MLFB) and the number of items in the packing, the Instr. Order No. is also specified for the operating instructions that you can order from your local Siemens branch. (For Siemens contact, see automation/partner). The device order nos. of most devices can also be acquired via the EAN barcode to simplify ordering and storage logistics. The assignment of order nos. to EAN codes is stored electronically in the master data of Low-voltage Controlgear, Switchgear and Systems Multi-unit and reusable packs Set deliveries (reusable, different devices) On request, we also deliver order-related packs of larger quantities of different unpacked devices in Euro standard boxes. For terms of delivery, for set deliveries or other types of delivery, such as container delivery/return delivery in Euro standard boxes/ multi-unit transport containers, please contact your local Siemens branch (please visit our Web site at automation/partner). To find out the location of your nearest contact). They will work out an agreement that best suits your individual requirements /2 Siemens LV

141 Annex Ordering notes Ag and Cu surcharges Surcharges for copper (Cu) and silver (Ag) will be added to the product prices; these surcharges will take the form of percentages of the list prices. Calculation of the surcharges will be governed by the official Ag quotation for refined silver and by the Cu-DEL quotation applying on the date of receipt of order or of call-off. The prices for products of catalogue LV 60 include the price of copper calculated on the basis of a list price of 150/100 kg.if the copper rate exceeds this price, a surcharge will be made on the basis of the current copper price in the month preceding the date of invoice. Orders for special designs For ordering products that differ from the versions listed in the catalog, the order number specified in the catalog must be supplemented with " Z"; the required features must be specified by means of the alphanumeric order codes or in plain text. Small orders When small orders are placed, the costs associated with order processing are greater than the order value. We recommend therefore that you combine several small orders. Where this is not possible, we unfortunately find it necessary to charge a processing supplement of to cover our costs for order processing and invoicing for all orders with a net goods value of less than Siemens LV /3

142 Annex Standards and approvals Overview IEC EN DIN VDE IEC EN Low-voltage controlgear and switchgear: General requirements IEC EN Circuit-breakers IEC EN Switches, disconnectors, switch-disconnectors and fuse-combination units IEC EN Contactors and motor starters: Electromechanical contactors and motor starters: IEC EN Contactors and motor starters: Semiconductor motor controllers and starters IEC EN AC semiconductor controllers and contactors for loads other than motors IEC EN Control circuit devices and switching elements: Electromechanical control circuit devices IEC EN Control circuit devices and switching elements: Proximity switches IEC EN Proximity switches (fault conditions) IEC EN EMERGENCY-STOP devices with mechanical latching IEC EN DC interface for proximity switches and switching amplifier (NAMUR) IEC EN Multifunctional controlgear and switchgear: Automatic transfer switch IEC EN Multifunctional controlgear and switchgear: Control and protection switchgear (CPS) IEC EN Ancillary equipment: Terminal blocks for copper conductors IEC EN Ancillary equipment: PE conductor terminal blocks for copper conductors IEC EN Ancillary equipment: Safety requirements for terminal blocks EN Actuator-Sensor Interface (AS-i) IEC EN Low-voltage fuses: General requirements IEC EN Low-voltage fuses: Supplementary requirements for fuse links for protecting semiconductor components IEC Terms for fuses IEC EN Low-voltage switchgear and controlgear assemblies: Type-tested and partially type-tested assemblies IEC Sect Part 302 Thermal protection for electrical rotating machines; Temperature sensors and tripping units IEC Sect Part 303 Thermal protection for electrical rotating machines; PTC thermistors and tripping units EN Optocouplers for safe electrical isolation: Requirements, tests EN Part 100 Protection against electric shock: Location of actuators near live parts EN Part 101 Protection against dangerous shock currents: Basic requirements for safe isolation in electrical equipment IEC Insulation coordination for equipment within low-voltage systems; basic principles, requirements and tests IEC EN Electrical equipment of machines: General requirements EN Equipment of electrical power installations with electronic equipment EN Electrical apparatus in potentially explosive atmospheres EN Electrical apparatus for potentially explosive atmospheres IEC EN Electrical relays without a fixed time response IEC EN Electrical relays, specified-time relays EN Connecting materials: Safety requirements for screw terminals and screwless terminals for copper electrical conductors IEC EN Safety of transformers, power supply units and similar: IEC EN Particular requirements for line transformers for general use IEC EN Particular requirements for control-power transformers IEC EN Particular requirements for isolating transformers for general use IEC EN Particular requirements for safety isolating transformers for general use IEC Power transformers 0552 Specifications for variable transformers with moving contacts perpendicular to the coiling direction IEC EN Electromagnetic compatibility (EMC); Part 4: Testing and measuring techniques; Main Section 1: Overview of measuring techniques for interference immunity; Basic EMC standard IEC EN Electromagnetic compatibility (EMC); Basic technical standard for emitted interference in residential and commercial environments as well as in light industry IEC EN Electromagnetic compatibility (EMC); Basic technical standard for emitted interference in industrial environments IEC EN Instrument transformers: Current transformers Other specifications UL 506 Special transformers UL 508 Industrial controlling equipment, motor starters UL 1561 General-purpose and power dry-type transformers UL 1604 Devices for use in hazardous areas UL 1059 Terminal blocks UL 486E Equipment wiring terminals for use with aluminum and/or copper conductors CSA C22.2 No. 66 Speciality transformers CSA C22.2 No. 14 Industrial control equipment CAN/CSA B44.1 Elevator and escalator electrical equipment JIS C Low-voltage switchgear and controlgear; Contactors and motor-starters 17 17/4 Siemens LV

