Application Note Sine wave filter solutions for motor drive applications

1 Note: This document is in­ Content tended to support designers, installers, and application engineers with sine wave 1. Technical background 3 filter selection, installation, application and maintenance 2. Motor drives output phenomena 4 in motor drives applications. 2.1 Excessive dv/dt 4 2.2. Peak- and overvoltage 5 In order to get the maximum 2.3 Additional losses in the motor 6 benefit out of the Schaffner 2.4 Cable shields and parasitic earth currents 6 filters, please also consult 2.5 HF electromagnetic noise in the motor cable 7 “Basics in EMC and Power 2.6 Bearing currents 8 Quality”, published in 2.7 Acoustic motor noise 9 the download section of www.schaffner.com. 3. Output filter solutions for motor drives 10 These additional guidelines 3.1 dv/dt reactor 10 provide helpful hints for HF- 3.2 dv/dt filter 11 grounding, shielding, prop­ 3.3 Sine wave filter 12 er cable routing including a 3.3.1 Symmetrical sine wave filter 13 chapter “Output solutions for 3.3.2 Sinus plus symmetrical and asymmetrical sine wave filter 14 motor drives”. 4. Sine wave filter selection 16 Schaffner will not assume 4.1 Current and voltage rating 16 liability for any consequential 4.2 Frequency 17 downtimes or damages 4.3 Required drives settings 18 resulting from use or appli­ 4.4 Voltage drop considerations 20 cation of this document and/ or installation of Schaffners 5. Application examples 21 or any other sine wave filter. 5.1 Motor drive with long motor cable 21 5.2 Motor drive with multiple motors in parallel 21 5.3 Retrofit installations with motor drives 21 5.4 LV motor drive with MV-motor/ 22 step-down / step-up transformer application

6. Mounting and installation guidelines 22 6.1 Important safety considerations 22 6.2 General application notes 23 6.3 General installation notes 24 6.4 Mechanical mounting 25 6.5 Wiring and cabling 25

2 1. Technical background

Whenever electricity is used to drive an equipment, in particular when a motor drive is controlling the speed of an special attention of the noises generated by the motor drives need to be taken into consid- erations along the entire electric power line from the source to the load.

This guideline is intended to describe why and when to use which type of motor drive output filter. Nevertheless, following overall view of the noise potential around the motor drive, which can cause equipment to malfunc- tion or be damaged, is shown as follow:

Overview of noise potential around a motor drive

For cancellation of the unwanted noises and fulfilment of the norms on the line side, Schaffner offers a complete range of EMC filter– and harmonic filter solutions for any applications, enabling cost effective standard and customized solutions to cancel or reduce the voltage and current noises to the levels required.

For 3-Phase motor drive applications, following filter combinations are ap- propriate to be considered:

In this application and selection guide the output filters and in particular the sine wave filters will be described in detail.

3 Motor drives (frequency inverters) are among the most widely used pieces of equipment for AC motor control. Nowadays, they are found in virtually every area of industry, in applications as diverse as pumps, air conditioning systems, elevators and cranes, conveyors, machine tools, renewable elec- tricity production and in a vast array of other industrial and domestic auto- mation. In the quest for ultra-compact, efficient power conversion, motor drive manufacturers employ high-speed semiconductor (IGBT) switches and pulse width modulation (PWM) techniques to generate fast rise time voltage pulses of the appropriate duration and polarity. Unfortunately, this creates a considerable number of problems for OEMs and system integra- tors, from purely functional difficulties to very severe motor damage. Here is a brief summary of the most significant problems and phenomena:

Motor drive input: Motor drive output: EMC problems Excessive dv/dt Harmonics Peak– and overvoltage Commutation notches Parasitic earth currents Inrush & peak currents losses in the motor Low-frequency interference Displacement currents in the coils Motor drive DC link: Bearing currents DC link capacitor stress Additional inverter pulse loads Harmonics Acoustic motor noise Other interference problems EMC problems

Whole system: Low efficiency/low power factor Uncertain system immunity Unacceptable interference emissions Uncertain service security & reliability

2. Motor drives output phenomena/influence

Motor drives are known sources of interference and are therefore usually equipped with an input filter. However, the problems generated on the output side of the motor drives where the converter supplies the motor with a modulated rectangular PWM signal (a switching frequency depen- dent series of trapezoidal pulses with variable width) have to be taken into additional consideration as described in following chapters.

