Reactors and Filters. Catalog LV SIDAC. Answers for industry.

Transcription

1 Reactors and Filters Catalog LV SIDAC Answers for industry.

2 Related catalogs Contents Low-Voltage Controls and Distribution SIRIUS SENTRON SIVACON Order No.: E86060-K1002-A101-A (available from 03/2010) LV 1 Industrial communication Controlgear: Contactors and contactor assemblies, soft starters and solid-state switching devices Protection equipment Load feeders and motor starters Monitoring and control devices Detecting devices Commanding and signaling devices Transformers Power supplies Planning and configuration with SIRIUS Power Management System SIVACON Power, distribution boards, busway and cubicle systems SENTRON switching and protection devices for power distribution: Air circuit breakers, molded case circuit breakers, switch disconnectors, busbar systems Software for power distribution BETA low-voltage circuit protection Low-Voltage Controls and Distribution Controls and Components for Applications according to UL Order No.: E86060-K1816-A101-A LV 16 SIRIUS 3RV17 and 3RV18 circuit breakers according to UL 489/ CSA C22.2 No SIVACON Components for Feeder Circuit SENTRON 3WL5 air circuit breakers/non-automatic air circuit breakers according to UL 489/IEC SENTRON 3VL Molded Case Circuit Breakers according to UL 489/IEC ALPHA Devices according to UL Standard BETA Devices according to UL standard SIMATIC NET Industrial Communication Order No.: E86060-K6710-A101-B IK PI PROFINET/Industrial Ethernet Industrial Wireless Communicaton PROFIBUS SIMATIC ET 200 distributed I/Os AS-Interface Telecontrol Routers ECOFAST system SIVACON System Cubicles and Cubicle Air-Conditioning Order No.: E86060-K1920-A101-A LV 50 System cubicles Cubicle modifications Cubicle expansion components Accessories Special cubicles Cubicle solutions in applications Cubicle air-conditioning Special colors SIDAC Reactors and Filters Order No.: E86060-K2803-A101-A SIVACON 8PS CD-L, BD01, BD2 Busbar Trunking Systems up to 1250 A Order No.: E86060-K1870-A101-A LV 60 LV 70 Commutating reactors for converters Mains reactors for frequency converters 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 Busbar trunking systems, overview CD-L system (25 A to 40 A) BD01 system (40 A to 160 A) BD2 system (160 A to 1250 A) The Offline Mall Order No.: E86060-D4001-A510-C (DVD) CA 01 All products of automation, drives and installation technology, including those in the catalogs listed above. The Online Mall Internet: All products of automation, drives and installation technology, including those in the catalogs listed above. Catalog-PDF Internet: All catalogs for low-voltage controls and distribution can be downloaded as PDF files. Registered trademarks All product designations may be registered trademarks or product names of Siemens AG or other supplying companies. Third parties using these trademarks or product names for their own purposes may infringe upon the rights of the trademark owners. Further information about low-voltage controls is available on the Internet at: Technical Assistance Expert technical assistance for Low-voltage controls. Tel.: +49 (9 11) Fax: +49 (9 11) technicalassistance@siemens.com

3 SIDAC Reactors and Filters Catalog LV Introduction 1 Commutation Reactors for 2 Converters Mains Reactors for Frequency 3 Converters Iron-Core Output Reactors 4 Supersedes: Catalog LV For the latest updates of this catalog, please visit our Industry Mall: The products in this catalog can also be found in the Offline Mall CA 01 Order No.: E86060-D4001-A510-C (DVD) Contact your local Siemens sales office for further information. Siemens AG 2009 The products and systems contained in this catalog are manufactured in accordance with a TÜV-certified quality management system (TÜV = German Technical Inspectorate) complying with EN ISO 9001 (Certificate Registration no TMS). The TÜV certificate is recognized in all IQ Net countries. SIDAC reactors SIDAC Filters Ferrite Output Reactors 5 Iron-Core Smoothing Reactors 6 Air-Core Smoothing Reactors 7 Filter Reactors 8 Reactors for Special Applications 9 Radio Interference Suppression 10 Filters dv/dt Filters 11 Sinewave Filters 12 SIDAC Reactors and Filters Specification Sheets 13 Accessories 14 Configuration Notes 15 Appendix 16

4 Explanations Things you should know about Catalog LV The Catalog LV contains all selection and order-relevant data. For technical information, please visit under Product list: - Technical specifications under Entry list: - Updates Delivery time class (DT) } Preferred type A 2 working days B 1 week C 3 weeks D 6 weeks X On request Price units (PU) Preferred types are available immediately from stock, i.e. are dispatched within 24 hours. Normal quantities of the products are usually delivered within the specified time following receipt of your order at our branch. The price unit defines the number of units, sets or meters to which the specified price and weight apply. Packaging sizes (PS) Price groups (PG) Weight Dimensions Standards The packaging size defines the number, e.g. of units, sets or meters, for outer packaging. Only the quantity defined by the packaging size or a multiple thereof can be ordered! Each product is assigned to a price group. The defined weight in kg refers to the price unit (PU). All dimensions in mm. EN (IEC 61558), DIN VDE 0532 The standard EN with VDE classification VDE 0570 represents the German version of the international standard 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 short-circuits and overloads. - Download -FAQ - Manuals - Characteristic curves - Certificates And under - Configurators In exceptional cases, the actual delivery time may differ from that specified. The delivery times apply up to the ramp at Siemens AG (products ready for dispatch). The transport times depend on the destination and type of shipping. The standard transport time for Germany is 1 day. The delivery times specified here represent the state of 10/2009. They are permanently optimized. Up-to-date information can be found at For multi-unit packing and reusable packaging, see Appendix. IEC (Safety of power transformers, power supply units and similar). Since 1st August 2003, this standard has partially superseded the old standard VDE 0550 and fully superseded VDE These amendments saw a considerable tightening of the production and test conditions for reactors. 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 cross-reference list "Old Order No. - New Order No." in the Appendix for the new number. 2 Siemens LV

5 Explanations Low-Voltage Controls and Distribution. Finding out more about UL. We can help. Our low-voltage controls and distribution products are not designed solely for the IEC market. Numerous devices comply with UL directives and make it easy for switchgear and controlgear manufacturers to venture onto the UL market. Exports to North America require special approvals which differ from the IEC directives. On the IEC market, directives define only the essential functions of a system. The technical details are not listed. By contrast, directives on the American market go into the details of how to carry out the installation work etc. For OEMs and machine manufacturers it is important to know the main differences between the two technical worlds and to work together respectively with manufacturers and suppliers who have the right products and know-how. This makes Siemens your ideal partner. Our expertise ranges from the production of UL-approved devices to the wiring of control cabinets according to UL directives. And the design of our low-voltage controls and distribution devices already incorporates these UL requirements, as they have been developed with both the IEC market and the UL market in mind. We have been working with UL (Underwriters Laboratories Inc. ), the leading technical certification company in the USA, since Furthermore, we are happy to share this knowledge with you within the scope of various training programs. With our UL-certified products for low-voltage controls and distribution and low-voltage protection, you can ensure safe operation and build control cabinets according to UL standards quickly and easily. This Catalog LV 60 contains UL-certified products. Take a closer look at our range of products and see for yourself or simply click This link provides further details on UL standards, UL classification and certain special technical features unique to UL. Under "UL Overview/Standards and Approvals" you will find a table that contains a summary of all available products/product groups and indicates the degree to which they conform with UL standards, complete with links to the respective UL report. In addition, the "Portfolio" tab provides a list of the most relevant products for low-voltage controls and distribution and low-voltage protection (incl. link to the relevant Internet product pages). Take a tour of our site and discover more about UL! Useful Internet addresses Low-Voltage Controls and Distribution Information and Download Center Training Industry Mall Offline Mall Online Support Siemens LV

6 Explanations 4 Siemens LV

7 Introduction Siemens AG /2 Answers for Industry. 1/4 Low-Voltage Controls and Distribution. The basis for progressive solutions. 1/6 SIDAC Reactors and Filters Power Quality. 1/10 Smooth operation from mains to motor: SIDAC reactors and filters for AC drives. 1/12 Proven technology for increased availability: SIDAC reactors and filters for DC drives. 1/13 Reliable and stable power supply conditions: SIDAC filter reactors. 1/14 Selection aids. Siemens LV

8 1/2 Siemens LV Siemens AG 2009

9 Answers for industry. Siemens Industry answers the challenges in the manufacturing and the process industry as well as in the building automation business. Our drive and automation solutions based on Totally Integrated Automation (TIA) and Totally Integrated Power (TIP) are employed in all kinds of industry. In the manufacturing and the process industry. In industrial as well as in functional buildings. Siemens offers automation, drive, and low-voltage switching technology as well as industrial software from standard products up to entire industry solutions. The industry software enables our industry customers to optimize the entire value chain from product design and development through manufacture and sales up to after-sales service. Our electrical and mechanical components offer integrated technologies for the entire drive train from couplings to gear units, from motors to control and drive solutions for all engineering industries. Our technology platform TIP offers robust solutions for power distribution. The high quality of our products sets industry-wide benchmarks. High environmental aims are part of our eco-management, and we implement these aims consistently. Right from product design, possible effects on the environment are examined. Hence many of our products and systems are RoHS compliant (Restriction of Hazardous Substances). As a matter of course, our production sites are certified according to DIN EN ISO 14001, but to us, environmental protection also means most efficient utilization of valuable resources. The best example are our energy-efficient drives with energy savings up to 60 %. Check out the opportunities our automation and drive solutions provide. And discover how you can sustainably enhance your competitive edge with us. Siemens LV /3

10 Low-Voltage Controls and Distribution. The basis for progressive solutions. Extremely high demands are made on modern low-voltage controls and distribution: users want cost-effective solutions that are easy to integrate in control cabinets, distribution boards and distributed systems and offer the perfect interaction of all components. Siemens has the answer: SIRIUS industrial controls and lowvoltage power distribution with Power Management, SIVACON and SENTRON. SIRIUS Industrial Controls The SIRIUS range has everything you need for switching, protecting and starting loads. Products for monitoring, control, detection, commanding, signaling and power supply round off the spectrum of industrial controls. Installation of the building control cabinets should be quick, easy, flexible and space-saving. But how can all these requirements be met simultaneously? The answer lies in the unique SIRIUS modular system for up to 250 kw / 400 V, which offers everything you need for switching, protecting and starting motors and plants. Key features of the components of the SIRIUS modular system are their compact design, high flexibility and optimum coordination. All configuration, installation, wiring and maintenance tasks can be performed quickly and easily. Regardless of whether you want to assemble your own load feeders by adding motor starter protectors/circuit breakers or overload relays, contactors or soft starters, or whether you opt for preassembled feeders, SIRIUS has the right product for every application. Continuous further development and regular innovations ensure that our customers are optimally equipped with SIRIUS and benefit from efficient solutions - both now and in the future. At the same time, with Totally Integrated Automation and Safety Integrated our product portfolio can be bundled to create fully optimized systems. All in all, Siemens provides innovative controls that use modern features, such as integrated communication and safety technology, to your advantage - the basis for ground-breaking and consistent solutions. The Siemens Safety Integrated concept is the logical implementation of safety technology within the context of Totally Integrated Automation. This means the consistent and direct integration of safety-related functions in our standard automation products, which offers a wide range of advantages to machine manufacturers and system operators alike. The SIRIUS Safety Integrated failsafe controls are an integral part of the overall Siemens Safety Integrated concept. Whether you require failsafe detection, commands, signaling, monitoring and analysis, or start-up and safe disconnection - our SIRIUS Safety Integrated controls have been specially developed for the consistent handling of safety tasks in your plant. 1/4 Siemens LV

11 Using failsafe communication over standard fieldbus systems, such as ASIsafe via AS-Interface and PROFIsafe via PROFIBUS, SIRIUS Safety Integrated is also able to solve more complex networked safety tasks. This ensures integration into the world of Totally Integrated Automation and into the overall Siemens Safety Integrated concept. Low-voltage power distribution with Power Management, SIVACON and SENTRON to the socket outlet. Only integrated solutions can ensure maximum efficiency during planning, configuration and operation. The concept that meets all these requirements is called Totally Integrated Power from Siemens. Total integration in planning and configuration creates synergies and saves costs. Perfectly matched products and systems ensure efficient engineering and reliable operation. Non-residential buildings and industrial plants have one thing in common: without electricity, everything grinds to a halt. The availability, safety and cost-effectiveness of power distribution systems have top priority from the medium voltage supply Siemens LV /5

12 SIDAC Reactors and Filters. Power Quality. It is common knowledge that faults in the power supply can prove extremely costly. In recent years, the liberalization of the power market and a growing proportion of non-linear loads in the network have led to an increase in supply problems. Loads, such as automation systems or data-processing installations, are highly sensitive to RF interference voltages or deviations of the mains voltage from the sinusoidal waveform. The availability of such systems and installations is increased by reactors and filters that are optimally adapted to the given requirements. SIDAC reactors and filters are used in all industries to reduce harmonics and to increase availability of plants and equipment. Transportation Infrastructure Power Factor Correctness Renewable Energy Industry Mechanical Engineering 1/6 Siemens LV

13 Overview of the product range SIDAC reactors Commutation reactors for converters Mains reactors for frequency converters Output reactors for frequency converters Smoothing reactors for DC drives Filter reactors for compensation systems SIDAC filters Radio interference suppression filters dv/dt filters for frequency converters Sinewave filters for frequency converters 4EM 1 AC commutation reactor The advantages at a glance Wide performance range Voltage ranges Reliable operation Variants and sizes Assignment Service Approvals Maintenance Design Mounting Connection Reliable operation Environment Reactor performance: kva, Currents: up to 1640 A, Filter performance: for drives with up to 900 kw drive power 1x V AC, 3 AC V, up to max. 3.6 kv, customized Rated voltage higher than operational/reference voltages Extensive product range, suitable for standard applications Components can easily be integrated in systems Short delivery times, also for spare parts, thanks to global logistics network Worldwide use of components through UL Extremely long life, minimum maintenance Fast commissioning, short set-up times, simple connection Simple screw fixing Screw terminals, pluggable screw terminals, flat terminals Long-term, worldwide availability of spare parts Environment-friendly production and materials, low power loss 4EU 3 AC mains reactor 4EF AC radio interference suppression filters 4EF11 3 AC sinewave filter Siemens LV /7

14 Power Quality Power Quality Ensures the availability of plants and electrical equipment in households, offices and the industrial and commercial sectors. Designed for applications with AC and DC drives and reactivepower compensation systems, SIDAC reactors and filters are Power Quality components that have been optimized to ensure maximum interference immunity. Products and Systems 110 kv PD30_00075 DC drives Mains reactors/ commutation reactors Chapter 2 RFI suppression filters Chapter 10 Power Converter Smoothing reactors Chapter Power system Motor You will find selection tables containing technical specifications on the products in the specified catalog chapters. For configuration aids, see Chapter 15. 1/8 Siemens LV

15 Compensation Choked reactive-power compensation system Filter reactors Chapter 8 PD30_00076 AC drives without reactors/filters Voltage Current Mains reactors Chapter 3 with output reactors Chapter 4 Power converter with dv/dt-filters Chapter 11 Motor RFI suppression filter Chapter 10 with sinewave filters Chapter 12 Siemens LV /9

16 Smooth operation from mains to motor: SIDAC reactors and filters for AC drives. In any industry or application where frequency converters are used, such as electrical and mechanical engineering, the process industry, fans, conveyor belts or lifting gear, SIDAC reactors and filters are simply indispensable. They reduce line harmonics as well as the effects of the converter infeed to the motor and protect the converter, thus ensuring the smooth operation of machinery and plants. The following overview shows suitable devices and typical applications. without reactors/filters Voltage Current Mains reactors Chapter 3 with output reactors Chapter Converter with dv/dt-filters Chapter 11 Motor RFI suppression filters Chapter 10 with sinewave filters Chapter 12 PD30_00073 Selection tables containing technical specifications and showing the assignment of components to the frequency converter outputs can be found in the specified catalog chapters. For configuration aids, see Chapter 15. 1/10 Siemens LV

17 Reliable reduction of current harmonics: SIDAC mains reactors The right choice - whatever the application and network: SIDAC mains reactors make it possible. For all standard applications, we offer reactors with a uk 2 %-related voltage drop, while for networks with very low line impedance, we have reactors with uk 4 %. The inductance of SIDAC mains reactors is characterized by its high linearity, which prevents undesirable DC link variations caused by load changes. The rated voltages of the mains reactors are at least 40 % higher than the operational voltage. Mains reactors uk 4% Mains reactors uk 2% no mains reactor Optimum interference suppression of frequency converters: SIDAC radio interference suppression filters When interference suppression is required for individual frequency converters, SIDAC RFI suppression filters are indispensable components. They can be easily matched to the respective frequency converter classes and ensure the reduction of radio interference voltages to the required values, thus ensuring that local devices are not affected. Paired with SIDAC mains reactors, they offer optimum interference suppression in frequency converters. PD30_00071 Effective minimization of load current peaks: SIDAC output reactors SIDAC output reactors effectively reduce load current peaks generated by clock signals and line capacities. Practical effects: motor cable lengths of up to 300 m are feasible with unshielded cables, and up to 200 m with shielded cables. Thanks to a rated voltage of 500 V + 5 %, SIDAC output reactors are suitable for use in practically all standard networks in the European and North American sector. Reliable motor protection: SIDAC dv/dt filters SIDAC dv/dt filters are commonly used with frequency converters in the chemical industry. They maintain voltage rise rates of < 500 V/µs and provide reliable motor protection by reducing voltage peaks to a defined value. The rated voltage of 500V +10% and reliable clock frequency of 4kHz make them suitable for a huge range of applications. The maximum motor cable length for unshielded cables is 300 m, and 200 m for shielded cables. Sinusoidal shaping of voltages: SIDAC sinewave filters SIDAC sinewave filters are used if a motor needs to be supplied with a virtually sinusoidal voltage, as is often the case in many sectors of the chemical industry and even in private households. They maintain voltage rise rates of < 500 V/µs and are also ideal in noise-sensitive areas as they reduce magnetic motor noises. With a rated voltage of 500 V +10 % and a permissible clock frequency of 8 khz, they are suitable for a wide range of applications. It goes without saying that long motor cables can also be used in this instance: maximum 300 m for unshielded cables and 200 m for shielded cables. 100 dbμv Typical interference spectrum without RFI suppression filter Lower interference spectrum with RFI suppression filter 1 10 MHz 30 QP_ Class B AV_ Class B PD30_00072 Siemens LV /11