143 Annex Standards and approvals Approval requirements valid in different countries Siemens low-voltage switchgear and controlgear are designed, manufactured and tested in accordance with the relevant German standards (DIN and VDE), ICE publications and European standards (EN) as well as CSA and UL standards. The standards assigned to the individual switchgear and controlgear components are stated in the respective parts of this catalogue. As far as is economically viable, the requirements of the various regulations valid in other countries are also taken into account in the design of the equipment. In some European countries and in North America (see table below), an approval is required for certain low-voltage switchgear and controlgear components. Depending on the market requirements, these components have been submitted for approval to the authorized testing institutes. In some cases, CSA for Canada and UL for the USA only approve special switchgear designs. Such special types are listed separately from the standard types in the individual parts of this catalogue. For this equipment, partial limitations of the maximum permissible voltages, currents and ratings can be imposed, or special approval and in some cases special identification is required. For use on board ship, the specifications of the marine classification societies must be observed (see table below). In some cases, they require type tests of the components to be approved. The present state of approval is shown in the "Overview" table on page 17/6. Testing bodies, approval identification and approval requirements Country Canada 1) USA 1) China Poland Slovakia Czech Republic 2) Hungary Government-appointed or private, officially recognized testing bodies CSA UL (USA) UL CQC SEP SKTC EZU MEEI Approval symbol s c u cu c UUS u U c UUS Approval requirements Remarks UL and CSA are authorized to grant approvals according to Canadian or US regulations. Important: These approvals are frequently not recognized and additional approval often has to be obtained from the national testing authority. CCC approval supersedes CCIB approval which has been obtained for SIRIUS devices 3RA, 3RH, 3RP, 3RT, 3RU, 3RV and 3RW. Siemens Prague shall obtain the necessary registration in the Czech Republic For further details on UL and CSA see page 17/6. 1) For guide numbers and file numbers for the approvals, visit and "Product Support". 2) Siemens Prague shall obtain the necessary registration in the Czech Republic. Marine classification societies Country Germany United Kingdom France Norway CIS Italy Poland USA Name Germanischer Lloyd Lloyds Register of Shipping Bureau Veritas Det Norske Veritas Russian Maritime Register of Shipping Registro Italiano Navale Polski Rejestre Statków American Bureau of Shipping Abbreviation GL LRS BV DNV RMRS RINA PRS ABS CE mark of conformity Manufacturers of products which fall within the subject area to which EU directives apply must identify their products, instruction manuals or packaging with a CE mark of conformity. The CE mark of conformity confirms that a product fulfills the appropriate basic requirements of all directives which are relevant to it. The mark of conformity is a mandatory requirement for introducing products into circulation throughout the whole of the EU. All the products in this catalog are in conformance with the EU directives and bear the CE mark of conformity. Low-voltage directive (NS 73/23/EU) CE mark of conformity: >. 17 Siemens LV /5

144 Annex Standards and approvals Special specifications for the USA and Canada Different features of UL approvals (for USA and Canada) Recognized component UL issues yellow "Guide cards" with a Guide No. and a File No. Devices are identified on the rating plate using the "UL recognition mark": USA: U, cuus Canada: cu, cuus Devices are approved as modules for "factory wiring", i.e.: as devices for installation in control systems, which are selected, installed, wired and tested entirely by trained personnel in factories, workshops or elsewhere, according to the conditions of use. Listed product UL issues white "Guide cards" with a Guide No. and a File No. Devices are identified using the "UL listing mark" on the rating plate e.g. USA:u LISTED 165 C Canada:cu LISTED 165 C IND. CONT. EQ.IND. CONT. EQ. (165 C stands for: Siemens, A & D CD Division, Amberg plant) Devices are approved for "field wiring", i.e.: as devices for installation in control systems which are completely wired by trained personnel in factories, workshops or elsewhere. as single devices for sale in retail outlets in the USA/Canada. If devices are u or cu approved as "listed products", they are also approved as "recognized components" and allowed to be marked U or cu. For further details on UL and CSA see page 17/5. Special specifications for Russia, Australia and China GOST approval for Russia CCC approval A GOST approval is required for all products that are to be sold in Russia. The GOST mark has been obligatory on the packaging of all devices since mid This customs certification must exist for all devices on delivery to any part of the Russian Federation. C-Tick licensing for Australia A Since August 1, 2003, CCC approval is required for all products that are marketed in China. The C-Tick license is required for marketing Siemens components in Australia. Electronic devices must provide proof of EMC clearance in Australia, similar to the CE mark of conformity laid down by the EMC directive applicable in the EU and bear the "C-Tick" mark. These requirements have been in force since October 1, /6 Siemens LV