2.1 Excessive dv/dt voltage To keep the losses in the frequency converter low, the aim is to keep the switching times of the power semiconductors as short as possible. The re- sult of this is that with the newest generation of IGBTs, rise times of some- times more than 12 kV/us can be measured, whereas – depending on the motor – a dv/dt of around 1000 V/us is considered permissible. The IEC 60034-17 standard does define the voltage peak limits in relation to the rise

4 time for general purpose 500 VAC motors when fed by motor drives and IEC 60034-25 specifies the limits for motor drive rated 500 VAC and 690 VAC motors. For US applications the NEMA MG1 standard shows the limit for definite purpose motor drive fed motors.

V

dv t t

dt

Definition of dv / dt: PWM-Signal and single pulse at the inverter output

In the case of short motor cables (up to about 20 m), these rise times – ow- ing to the small line impedance – act fully on the insulation of the motor windings. Depending on the structure of the motor coils, wires that carry the full voltage are situated immediately in parallel and next to each other. Since even very short parallel-laid wires have a capacitive action, the per- manent potential jumps result in pole reversal losses across the winding insulation. Now, if the enamel insulation is impure even to a very minor extent, this results in hot-spots, and hence, sooner or later, to a destruction of the winding insulation. In any case, this dv/dt stress leads to premature aging and thus to a reduction in the life of the motor, in particular when an older motor is fed by a motor drive.

2.2 Peak- and overvoltage Voltage overshoots and voltage peaks can come with high dv /dt values but are also a problem on their own. Due to the structure of the windings, a motor acts like a capacitor in the equivalent circuit diagram – owing to the fast voltage pulses of the switching frequency – and not as an inductance, as is the case in normal 50 Hz applications. With every additional meter of motor cable, more wire inductance is added to this structure. This induc- tance acts like a choke according to the energy storage principle. If chokes are subject to voltage pulses, voltage peaks occur every time switching on or off takes place. The higher the energy content (inductance) of the choke, the higher these voltage peaks become. In other words, the longer the motor cable, the higher the maximum voltage amplitudes.

VInv. t

V VInv. Mot.

VMot.

Inverter Motor cable Motor 10m cable / 100m cable

Simplified equivalent circuit diagram of shielded cables (only 2 phases are shown) and theoretical single pulse at 10 m and at 100 m motor cable length

5 These amplitudes can, in turn, reach values that cause a stress situation in the winding insulation of the connected motor. Owing to the cable im- pedance, the dv/dt stress – in the case of longer motor cables – is reduced to less problematical values. On the basis of the line theory, however, peak values of 1600 V or more (depending on the DC link voltage) can occur due to cable reflections, which can have very steep dv/dt values. According to IEC 60034, peak values of around 1000 V are recommended. In cases the resulting voltage peak and rise time exceed the standard limits an output filter should be used for protecting the motor winding insulation. Despite the reduced dv /dt owing to the cable impedance, there is no significant stress relief for the motor, since now the increased voltage amplitudes rep- resent the dominant stress factor.

2.3 Additional losses in the motor Apart from protecting the winding insulation against unacceptable voltage peaks, the steep switching edges create another phenomenon of harmon- ics of the output signal. By applying Fourier analysis, it can be mathemati- cally proven that the harmonic spectrum of the motor currents becomes wider with the steepness of the pulses which means that the harmonic content increases. The current ripple (PWM and harmonics) results in ad- ditional magnetic losses in the motor. The life of the motor is sensitively shortened owing to the permanently increased operating temperature.