18 Proven technology for increased availability: SIDAC reactors and filters for DC drives. Depending on the application, DC drives can offer a cost-effective alternative to AC drive technology with frequency converters. In such cases, SIDAC reactors and filters also serve to considerably increase the operating safety and availability of converter installations. Mains reactors/ commutation reactors Chapter 2 RFI suppression filters Chapter 10 Power Converter Smoothing reactors Chapter Power system PD30_00068 Motor Optimum control of system perturbations: SIDAC mains/commutation reactors and SIDAC radio interference suppression filters Frequency converters and DC converter drives are subject to similar system perturbation so that the same components can be used on the line side as for AC drives: mains reactors, commutation reactors and radio interference suppression filters. With large DC drives in particular, a sufficiently high inductance is essential a requirement that SIDAC reactors and filters optimally satisfy with their robust design and high availability. Reliable current ripple reduction: SIDAC smoothing reactors DC drives are typically used as main drives for printing presses, rolling mill/winding drives and traversing and lifting drives in the lifting gear industry. SIDAC smoothing reactors reliably reduce current ripples in the motor circuit. Reactors are available from the kw to the MW range. Please contact us and we will be happy to determine the component parameters that optimally suit your requirements and implement the design. You too can benefit from our many years of experience in the dimensioning and design of drive components. Smoothing reactors for decoupling on printing presses: SIDAC in action DC current 700 A Total current of DC motor (I d = 620 A) with reactor without reactor DC current of the two power converter units s Time PD30_00069 The application example on the left shows a 12-pulse DC main drive of a printing press where smoothing reactors are in use as decoupling reactors. The reactors reduce the current ripples of the converter sections and thus the harmonic stress on the DC motor a clear advantage in terms of motor service life. Using reactors to decouple the two power converters enables parallel operation of two 6-pulse rectifier sets, thus creating 12-pulse system perturbations on the primary side of the mains transformer. In other words: SIDAC reactors significantly reduce line harmonics, thus improving power supply conditions. One dual-value reactor per power converter unit to balance different momentary voltage values Power converter transformer e.g. Dy5Dd0 or Yy0Yd11 Power Decoupling converter reactor units 1 and 2 M DC Motor PD30_00070 Selection tables containing technical specifications and showing the assignment of components to the motor ratings can be found in the specified catalog chapters. For configuration aids, see Chapter 15. 1/12 Siemens LV

19 Reliable and stable power supply conditions: SIDAC filter reactors. Inductive loads that generate harmonics are becoming increasingly common in modern supply systems. The result: an increase in the harmonic load and THD-V (Total Harmonic Distortion-Voltage) of the network. However, there is now a solution: near-load compensation. When filter reactors are used, the capacitors connected to the supply system cannot resonate in an undefined manner with the inductances in the supply system. This increases electricity costs, maximizes transmission losses and places an additional load on transmission and distribution systems. The capacitors are used to set the filter reactors to a defined series resonant frequency, taking into account an AF ripple control. Excellent reliability and safety in extreme applications Filter reactors in reactive-power compensation systems are connected to the supply system together with capacitors. Depending on the degree of choking, capacitors and reactors form a series resonant circuit with a defined resonant frequency p = 5.67 % with f res = 210 Hz / p = 7 % with f res = 189 Hz / p = 14 % with f res = 134 Hz. The rated current already takes into account a high harmonic load. SIDAC filter reactors also permit a continuous overload of up to 5 % above the harmonic level. This ensures the necessary reliability and safety for extreme applications. The integrated temperature monitoring reliably signals overload, while the high linearity of the inductance ensures the precise tuning of the filter circuit, even in the event of transient peak loads, such as when switching on. Constant inductance under any conditions Filter reactors are connected with capacitors to form filter banks with a specific reactive power in kvar. SIDAC filter reactors are available in the usual sizes of kvar. A key feature is their high overload capability, which increases operational safety and reliability if the supply system is subject to varying harmonic content. Depending on the degree of choking, the linearity of the inductance remains constant up to 1.8 x the rated current. This ensures that the filter circuit remains tuned to the resonant frequency even in the event of overload currents. Not even high inrush currents can saturate SIDAC filter reactors and the inductance remains constant, which prevents the undefined detuning of the filter circuit. Power system Medium voltage Low voltage Load power converters drives PD30_00074 Choked reactive-power compensation system Siemens LV /13

20 Selection aids. What's the problem? Whatever the problem our comprehensive range of SIDAC reactors and filters has a solution! 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 possible Reduction of commutation notches and limiting of the rate of current rise in the input circuit Reduction of commutation reactive power Attenuation of RFI voltages and reduction of high-frequency system perturbations Reduction of mains-borne electromagnetic emission and its influence Output reactors Commutating/ mains reactors Output reactors with integrated radio interference suppression filters Commutation reactors with integrated radio interference suppression filters Link reactors Sintered metal reactors SIDAC filters dv/dt filters Sinewave filters Reduction of load current peaks, output/input circuit Reduction of voltage gradient dv/ dt at the motor terminals Limiting of overvoltage due to line reflection Generation of sinusoidal motor terminal voltage and currents Reduction of stray losses in the motor Sinewave radiated noise filters Radio interference suppression filters Output reactors with integrated radio interference suppression filters 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 possible Reduction of commutation notches and limiting of the rate of current rise in the input circuit Reduction of commutation reactive power Attenuation of RFI voltages and reduction of high-frequency system perturbations Reduction of mains-borne electromagnetic emission and its influence Commutation reactors with integrated radio interference suppression filters 1/14 Siemens LV

21 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 For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

22 SIDAC Commutation Reactors for Converters 2 Single-phase reactors Application nc DC drives Mains reactors/ commutation reactors Chapter 2 RFI suppression filters Chapter 10 Power Converter Smoothing reactors Chapter Power system PD30_00068 Motor Single-phase commutation reactors for DC drives Single-phase 4EM commutation reactors for converters are used in the line-side infeed as line reactors for the two-way connections of converter assemblies. Alternating current flows through the reactors. Their task is to limit line-side voltage drops during commutation of the converter. The reactors also limit the rate of voltage rise dv/dt at the thyristors by limiting the rate of current rise di/dt. There are various reactor series: u D ~ 2 % for the following supply voltage: 230 V AC u D ~ 4 % for the following supply voltage: 230 V, 400 V AC The figures are based on a frequency f = 50 Hz. Technical specifications Recommended supply voltage U N Rated alternating current I Ln See the table "Selection and ordering data". Max. continuous thermal current I thmax Peak current I Lmax Permissible continuous direct current with downstream two-pulse bridge connection (I dn = I thmax 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 distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation (for installation altitudes of up to 2000 m above sea level) 690 V AC at U N 500 V for 4EM with terminals 600 V AC at U N 500 V for 4EM according to UL Permissible ambient temperature during operation Type 4EM: 25 C C Deviation of the permissible alternating current See "Configuration notes". from the rated alternating current I Ln at coolant temperatures +40 C Temperature classes Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln at installation altitudes > 1000 m above sea level t a 40 C/B 1000 m above sea level See "Configuration notes". Standards/approvals The reactors comply with EN UL 1561: XQNX2, XQNX8, CSA 22.2 H4 (only applies to reactors with U N 600 V according to UL) Storage temperature 25 C C Transport temperature 25 C C Permissible humidity rating Humidity 5 % % occasional condensation permissible 2/2 Siemens LV

23 SIDAC Commutation Reactors for Converters Selection and ordering data Overview I thmax = I Lmax Single-phase reactors nc 2 4EM Max. permissible continuous thermal current I thmax A Rated current I Ln A 1) For downstream two-pulse bridge connection: reactors with higher rated currents on request. 2) Permissible continuous direct current 1) Reference voltage drop of reactor u D at I thmax and U N, f = 50 Hz I dn Order No. Order No. Order No. A 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 CB EM 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 2) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). Siemens LV /3

24 SIDAC Commutation Reactors for Converters 2 Single-phase reactors I thmax = I Lmax nc 4EM Max. permissible continuous thermal current Rated current 1) Permissible 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 C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T } 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 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 C 4EM CB T } 4EM CB T C 4EM CB T } 4EM CB T C 4EM CB T C 4EM CB T } 4EM CB ,4 14 T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 4EM CB T C 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 } 4EM CB T } 4EM CB T } 4EM CB T } 4EM CB T } 4EM CB T } 4EM CB T } 4EM CB T } 4EM CB T } 4EM CB T C 4EM CB T } 4EM CB T C 4EM CB T C 4EM CB Packaging size for reactors: 1 unit, i.e. 1 unit 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 the flat terminations: see "Accessories". 2/4 Siemens LV

25 SIDAC Commutation Reactors for Converters Application Three-phase reactors nc 2 DC drives Mains reactors/ commutation reactors Chapter 2 RFI suppression filters Chapter 10 Power Converter Smoothing reactors Chapter Power system PD30_00068 Motor Three-phase commutation reactors for DC drives Commutation reactors for converters are used in the B6 and B6C connections of converter assemblies in the line-side infeed. Their task is to limit line-side voltage drops during commutation of the converter. The reactors also limit the rate of voltage rise dv/dt at the thyristors by limiting the rate of current rise di/dt. These reactors can also be deployed to decouple converter assemblies working in parallel. There are various 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 are based on a line frequency f = 50 Hz. Technical specifications Recommended supply voltage U N Rated alternating current I Ln See the table "Selection and ordering data" Max. continuous thermal current I thmax Peak current I Lmax Permissible continuous direct current with downstream six-pulse bridge converter (I dn = I thmax 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 distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation (for installation altitudes of up to 2000 m above sea level) Permissible ambient temperature during operation Type 4EP: 25 C C Type 4EU: 25 C C Deviation of the permissible alternating current See "Configuration notes". from the rated alternating current I Ln at coolant temperatures +40 C Temperature classes Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln at installation altitudes > 1000 m above sea level 690 V AC at U N 500 V for 4EP with terminals 1000 V AC at U N 830 V for 4EP, 4EU24 to 4EU43 with flat terminals Type 4EP: t a 40 C/B Type 4EU: t a 40 C/H (utilization according to F for applications according to EN 61558) Type 4EU: temperature class H (for applications according to UL) 1000 m above sea level See "Configuration notes". Operation with varying load Rating on request Operation at 60 Hz 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 recognized under Guide No. XQNX2 and cul approved under Guide No. XQNX8 (only applies to reactors with U N 600 V according to UL) Storage temperature 25 C C Transport temperature 25 C C Permissible humidity rating Humidity 5 % % occasional condensation permissible Siemens LV /5

26 SIDAC Commutation Reactors for Converters 2 Three-phase reactors Selection and ordering data nc 1) Overview I thmax = I Lmax 4EP 4EU Max. permissible continuous thermal current I thmax A 1) All reactors with U N 600 V according to UL. 2) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). Rated current 2) I Ln A Permissible continuous direct current 3) I dn A Reference voltage drop of reactor u D = 2 % at 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 4) EU BD00-0A -- 3) For downstream six-pulse bridge converters: reactors with higher rated currents on request. 4) Reactors according to VDE 0532: I thmax = Rated current. 2/6 Siemens LV

27 SIDAC Commutation Reactors for Converters Three-phase reactors I thmax = I Lmax nc 1) 2 4EP 4EP 4EU 4EU Max. permissible continuous thermal current 2) I thmax A Rated current 3) I Ln A 1) All reactors with U N 600 V according to UL. 2) Reactors according to VDE 0532: I thmax = Rated current. 3) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). Max. permissible Reference voltage drop of reactor u D = 4 % at I thmax and U N continu- ous direct current 4) 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 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 2) EU AA00-0A 4EU AA00-0A 4EU AA00 2) 4EU AA00 2) EU AA00-0A 4EU AA00-0A 4EU AA00 2) 4EU AA00 2) EU AX00 2) EU BB00-0A 4EU AM00 2)5) EU AL00 2) 4EU AA00 2)5) 4EU AA00 2) -- 4) For downstream six-pulse bridge converters: reactors with higher rated currents on request. 5) Reference voltage drop of reactor u D ~ 4 % at I Ln and U N = 575 V. Siemens LV /7

28 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = 0.8 I Lmax nc 1) 4EP 4EP 4EU 4EU Max. permissible continuous thermal current I thmax A Rated current 3) I Ln A Peak current 4) I Lmax A 1) All reactors with U N 600 V according to UL. 2) Reactors according to VDE 0532: I thmax = Rated current. 3) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). 4) Load with I max permissible, occasional or periodic, if the effective current does not exceed the value I thmax. Max. permissible Reference voltage drop of reactor u D = 4 % at I thmax and U N continuous direct current 5) 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 2) EU AL00-0A 4EU AX00-0A 6) EU AW00-0A 4EU AK00 2)6) 4EU AP00 2) EU CH10-0A 4EU CP10-0C 4EU BD10-0C 4EU AM10-0C EU CK10-0C 4EU CQ10-0C 4EU BE10-0C 4EU BF10-0C EU BG10-0B 4EU BA10-0C 4EU BF10-0C 4EU BG10-0C EU AL10-0C 4EU BB10-0C 4EU BG10-0C 4EU BH10-0C EU AK10-0B 4EU BC10-0C 4EU AV10-0C 4EU AW10-0C 5) For downstream six-pulse bridge converters: reactors with higher rated currents on request. 6) Reference voltage drop of reactor u D ~ 4 % at I Ln and U N = 575 V. 2/8 Siemens LV

29 SIDAC Commutation Reactors for Converters I thmax = I Lmax Three-phase reactors nc 2 4EP 4EP Max. motor rated output up to U dc 1) Permissible continuous direct current 2) Max. continuous thermal current Rated current 3) Inductance Core losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) Rated direct voltage of the converter. 2) For downstream six-pulse bridge converters: reactors with higher rated currents on request. Winding losses Connections 4) DT Order No. Al T = Terminal F = Flat termination weight per PU approx. Cu weight per PU approx. P Motor I dn I thmax I Ln L x P FE P W kw 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 485 V Total weight per PU approx 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 C 4EP DS F C 4EP DS F C 4EP DS F C 4EP DS F C 4EP DS ) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). 4) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". Siemens LV /9

30 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = I Lmax nc 4EP 4EP 4EU 4EU Max. motor rated output up to U dc 1) Permissible continuous direct current 2) Max. continuous thermal current Rated current 3) Inductance Core losses Winding losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) Rated direct voltage of the converter. 2) For downstream six-pulse bridge converters: reactors with higher rated currents on request. Connections 4) DT Order No. Al T = Terminal F = Flat termination weight per PU approx. Cu weight per PU approx. P Motor I dn I thmax I Ln L x P FE P W kw 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 485 V Total weight per PU approx 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 C 4EP DS T C 4EP DS T C 4EP DS F C 4EP DS F C 4EP DS F C 4EP DS F C 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 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 AA00-1BA F C 4EU AA00-1BA F C 4EU AA00-0A F C 4EU AA00-0A F C 4EU BB00-0A ) F C 4EU AL ) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). 4) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". 5) Reactors according to VDE 0532: I thmax = Rated current. 2/10 Siemens LV

31 SIDAC Commutation Reactors for Converters I thmax = I Lmax Three-phase reactors nc 2 4EP 4EP 4EU 4EU Max. motor rated output up to U dc 1) Permissible continuous direct current 2) Max. continuous thermal current Rated current 3) Inductance Core losses Winding losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) Rated direct voltage of the converter. 2) For downstream six-pulse bridge converters: reactors with higher rated currents on request. Connections 4) DT Order No. Al T = Terminal F = Flat termination weight per PU approx. Cu weight per PU approx. P Motor I dn I thmax I Ln L x P FE P W kw 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 600 V Total weight per PU approx 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 C 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 ) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). 4) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". Siemens LV /11

32 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = I Lmax nc 5) 4EU 4EU Max. motor rated output up to U dc 1) Permissible continuous direct current 2) Max. continuous thermal current Rated current 3) Inductance Core losses Winding losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) Rated direct voltage of the converter. 2) For downstream six-pulse bridge converters: reactors with higher rated currents on request. Connections 4) DT Order No. Al T = Terminal F = Flat termination weight per PU approx. Cu weight per PU approx. P Motor I dn I thmax I Ln L x P FE P W kw 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 690 V Total weight per PU approx ) F C 4EU AM ) F C 4EU AA AC 690 V 50 Hz, u D ~ 7.8 V 2 % reference voltage drop for I thmax and U N 830 V 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 830 V 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 C 4EU AA ) F C 4EU AA ) F C 4EU AX ) F C 4EU AA ) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). 4) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". 5) All reactors with U N 600 V according to UL. 6) Reactors according to VDE 0532: I thmax = Rated current. 2/12 Siemens LV