145 Annex Standards and approvals Overview Equipment Reactors Filters Type Approvals Marine classifications 4EM, 4EP, 4EU, 4ET 4EF11 4EF15 Canada 1) 2) USA 1) 1) China Czech Republic Slovakia Poland Hungary Germany United Kingdom France Norway CIS Italy Poland s cuus u cuus U CCC EZU SKTC SEP MEEI GL LRS BV DNV RMRS RINA PRS ABS ) + + m m m USA In the event of queries regarding UL/CSA approvals, please contact: Technical Assistance +49 (911) For further information about standards and approvals, visit and select "Product Support". + Standard version approved. Not yet submitted for approval. O Equipment submitted for approval, please enquire. U-approval not required because u approved. k Approved for use in connection with AS-Interface, also approved by ABS (American Bureau of Shipping). m For exporting products to the Peoples Republic of China, CCC marking is not necessary. 1) For guide numbers and file numbers for the approvals, visit and select "Product Support". 2) cu and cu approvals are available in accordance with the US approval. 3) See Radio interference suppression filters". 17 Siemens LV /7

146 Annex Siemens contact Siemens contact worldwide At you can find details of Siemens contact worldwide responsible for particular technologies. You can obtain in most cases a contact for Technical Support, Spare parts/repairs, Service, Training, Sales or Consultation/engineering. You start by selecting a Country, Product or Sector. By further specifying the remaining criteria you will find exactly the right contact with his/her respective expertise /8 Siemens LV

147 Annex Service & Support A&D in the WWW A detailed knowledge of the range of products and services available is essential when planning and configuring automation systems. It goes without saying that this information must always be fully up-to-date. The Siemens Automation and Drives (A&D) Group has therefore built up a comprehensive range of information in the World Wide Web, which offers quick and easy access to all data required. At the address you will find everything you need to know about products, systems and services. Product Selection using the Interactive Catalogs Detailed information together with convenient interactive functions: The interactive catalog CA 01 covers more than 80,000 products and thus provide a full summary of the Siemens Automation and Drives product base. Here you will find everything that you need to solve tasks in the fields of automation, switchgear, installation and drives. All information is linked into a user interface which is easy to work with and intuitive. After selecting the product of your choice you can order at the press of a button, by fax or by online link. Information on the interactive catalogue CA 01 can be found in the Internet under or on CD-ROM or DVD. Easy Shopping with the A&D Mall The A&D Mall is the virtual department store of Siemens AG on the Internet. Here you have access to a huge range of products presented in electronic catalogs in an informative and attractive way. Data transfer via EDIFACT allows the whole procedure from selection through ordering to tracking of the order to be carried out online via the Internet. Numerous functions are available to support you. For example, powerful search functions make it easy to find the required products, which can be immediately checked for availablilty. Customer-specific discounts and preparation of quotes can be carried out online as well as order tracking and tracing. Please visit the A&D Mall in the Internet under: 17 Siemens LV /9

148 Annex Customer support Configuring and Software Engineering Support in configuring and developing with customer-oriented services from actual configuration to implementation of the automation project. 2).I In the face of harsh competition you need optimum conditions to keep ahead all the time. A strong starting position, a sophisticated strategy and team for the necessary support - in every phase. Service & Support from Siemens provides this support with a complete range of different services for automation and drives. In every phase: from planning and startup to maintenance and upgrading. Our specialists know when and where to act to keep the productivity and cost-effectiveness of your system running in top form. Technical Support Competent consulting in technical questions covering a wide range of customer-oriented services for all our products and systems. Tel.: +49 (180) Fax: +49 (180) adsupport@siemens.com Online Support The comprehensive information system available round the clock via Internet ranging from Product Support and Service & Support services to Support Tools in the shop. automation/service&support Service On Site With Service On Site we offer services for startup and maintenance, essential for ensuring system availability. In Germany Tel.: +49 (180) ) Technical Consulting Support in the planning and designing of your project from detailed actual-state analysis, target definition and consulting on product and system questions right up to the creation of the automation solution. 2) Repairs and Spare Parts In the operating phase of a machine or automation system we provide a comprehensive repair and spare parts service ensuring the highest degree of operating safety and reliablity. In Germany Tel.: +49 (180) ) Technical Assistance Expert technical assistance 1) for low-voltage controlgear, switchgear and systems and electrical installation. Tel.: +49 (9 11) Fax: +49 (9 11) Optimization and Upgrading To enhance productivity and save costs in your project we offer high-quality services in optimization and upgrading. 2) 1) Contact: Technical assistance for product selection old/new code coding competitor code conversion special variants special requirements sales promotion (info line). Your regional contact for sales support (prices, discounts, delivery times). Technical support for commissioning support and after-sales service. 2) For country-specific telephone numbers go to our Internet site /10 Siemens LV