2.4 Cable shields and parasitic earth currents From the standpoint of EMI suppression, shielded motor cables are re- quired to avoid back-coupling of radiated interference to the mains cable in the frequency range from about 1 to 30 MHz. This measure of the EMC can, however, only be considered to be efficient if the ends of the cable shield of the motor cable are put in contact with the ground of the motor and the frequency converter – if possible, at HF low impedance and over as large an area as possible. This ensures that the interference currents can mostly flow back to the source by the shortest route. Frequency convert- ers normally work in grounded networks and do not have any potential separation. The geometric expansion of the frequency converter, motor and this shielded motor cable therefore form parasitic capacitances of the electrically conducting components with respect to the ground potential. If the available DC voltage is chopped in the frequency converter, then during the potential jumps of the voltage, considerable pulse currents flow across the parasitic capacitances to the earth. The level of the interference currents on the cable shield depends on the dv/dt as well as the value of the parasitic capacitances (I = C * dv/dt). With a motor cable length of about 100 m, peak values of the pulse currents of 20 amperes and more are not unusual, regardless of the power rating class of the drive.

The harmonic spectrum of these currents can reach a range of several MHz. The shield of the motor cable, owing to the existing braiding, offers a very large surface area and a sufficient cross-section to carry these currents. As a result, the impedance of the shield across a broad frequency range is of a very low-impedance nature. Losses due to the skin effect are limited to a minimum because of the large surface area. Inadequate ground con- nections of the cable shield (the so-called “pigtails”), on the other hand, are highly resistive for the frequency range under consideration and often nullify the desired shielding effect.

6 If there are parallel-laid control cables or electronic components in the vi- cinity of the motor cables, pulsed HF currents flow across their geometric expansion and the resultant parasitic capacitances, which in turn could have an impermissible influence on neighbouring equipment through ca- pacitive coupling.

If neighbouring components are located in the immediate vicinity of the motor cable, the conductor loops and the high di / dt values of the shield currents also result in a magnetic coupling that can also lead to impermis- sible influencing.

Parasitic capacitances in a drive system

The currents flowing across the shield must be supplied by the frequency converter as well. They are not dependent on the rating of the drive but only on the geometric expansion of the structure. With small power rat- ings, the result of this, especially in case of long motor cables, can be that a frequency converter of the next higher rating has to be used that is able to supply both the currents required by the load and the parasitic currents via the earthing. The operation of several motors connected in parallel on one frequency converter is problematic. The parallel connection of several shielded cables results in a relatively high total capacitance and thus cor- respondingly high shield currents. The parallel connection of several drives, however, is accompanied by even more issues to be solved. Parasitic cur- rents across the motor and the installation can considerably affect the re­ liability of the entire system.

>>> refer also application examples in chapter 5

2.5 HF electromagnetic noise in the motor cable The high frequency noise is caused by the switching frequency of the semiconductors. The source occurs due to the pulse voltage overshoot at the motor terminal. With the use of a dv/dt filter the frequency of the ring- ing oscillation is only reduced below 150 kHz compared with a sine wave filter eliminating the pulse voltage overshoot completely by feeding the motor with a sine wave phase-to-phase voltage.

7 The noise coupling between the unshielded motor cable with the line ca- ble or other sensitive cables (sensors, encoder etc.) can be reduced when using sine wave filters in combination with EMC line filters.

Line conducted noise without (left) and with sine wave filter (right)

2.6 Bearing currents A general distinction has to be made between two different physical oc- currences:

The shaft voltage (or voltage) is an inductive voltage that is induced in the motor shaft owing to the differences in the flux densities of the and rotor. Above all, it is influenced by the length of the motor. As long as the lubricant film in the bearing is intact, the voltage builds up until, finally, a compensating current flows towards the earth. In this case, the path of least resistance is through the motor bearings. This bearing current (I 1), over a long period of time, usually results in drying out the bearings and thus create a mechanical motor failure, acoustic noise and a possible break-down. It is possible to counter this phenomenon to a certain degree through the use of ceramic bearings. The bearing voltage is an asymmetric (common-mode) voltage that oc- curs because of capacitive coupling between the motor housing, the stator and the rotor (C 1, C 2, C 3) and results in dv/dt and electrostatic discharge currents (I dv/dt and I EDM) across the bearing (C Bearing, U Bearing). To be more accurate, this bearing voltage results in two differ- ent currents: in the first minutes of operation, as long as the lubricant in the bearing is cold, currents in the range of 5 to 200 mA (I dv/dt) flow through C Bearing because of the dv/dt. These rather negligible currents generally do not result in any bearing damage. After a little while, when the lubricant film has heated up, peak currents of 5 to 10 A and more can be measured (IEDM). These flashovers leave behind small pits on the surface of the bearing. The running of the bearing becomes increasingly rough because of the damaged surface and the life is thus considerably shortened. Typically, the bearing voltage is between 10 and 30 V. But since it is directly dependent on the mains supply voltage, bearing dam- age increases over proportionally at higher supply voltages.