33 SIDAC Commutation Reactors for Converters Three-phase reactors I thmax = I Lmax nc 5) 2 4EU 4EU Max. motor rated output up to U dc 1) Permissible continuous direct current 2) Max. continuous thermal current Rated current 3) Inductance Core losses Winding losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) Rated direct voltage of the converter. 2) For downstream six-pulse bridge converters: reactors with higher rated currents on request. Connections 4) DT Order No. Al T = Terminal F = Flat termination weight per PU approx. Cu weight per PU approx. P Motor I dn I thmax I Ln L x P FE P W kw 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 900 V Total weight per PU approx 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 C 4EU AA ) F C 4EU AA ) F C 4EU AA AC 830 V 50 Hz, u D ~ 9.6 V 2 % reference voltage drop for I thmax and U N 1000 V F C 4EU BE00-0A ) F C 4EU AN ) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). 4) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". 5) All reactors with U N 600 V according to UL. 6) Reactors according to VDE 0532: I thmax = Rated current. Siemens LV /13

34 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = 0.8 I Lmax nc 4EP 4EP 4EU 4EU Max. motor rated output up to U dc 1) Max. permissible direct current 2) Max. continuous thermal current Core losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) Rated direct voltage of the converter. 2) For downstream six-pulse bridge converters: reactors with higher rated currents on request. Rated Peak Inductance 3) current current 4) Winding losses Connections 5) DT Order No. Al T = Terminal F = Flat termination weight per PU approx. Cu weight per PU approx. P Motor I dn I thmax I Ln I Lmax L x P FE P W kw 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 Lmax and U N 485 V Total weight per PU approx T } 4EP DS T C 4EP DS T } 4EP DS T } 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 } 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 } 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 C 4EU AL00-0A F C 4EU AW00-0A F C 4EU CH10-0A F D 4EU CK10-0C F C 4EU BG10-0B F D 4EU AL10-0C F X 4EU AK10-0B ) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). 4) Load with I Lmax permissible, occasional or periodic, if the effective current does not exceed the value I thmax. 5) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". 2/14 Siemens LV

35 SIDAC Commutation Reactors for Converters I thmax = 0.8 I Lmax Three-phase reactors nc 2 4EP 4EP 4EU 4EU Max. motor rated output up to U dc 1) Max. permissible direct current 2) Max. continuous thermal current Core losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) Rated direct voltage of the converter. 2) For downstream six-pulse bridge converters: reactors with higher rated currents on request. Rated Peak Inductance 3) current current 4) Winding losses Connections 5) DT Order No. Al T = Terminal F = Flat termination weight per PU approx. Cu weight per PU approx. P Motor I dn I thmax I Ln I Lmax L x P FE P W kw 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 Lmax and U N 600 V Total weight per PU approx 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 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 C 4EU CA00-1BA F C 4EU BA00-0A F C 4EU BA00-0A F C 4EU CA00-0A F C 4EU CA00-0A F D 4EU CP10-0C F D 4EU CQ10-0C F D 4EU BA10-0C F D 4EU BB10-0C F D 4EU BC10-0C ) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). 4) Load with I Lmax permissible, occasional or periodic, if the effective current does not exceed the value I thmax. 5) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". Siemens LV /15

36 SIDAC Commutation Reactors for Converters 2 Three-phase reactors I thmax = 0.8 I Lmax nc 6) 4EU 4EU Max. motor rated output up to U dc 1) Max. permissible direct current 2) Max. continuous thermal current Core losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) Rated direct voltage of the converter. 2) For downstream six-pulse bridge converters: reactors with higher rated currents on request. 3) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). Rated Peak Inductance 3) current current 4) Winding losses Connections 5) DT Order No. Al T = Terminal F = Flat termination weight per PU approx. Cu weight per PU approx. P Motor I dn I thmax I Ln I Lmax L x P FE P W kw 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 Lmax and U N 690 V Total weight approx F C 4EU AX00-0A ) F C 4EU AK AC 690 V 50 Hz, u D ~ 15.0 V 4 % reference voltage drop for I Lmax and U N 830 V 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 C 4EU AP F D 4EU BD10-0C F D 4EU BE10-0C F D 4EU BF10-0C F D 4EU BG10-0C F D 4EU AV10-0C AC 750 V 50 Hz, u D ~ 17.3 V 4 % reference voltage drop for I Lmax and U N 900 V 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 C 4EU BA ) F C 4EU BA F D 4EU AM10-0C F D 4EU BF10-0C F D 4EU BG10-0C F D 4EU BH10-0C F D 4EU AW10-0C ) Load with I Lmax permissible, occasional or periodic, if the effective current does not exceed the value I thmax. 5) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". 6) All reactors with U N 600 V according to UL. 7) Reactors according to VDE 0532: I thmax = Rated current. 2/16 Siemens LV

37 SIDAC Mains Reactors for Frequency Converters Three-phase reactors3 3/2 Application 3/2 Technical specifications 3/3 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

38 SIDAC Mains Reactors for Frequency Converters Three-phase reactors 3 Application nc AC drives without reactors/filters Voltage Current Mains reactors Chapter 3 with output reactors Chapter Converter with dv/dt-filters Chapter 11 Motor RFI suppression filters Chapter 10 with sinewave filters Chapter 12 PD30_00073 Mains reactors for AC drives Three-phase mains reactors for frequency converters are used in line-side infeeds. They are connected such that alternating currents with line frequency flow through the reactors as the fundamental wave frequency. The reactors limit system perturbations that occur in the form of harmonics and reduce the alternating currents by means of the frequencies caused by the switching of the input rectifier in the DC link capacitors. Technical specifications Recommended supply voltage U N Rated alternating current I Ln Max. continuous thermal current I thmax Voltage drop Δu per phase Inductance per phase mh Core losses P Fe at f = 50 Hz Winding losses P W Weight See the table "Selection and ordering data" Degree of protection IP00 according to DIN VDE / EN Rating of creepage distance and clearance Rated voltage for insulation (for installation altitudes of up to 2000 m above sea level) Permissible ambient temperature during operation Pollution degree 2 according to DIN VDE EP with terminals: 4EP with flat terminal and 4EU24 to 4EU43 (EN 61558): 4EU45 to 4EU56 (DIN VDE 0532): At U N 500 V for 4EP and 4EU: Type 4EP: 25 C C Type 4EU: 25 C C 690 V AC 1000 V AC 1100 V AC 600 V AC according to c Two reactor series are available: Reactors with a reference voltage drop u D of ~ 2 % for operation with converters without power recovery. Reactors with a reference voltage drop u D of ~ 4 % for operation with converters combined with autotransformers with power recovery and for application in networks with a u K power supply of < 1 %. Deviation of the permissible alternating current from the rated alternating current I Ln Coolant temperatures +40 C See "Configuration notes". Temperature classes Type 4EP: t a 40 C/B Type 4EU: t a 40 C/H (utilization according to F for applications according to EN 61558) Type 4EU: Temperature class H (for applications according to c) Installation altitude 1000 m above sea level Deviation of the permissible See "Configuration notes". alternating current from the rated alternating current I Ln at installation altitudes > 1000 m above sea level Operation with varying load Rating on request Standards/approvals The reactors comply with EN (type 4EU45 to 4EU56: DIN VDE 0532) UL 1561: XQNX2, XQNX8, CSA 22.2 H47 (applies to reactors with U N 600 V according to UL) Storage temperature 25 C C Transport temperature 25 C C Permissible humidity rating Humidity 5 % % occasional condensation permissible 3/2 Siemens LV

39 SIDAC Mains Reactors for Frequency Converters Three-phase reactors Selection and ordering data nc 1) Overview 3 4EP 4EP 4EU 4EU Max. permissible continuous thermal current 2) I thmax A Rated current I Ln A 1) All reactors with U N 600 V according to UL Reactors with higher rated currents on request. Reference voltage drop of reactor u D = 2 % at I thmax and U N Order No. Order No. Order No. 3 AC 400 V 50 Hz 3 AC 480 V 60 Hz 3 AC 500 V 50 Hz 3) 3 AC 690 V 50 Hz 3) 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 US EU UA00-0AA EP US EU UA00-0AA EP US EP US EU 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) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). Siemens LV /3

40 SIDAC Mains Reactors for Frequency Converters Three-phase reactors Overview nc 1) 3 4EP 4EP 4EU 4EU Max. permissible continuous thermal current 2) I thmax A Rated current I Ln A 1) All reactors with U N 600 V according to UL Reactors with higher rated currents on request. 2) Reactors according to VDE 0532: I thmax = Rated current. 3) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). Reference voltage drop of reactor u D = 4 % at I thmax and U N Order No. Order No. Order No. 3 AC 400 V 50 Hz V AC 60 Hz 3 AC 500 V 50 Hz 3) 3 AC 690 V 50 Hz 3) EP US EP US EP US EP US EP US EP US EP US00 4EP US EP US EP US00 4EP US EP US EP US00 4EP US EU UB00-0AA EU UC00-0AA0 4EU UA00-0AA EU UA00-0AA0 4EU UB00-0AA EU UB00-0AA EU UC00-0AA0 4EU UB00-0AA EU UC00-0AA0 -- 4EU 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 UC00-0AA0 4EU 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 UC10-0A EU UB00-0A EU UB00-0A 4EU UA00 2) 4EU UA00 2) 3/4 Siemens LV

41 SIDAC Mains Reactors for Frequency Converters Three-phase reactors nc 3 4EP 4EP 4EU 4EU Typical drive power Max. permissible continuous thermal current Rated current 1) Inductance Core losses 2) Winding losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). Connections 3) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. P drive I thmax I Ln L x P FE P W kw 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 400 V Total weight per PU approx 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 } 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 C 4EU UC00-0A ) At f = 60 Hz: P Fe60 = P Fe ) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". Siemens LV /5

42 SIDAC Mains Reactors for Frequency Converters 3 Three-phase reactors nc 4EP 4EU 4EU Typical drive power Max. permissible continuous thermal current Rated current 1) Inductance Core losses 2) Winding losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. Connections 3) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. P drive I thmax I Ln L x P FE P W kw 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 400 V Total weight per PU approx T C 4EP US T C 4EP US T D 4EP US T C 4EP US T D 4EP US T } 4EP US T C 4EP US T D 4EP US T } 4EP US T D 4EP US T C 4EP US F-Al D 4EU UB00-0AA F-Al D 4EU UC00-0AA F-Al } 4EU UA00-0AA F-Al C 4EU UB00-0AA F-Al D 4EU UC00-0AA F-Al D 4EU UC00-0AA F-Al } 4EU UB00-0AA F-Al } 4EU UB00-0AA F-Al C 4EU UB00-0AA F-Al D 4EU UC00-0AA 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 } 4EU UB00-0AA F-Cu C 4EU UC00-1BA F-Cu C 4EU UA00-0A F-Cu C 4EU UB00-0A F-Cu C 4EU UB00-0A F-Cu D 4EU UC10-0A F-Cu C 4EU UB00-0A F-Cu C 4EU UB00-0A ) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). 2) At f = 60 Hz: P Fe60 = P Fe ) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". 3/6 Siemens LV

43 SIDAC Mains Reactors for Frequency Converters Three-phase reactors nc 3 4EP 4EP 4EU 4EU Typical drive power Max. permissible continuous thermal current Rated current 1) Inductance Core losses 2) Winding losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). Connections 3) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. P drive I thmax I Ln L x P FE P W kw A A mh W W kg kg kg 3 AC 500 V 50 Hz, u D ~ 5.7 V 2 % reference voltage drop for I thmax and U N 500 V Total weight per PU approx 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 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 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 C 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 AC 500 V 50 Hz, u D ~ 11.5 V 4 % reference voltage drop for I thmax and U N 500 V 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 D 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 C 4EU UA ) F-Cu C 4EU UA ) F-Cu C 4EU UA ) At f = 60 Hz: P Fe60 = P Fe ) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". 4) Reactors according to VDE 0532: I thmax = Rated current. Siemens LV /7

44 SIDAC Mains Reactors for Frequency Converters 3 Three-phase reactors nc 1) 4EP 4EU 4EU Typical drive power Max. permissible continuous thermal current Rated current 2) Inductance Core losses 3) Winding losses Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) All reactors with U N 600 V according to UL. 2) I Ln (60 Hz) = 0.9 x I Ln (50 Hz). Connections 4) T = Terminal F = Flat termination DT Order No. Al weight per PU approx. Cu weight per PU approx. P drive I thmax I Ln L x P FE P W kw 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 690 V Total weight per PU approx F-Cu } 4EP US F-Al } 4EU UA00-0AA F-Al C 4EU UA00-0AA F-Al C 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 D 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 C 4EU UB00-0A F-Cu C 4EU UB00-0A ) F-Cu C 4EU UA AC 690 V 50 Hz, u D ~ 15.9 V 4 % reference voltage drop for I thmax and U N 690 V 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 C 4EU UA ) F-Cu C 4EU UA ) F-Cu C 4EU UA ) F-Cu C 4EU UA ) At f = 60 Hz: P Fe60 = P Fe ) For terminal covers offering protection against accidental contact with the flat terminations: see "Accessories". 5) Reactors according to VDE 0532: I thmax = Rated current. 3/8 Siemens LV

45 SIDAC Iron-Core Output Reactors Three-phase reactors4 4/2 Application 4/2 Technical specifications 4/3 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates And under - Configurators Siemens LV

46 SIDAC Iron-Core Output Reactors Three-phase reactors Application nc AC drives without reactors/filters Voltage Current 4 Mains reactors Chapter 3 with output reactors Chapter Converter with dv/dt-filters Chapter 11 Motor RFI suppression filters Chapter 10 with sinewave filters Chapter 12 Iron-core output reactors for AC drives Output reactors are connected on the load side of frequency converters so that all motor currents flow through the reactor. 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 synchro- PD 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 the table "Selection and ordering data". Maximum converter output frequency: 200 Hz Clock frequency of converter: up to 8 khz Degree of protection IP00 according to DIN VDE /EN Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation (for installation altitudes of 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 +40 C Temperature classes Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln (at installation altitudes > 1000 m above sea level) Version with terminals: 690 V AC Version with flat terminals: 1000 V AC 0 C C See "Configuration notes". Type 4EP t a 40 C/F; Type 4EU t a 40 C/H 1000 m above sea level See "Configuration notes". Standards/approvals The reactors comply with EN UL 508: NMTR2, NMTR8, CSA 22.2 No. 14-M95 for types 4EP UL 1561: XQNX2, XQNX8, CSA 22.2 H47 for types 4EU Storage temperature 25 C C Transport temperature 25 C C Permissible humidity rating Humidity 5 % % occasional condensation permissible 4/2 Siemens LV

47 SIDAC Iron-Core Output Reactors Three-phase reactors Selection and ordering data nc 4EP 4EU 4 Typical drive power Max. permissible continuous thermal current 4kHz 1) Max. permissible 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. P drive I thmax I thmax I Ln L x P FE P W kw A A A mh W W kg kg kg 3 AC 500 V ±5 % 200 Hz, maximum clock frequency up to 8 khz 500 V T C 4EP ES T C 4EP FS T C 4EP BS T C 4EP CS T C 4EP AS T C 4EP RS F C 4EU ED00-4BA F } 4EU EE00-4BA F } 4EU EF00-4BA F C 4EU EB00-4BA F C 4EU EC00-4BA F C 4EU ED00-4BA Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) For clock frequencies > 4 khz, the following formula lets you determine the current : I thmax, depending on the clock frequency: 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 the 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 7.5 kw/2.5 mm² ->7.5kW 11 kw/4 mm² ->11kW 22 kw/10 mm² ->22kW 30 kw/16 mm² ->30kW 37 kw/25 mm² ->37kW 50 kw/35 mm² ->50kW 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 3500VAC ±5% If these do not meet your requirements, customized solutions are available. For further information, please contact "mdexx GmbH" in Bremen: Anfrage@mdexx.com Siemens LV /3

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

49 SIDAC Ferrite Output Reactors Three-phase reactors5 5/2 Application 5/2 Technical specifications 5/3 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

50 SIDAC Ferrite Output Reactors Siemens AG 2009 Three-phase reactors Application AC drives without reactors/filters Voltage Current Mains reactors Chapter 3 with output reactors Chapter Converter with dv/dt-filters Chapter 11 Motor RFI suppression filters Chapter 10 with sinewave filters Chapter 12 PD30_00073 Ferrite Output Reactors for AC drives Thanks to their special material characteristics, ferrite reactors can be operated at higher converter output frequencies of up to 600 Hz. They can be used at clock frequencies of up to 16 khz. 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. Application 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. Technical specifications Recommended supply voltage U N Rated alternating current I Ln Maximum converter output frequency Performance range of drive kw Inductance per phase mh Total power loss W Total weight kg Frequency See the table "Selection and ordering data". Maximum converter output frequency: 600 Hz Clock frequency of converter: 16 khz Degree of protection IP00 according to DIN VDE /EN Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation (for installation altitudes of up to 2000 m above sea Version with terminals: 690 V AC; with flat terminals: 1000 V AC level) Permissible ambient temperature during operation 0 C C Deviation of the permissible alternating current from the rated alternating See "Configuration notes". current I Ln at coolant temperatures +40 C Temperature classes t a 40 C/B, natural air cooling (S) according to DIN Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln (at installation altitudes > 1000 m above sea level) 1000 m above sea level See "Configuration notes". Standards/approvals The reactors comply with VDE 0805 Storage temperature Transport temperature Permissible humidity rating 25 C C 25 C C Humidity 5 % % occasional condensation permissible 5/2 Siemens LV

51 SIDAC Ferrite Output Reactors Three-phase reactors Selection and ordering data Max. permissible continuous thermal current 6kHz 1) Max. permissible 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 AC Hz 460 V 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 ) Within an application range of 6 khz to 16 khz, the current I thmax can be linearly interpolated. 5 The selection table shows an overview of the range of reactors. If you are interested in any of our products or need further assistance, simply copy the query form 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 form is also available on our home page Siemens LV /3

52 SIDAC Ferrite Output Reactors Siemens AG 2009 Notes 5 5/4 Siemens LV

53 SIDAC Iron-Core Smoothing Reactors 6 Single-phase reactors 6/2 Application 6/2 Technical specifications 6/3 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

54 SIDAC Iron-Core Smoothing Reactors Single-phase reactors Application nc DC drives Mains reactors/ commutation reactors Chapter 2 RFI suppression filters Chapter 10 Power Converter Smoothing reactors Chapter Power system PD30_ Iron-Core Smoothing Reactors for DC drives Smoothing reactors are used on the direct current side of converter assemblies. They are connected such that direct current flows through the reactor. Iron-core smoothing reactors as series inductance for direct current motors (series reactors, 4EM, 4ET range) They are used to enable problem-free commutation and reduce motor losses when the used converter connection results in the DC ripple being too high for DC motors. The reactors have an almost constant inductance L up to the rated direct current I dn. Technical specifications Motor 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 loads. Reactors are 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. Max. continuous thermal current I thmax Rated direct current I dn Inductance at I thmax Iron-core smoothing reactors as series inductance for direct current motors See the table "Selection and ordering data". Iron-core smoothing reactors with selectable inductance and current See the table "Selection and ordering data". Energy content E at I thmax Connection of winding for type 4ET Permissible ripple of superimposed alternating 30 % 30 % current Core losses P Fe /winding losses P W /weight See the table "Selection and ordering data". See the table "Selection and ordering data". Degree of protection IP00 according to DIN VDE /EN Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation According to EN (for installation altitudes of up to 2000 m above sea level) Reduction of the rated voltage for insulation (at installation 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 +40 C Type 4EM: Type 4ET with terminal: Type 4ET25 to 4ET45: Type 4ET47 to 4ET80: See "Configuration notes". Type 4EM: 25 C C Type 4ET: 25 C C See "Configuration notes". 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 (up to 4ET54) Temperature classes Type 4EM: t a 40 C/B Type 4ET: Type 4ET: t a 40 C/H (utilization according to F for applications according to EN) t a 40 C/H (for applications according to c) Installation altitude 1000 m above sea level Deviation of permissible direct current See "Configuration notes" from rated direct current I dn (at installation altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN (Type 4ET47 to 4ET80: DIN VDE 0532). UL 1561: XQNX2, XQNX8, CSA 22.2 H47 Storage temperature 25 C C Transport temperature 25 C C Permissible humidity rating Humidity 5 % % occasional condensation permissible 6/2 Siemens LV

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

56 SIDAC Iron-Core Smoothing Reactors Single-phase reactors Iron-core smoothing reactors with selectable inductance and current nc 1) 6 Energy content Max. possible rated direct current (standard version) Max. possible rated direct current 2) (for an additional price) Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. 1) 4EM46 to 4ET54 - UL Recognized. 2) Higher rated direct current I dn for reduced energy content on request. Losses DT Order No. stem 3) Weight per PU approx. E I dn I dn P FE P W Ws A (DC) A (DC) W W kg 4EM iron-core smoothing reactors X 4EM X 4EM X 4EM X 4EM X 4EM X 4EM EM 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 ET 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 ) 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 need to re-order a reactor. For further information, see "Specification Sheets", "Specification sheet for customised smoothing reactors, selectable inductance and current". If you need any further assistance or have any queries, please Anfrage@mdexx.com. 6/4 Siemens LV

57 Air-Core Smoothing Reactors 7 Single-phase reactors 7/2 Application 7/2 Technical specifications 7/3 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

58 SIDAC Air-Core Smoothing Reactors Single-phase reactors Application n DC drives Mains reactors/ commutation reactors Chapter 2 RFI suppression filters Chapter 10 Power Converter Smoothing reactors Chapter Power system PD30_00068 Motor 7 Air-Core Smoothing Reactors for DC drives 4PK air-core smoothing 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 shoot-throughs. Technical specifications They cause the high-speed DC circuit-breakers in the circuit to interrupt the rising fault current fast enough to prevent the fuses in the thyristor branches from responding. Rated direct current I dn See the table "Selection and ordering data". Energy content E at I thmax Max. rated direct current I dn Power loss P Al at 4PK Weight Inductance at I dn On request Degree of protection IP00 according to DIN VDE /EN Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation (for installation altitudes of up to 2000 m above sea level) Reduction of the rated voltage for insulation (for installation altitudes > 2000 m above sea level) 2kV See "Configuration notes". Permissible ambient temperature during operation 25 C C Deviation of permissible direct current from rated direct current I dn at coolant temperatures +40 C Temperature classes Installation altitude Deviation of permissible direct current from rated direct current I dn (for installation altitudes > 1000 m above sea level) See "Configuration notes". t a 40 C/F 1000 m above sea level See "Configuration notes" Standards/approvals The reactors comply with DIN VDE 0532 Storage temperature 25 C C Transport temperature 25 C C Permissible humidity rating Permissible short-circuit current Humidity 5 % % occasional condensation permissible 20 I dn for 1 s 7/2 Siemens LV

59 SIDAC Air-Core Smoothing Reactors Single-phase reactors Selection and ordering data n Energy content (max.) at I dn Rated direct current (max. standard version) Losses DT Order No. stem Weight per PU approx. E I dn P Al Ws A W kg 4 PK air-core smoothing reactors X On request X On request X On request X On request Packaging size for reactors: 1 unit, i.e. 1 unit 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 the rated direct current I dn. As a consequence of the design of the reactors, each type has specific maximum values for the rated direct current I dn (see the table "Selection and ordering data"). The "Selection and ordering data" table provides an overview of the range of reactors available. If you are interested in any of our products or need further assistance, simply copy the query form 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 form is also available on our homepage 7 Siemens LV /3

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

61 SIDAC Filter Reactors Three-phase reactors8 8/2 Application 8/2 Technical specifications 8/3 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

62 SIDAC Filter Reactors Siemens AG 2009 Three-phase reactors Application Low-voltage compensation Load power converters drives PD30_00074 Power system Medium voltage Low voltage Choked reactive-power compensation system nc Nowadays, an increasing number of harmonic-generating loads in our networks are operated with an inductive load. These include fluorescent lamps, dimmers, speed-controlled 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 power costs, transmission losses and the load on transmission and distribution systems. The capacitors required for near-load compensation combine with the feeding transformers and network inductances to form a resonant circuit. This results in an undefined resonance, which, in turn, can increase the harmonics. Filter reactors prevent this physical effect. The capacitors are used to set the filter reactors to a defined series resonant frequency, taking into account an AF ripple control. Filter reactors for low-voltage compensation Technical specifications 8 Degree of protection IP00 according to DIN VDE /EN Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation (for installation altitudes of up to 2000 m above sea level) Version with terminals: 690 V AC Version with flat terminals: 1000 V AC All versions: 600 V AC for 4EP and 4EU according to UL Reduction factor 5.67 %, 7 %, 14 % Performance range P n 5 kvar kvar Monitoring Temperature switch is integrated, contacts are fitted on terminals. Permissible ambient temperature during operation Deviation of the permissible alternating current from the rated alternating current I Ln at coolant temperatures +40 C Temperature classes Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln at installation altitudes > 1000 m above sea level Type 4EP: -25 C C type 4EU: -25 C C See "Configuration notes". Type 4EP: t a 40 C/B Type 4EU: t a 40 C/H 1000 m above sea level See "Configuration notes". Standards/approvals The reactors comply with EN / VDE UL 1561: XQNX2, XQNX8, CSA 22.2 H47 Storage temperatures 25 C C Transport temperatures 25 C C Permissible humidity rating Humidity 5 % % occasional condensation permissible 8/2 Siemens LV

63 SIDAC Filter Reactors Three-phase reactors Selection and ordering data U N = 3 AC 400 V/50 Hz, overload capability I thmax ) nc Max. continuous thermal current Rated current Filter bank capacity Required Inductance capacity for capacitors in delta circuits 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 μf mh W kg kg kg Choking factor p = 5.67 %, L = constant to 1.82 I thmax, f RES = 210 Hz 4EP 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 4EU MA08-4CA F C 4EU MA08-0AA F C 4EU MA08-0AA F C 4EU MA08-0AA F C 4EU MA08-0AA EU Choking factor p = 7 %, L = constant to 1.66 I thmax, f RES = 189 Hz 4EP 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 EU Choking factor p = 14 %, L = constant to 1.4 I thmax, f RES = 134 Hz 4EP 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 4EU MB08-4CA T C 4EU MA08-4CA F C 4EU MA08-0AA F C 4EU MB08-0AA F C 4EU MA08-0AA F C 4EU MA80-0A EU Packaging size for reactors: 1 unit, i.e. 1 unit or a multiple thereof can be ordered. Harmonic voltages taken into account according to EN for public low-voltage systems and according to EN for industrial systems: 110 % mains overvoltage of the fundamental component 6% of U N for 5th harmonic (250 Hz) 5% of U N for 7th harmonic (350 Hz) 3.5 % of U N for 11th harmonic (550 Hz) 3% of U N for 13th harmonic (650 Hz) 1) The current I thmax is the maximum continuous thermal current permitted. It applies to the specified 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 the flat terminations: see "Accessories". Siemens LV /3

64 SIDAC Filter Reactors Siemens AG 2009 Notes 8 8/4 Siemens LV

65 SIDAC Reactors for Special Applications 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-phase and three-phase reactors 9/8 Application 9/8 Technical specifications Single-phase reactors 9/9 Application 9/9 Technical specifications For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

66 SIDAC Sintered Metal Interference Suppression Reactors Three-phase reactors Application n 9 Sintered metal reactor, three-phase Sintered metal reactors for three-phase infeeds comprise three mutually independent single-phase reactors. They are located in the main supply line of converters and connected such that the alternating currents with line frequency and the converter-generated harmonics flow through the reactor. Sintered metal reactors are used where, in addition to a commutation reactor, there is also a need for interference suppression from a low to high frequency range. The special material characteristics of the reactors enable excellent interference suppression up to frequencies of 150 khz. Technical specifications Sintered metal reactor, single-phase The closed design of the pot-type cores reduces radiationlinked interferences to a minimum, thus enabling the installation of reactors in close proximity to electronic devices without adverse effect. They are primarily used in controlled rectifier/regenerative units operating in high-frequency systems. They also offer cost-effective interference suppression in converter connections for uninterruptible power supplies. As individual components, sintered metal reactors can be used as both input and output reactors. Recommended supply voltage U N 3 AC 400 V ± 10 % V AC +6 %, 10 % Maximum converter output frequency If you are interested in any of our products or need further assistance, please Anfrage@mdexx.com 600 Hz Performance range P n kw Frequency Power supply frequency Hz ± 10 % Degree of protection IP00 according to DIN VDE /EN Connection Terminal or customized Rating of creepage distance and clearance Pollution degree 1 according to DIN VDE 0110 Test voltage 2.5 kv AC Permissible ambient temperature during operation 25 C C, for power reduction up to +55 C Temperature classes Installation altitude t a 40 C/H 1000 m above sea level Standards/approvals The reactors comply with EN Storage temperature 25 C C Transport temperature 25 C C Permissible humidity rating Low air temperature 0 C Condensation and ice formation excluded IEC /04.90 Class 3K5 9/2 Siemens LV

67 SIDAC Discharge Reactors Three-phase reactors Application Discharge reactor for low-voltage compensation 34 U V W Discharge reactors for compensation equipment: Capacitor banks in reactive-power compensation equipment are connected and disconnected to and from the mains as required. Connecting the mains to a capacitor bank that is not fully discharged causes mains overvoltages that can damage connected devices. To enable the fastest possible reconnection of a capacitor bank after disconnection, the capacitors must be rapidly discharged. Discharge reactors offer significant advantages here. Compared to the discharge resistors previously used, they cause significantly lower losses and reduce the ambient temperature rise, which serves to extend 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. The high AC resistance means that power losses during operation are lower than 1.8 W, and therefore negligible. UVW 72, PD30_00006a Dimensional drawing and circuit diagram Technical specifications Recommended supply voltage U N Operating losses No-load current Total weight Frequency 3AC230V to 690V AC < 1.8 W < 4.5 ma 0.5 kg Hz Degree of protection IP40 acc. to DIN Connection Terminals for 0.75 mm 2 to 2 x 2 mm 2 Inductance 230 V 730 μh 400 V 710 μh 525 V 670 μh 690 V 350 μh 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) acc. to DIN Standards/approvals The reactors comply with EN Dimensions See Dimensional Drawing Permissible ambient temperature during operation 25 C C (average over 24 h) Storage temperature 25 C C Installation Indoors 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 V Up to 25 kvar Up to 50 kvar Up to 100 kvar < 5 s < 10 s < 20 s Siemens LV /3

68 SIDAC Footprint Reactors Mains Reactors for Frequency Converters Single-phase reactors Siemens AG 2009 Application Mains reactors for frequency converters n Mains reactors for frequency converters are used in line-side infeeds. The reactors limit system perturbations that occur in the form of harmonics and reduce the alternating currents by means of the frequencies caused by the switching of the input rectifier in the DC link capacitors. The use of 2 % reactors is recommended when the network inductance of the supplying network is very small. Recommended network short-circuit power to apparent drive power > 33 : 1. All the aforementioned reactors can be customized 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 Test voltage Reference voltage drop u per phase at I Ln and f = 50 Hz or f = 60 Hz Performance range P n Inductance per phase mh Total power loss W Total weight kg Frequency Degree of protection If you are interested in any of our products or need further assistance, please Anfrage@mdexx.com 3.0 A A 4 kv AC live parts against enclosure 2 %, 4 % (application and type-specific) customized design 0.75 kw kw, higher outputs on request mh (application and type-specific) On request On request Hz Assembly in zinc-plated steel housing in IP20 Connection Line-side bushing terminals, free cable end for connection to frequency converter input, cable according to customer requirements Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation Version with terminals: 600 V AC (for installation altitudes of up to 2000 m above sea level) Permissible ambient temperature during operation 10 C C Deviation of the permissible alternating current On request from the rated alternating current I Ln (at coolant temperatures +40 C) Temperature classes Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln (for installation altitudes > 1000 m above sea level) t a 50 C/F (B) 1000 m above sea level See "Configuration notes". Standards/approvals The reactors comply with EN Electromagnetic compatibility according to EN , 3, 4 Vibration EN All reactors are built in compliance with UL506, approval on request. Dimensions Reactor enclosure with a maximum height of 50 mm for P n 11 kw. Further dimensions on request Storage temperature 20 C C Permissible humidity rating Relative humidity +40 C to 95 % Condensation not permissible 9/4 Siemens LV

69 SIDAC Footprint Reactors Mains Reactors for Frequency Converters Three-phase reactors Application n Mains reactors for frequency converters are used in line-side infeeds. The reactors limit system perturbations that occur in the form of harmonics and reduce the alternating currents by means of the frequencies caused by the switching of the input rectifier in the DC link capacitors. The use of 2 % reactors is recommended when the network inductance of the supplying network is very small. Recommended network short-circuit power to apparent drive power > 33 : 1. All the aforementioned reactors can be customized 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 Test voltage Reference voltage drop U per phase at I Ln and f = 50 Hz or f = 60Hz Performance range of corresponding converter P n Inductance per phase mh Total power loss W Total weight kg Frequency Degree of protection If you are interested in any of our products or need further assistance, please Anfrage@mdexx.com 1.7 A A 4 kv AC live parts against enclosure 2 %, 4 % (application and type-specific) customized design 0.75 kw kw, higher outputs on request 0.07 mh mh (application-specific) On request On request Hz Assembly in zinc-plated steel housing in IP20 Connection Line-side bushing terminals, free cable end for connection to frequency converter input, cable according to customer requirements Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation Version with terminals: 600 V AC (for installation altitudes of up to 2000 m above sea level) Permissible ambient temperature during operation 10 C C Deviation of the permissible alternating current On request from the rated alternating current I Ln Temperature classes t a 50 C/F (B) Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln (for installation altitudes > 1000 m above sea level) 1000 m above sea level See "Configuration notes". Standards/approvals The reactors comply with EN Electromagnetic compatibility according to EN ,3,4 Vibration EN All reactors are built in compliance with UL506, approval on request. Dimensions Reactor enclosure with a maximum height of 50 mm to P n = 22 kw, Maximum height of enclosure 60 mm to P n 75 kw. Further dimensions on request Storage temperature 20 C C Permissible humidity rating Relative humidity +40 C to 95 % Condensation not permissible 9 Siemens LV /5

70 SIDAC Footprint Reactors DC-Link Reactors for Frequency Converters Single-phase reactors Siemens AG 2009 Application DC-link reactors for frequency converters n Link reactors for frequency converters are inserted behind the input rectifier in the voltage link. The reactors limit system perturbations that occur in the form of harmonics and reduce the load current peaks in the DC link capacitors, which greatly reduces component stress in the DC link. This results in longer converter life. DC link reactors can be either permanently integrated in the DC link of the converter during development of the converter, or terminals can be fited that enable an additional inductance to be connected to the DC link. Given the right dimensioning, link reactors can be an alternative to three-phase mains reactors. Their use is recommended when the network inductance of the supplying network is very small. All the aforementioned reactors can be customized 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 Test voltage Performance range of corresponding converter P n Inductance per phase mh Total power loss W Total weight kg If you are interested in any of our products or need further assistance, please Anfrage@mdexx.com 4 A A 4 kv AC live parts against enclosure mh (application and type-specific) 0.75 kw kw, higher outputs on request On request On request Frequency Hz ±10 % Degree of protection Assembly in zinc-plated steel housing in IP20 Connection Shielded cable end for connection to the voltage link input, cable according to customer requirements Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation Version with terminals: 600 V AC (for installation altitudes of up to 2000 m above sea level) Permissible ambient temperature during operation 10 C C Deviation of the permissible alternating current On request from the rated alternating current I Ln Temperature classes t a 50 C/F (B) Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln (for installation altitudes > 1000 m above sea level) 1000 m above sea level See "Configuration notes". Standards/approvals The reactors comply with EN Electromagnetic compatibility according to EN ,3,4 Vibration EN All reactors are built in compliance with UL506, approval on request. Dimensions Reactor enclosure with a maximum height of 50 mm to P n = 22 kw, Maximum height of enclosure 60 mm to P n 75 kw. Further dimensions on request Storage temperature 20 C C Permissible humidity rating Relative humidity +40 C to 95 % Condensation not permissible 9/6 Siemens LV