In the case of the use of unshielded motor cables, the cable capacitance (C Cable) and hence the current (I Cable) is relatively small. The parasitic capacitances on the inside of the motor dominate. Ideally, the parasitic cur- rents flow through the motor housing to the ground (I C1).

8 Motor cable IC1 Motor uninsulated coupling Line Inv. I C1 C Bearing I1 C2 3 CBearing

Idv/dt Load U Bearing Bear. IEDM Rotor shaft CCable Rotor ICable Copper coils Stator C1 Metal frame

Imp. IBearing IC1

However, if the grounding of the motor is inadequate, an additional im- pedance (Imp.) is limiting the current (I C1). As a result of the additional im- pedance, the potentials at C 2, C 3 and C Bearing increase sharply. The val- ues of the bearing currents also increase massively and flow fully through the bearings to the earth (I Bearing); in that case, the life expectancy of the ball bearings, and hence of the entire motor, is reduced to a few hours.

I e [A] 120

100

80

60

40

20

0 500 kW motor A 500 kW motor B 110 kW motor A 110 kW motor B

motor earth current with out filter motor earth current with sine wave filter motor bearing current with out filter motor bearing current with sine wave filter

2.7 Acoustic motor noise Compared to the previously described issues, the whistling noises of the motor – caused by the pulse width modulated (PWM) switching frequency – would appear to be negligible. However, in applications related to heating, ventilation and airconditioning technology (HVAC), the noise is distributed and may be amplified in the entire building through air ducts or heat- ing pipes. For acoustic noise sensitive applications, often the motor drive switching frequency is set to 16 kHz, since this audible frequency noise level is less noticeable by humans. This generates higher IGBT switching losses, higher heating, higher leakage currents and therefore a correspond- ing derating of the motor drive need to be taken into consideration. Three main acoustic noise sources are generated by motors:

Motor core magnetic noise, through magnetostriction Motor bearing noise Motor ventilation noise

9 6 > Sine Wave Filter - Application and Selection

In order to eliminate or reduce unwanted acoustic noise levels, a sine-wave filter can be used. This will filter the pulse shaped voltage from the frequen- cy converter and provide a smooth sinusoidal phase-to-phase voltage at the motor terminals.

3. Output filter solutions for motor drives With Schaffner dv/dt reactor types RWK305 a cost efficient reduction of high output voltage dv/dt from IGBT motor drives For reasons of cost, time and space, an attempt is generally can be achieved. The voltage still being PWM pulse pattern first made to overcome the motor drives issues without addi- 3. Output filter solutions for motor drives shaped generates a lower output current ripple. tional components. However, the subsequent costs that can result from motor or system failures are often entirely out of It protects the motor coil insulation from premature aging and destruction and increases significantly the service life of elec- Forpro reasonsportion of to cost, the fartime lo weandr inspace,itial costsan attempt of preventive is generallyou firsttput made filter to overcomemeasure s.the If motor the decision drives issues is ma withoutde in favou additionalr of components components. to How- tric motors. dv/dt reactors are limited when used with long mo- ever,increa these subsequent the reliability, costs thethat operational can result from saf motorety and or system the install failuresa- are tor cables. The maximum admissible motor cable length de- oftention lifetientirelyme theout of follo proportionwing type tos theof pa farssive lowerout initialput costs filter of compo- preventive pends mainly on the switching frequency and the drive output outputnents hafilterve measures.establishe If thed thems decisionelves is made to solv in efavourthe maj of componentsor applica- to voltage. The value for a given application can be found in the increasetion requirements: the reliability, the operational safety and the installation lifetime derating curve below. the following types of passive output filter components have established I dv/dt reactors (increase inductivity, signal smoothing) themselves to solve the major application requirements: I dv/dt filters (low inductance, hardly any reduction in the con- trol dv/dtdynamic) reactors (increase inductivity, signal smoothing) dv/dt filters (low inductance, hardly any reduction in the control dynamic) I Sinusoidal output output filters filters (high (hig Lh and L and C forC optimizingfor optimizi theng outputthe ou t-signal, putbut signal, also not but universally also no tapplicable)universally applicable)