71 SIDAC Footprint Reactors Iron-Core Output Reactors for Frequency Converters Three-phase reactors Application Output reactors for frequency converters n Output reactors for frequency converters are used at the converter output. The 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. They are used with standard asynchronous motors with a maximum frequency of 200 Hz or with reluctance or permanently excited synchronous motors with a maximum frequency of 120 Hz. They can be operated at a maximum converter output frequency of f max = 400 Hz. No general statement can be made about the maximum permissible length of the motor connection cable when using output reactors. Guide values for the use of shielded and unshielded motor cable in operation with output reactors: 300 m unshielded/ 200 m shielded cable. All the aforementioned reactors can be customized 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 Test voltage Performance range of corresponding converter P n Inductance per phase mh Total power loss W Total weight kg If you are interested in any of our products or need further assistance, please Anfrage@mdexx.com 3.9 A A 4 kv AC live parts against enclosure 0.75 kw kw, higher outputs on request mh mh (application-specific) On request On request Frequency f max = 400 Hz at converter output Clock frequency 4 khz Degree of protection Assembly in zinc-plated steel housing in IP20 Connection 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 distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation Version with terminals: 600 V AC (for installation altitudes of up to 2000 m above sea level) Permissible ambient temperature during operation 10 C C Deviation of the permissible alternating current On request from the rated alternating current I Ln Temperature classes t a 50 C/F Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln (for installation altitudes > 1000 m above sea level) 1000 m above sea level See "Configuration notes". Standards/approvals The reactors comply with EN Electromagnetic compatibility according to EN ,3,4 Vibration EN All reactors are built in compliance with UL506, approval on request. Dimensions Reactor enclosure with a maximum height of 80 mm to P n 75 kw. Further dimensions on request Storage temperature 20 C to +70 C Permissible humidity rating Relative humidity +40 C to 95 % Condensation not permissible 9 Siemens LV /7

72 SIDAC Railway Reactors Siemens AG 2009 Single-phase and three-phase reactors Application On-board network container/acceptor circuit reactor/chopper reactor n These include reactors for operation in electrical railcars. These reactors are used in trams, subway trains and modern highspeed railcars. The components have been specially designed and manufactured for the harsh ambient 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. 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 pulsed chopper current and the short-circuit currents Rod core reactors as a component of the line filter for overvoltage protection and the reduction of line harmonics or DC link harmonic currents Technical specifications 9 Rated alternating current I Ln Available supply voltages Inductance per phase mh If you are interested in any of our products or need further assistance, please Anfrage@mdexx.com From 450 A A 15 kv AC 16 2 / 3 Hz 25 kv AC 50 Hz 1.5 kv DC 0.3 mh 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 On request On request Application-specific 33 1 / 3 Hz, 50 Hz, 100 Hz, Hz IP00, exposed to all weather conditions Total power loss W Total weight kg Frequency Degree of protection Protection class I according to VDE 0106 Connection Free cable, flat copper (application-specific) Installation Hanging, underfloor (application-specific) Cooling CF, forced air cooling Typically m/s at 40 C Climatic conditions Stress due to "damp heat" and "salt mist" IEC Class 5C2 (chemically active materials) IEC Class 5F2 (contaminated materials) IEC Class 5S2 (mechanically active materials) Insulation Up to 25 kv rated voltage for clearances 32 mm clearance (minimum value) 4000 V DC insulation rated voltage for creepage distances Permissible ambient temperature during operation 40 C C Temperature classes t a 40 C/F... t a 65 C/F, t a 55 C/H Mechanical stress IEC /06.90 Vibration, sinusoidal approx. 2 g IEC 9/426/CDV Vibration, broadband noise 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 C 9/8 Siemens LV

73 SIDAC Railway Reactors Application Air-core reactor 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 operation in electrical railcars. These reactors are used in trams, subway trains and modern highspeed railcars. The components have been specially designed and manufactured for the harsh ambient 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 Available supply voltages If you are interested in any of our products or need further assistance, please Anfrage@mdexx.com Up to 600 A 2.3 kv DC Inductance per phase mh 9 mh mh, typical ratings 6 to 9 mh at 230 A A with E = 230 Ws 17 mh for 500 A A Total power loss W On request Total weight kg On request Frequency DC applications, the specified currents allow for an AC ripple of 30 % Degree of protection IP00, exposed to all weather conditions Protection class I according to VDE 0106 Connection Free cable, flat copper (application-specific) Installation Hanging, underfloor (application-specific) Cooling CF, forced air cooling Typically m/s at 40 C Climatic conditions Stress due to "damp heat" and "salt mist" IEC Class 5C2 (chemically active materials) IEC Class 5F2 (contaminated materials) IEC Class 5S2 (mechanically active materials) IEC Class 5K3 (climatic category) IEC Class 5B2 (biologically active materials) Insulation Up to 12 kv rated voltage for clearances >20 mm clearances (minimum value) 1900 V DC insulation rated voltage for creepage distances Permissible ambient temperature during operation 30 C C Temperature classes t a 60 /H Mechanical stress IEC /06.90 Vibration, sinusoidal approx. 2 g IEC 9/426/CDV Vibration, broadband noise IEC /08.89 Shock UIC 566 Vibration and shock resistance Standards/approvals The reactors comply with VDE 0535, EN Dimensions On request Storage/transport temperature -40 C C 9 Siemens LV /9

74 SIDAC Railway Reactors Siemens AG 2009 Notes 9 9/10 Siemens LV

75 SIDAC Radio Interference Suppression Filters 10 Single-phase filters 10/2 Application 10/3 Technical specifications 10/4 Selection and ordering data Three-phase filters 10/2 Application 10/3 Technical specifications 10/4 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

76 SIDAC Radio Interference Suppression Filters Single-phase filters, three-phase filters Application AC drives without reactors/filters Voltage Current Mains reactors Chapter 3 with output reactors Chapter Converter with dv/dt-filters Chapter 11 Motor RFI suppression filters Chapter 10 with sinewave filters Chapter 12 PD30_00073 Radio interference suppression filters for AC drives 10 DC drives Mains reactors/ commutation reactors Chapter 2 RFI suppression filters Chapter 10 Power Converter Smoothing reactors Chapter Power system PD30_00068 Motor Radio interference suppression filters for DC drives Radio interference suppression filters for frequency converters are used in line-side supply cables to attenuate conducted RF interference voltages. Using radio interference suppression filters enables compliance with interference suppression level A or B according to EN It is also possible to use significantly longer motor connection 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-wire filters are also available for the interference suppression of complete control cabinets. Customized versions enable solutions that are optimally tailored to specific applications. For example, using combination filters (radio interference suppression filter and output reactor) it is possible to increase the length of the motor cable still further while maintaining the required level of radio interference suppression. Combining the radio interference suppression filter with a mains reactor enables further reduction of system perturbations. For further advice Anfrage@mdexx.com 10/2 Siemens LV

77 SIDAC Radio Interference Suppression Filters Single-phase filters, three-phase filters Technical specifications Recommended supply voltage U N See "Selection and ordering data". Rated alternating current I Ln Leakage current at U N and 50 Hz Drive power for 2 AC 230 V/3 AC 400 V DC resistance mω 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/enclosure Permissible overload 1.5 I Ln for 3 min 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) Test according to EN Standards EN Approvals See "Selection and ordering data" Compliant with UL1283, FOKY2, FOKY8 and CSA22.2 No Siemens LV /3

78 SIDAC Radio Interference Suppression Filters Single-phase filters, three-phase filters Selection and ordering data 10 4EF15, single-phase, BsRKI Typical drive power 4EF15, singlephase, BsRKI Recommended filter class 1) Rated current 4EF15, three-phase, BsRKI Leakage current DC resistance 4EF15, three-phase, F Connection 2) Degree of protection 4EF15, three-phase, BsRKI/frE Approvals DT Order No. Total weight approx. P drive kw I Ln A I leak ma R typ mω IP U cu q kg 1 AC 250 V 50/60 Hz for converters and power converters 230 V 0.75 A 3) 10 < BsRKl 20 x x x C 4EF AA A 3) 20 < BsRKl 20 x x x C 4EF AA B 8 < BsRKl C 4EF AA B 12 < BsRKl C 4EF AA B 16 < BsRKl C 4EF AA B 25 < BsRKl C 4EF AA ) 4) 3 AC 520 V 50/60 Hz for converters and power converters 480 V 2.2 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 C 4EF AA AC 480 V 50/60 Hz for converters and power converters 480 V 2.2 B 8 < BsRKl / fre C 4EF AA B 16 < BsRKl / fre C 4EF AA B 25 < BsRKl / fre C 4EF AA B 36 < BsRKl / fre C 4EF AA B 50 < BsRKl / fre C 4EF AA B 66 < BsRKl / fre C 4EF AA B 90 < BsRKl / fre C 4EF AA B 120 < BsRKl / fre C 4EF AA B 150 < BsRKl / fre C 4EF AA B 200 < BsRKl / fre C 4EF AA N AC 520/300 V 50/60 Hz for converters and power electronics 8 < S 20 x x -- D 4EF AA < S 20 x x -- D 4EF AA < S 20 x x -- D 4EF AA < S 20 x x -- D 4EF AA < S 20 x x -- D 4EF AA < S 20 x x -- D 4EF AA < S 20 x x -- D 4EF AA < S 20 x x -- D 4EF AA < S 20 x x -- D 4EF AA < S 20 x x -- D 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. The ratings of the converter must be taken into account when selecting a filter. Always ensure correct installation of filters and any additional pertinent measures for compliance with the EMC Directive. 2) BsRKl: Finger-safe terminal block BsRKl / fre: Finger-safe terminal block / free ends F: Flat terminal S: Screw terminals 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. 10/4 Siemens LV

79 SIDAC dv/dt Filters Siemens AG Three-phase filters 11/2 Application 11/2 Technical specifications 11/3 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

80 SIDAC dv/dt Filters Siemens AG 2009 Three-phase filters Application n AC drives without reactors/filters Voltage Current Mains reactors Chapter 3 with output reactors Chapter Converter with dv/dt-filters Chapter 11 Motor RFI suppression filters Chapter 10 with sinewave filters Chapter 12 PD30_ dv/dt filter for AC drives Dv/dt filters comprise a limiter circuit and a reactor, or a reactor only. The filter is installed at the output of frequency converters, and motor currents flow through the reactor. Connection of a filter to the three-phase system at the output of the frequency converter reduces transient voltage peaks and limits the voltage gradients in the motor winding to non-critical values of less than Technical specifications Recommended supply voltage U N Rated alternating current I Ln Test voltage Performance range of the drive Total power loss W Total weight kg Frequency 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 the motor cable. Specifications for motor cable lengths: m shielded motor cable m unshielded motor cable 3 AC 500 V/690 V Up to approx. 860 A Version-dependent Up to approx. 800 kw On request On request f max = 200 Hz at converter output Clock frequency 4 khz Degree of protection IP00 according to DIN VDE /EN Protection class I according to DIN VDE /05.82 IEC 536/1976 Connection Flat terminal/terminals according to performance class Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Permissible ambient temperature during operation 0 C C Deviation of the permissible alternating current from the rated alternating current I Ln (at coolant temperatures +40 C) Temperature classes Installation altitude Deviation of the permissible alternating current from the rated alternating current I Ln (for installation altitudes > 1000 m above sea level) On request Version-dependent 1000 m above sea level See "Configuration notes". Standards/approvals The reactors comply with EN Storage temperature 25 C C Transport temperature 25 C C Permissible humidity rating Humidity 5 % % occasional condensation permissible 11/2 Siemens LV

81 SIDAC dv/dt Filters Three-phase filters Selection and ordering data Max. permissible continuous thermal current 4kHz Rated current Connections T = Terminal F = Flat termination DT Order No. stem I thmax A I Ln A 3 AC 200 Hz 400 V/500 V, 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 customized dv/dt filters", see "Specification Sheets". The specified data will enable us to make a detailed offer. The offer will also contain details of delivery times and dimensions. 11 Siemens LV /3

82 SIDAC dv/dt Filters Siemens AG 2009 Notes 11 11/4 Siemens LV

83 SIDAC Sinewave Filters 12 Three-phase filters 12/2 Application 12/2 Technical specifications 12/3 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

84 SIDAC Sinewave Filters Siemens AG 2009 Three-phase filters Application nc AC drives without reactors/filters Voltage Current Mains reactors Chapter 3 with output reactors Chapter Converter with dv/dt-filters Chapter 11 Motor RFI suppression filters Chapter 10 with sinewave filters Chapter 12 PD30_00073 Sinewave filters for AC drives Sinewave filters are 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 almost sinusoidal motor voltages and currents are produced at the motor. 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. The use of sinewave filters enables EX(d) motors to be converter-fed 1). Permissible motor cable lengths when using sinewave filters: m shielded motor cable m unshielded motor cable Technical specifications 12 Recommended supply voltage U N See the table "Selection and ordering data" Rated alternating current I Ln Total power loss W Total weight kg Test voltage 3.6 kv DC, live parts against enclosure Performance range of the drive 1.5 kw kw, higher outputs on request Frequency f max = 150 Hz, clock frequency 4 khz 8 khz Degree of protection IP00 according to DIN VDE /EN Finger-safe terminals according to BGV A2 Protection class I according to DIN VDE /05.82, IEC 536/1976 Connection Finger-safe terminals Rating of creepage distance and clearance Pollution degree 2 according to DIN VDE 0110 Rated voltage for insulation (for installation altitudes of up to 1000 m above sea level) 500 V AC Permissible ambient temperature during operation 0 C C Deviation of the permissible alternating current See "Configuration notes". from the rated alternating current I Ln (at coolant temperatures +40 C) Temperature classes t a 40 C/F or t a 40 C/H depending on design rating Installation altitude 1000 m above sea level Deviation of the permissible alternating current See "Project planning aids". from the rated alternating current I Ln (at installation altitudes > 1000 m above sea level) Standards/approvals The reactors comply with EN , UL 508: Device assembly Storage temperature 25 C C Transport temperature 25 C C Permissible humidity rating Humidity 5 % % 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 operating conditions. 12/2 Siemens LV

85 SIDAC Sinewave Filters Three-phase filters Selection and ordering data 4EF11 4EF11 Typical drive power Max. permissible 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. P drive I thmax I Ln L x P V kw A A mh W kg kg kg 3 AC 480 V + 10 % 150 Hz, clock frequency 4kHz 8kHz 400 V T C 4EF GB T C 4EF GB T C 4EF GB T C 4EF GB T C 4EF GB T D 4EF GB T D 4EF GB T D 4EF GB T D 4EF GB T D 4EF GB T X 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 7.5 kw/2.5 mm² - >7.5kW 11 kw/4 mm² - >11kW 22 kw/10 mm² - >22kW 30 kw/16 mm² - >30kW 37 kw/25 mm² - >37kW 50 kw/35 mm² - >50kW 75 kw/70 mm² - 75 kw/150 mm² Maximum clock frequency: 8 khz Maximum motor frequency of output reactor: 200 Hz Maximum motor frequency of sinewave filter: 150 Hz If these do not meet your requirements, customized solutions are available. For further information, please contact "mdexx GmbH" in Bremen: Anfrage@mdexx.com Use of 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 operating conditions. 12 Siemens LV /3

86 SIDAC Sinewave Filters Siemens AG 2009 Notes 12 12/4 Siemens LV

87 SIDAC Specification Sheets 13 Query forms 13/2 Specification sheet for customized reactors 13/3 Specification sheet for customized smoothing reactors, with selectable inductance and current 13/4 Specification sheet for customized radio interference suppression filters 13/5 Specification sheet for customized dv/dt filters 13/6 Specification sheet for customized sinewave filters For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

88 SIDAC Specification Sheets Query Form Specification sheet for customized reactors Siemens AG 2009 Recipient mdexx GmbH Fax: Tel: /-616/ Sender Company: Department: Name: City: Tel.: Fax: Date: Three-phase Please specify all currents and voltages as rms 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]: Choking [%]: 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[%] = *) Please list any other currents or frequencies below. U 13[%] = I 13[%] = 13 General information Ambient temperature: Operating mode: Degree of protection: 40 Continuous ON-time IP23 Varying load according to Book 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]: η: I noutput [A]: Operating load in [%] of P n : U N [V] = I n [A] = p.f. = U DC link [V]: M = constant Permissible overload in [%] of I noutput : M ~ n 2 (fan, pump) U/min n : U/min operation : from: to: Special features / comments: Start of delivery: No. of items: per annum/per order Target price: Dimensional Load Electrical data of 13/2 Siemens LV

89 SIDAC Specification Sheets Query Form Specification sheet for customized smoothing reactors, with selectable inductance and current Recipient mdexx GmbH 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 rms values! Iron-core smoothing reactors Iron-core smoothing reactors Air-core smoothing reactors I x = I dn L x = L 0 I x > I dn L x L 0 Rated direct current I dn [A] Inductance [mh] at I dn Inductance L x [mh] at I x (I max ) Inductance L 0 [mh] at I d = 0A Connection of converter No-load voltage of converter U di [V] Power supply frequency f [Hz] Ambient temperature Additional data 1) Required Required Required 1) If you have any special requirements with regard to the pollution degree, reference voltage for the rating of insulation, etc., please enter below under "Comments". Special features / comments: 13 Start of delivery: No. of items: per annum/per order Target price: Dimensional Load Electrical data of Siemens LV /3