Locations of filters around motor / power drives Locations of filters around motor/power drives

3.1 dv/dt reactor Switching frequency depending cable length curves for RWK305 reactor Reactors can be used in various locations in a power drive system: as line reactor,3.1 dv/dt in the reactor DC link between the rectifier and capacitor (DC link choke) and at the drive output to the motor (dv/dt reactor). A reactor at each of Reactors can be used in various locations in a power drive these positions has specific effects that are by no means mutually exclu- system: as line reactor, in the DC link between the rectifier and sive. capacitor (DC link choke) and at the drive output to the motor (dv/dt reactor). A reactor at each of these positions has specif- Generally, it would be unnecessary to have a reactor in both the power ic effects that are by no means mutually exclusive. input and the DC link, but the functions of the input line reactor are quite differentGenera llfromy, it woa filteruld atbe theun necessardrive output,y to andhave it isa reactorentirely reasonable in both to includethe po webothr inpu of these.t and the DC link, but the functions of the input line reactor are quite different from a filter at the drive output, Aand reactor it is on entirel the ylinereasonabl side will edoto two include things: both protect of these the drive. electronics from power disturbances and protect the power supply from disturbances createdA reacto byr theon thdrive.e line In sidethis documentwill do tw theo things: line input protect side thewill not driv bee cov- eredelectro in depth,nics fro thereforem powe pleaser disturbances consult for an mored protect information the po thewe “Basicsr in EMCsupp andly from Powerdi stQuality”,urbances published created in theby downloadthe drive. section In this docuof - www.schaffner.comment the line input side will not be covered in depth, therefore please consult for more information the “Basics in EMC and Power Quality”, published in the download section of 10 www.schaffner.com With Schaffner dv/dt reactor types RWK305 a cost efficient reduction of high output voltage dv/dt from IGBT motor drives can be achieved. The voltage still being PWM pulse pattern shaped generates a lower output current ripple.

It protects the motor coil insulation from premature aging and destruction and increases significantly the service life of electric motors. dv/dt reactors are limited when used with long motor cables. The maximum admissible motor cable length depends mainly on the switching frequency and the drive output voltage. The value for a given application can be found in the derating curve below. kHz 15 14 13 12 11 400 VAC 10 9 8 480 VAC 7

Switching frequency Switching 6 7 > Sine5 Wave Filter - Application and Selection 4 3 2 1 10 20 30 40 50 60 70 m Cable length Switching frequency depending cable length curves for RWK305 reactor 3.2 dv/dt filter

3.2Motor dv/dt drives filterswitching frequencies of 16kHz or more can gen- Side effect of the use of a dv/dt filter: the frequency of the Motorerate dv/ddrivest values switching of upfrequencies to 12 kV/us. of 16 Dependin kHz or moreg on can the generateoutput dv/ pulse ringing voltage oscillation is reduced below 150kHz. dtvoltag valuese of of theup to motor 12 kV/us. drive, Depending the cable onlength the output and ty voltagepe as weof thell as mo- Mainly for high power motors, the motor bearing stress is torthe drive,layout the do cable influenc lengthe thande voltag type ase wellrise astime. the layout High dv/dtdo influence levels the slightly reduced, but dv/dt filters do not eliminate the acoustic voltagecan damag rise time.e the High motor dv /dtwind leings.vels can Accordin damageg theto EN motor 60034 windings. volt- Ac- cording to EN 60034 voltage rise times of 500 to 1000 V/us are permissible switching frequency noise from the motor. age rise times of 500 to 1‘000V/us are permissible depending depending on motor types. on motor types.

TheThe dv/dtdv/dt filters filters are are low lo passw pa filterss filterbuilt with built inductors,with inductors, capacitors cap andaci- pow- ertors resistors. and po Thewe rnominalresistors. switchingThe nominal frequencysw itchingof the motor frequenc drivey shallof be belowthe motor the typical drive cut shal offl be frequencybelow the of thetypic dv/dtal cut filter off (typical frequenc < 10y kHz).of The sinethe dv/dtwave filter filter have (typ icalhigher< 10L and kHz). C values,The sinethereforewave dv filter / dt filters have are lower inhi ghcoster andL an smallerd C values, in size. therefore With a dv/dt dv/dt filter filters the outputare lowe currentr in cost ripple is lowerand smaller but the involtagesize. isWi stillth PWM a dv/dt pulse filter pattern the output shaped. current ripple is lower but the voltage is still PWM pulse pattern shaped. 11

Without dv/dt filter With dv/dt filter

The Filter FN510 from Schaffner reduces the high output volt- age dv/dt from IGBT motor drives and limits the peak voltage to 1’000V. It protects the motor insulation windings from prem- ature aging and destruction and increases significantly the service life of electric motors. In addition less interference propagation towards neighbouring equipment or lines are oc- curring. The typical cable length used is ≤ 80m at a maximum switching frequency of 16kHz at 400VAC. 7 > Sine Wave Filter - Application and Selection

3.2 dv/dt filter

Motor drives switching frequencies of 16kHz or more can gen- Side effect of the use of a dv/dt filter: the frequency of the erate dv/dt values of up to 12 kV/us. Depending on the output pulse ringing voltage oscillation is reduced below 150kHz. voltage of the motor drive, the cable length and type as well as Mainly for high power motors, the motor bearing stress is the layout do influence the voltage rise time. High dv/dt levels slightly reduced, but dv/dt filters do not eliminate the acoustic can damage the motor windings. According to EN 60034 volt- switching frequency noise from the motor. age rise times of 500 to 1‘000V/us are permissible depending on motor types.

The dv/dt filters are low pass filter built with inductors, capaci- tors and power resistors. The nominal switching frequency of the motor drive shall be below the typical cut off frequency of the dv/dt filter (typical < 10 kHz). The sine wave filter have higher L and C values, therefore dv/dt filters are lower in cost and smaller in size. With a dv/dt filter the output current ripple is lower but the voltage is still PWM pulse pattern shaped.

Without dv/dt filter With dv/dt filter

Without dv/dt filter With dv/dt filter The Filter FN510 from Schaffner reduces the high output volt- Theage F dv/dtilter FN510 from IGBTfrom Schaffner motor drives reduces and thelimits high the output peak voltage voltage dv/dt fromto 1’000V. IGBT motor It protects drives and the motorlimits the insulation peak voltagewindings to 1000 from V. It prem- protects the motor insulation windings from premature aging and destruction and ature aging and destruction and increases significantly the increases significantly the service life of electric motors. In addition less service life of electric motors. In addition less interference interference propagation towards neighbouring equipment or lines are propagation towards neighbouring equipment or lines are oc- occurring. The typical cable length used is ≤ 80 m at a maximum switching curring. The typical cable length used is ≤ 80m at a maximum frequency of 16 kHz at 400 VAC. switching frequency of 16kHz at 400VAC.

Side effect of the use of a dv/dt filter: the frequency of the pulse ringing voltage oscillation is reduced below 150 kHz. Mainly for high power motors, the motor bearing stress is slightly reduced, but dv/dt filters do not elimi- nate the acoustic switching frequency noise from the motor.

3.3 Sine wave filter Sine wave filters are low pass frequency filters which convert the rectan- gular PWM output signal of motor drives into a smooth sine wave voltage with low residual ripple. Sine wave filters, also known as LC-filters or named sinusoidal filters, are mainly used in combination with variable speed drives to protect the motor against excessive voltage spikes and overheating. As a result, insulation stress and losses in AC motors are reduced and prolon- gate the motor life time.