90 SIDAC Specification Sheets Query Form Specification sheet for customized radio interference suppression filters Siemens AG 2009 Recipient mdexx GmbH Fax: Tel: /-616/ Sender Company: Department: Name: City: Tel.: Fax: Date: Application: Please specify currents and voltages as rms Radio interference suppression filters P nfu [kw]: I n [A]: U line [V]: I deriv [ma]: f line [Hz]: Adherence to interference A Industry, EN "Second B Living and business, EN "First Environment" Option Commutation reactors: Option Output u D = 2 u D = 4 u D = % f max [Hz]: f clock [Hz]: Maximum required length of motor supply cable Shielded Unshielded cable Cable type = Coatings if known: L [mh/m]= C [nf/m] = 13 General information: Ambient temperature: Operating mode: Degree of protection: Continuous ON-time Varying load according to specifications Please enter any alternative or supplementary data on converters and motors: Converters IP00 Book Acc. to customer specifications Rated power P n [kw]: P n [kw]: η: I noutput [A]: Operating load in [%] of P n : U n [V]: I n [A]: p.f.: U DC link [V]: M = constant Permissible overload in [%] of I noutput : M ~ n 2 (fan, pump) U/min n : U/min operation : from: to: Special features / comments: Start of delivery: No. of items: per annum/per order Target price: Dimensional Load Electrical data of 13/4 Siemens LV

91 SIDAC Specification Sheets Query Form Specification sheet for customized dv/dt filters Recipient mdexx GmbH Fax: Tel: /-616/ Sender Company: Department: Name: City: Tel.: Fax: Date: Application: Please specify currents and voltages as rms dv/dt filters P nfu [kw]: I n [A]: U line [V]: f max [Hz]: f clock [Hz]: Maximum required length of motor supply cable Shielded Unshielded cable Cable type = Coatings if known: L [mh/m]= C [nf/m] = General information: Ambient temperature: Operating mode: Degree of protection: Continuous ON-time Varying load according to IP00 Book 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]: η: I noutput [A]: Operating load in [%] of P n : U n [V]: I n [A]: p.f.: U DC link [V]: M = constant Permissible overload in [%] of I noutput : M ~ n 2 (fan, pump) U/min n : U/min operation : from: to: 13 Special features / comments: Start of delivery: No. of items: per annum/per order Target price: Dimensional Load Electrical data of Siemens LV /5

92 SIDAC Specification Sheets Query Form Specification sheet for customized sinewave filters Siemens AG 2009 Recipient mdexx GmbH Fax: Tel: /-616/ Sender Company: Department: Name: City: Tel.: Fax: Date: Application: Please specify currents and voltages as rms Sinewave filters P nfu [kw]: I n [A]: U line [V]: f max [Hz]: f clock [Hz]: Maximum required length of motor supply cable Shielded Unshielded cable Cable type = Coatings if known: L [mh/m]= C [nf/m] = General information: Ambient temperature: Operating mode: Degree of protection: Continuous ON-time Varying load according to IP00 Book 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]: η: I noutput [A]: Operating load in [%] of P n : U n [V]: I n [A]: p.f.: U DC link [V]: M = constant Permissible overload in [%] of I noutput : M ~ n 2 (fan, pump) U/min n : U/min operation : from: to: Special features / comments: Start of delivery: No. of items: per annum/per order Target price: Dimensional Load Electrical data of 13/6 Siemens LV

93 SIDAC Accessories Siemens AG Terminal covers 14/2 Selection and ordering data For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

94 SIDAC Accessories Siemens AG 2009 Terminal covers Selection and ordering data Version DT Order No. PS* Weight per PU approx. kg Terminal covers for protection against accidental contact with exposed busbar connections (DIN VDE 0106 Part 100/EN 50274) The covers are suitable for all reactors and filters with 1-hole flat terminations. Terminal covers can be assigned to the appropriate reactors and filters using 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 on free screw end. Covers one busbar connection (1 set = 6 units). M6 B 3TX B 1 unit M8 B 3TX B 1 unit M10 B 3TX B 1 unit M12 D 3TX B 1 unit /2 Siemens LV * You can order this quantity or a multiple thereof.

95 SIDAC Configuration Notes 15 Technical information Reactors and filters 15/2 Overview 4EM single-phase reactors Single-phase reactors 15/6 Dimensional drawings 4ET single-phase reactors Single-phase reactors 15/7 Dimensional drawings 4EP three-phase reactors Three-phase reactors 15/9 Dimensional drawings 4EU three-phase reactors Three-phase reactors 15/11 Dimensional drawings Air-core smoothing reactors Single-phase reactors 15/13 Dimensional drawings 4EM, 4ET, 4EP, 4EU single-phase and three-phase reactors Single-phase and three-phase reactors 15/14 Circuit diagrams Sinewave filters Three-phase filters 15/15 Dimensional drawings 15/15 Circuit diagram Radio interference suppression filters Single-phase filters 15/16 Characteristic curves 15/21 Dimensional drawings 15/30 Circuit diagrams Three-phase filters 15/16 Characteristic curves 15/22 Dimensional drawings 15/30 Circuit diagrams For technical information please visit under Product list: - Technical specifications under Entry list: - Updates - Download - FAQ - Manuals - Characteristics - Certificates and under - Configurators Siemens LV

96 SIDAC Configuration Notes Technical Information Reactors and filters Siemens AG 2009 Overview General information Inductance The inductance of the iron or ferrite-yoke-based reactors depends on the core material and the dimensioning of the core, winding and air gap. It is a function of the saturation state of the core and is thus current-dependent. In the case of air-core reactors, the inductance depends solely on the dimensioning of the winding. Losses A loss balance can be determined during configuration using the iron losses P Fe and winding losses P W specified in the "Selection and ordering data". Deviations of rated values - Reduction of the rated voltage/rated current, depending on installation altitude and coolant temperature Max. permissible current 100 % C 80 Coolant temperature Deviation of the permissible direct current from the rated direct current I dn, or of the permissible alternating current from the rated alternating current I n (at coolant temperatures 40 C) Characteristic curve 74 applies to 4EU, 4ET and 4PK reactors Characteristic curve 72 applies to 4EP, 4EM and 4EF11 reactors Max. permissible current Deviation of the permissible direct current from the rated direct current I dn, or of the permissible alternating current from the rated alternating current I n (at installation altitudes > 1000 m above sea level) Max. permissible rated voltage 100 % % EP series 4EU series PD30_00055 PD30_ m 5000 Site altitude 67 Radio interference suppression filters can be operated with a current derating. For further details, see: Radio interference suppression filters can be operated with a current derating, taking into account the following characteristic curve. The current derating can be calculated as follows: I (TA) = I Ln x (I/I R ) I (TA) : Operational current at ambient temperature TA I Ln : Rated current I/I R : Factor to be taken from the following table Current derating characteristic curve The curves apply to the specified conditions: Curve I IR 1.2 1) See rating plate or product description, Ident. No. to EN : e.g. 25/100/21, whereby the upper category temperature is the middle value. Permissible mounting position Example Rated temperature/ Upper category temperature 40/085 40/100 60/085 60/ C 110 T A Rated temperature T A Upper category temperature 1) 40/ C 85 C 40/ C 100 C 60/ C 85 C 60/ C 100 C A B C EP, 4EU, 4ET, 4EM 4EP, 4EM 4EP, 4EM Mounting position of reactors $ Cooling air flow Mounting instructions for 4ET and 4EU reactors can be found at: A B C PD30_ m 5000 Site altitude Reduction of the rated voltage for insulation (at installation heights > 2000 m above sea level) PD30_ EF EF11, I 17.5 A Permissible mounting position for sinewave filters $ Cooling air flow 15/2 Siemens LV

97 SIDAC Configuration Notes Technical Information Reactors and filters Clearance from adjacent components When installing products from Catalog LV 60 in control cabinets, we recommend a clearance of approx. 100 mm from adjacent components. This clearance ensures heat dissipation from the reactors and filters. More information on operating temperatures: Operation according to EN Standards Reactors from the 4EU and 4ET series are in temperature class H, but the specification of the rated alternating current I thmax is based on utilization according to temperature class F. These reactors can handle a continuous overload of 6 %, which means they then reach the permissible overtemperature for temperature class H. Operation with varying load, overload Reactors can be operated with overload, for further details, see: Reactors cannot be continuously overloaded (exception: reactors that are insulated according to temperature class H but whose data are specified as corresponding to utilization according to temperature class F). Momentary overloads are permissible if the following conditions are complied with: I L k = n 2 I Lk t k k= 1 = I SD Ln I I L1 t 1 + I L2 t2 + I L3 t3 L = I SD Ln The cycle duration CD of the load cycle is 10 min. CD > 10 min corresponds to uninterrupted duty for reactors. The rms value of the load during the cycle duration does not exceed the rated current of the reactor. The overloads during the cycle duration do not exceed 10 times the rated current of the reactor. Commutation and mains reactors Inductance The inductance L x specified in the "Selection and ordering data": Applies to commutation reactors for operation at I max. Applies to mains reactors for operation at I thmax. The tolerance of the inductance is ± 10 %. Inductance curve The curves of inductance of the commutation reactors and mains reactors differ significantly. The inductance is virtually constant up to the rated current I Ln, Mains reactors still have 90 % of the rated inductance at 1.6 times the rated current I Ln. Commutation reactors have a residual inductance of 60 % at 2.0 times the rated current I Ln. Typical curves of inductance over the reactor current: N ' & $ " 2,! # % $! " Typical inductance curve of a mains reactor over the reactor current N & $ " 2,! # &! " Typical inductance curve of a commutation reactor over the reactor current Example: operation with varying load Operating the reactors above the rated alternating current I Ln will increase the noise level of the reactors. Voltage drop ΔU or reference voltage drop u D A voltage drop of Δ U per reactor phase is specified for threephase reactors when loaded with the maximum permissible continuous thermal current I thmax and power supply frequency f = 50 Hz or 60 Hz. The percentage voltage drop u D is calculated as follows: For converter connection B6: ΔU u D = in % U N The inductance per reactor phase is: L x = ΔU ω ω =2π x f I thmax where f = power supply frequency (50 Hz or 60 Hz) 15 Siemens LV /3

98 SIDAC Configuration Notes Technical Information Reactors and filters Siemens AG Recommended supply voltage U N, reference voltage drop u D and insulation rating The "Selection and ordering data" specifies a recommended supply voltage U N for the reactors. The percentage voltage drops u D assigned to the reactors also apply to the recommended supply voltage U N. The rated voltage for the insulation specified in the "Selection and ordering data" also allows the use of reactors at voltages that deviate from the recommended supply voltage U N, as long as they are lower than or equal to 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 ΔU / reference voltage drop u D ". A reactor with the reference voltage drop u D specified as a percentage has the same effect on the system as a transformer with the same u K. Operation with power supply frequency 50 Hz and 60 Hz For commutation reactors and mains reactors, the rated currents I thmax or I Lmax for reactors specified in the "Selection and ordering data" apply. Some of these are only intended for use with power supply frequency f= 50 Hz. Operation of the reactors with power supply frequency f= 60 Hz is permissible. In this case, the permissible rated current I Ln is reduced to 90 %. I Ln (60 Hz) = 0.9 x I Ln (50 Hz) For the application of mains reactors, 2 % and 4 % u K versions are available, which are suitable for operation on a 3-AC- 400/480-V-50/60-Hz power system. These reactors can be operated on 60 Hz power systems without a reduction of the rated current. Losses The losses specified in the "Selection and ordering data" apply to commutation reactors at a rated current I thmax and f= 50Hz, as well as operation at 0.9 x I thmax at power supply frequency f= 60Hz. In the case of mains reactors rated for power systems with f= 50 Hz, the following formula must be applied to determine core losses for operation with 60 Hz: P Fe60 = 1.3 x P Fe50 Output reactors See the manual "Output filters for frequency converters": See the operating instructions "Output reactors": Smoothing reactors Direct current I d, rated direct current I dn All data pertaining to "direct currents I d " in this catalog refer to rms values (determined from the mean value and the superimposed periodic quantity). This takes into account the frequencies of the superimposed alternating currents produced by 2 or 6-pulse converter connections. The data apply to power supply frequencies of 50 Hz Hz. Ripple of direct current The rating of the reactors is based on the following definition of the ripple: W i = I rms / I ar x 100 [%] I rms = rms value of the superimposed alternating current Wi = ripple of the direct current I d I ar = arithmetic mean value of the direct current Determination of the required energy content E The determining value for selecting smoothing reactors is the energy content E E = ½ x L x I 2 d in [Ws] The selection tables specify the maximum possible energy content for each reactor type. Filter reactors Filter circuit application with reactor and capacitor The resonant frequency f R can be determined as follows: f R = π Cy Lx C y, L x see Selection and ordering data Degree of choking p 5.67 % 210 Hz 7% 189Hz 14 % 134 Hz As significant harmonics generally occur in the range of the 5th harmonic (250 Hz/300 Hz), the closer the resonant frequency is to the 5th harmonic, the better the suppression of these interferences. Performance-adapted version Voltage overshoots occur at the capacitor in the resonant circuit formed by the reactor and the capacitor. If the capacitance is precisely defined, these voltage overshoots can be taken into account. By selecting a suitable reactor with the correct inductance, it is possible to determine the compensation characteristics required by the customer. The reactors described in this catalog are dimensioned to allow adjustment of their performance. Non-adapted version Choking can be retrofitted in existing unchoked compensation equipment. As standard capacitors are generally used in such cases, the use of non-adjusted reactors causes a voltage overshoot at the capacitors, which may need to be taken into account when dimensioning the capacitors. The standard choking factors are not reached precisely. Radio interference suppression filters See manual and operating instructions "Radio interference suppression filters": Sinewave filters Resonant frequency f R See the manual "Output filters for frequency converters": See operating instructions "Sinewave filters": 15/4 Siemens LV

99 SIDAC Configuration Notes Technical Information Reactors and filters Connection General information on reactors Torque for current-carrying connections: Thread φ Nm M6 6 M8 13 M10 25 M12 50 Torque S3 Data for terminal connection: Screw terminals are not suitable for connecting finely stranded conductors with soldered ends. Terminals Terminal dimensions Stripped length Screw connection for cable type and cross-section Tightening torque W H D Solid Stranded Finely stranded EN Type mm mm mm mm mm² mm² mm² Nm 8WA DG WA DH WA WA /kr RKW TRKSD WA WA Radio interference suppression filters You will find details on connection in the following manual: Sinewave filters Typical drive power Order No. Screw terminal Tightening torque Cross-section kw mm² Nm 1.5 4EF GB EF GB EF GB EF GB EF GB EF GB EF GB EF GB EF GB EF GB EF GB Siemens LV /5

100 SIDAC Configuration Notes 4EM Single-Phase Reactors Single-phase reactors Dimensional drawings Siemens AG 2009 e 2 e 1 PD30_00012 h 1 PD30_00014a h 2 n 2 d 1 d 2 l 2 n 1 b 1 4EM ( 40 A) 4EM (I Ln 22 A to 50 A) n 2 d 1 d 2 l 2 n 1 b 1 8WA9 200 terminal (for I dn = 21 A) Cross-sections: Solid: 0.5 mm mm 2 Finely stranded: 0.5 mm mm 2 RKW110 or TRKSD10 terminal (for I dn = 22 A to 40 A) Cross-sections: Solid: 1 mm mm 2 Finely stranded: 1 mm mm 2 DA d 3 n 2 Mounting holes n 1 8WA1 204 terminal Crosssections Solid: 0.5 mm mm 2 Stranded: 10 mm mm 2 Finely 2.5 mm mm 2 stranded: Type b 1 d 1 d 2 d 3 e 1 e 2 h 1 h 2 l 2 n 1 n 2 With terminal connections, for any 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 a 1 a 2 e 1 PD30_00015 s 1 DA d4 h 1 d 3 n 1 Rated current to a 1 a 2 d 4 s 1 Flat terminal 100 A A A n 2 d 1 d 2 l 2 4EM > 40 A n 1 b 1 n 2 Mounting holes 15 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) With flat terminals, for any 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 /6 Siemens LV

101 SIDAC Configuration Notes 4ET Single-Phase Reactors Single-phase reactors Dimensional drawings Versions 4ET36 to 4ET47 (shown without terminals) Versions 4ET25 to 4ET30 (shown without terminals) 8WA DG11 terminal (for I dn = 21 A) b 3 = 30 mm Cross-sections: Solid: 0.5 mm mm 2 Finely stranded: 0.5 mm mm 2 8WA DH11 terminal (for I dn = 22 A to 27 A) b 3 = 30 mm Cross-sections: Solid: 0.75 mm mm 2 Finely stranded: 1.5 mm mm 2 8WA1 204 terminal (for I dn = 20 A to 50 A) b 3 = 38 mm Cross-sections: Solid: 1.0 mm mm 2 Stranded: 10 mm mm 2 Finely stranded: 2.5 mm mm 2 Terminals 4ET36 to 4ET47, 4ET25 to 4ET30 DA n 2 Mounting holes d 3 Flat terminals 4ET36 to 4ET47, 4ET25 to 4ET30 n 1 Type b 1 b 2 d 1 d 2 d 3 e h h 2 h 3 l 1 l 2 l 4 n 1 n 2 b 3 Rated direct current I dn 50 A, with terminal connections, for arrangement on horizontal surfaces 4ET M See terminals 4ET M above 4ET M ET M ET M ET M ET M ET M Rated current a 1 a 2 a 3 a 4 a 5 to Flat terminal 200 A A A Flat terminals 4ET36 to 4ET47, 4ET25 to 4ET30 15 Siemens LV /7

102 SIDAC Configuration Notes 4ET Single-Phase Reactors Single-phase reactors 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 e h b 2 DA n 1 Siemens AG 2009 M16 n 1 l 2 d 1 n 2 b 1 DA d 3 l 1 4ET72 to 4ET80 n 2 Mounting holes 15 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) c) G_PD30_DE_00132 a 6 a 2 a 5 a 7 a 4 DA a 5 a 6 a 7 a 4 a 1 a 2 a 3 Rated current to a 1 a 2 a 3 a 4 a 5 a 6 a 7 a) Flat terminal 100 A A A A A A b) Flat terminal 1250 A A c) Flat terminal 2500 A /8 Siemens LV

103 SIDAC Configuration Notes 4EP Three-Phase Reactors Three-phase reactors Dimensional drawings DA a 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 4EP 40 A to 50 A n 2 n 4 l 2 n 1 n 3 b 1 4EP 48 A Ground studs M6 x 12 for connecting cables with ring terminal lugs DA a n 1 n 3 d 3 Mounting holes n 2 n 4 8WA9 200 terminal 8WA1 304 terminal (for I Ln 15 A) (for I Ln = 40 A to 50 A) Cross-sections: Solid: 0.5 mm mm 2 Cross-sections: Solid: 1 mm mm 2 Finely stranded: 1.5 mm mm 2 Stranded: 10 mm mm 2 Finely stranded: 2.5 mm mm 2 RKW110 or TRKSD10 terminal Corresponding ground terminal EK16/35 (for I Ln 16 to 48 A) Cross-sections: Solid: 2.5 mm mm 2 Cross-sections: Solid: 1 mm mm 2 Finely stranded: 4 mm mm 2 Finely stranded: 1 mm mm 2 Ground studs M6 x 12 Cross-sections: Solid: 2.5 mm mm 2 Finely stranded: 4 mm 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 48 A, terminal connections for any arrangement of reactors 4EP M ) ) 4EP M ) 4EP M EP M EP M EP M EP M EP M EP M EP M EP M I Ln 40 A to 50 A, terminal connections for any arrangement of reactors 4EP M EP M EP M EP M ) Fixing slot in the base center. 15 Siemens LV /9

104 he SIDAC Configuration Notes 4EP Three-Phase Reactors Three-phase reactors Siemens AG 2009 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 Ground studs M6 x 12 for connecting cables with ring terminal lugs n 1 n 3 b 1 n 2 n 4 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 terminal for any arrangement of reactors 4EP M EP M EP M EP M EP M Flat terminal I Ln a 1 a 2 a 3 a 4 a 5 Flat terminal A A /10 Siemens LV

105 SIDAC Configuration Notes 4EU Three-Phase Reactors Three-phase reactors Dimensional drawings l 4 l 1 e 1max e 2max A e 3max l 5 PD30_00007 b h max DA n 1 d 1 d 2 l 2 b 1 4EU24 to 4EU36 n 2 Mounting holes d 3 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 Grounding For 4EU24 to 4EU36 with flat terminals, 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 b e l 1 h DA d 4 d 4 n 1 d 1 d 2 d 3 n 2 n 1 l 2 b 1 4EU39 to 4EU51 n 2 Mounting holes Type b 1 d 1 d 2 d 3 e 1 max e 1 max Chapter 3 h max l 1 l 2 l 4 n 1 n 2 Grounding For 4EU39 to 4EU56 with flat terminals, 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 4EU M M12 4EU M M12 4EU M M12 4EU M M12 4EU M M12 l 4 Version with 10 mm 2 terminal for arrangement of reactors on horizontal surfaces PD30_00010a l 1 e h Type b 1 d 1 d 2 d 3 e max h max l 1 max l 2 l 4 n 1 n 2 4EU M EU M d 1 d 2 4EU25, 4EU27 n 2 l 2 n 1 b 1 Siemens LV /11

106 SIDAC Configuration Notes 4EU Three-Phase Reactors Three-phase reactors Siemens AG 2009 a 5 a 7 a 1 DA a 4 Versions up to 1000 A Versions > 1000 A a 6 a 3 a 2 Versions > 1600 A Flat terminal 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 80 A A A A A A For 4EU39 to 4EU56, for arrangement of reactors on horizontal surfaces 45 A A A A A A A A A A A A A A A A Exception - Chapter "Reactors for frequency converters" Versions up to 1000 A Versions > 1000 A 15 Flat terminal 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 terminals, for arrangement of reactors on horizontal surfaces 200 A A A A A A For 4EU39 to 4EU51 with flat terminals, for arrangement of reactors on horizontal surfaces 200 A A A A A A A /12 Siemens LV

107 a 3 Siemens AG 2009 SIDAC Configuration Notes Air-Core Smoothing Reactors Single-phase reactors Dimensional drawings Flat terminals 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 PK60 as agreed with the customer Ironless zone Distance between two reactors axial 500 axial 500 radial 300 radial Siemens LV /13

108 SIDAC Configuration Notes 4EM, 4ET, 4EP and 4EU Single-Phase and Three-Phase Reactors Single-phase and three-phase reactors Circuit diagrams Terminal designations 1 2 Siemens AG 2009 DA EM, 4ET reactors 1U1 1V1 1W1 1U2 1V2 1W2 DA a 4EU, 4EP reactors 4ET reactors, series connection, high inductance, low current 4ET reactors, parallel connection, low inductance, high current 15 15/14 Siemens LV

109 SIDAC Configuration Notes Sinewave Filters Three-phase filters Dimensional drawings PE b 2 d n 3 n 4 h n 4 l 2 n 3 b 1 4EF11 (for drives from 1.5 kw to 7.5 kw) b PD30_00017a 4EF11 (for drives from 11 kw to 132 kw) Drawing example, solutions available with different quantities of capacitors, whereby the dimensions are the same Filter with drive power b max b 1 b 2 max d h max l 2 n 3 n 4 Grounding 4EF11 sinewave filters for drives with 1.5 kw to 7.5 kw drive power, for any arrangement 1.5 kw/2.2 kw M M6 4.0 kw M M6 7.5 kw M M6 Filter with drive power b max b 1 b 2 d h max l 2 n 1 n 2 Grounding 4EF11 sinewave filters for drives with 11 kw to 132 kw drive power, for arrangement of filters on horizontal surfaces 11 kw M x M6 22 kw/30 kw M x M6 45 kw M x M6 75 kw M x M8 90 kw M x M8 132 kw M x M8 Circuit diagrams 15 Siemens LV /15

110 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase and three-phase filters Siemens AG 2009 Characteristic curves 120 db 100 PD30_ db 100 PD30_ db 80 PD30_ EF1510-1AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA00, I rms = 10 A 100 db 80 PD30_ EF1510-2AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA00, I rms = 20 A 100 db 80 PD30_ EF1510-3AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA00, I rms = 8 A 100 db 80 PD30_ EF1510-4AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1510-5AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1510-6AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA00, I rms = 12 A 4EF AA00, I rms = 16 A 4EF AA00, I rms = 25 A 100 db PD30_ db PD30_ db PD30_ EF1510-1AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 20 4EF1510-2AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA10, I rms = 8 A 4EF AA10, I rms = 16 A 4EF AA10, I rms = 25 A 20 4EF1510-3AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 15/16 Siemens LV

111 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase and three-phase filters 100 db PD30_ db PD30_ db PD30_ EF1510-4AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1510-5AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1510-6AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA10, I rms = 36 A 4EF AA10, I rms = 50 A 4EF AA10, I rms = 66 A 100 db PD30_ db PD30_ db PD30_ EF1510-7AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1510-8AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1512-7AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA10, I rms = 90 A 4EF AA10, I rms = 120 A 4EF AA10, I rms = 150 A 120 db 100 PD30_ db 80 PD30_ db 80 PD30_ EF1511-0AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1511-1AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1511-2AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA10, I rms = 220 A 4EF AA10, I rms = 250 A 4EF AA10, I rms = 320 A 15 Siemens LV /17

112 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase and three-phase filters Siemens AG db PD30_ db PD30_ db PD30_ EF1511-3AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1511-4AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1511-5AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA10, I rms = 400 A 4EF AA10, I rms = 600 A 4EF AA10, I rms = 1000 A 100 db 80 PD30_ db 100 PD30_ db 100 PD30_ EF1511-6AA Hz 10 8 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1511-7AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1511-8AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA10, I rms = 1600 A 4EF AA10, I rms = 8 A 4EF AA10, I rms = 16 A 120 db 100 PD30_ db 100 PD30_ db 100 PD30_ EF1512-8AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1512-0AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1512-1AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA10, I rms = 25 A 4EF AA10, I rms = 36 A 4EF AA10, I rms = 50 A 15/18 Siemens LV

113 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase and three-phase filters 120 db 100 PD30_ db 100 PD30_ db 100 PD30_ EF1512-2AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1512-3AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF1512-4AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode 4EF AA10, I rms = 66 A 4EF AA10, I rms = 90 A 4EF AA10, I rms = 120 A 120 db 100 PD30_ db 100 PD30_00110 α 100 db 80 PD30_ EF1512-5AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode EF1512-6AA Hz 10 f Insertion loss/einfügungsdämpfung CISPR17 Z=50 unsym asym, common mode sym, differential mode EF1510-0AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 4EF AA10, I rms = 150 A 4EF AA10, I rms = 200 A 4EF AA20, I rms = 8 A 100 db 80 PD30_ db 80 PD30_ db 80 α α α PD30_ EF1510-1AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 4EF1510-2AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 4EF1510-3AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 15 4EF AA20, I rms = 16 A 4EF AA20, I rms = 25 A 4EF AA20, I rms = 36 A Siemens LV /19

114 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase and three-phase filters Siemens AG 2009 α 100 db 80 PD30_00115 α 100 db 80 PD30_00116 α 100 db 80 PD30_ EF1510-4AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 4EF1510-5AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 4EF1510-6AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 4EF AA20, I rms = 50 A 4EF AA20, I rms = 66 A 4EF AA20, I rms = 90 A α 100 db 80 PD30_ db 80 PD30_ db 80 α α PD30_ EF1510-7AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 4EF1510-8AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 4EF1511-0AA Hz 10 8 f Insertion Ioss/Einfügungsdämpfung CISPR17 Z=50 Ω unsym asym, common mode sym, differential mode 4EF AA20, I rms = 120 A 4EF AA20, I rms = 150 A 4EF AA20, I rms = 200 A 15 15/20 Siemens LV

115 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase filters Dimensional drawings Terminals 4 mm Terminals 4 mm 2 Marking LINE LOAD ,5 Terminals 4 mm 2 PD30_ ,8 7, , PE M4x15 LINE Marking LOAD 60, , , EF AA00 (I rms = 10 A) Mounting in any arrangement 11 PD30_ PE M5x EF AA00 (I rms = 20 A) Mounting in any arrangement 144 max. 70 PD30_ ,5 32 max max. 113 max. 31 max. 61max. PE M6x max ,8 PD30_ max. 86 max. 113 max max. L N PE LINE Marking 5,8 LOAD L N PE max. 4EF AA00 (I rms = 8 A), 4EF AA00 (I rms = 12 A), 4EF AA00 (I rms = 16 A) 2 Terminal blocks 4 mm Mounting in any arrangement PE N L1 LINE Marking LOAD 5, max. 4EF AA00 (I rms = 25 A) L1 N PE 100 Terminal block 10 mm 2 Mounting in any arrangement 15 Siemens LV /21

116 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Siemens AG 2009 Dimensional drawings 8 PE M4x11 133,7 9 PE M5x15 199,5 50 Terminals 4 mm 2 PD30_ ,5 1, PD30_00038 Terminals 4 mm2 4,5 1, L1 L2 L3 Marking LINE LOAD 155 L1' L2' L3' 46,4 38 L1 L2 L3 Marking LINE LOAD L1' L2' L3' 165 4EF AA10 (I rms = 8 A) Mounting in any arrangement 4EF AA10 (I rms = 16 A) Mounting in any arrangement 9 PE M5x15 199,5 8 PE M6x PD30_00050 Terminals 4 mm 2 46,4 38 L1 L2 L3 Marking LINE LOAD L1' L2' L3' 1,5 4, PD30_00051 Terminals 10 mm L1 L2 L3 LINE Marking L1' L2' LOAD L3' 4,5 1,5 90 4EF AA10 (I rms = 25 A) Mounting in any arrangement 4EF AA10 (I rms = 36 A), 4EF AA10 (I rms = 50 A) Mounting in any arrangement PE M6x ,5 Terminals 16 mm2 PD30_ ,5 1, L1 L2 L3 LINE Marking LOAD L1' L2' L3' 15 4EF AA10 (I rms = 66 A) Mounting in any arrangement 15/22 Siemens LV

117 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters PD30_00045 PE M10x Terminals 35 mm2 6,5 L1 L2 L3 L1' Marking L2' LINE LOAD L3' 60 4EF AA10 (I rms = 90 A) 255 Mounting in any arrangement PE M10x34 1, PD30_ Terminals 35 mm2 6,5 L1 L2 L3 Marking LINE LOAD L1' L2' L3' EF AA10 (I rms = 120 A) Mounting in any arrangement Terminals 50 mm , PE M10x PD30_ ,5 L1 L2 Marking LINE LOAD L3 4EF AA10 (I rms = 150 A) L1' L2' L3' 65 Mounting in any arrangement 15 Siemens LV /23

118 #! # # SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Siemens AG Terminals 95 mm Strand End sleeve L3' 220 L2' L1' PE PE M10x Strand designation L1 L2 L3 Marking LINE LOAD EF AA10 (I rms = 220 A) PD30_00031 Mounting in any arrangement!! " " ' # # ' # " ' % $ 2,!! '! " # = H E C 1 - ), $ $! # # % " ' % & 2,! "! % = H E C 1 - ),! $ # ' 4EF AA10 (I rms = 250 A) Mounting in any arrangement $ 4EF AA10 (I rms = 320 A), 4EF AA10 (I rms = 400 A) Mounting in any arrangement! " "! # ' # % & % 15 " ' 2,! #! = H E C 1 - ),! $ # ' $ 4EF AA10 (I rms = 600 A)! Mounting in any arrangement 15/24 Siemens LV

119 & Siemens AG 2009 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters # # " "! % & ' % # " " 2,! "! = H E C 1 - ),!! # $ " 4EF AA10 (I rms = 1000 A)! Mounting in any arrangement ' ' " # " " # " & ' % # " " 2,! "! = H E C 1 - ),!! # $ " 4EF AA10 (I rms = 1600 A)! Mounting in any arrangement Terminals 4 mm 2 Strand ,5 1 L3' L2' L1' PE PD30_00047 PE M6x ,5 End sleeve Strand designation L2 L1 L3 4EF AA10 (I rms = 8 A), 4EF AA10 (I rms = 16 A) Marking LINE LOAD Mounting in any arrangement 15 Siemens LV /25

120 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Siemens AG Terminals 6 mm 2 Strand L3' 150 L2' L1' PE PE M6x End sleeve Strand designation L1 L2 L3 4EF AA10 (I rms = 25 A), 4EF AA10 (I rms = 36 A) Marking LINE LOAD PD30_ Mounting in any arrangement Terminals 16 mm Strand L3' 150 L2' 75 L1' PE PE M6x End sleeve Strand designation L1 L2 L3 4EF AA10 (I rms = 50 A) Marking LINE LOAD PD30_ Mounting in any arrangement Terminals 2 25 mm Strand L3' 150 L2' ,5 1 L1' PE PE M10x End sleeve Strand designation 6.5 L1 L2 L3 Marking LINE LOAD PD30_ EF AA10 (I rms = 66 A) Mounting in any arrangement 15 15/26 Siemens LV

121 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters 80 2 Terminals 25 mm Strand L3' 200 L2' L1' PE PE M10x35 L1 L2 L3 4EF AA10 (I rms = 90 A) Marking LINE LOAD PD30_00034 End sleeve Strand designation Mounting in any arrangement Terminals 50 mm 2 Strand L3' L2' L1' PE 40 0, PE M10x ,5 6.5 End sleeve Strand designation L1 L2 L3 Marking LINE LOAD EF AA10 (I rms = 120 A), 4EF AA10 (I rms = 150 A) PD30_00035 Mounting in any arrangement 110 Terminals 95 mm 2 Strand End sleeve L1' 220 L2' ,5 1 PE L3' PE M10x ,5 Strand designation 15 L1 L2 L3 Marking LINE LOAD EF AA10 (I rms = 200 A) PD30_00036 Mounting in any arrangement Siemens LV /27

122 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters Siemens AG PE M5 x PE M6 x mm 2 0, ,8 Nm 6, ± 0,5 L1 L2 L1' L2' L3 N Marking L3' N' PE PE' LINE LOAD PD30_ ± 0,3 80 4EF AA20 (I rms = 8 A), 4EF AA20 (I rms = 16 A), 4EF AA20 (I rms = 25 A) 10 mm 2 1,2... 1,5 Nm 6, ± 0,5 L1 L1' L2 L2' L3 Marking L3' N N' PE PE' LINE LOAD PD30_ EF AA20 (I rms = 36 A), 4EF AA20 (I rms = 50 A) 75 ± 0, PE M6 x mm 2 L1 L1' L2 L2' ,3 Nm L3 L3' 4EF AA20 (I rms = 66 A) PD30_ PE M8 x , ,3 64,5 6,5 32, ± 0, Marking N PE LINE N' PE' LOAD 85 ± 0, ,1 10,2 6,5 38, ± 0,5 25 mm ,5 Nm L1 L1' L2 L2' L3 L3' Marking N N' PE PE' LINE LOAD 115 ± 0, EF AA20 (I rms = 90 A) PD30_ /28 Siemens LV

123 SIDAC Configuration Notes Radio Interference Suppression Filters Three-phase filters PE M10 x ,8 43 6, ± 0,5 50 mm Nm L1 L1' L2 L2' L3 L3' Marking N N' PE PE' LINE LOAD 115 ± 0,3 130 PD30_ EF AA20 (I rms = 120 A) PE M10 x , ,5 50, ,5 265 ± 0,5 95 mm Nm L1 L1' L2 L2' L3 L3' Marking N N' PE PE' LINE LOAD 145 ± 0,5 160 PD30_ EF AA20 (I rms = 150 A), 4EF AA20 (I rms = 200 A) 15 Siemens LV /29

124 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase and three-phase filters Siemens AG 2009 Circuit diagrams Typical circuit diagrams LINE L LOAD L N N PD30_ EF AA00 (I rms = 10 A), 4EF AA00 (I rms = 20 A) LINE LOAD L L N N PD30_ EF AA00 (I rms = 8 A), 4EF AA00 (I rms = 12 A), 4EF AA00 (I rms = 16 A), 4EF AA00 (I rms = 25 A) LINE L1 LOAD L1 L2 L2 L3 L3 PD30_ EF AA EF AA10 (I rms = A), 4EF AA10 (I rms = 150 A) LINE L1 L2 L3 LOAD L1 L2 L3 15 PD30_ EF AA10 (I rms = 220 A) 15/30 Siemens LV

125 SIDAC Configuration Notes Radio Interference Suppression Filters Single-phase and three-phase filters LINE L1 L2 L3 LOAD L1 L2 L3 PD30_ EF AA EF AA10 (I rms = A) LINE L1 L2 L3 LOAD L1 L2 L3 PD30_ EF AA10 (I rms = 8 A), 4EF AA10 (I rms = 16 A) LINE L1 L2 L3 LOAD L1 L2 L3 PD30_ EF AA10 (I rms = 25 A), 4EF AA EF AA10 (I rms = A) LINE L1 L2 L3 LOAD L1' L2' L3' N N' PD30_ EF AA EF AA20 (I rms = A), 4EF AA20 (I rms = 200 A) 15 Siemens LV /31

126 SIDAC Configuration Notes Siemens AG 2009 Notes 15 15/32 Siemens LV

127 Appendix Siemens AG /2 Ordering notes 16/4 Further documentation 16/5 Standards and approvals 16/10 Siemens contacts 16/11 Online services 16/12 Customer support 16/15 Subject index 16/16 Order No. index 16/22 Terms and conditions of sale and delivery Export regulations Siemens LV

128 Appendix Siemens AG 2009 Ordering notes Logistics General Our logistics service ensures "quality from order placement to delivery" and covers all aspects of delivery service, communications and environmental protection. By implementing a customer-oriented infrastructure and electronic order processing, we have successfully optimized our logistics processes. We are proud of our personal consulting service, on-time delivery and 1-day transport within Germany. To achieve this, we always carry preferred types bearing the mark } in stock. The DIN ISO 9001 certification and consistent quality checks are an an integral part of our services. Electronic order processing is fast, cost-efficient and error-free. Please contact us if you want to benefit from these advantages. Packaging, packing units The packaging in which our equipment is dispatched provides protection against dust and mechanical damage during transport, thus ensuring that all our products arrive in perfect condition. We select our packaging for maximum waste reduction, environmental compatibility and reusability (e.g. crumpled paper instead of polystyrene chips for protection during transport in packages up to 32 kg). With our multi-unit packaging and reusable 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 order costs. Cost savings through uniform-type packaging: low/no disposal costs. Reduced time and cost thanks to short unpacking times. "Just-in-time" delivery directly to the production line helps reduce stock: cost savings through reduction of storage area. Fast assembly thanks to supply in sets. Standard Euro boxes - corresponding to the Euro pallet modular system - suitable for most conveyor systems. Active contribution to environmental protection. Unless stated otherwise in the "Selection and ordering data" of this catalog, our products are supplied individually packed. For small parts/accessories, we offer you economical packaging 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 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 packaging, the Order No. for the operating instructions (Instr. Order No.) is also specified. This can be obtained from your local Siemens representative (you will find a list of your local Siemens representatives at The device Order No. of most devices can also be acquired through the EAN barcode to simplify ordering and storage logistics. The Order Nos. are assigned electronically to the EAN code in the master data of low-voltage controls. Multi-unit and reusable packaging Set deliveries (reusable, different devices) On request, we can also deliver larger quantities of separate loose items packed together in standard Euro boxes. Please contact your local Siemens office (you will find a list of Siemens branches at to clarify delivery details or requirements for set supply or delivery in reusable packaging. We can then find a delivery solution that best meets your requirements. ENK = Standard Euro boxes 16 16/2 Siemens LV

129 Appendix Ordering notes Ordering special versions When ordering products that differ from the versions listed in the catalog, " Z" must be addded to the order number specified in the catalog and the required features must be specified using alphanumeric order codes or 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 regret that we 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

130 Appendix Siemens AG 2009 Further documentation Overview We regard product support as just as important as the products and systems themselves. Visit our Support site on the Internet for a comprehensive range of material on SIRIUS, SENTRON and SIVACON, such as Operating instructions and manuals for direct download Online registration for seminars and events Up-to-date answers to your queries and problems Software upgrades and updates for fast download Telephone assistance in more than 190 countries Photos and graphics for external use and much, much more - all conveniently and easily accessible. Address: You will find all the latest information material, such as catalogs, customer journals, brochures and demo software on low-voltage controls and distribution, on the Internet at: Here you can order your copy of the available documentation or download it in common file formats (PDF, ZIP). 16 For your configuration systems, we can provide technical and graphic data in electronic form for our range of low-voltage control products: Technical Product Data for CAx Applications Edition 08/2009 The DVD provides the product range of low-voltage controls and distribution for further processing in CAE/CAD systems. Technical product data in CSV and Excel format Graphic product data - 2D dimensional drawings in DXF format (other formats optional) - 3D models in STEP format - Internal circuit diagrams - EPLAN electric P 8 macros Documentation as PDF files - Product data sheets - Manuals - Operating instructions - Characteristic curves - Certificates Product photos Texts for tenders in GAEB and Text format Order No.: E86060-D1000-A207-A Token fee E 10 16/4 Siemens LV

131 Appendix Standards and approvals Overview Approvals, test certificates, characteristic curves An overview of the certificates available for low-voltage control products along with more technical documentation can be consulted daily on the Internet at: Product support: Approvals / Certificates Product support: Characteristic curves 16 Siemens LV /5

132 Appendix Siemens AG 2009 Standards and approvals Standards IEC EN DIN VDE Title Low-voltage controlgear and switchgear: General requirements Circuit breakers Load-break switches, disconnectors, switch disconnectors and fuse-combination units Contactors and motor starters: Electromechanical contactors and motor starters Contactors and motor starters: Semiconductor motor controllers and starters, soft starters AC semiconductor controllers and contactors for loads other than motors Control devices and switching elements: Electromechanical control circuit devices Control devices and switching elements: Proximity switches Proximity switches (specific behavior under fault conditions) EMERGENCY-STOP devices with mechanical latching Control devices and switching elements - DC interface for proximity switches and switching amplifier (NAMUR) Requirements for proximity switches with analog output Enabling switches Flow sensors Multifunctional controlgear and switchgear: Transfer switches Multifunctional controlgear and switchgear: Control and protection switchgear (CPS) Ancillary equipment: Terminal blocks for copper conductors Ancillary equipment: Protective conductor terminal blocks for copper conductors Ancillary equipment: Safety requirements for terminal blocks Control units for built-in thermal protection (PTC) of rotating electrical machines Actuator-Sensor Interface (AS-i) Low-voltage fuses: General requirements Low-voltage fuses: Supplementary requirements for fuse links for protecting semiconductor components International dictionary/switchgear and/or switching devices and fuses Low-voltage switchgear and controlgear assemblies: Type-tested and partially type-tested assemblies Low-voltage switchgear and controlgear assemblies - Protection from electric shock - Protection against unintentional direct contact with hazardous live parts Protection from electric shock - General requirements for apparatus and equipment Insulation coordination for electrical equipment in low-voltage systems; Principles, requirements and tests Electrical equipment of machines: General requirements Equipment of electrical power installations with electronic equipment Electrical apparatus for potentially explosive gas atmospheres Installing electrical apparatus in potentially explosive gas atmospheres (except mining) Electrical equipment for potentially explosive gas atmospheres - Part 2 Pressurized enclosures M "p" Electromechanical elementary relays (electromechanical switching relays without a fixed time response); General and safety-related requirements Relays with a fixed time response (timing relays) for industrial applications - Part 1: Requirements and tests Connecting materials - Safety requirements for screw terminals and screwless clamping points for electrical copper conductors - Part 1: General requirements and special requirements for terminals for conductors from 0.2 mm 2 up to and including 35 mm ) Safety of power transformers, power supplies, reactors and similar products - Part 1: General requirements and tests ) -Part 2-1: Particular requirements and tests for separating transformers and supplies incorporating separating transformers for general applications ) -Part 2-2: Particular requirements for control transformers ) -Part 2-4: Particular requirements for isolating transformers for general use ) -Part 2-6: Particular requirements for safety transformers for general use ) -Part 2-9: Particular requirements for mains transformers for handheld lamps of protection class III, for tungsten lamps ) -Part 2-12: Particular requirements for magnetic-type voltage regulators ) -Part 2-13: Particular requirements for autotransformers ) -Part 2-15: Special requirements for isolating transformers for supply of medical premises ) -Part 2-20: Particular requirements for small reactors ) Safety of transformers, power supply units, reactors and similar - EMC requirements Power transformers - Part 11: Dry transformers Standards for variable-ratio transformers with moving contacts perpendicular to the coiling direction Electromagnetic compatibility (EMC) - Part 4: Testing and measuring techniques; Main Section 1: Overview of measuring techniques for interference immunity; Basic EMC standard Electromagnetic compatibility (EMC); Basic specification for emitted interference in residential and commercial environments as well as in light industry Electromagnetic compatibility (EMC); Basic specification for emitted interference in industrial environments Measuring transducers: Current transformers 16 UL CSA C22.2 ASME JIS Title Specialty transformers Industrial control equipment Molded case circuit breakers, molded case switches, and circuit breaker enclosures Power units other than CLASS Dry-type general purpose and power transformers Low-voltage transformers Medical electrical equipment, Part 1: General requirements for safety (IEC 60601, EN 60601, VDE ) 1) VDE classification. 16/6 Siemens LV

133 Appendix Standards and approvals UL CSA C22.2 ASME JIS Title Electrical equipment for use in CLASS I and II, Division 2 and CLASS III hazardous (Classified) locations Terminal blocks 486A-486B Wire connectors 486E Equipment wiring terminals for use with aluminum and/or copper conductors Enclosures for electrical equipment. Non-environmental considerations -- No Specialty transformers -- No Industrial control equipment -- No Molded case circuit breakers, molded case switches, and circuit breaker enclosures -- No General use power supplies A17.5 / B Elevator and escalator electrical equipment C Low-voltage switchgear and controlgear; Contactors and motor-starters Approval requirements valid in different countries Siemens low-voltage switchgear and controlgear are designed, manufactured and tested according to the relevant German standards (DIN and VDE), IEC publications and European standards (EN), as well as CSA and UL standards. The standards assigned to individual devices are stated in the relevant parts of this catalog. As far as is economically viable, in addition to the pertinent VDE-, EN- and IEC regulations, we endeavor to incorporate the requirements of the various regulations applicable in other countries into the standard version of the equipment. In some countries (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 versions. Such special versions are listed separately from the standard versions in the individual parts of this catalog. 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 of approved equipment" tables on page 16/9. Testing bodies, approval identification and approval requirements Country Canada 1) USA 1) China Government-appointed or private, officially recognized testing bodies CSA UL (USA) UL CQC Approval symbol s c u cu c UUS cuus u U c UUS cuus Approval requirements Remarks UL and CSA are authorized to grant approvals according to Canadian or US regulations. Please note: these approvals are frequently not recognized and additional approval often has to be obtained from the national testing authority. CCC For more information about UL and CSA see page 16/8. 1) For registration numbers and file numbers for approvals, please visit and select "Product Support". Marine classification societies Country Germany Great Britain 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 Codes GL LRS BV DNV RMRS RINA PRS ABS CE mark of conformity Manufacturers of products which fall within the subject area to which EC directives apply must identify their products, operating instructions or packaging with a CE mark of conformity. The CE mark of conformity confirms that a product fulfills the appropriate basic requirements of all pertinent directives. The mark of conformity is a mandatory requirement for putting products into circulation throughout the EU. All the products in this catalog are in conformance with the EC directives and bear the CE mark of conformity. Low-voltage directive EMC directive Machinery directive Ex protection directive The CE mark of conformity: >. 16 Siemens LV /7

134 Appendix Siemens AG 2009 Standards and approvals Special standards for the USA and Canada In the USA and Canada, for machine tools and processing machines in particular, supply lines are laid using rubber insulated cable enclosed in heavy-duty steel piping similar to that used for gas or water pipe systems. The tubing system must be completely watertight and electrically conductive (especially sleeving and elbows). Since the tubing system can also be grounded, the cable entries of enclosed units equipped with heavy-gauge or metric threads must be fitted with metal adapters between these threads and the tube thread. The necessary adapters are specified for the switchgear as accessories; they should be ordered separately unless otherwise specified. Low-voltage switchgear and controlgear for auxiliary circuits (e. g. contactor relays, commanding and signaling devices and auxiliary switches/auxiliary contacts in general) are generally only approved by CSA and UL for "Heavy Duty" or "Standard Duty" and are identified either with these specifications in addition to the maximum permissible voltage or by using an abbreviation. The abbreviations are harmonized with IEC Appendix 1 Table A1 and correspond to the stated utilization categories. For various devices detailed in the catalog, a note has been included to the effect that, above a certain voltage, the auxiliary switches/auxiliary contacts can only be used if they have the same polarity. This means that the input terminals can only be connected to the same pole of the control voltage. e.g. "600 V AC above 300 V AC same polarity", i.e. above 300 V AC to 600 V AC only for same polarity. Different features of UL approvals (for USA and Canada) Recognized Component 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 operating conditions. Listed Product 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, I IA 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 U or cu "recognized components". For more information about UL and CSA see page 16/7. Special standards 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 All devices delivered to any part of the Russian Federation must have this customs certification. C-Tick licensing for Australia A Since August 1, 2003, CCC approval is required for many products that are marketed in China. 16 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 EC, and must bear the "C-Tick" mark. These requirements have been in force since October 1st, /8 Siemens LV

135 Appendix Standards and approvals Overview Devices Type Approvals Marine classifications Reactors Filters 4EM, 4EP, 4EU, 4ET 4EF11 4EF15 Canada 1 ) 2 ) USA 1 ) 1 ) China Czech Slovakiland Po- Republic Hungary Germany Great France Norway Britain 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 If you have any questions concerning UL/CSA approvals, please contact: Technical Assistance +49 (9 11) For more information about standards and approvals go to and select "Product Support". + Standard version approved. -- Not yet submitted for approval. O Device submitted for approval, please inquire. U approval not required because u approved. k Approved for operation in connection with AS-Interface (Actuator Sensor Interface), also approved by ABS (American Bureau of Shipping). m For exporting products to the People s Republic of China, CCC marking is not necessary. 1) For registration numbers and file numbers for approvals, please visit and select "Product Support". 2) The cu or cu approvals are granted with US approval, unless otherwise specified. 3) See "Radio Interference Suppression Filters" 16 Siemens LV /9

136 Appendix Siemens AG 2009 Siemens contacts Siemens contacts worldwide At you can find details of Siemens contact partners worldwide responsible for particular technologies. You can obtain in most cases a contact partner 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 partner with his/her respective expertise /10 Siemens LV

137 Appendix Online Services Information and ordering in the Internet and on DVD Siemens Industry Automation 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. Siemens Industry Automation and Drive Technologies has therefore built up a comprehensive range of information in the World Wide Web, which offers quick and easy access to all data required. Under the address you will find everything you need to know about products, systems and services. Product selection with the Offline Mall Detailed information together with convenient interactive functions: The Offline Mall CA 01 covers more than 80,000 products and thus provides a full summary of the Siemens Industry Automation and Drive Technologies 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 Offline Mall CA 01 can be found in the Internet under: or on DVD. Easy Shopping with the Industry Mall The Industry Mall is the virtual department store of Siemens AG in 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 availability. Customer-specific discounts and preparation of quotes can be carried out online as well as order tracking and tracing. Please visit the Industry Mall on the Internet under: 16 Siemens LV /11

138 Appendix Service & Support Siemens AG 2009 Services covering the entire life cycle Technical Support Competent consulting in technical questions covering a wide range of customer-oriented services for all our products and systems. automation/support-request Our Service & Support accompanies you worlwide in all concerns related to the automation and drive technology of Siemens. In more than 100 countries directly on site and covering all phases of the life cycle of your machines and plants. Round the clock. An experienced team of specialists with their combined knowhow is ready to assist you. Regular training courses and a close contact of our employees among each other - also across continents - assure a reliable service for multifaceted scopes. Online Support Technical Consulting 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 Support in the planning and designing of your project from detailed actual-state analysis, target definition and consulting on product and system questions right to the creation of the automation solution. Engineering Support Field Service Repairs and spare parts Support in configuring and developing with customer-oriented services from actual configuration to implementation of the automation project. With Field Service, we offer services for startup and maintenance essential for ensuring system availability. In the operating phase of a machine or automation system, we provide a comprehensive repair and spare parts service ensuring the highest degree of plant availability. Technical Assistance Competent expert advice 1) for low-voltage controls and distribution. Tel.: +49 (0) Fax: +49 (0) Optimization and Upgrading After startup or during the operating phase, additional potential for inceasing the productiviy or for reducing costs often arises. For this purpose, we offer you high-quality services in optimization and upgrading ) Contact: Technical assistance for product selection Old/new coding Competitor coding Special versions Special requirements. Your regional contacts for sales support (prices, discounts, delivery times). Technical Support for commissioning support and after-sales services. 16/12 Siemens LV