12 8 > Sine Wave Filter - Application and Selection

3.3 Sine wave filter For following applications differential mode sine wave filters are strongly recommended: Sine wave filters are low pass frequency filters which convert the rectangular PWM output signal of motor drives into a I Applications with motor cable runs above 100m long smooth sine wave voltage with low residual ripple. Sine wave I Applications with 600VAC/60Hz or 690VAC/50Hz motors, filters, also known as LC-filters or named sinusoidal filters, are even with short motor cables mainly used in combination with variable speed drives to pro- tect the motor against excessive voltage spikes and overheat- I Motor drive applications with multiple motors in parallel ing. As a result, insulation stress and losses in AC motors are I LV motor drive feeding MV motor through step-up transform- reduced and prolongate the motor life time. er Voltages: drive output w/o filter sine wave filter output Voltages: drive output w/o filter sine wave filter output I Increase in the reliability and operational safety of the overall system

For a large number of applications, differential mode sine wave filters can be considered to be the ideal solution. The major motor drives issues are solved efficiently and in a cost- effective way.

Schaffner’s sine wave filter are matching the technical require- ments of modern drive systems and are particularly used for long motor cable applications. In addition they calm down acoustic motor noises, lower the HF-leakage currents, reduce bearing currents and eliminate the pulse reflections in the mo- tor cable thus reducing the motor drive losses. Finally they are very useful for special AC motor drive applications requiring a smooth sine wave voltage.

Currents: drive output w/o filter sine wave filter output Currents: drive output w/o filter sine wave filter output

3.3.13.3.1 Differential Differential mode mode sine sine wave wafilterve filter There are basically two types of sine wave filters. For the majority of the There are basically two types of sine wave filters. For the ma- applications, the basic versions are the differential mode (also called sym- jority of the applications, the basic versions are the differential metric) sine wave filter types FN5020, FN5040, FN5040HV and FN5045 from modeSchaffner. (also called symmetric) sine wave filter types FN5020, FN5040, FN5040HV and FN5045 from Schaffner. Motor drive with differential mode sine wave filter DifferentDifferentialial mode mode sinsinee wavewave outputoutput filters filter connecteds connected directlydirectl to they to motor drive output have, above all, the following advantages: the motor drive output have, above all, the following ad- vantages: Protect motor winding insulation against The residual ripple of the signal can be adjusted by using the I Protectdv/dt motorvoltagewi spikesnding andinsul overvoltageation against dv/dt voltage spikes values of the L and C. An optimum cost-benefit ratio is often and Reduction overvoltag ofe the additional magnetic losses reached at a ripple voltage of 3 % to 5 %. and eddy current losses in the motor I Reductio Reductionn of of the motor additiona heatingl magnetic losses and eddy current losses Reduction in the motorof the additional losses of the motor drives Reduction of motor bearing currents caused by circulating currents I Reduction of motor heating Reduction of the acoustic noise of the motor I Reductio Reductionn of of the electromagnetic additional losses emissions of the of motor cables drives

I Reduction of motor bearing currents caused by circulating For following applications differential mode sine wave filters are strongly currents recommended: I Reduction of the acoustic noise of the motor Applications with motor cable runs above 100 m long Differential mode LC sine wave filter I Reductio Applicationsn of electromagneti with 600 VAC/60c Hzemissio or 690 nsVAC/50of motor Hz motors, cables even with short motor cables Motor drive applications with multiple motors in parallel LV motor drive feeding MV motor through step-up transformer Increase in the reliability and operational safety of the overall system

13 8 > Sine Wave Filter - Application and Selection

3.3 Sine wave filter For following applications differential mode sine wave filters are strongly recommended: Sine wave filters are low pass frequency filters which convert the rectangular PWM output signal of motor drives into a I Applications with motor cable runs above 100m long smooth sine wave voltage with low residual ripple. Sine wave I Applications with 600VAC/60Hz or 690VAC/50Hz motors, filters, also known as LC-filters or named sinusoidal filters, are even with short motor cables mainly used in combination with variable speed drives to pro- tect the motor against excessive voltage spikes and overheat- I Motor drive applications with multiple motors in parallel ing. As a result, insulation stress and losses in AC motors are I LV motor drive feeding MV motor through step-up transform- reduced and prolongate the motor life time. er Voltages: drive output w/o filter sine wave filter output I Increase in the reliability and operational safety of the overall system

For a large number of applications, differential mode sine Forwa ave large filters number can be of considereapplications,d todifferential be the id modeeal sol sineution. waveTh filterse can bemajor considered motor drtoiv bees the issues ideal arsolution.e solve Thed efficient major motorly and drivesin a cost issues- are solvedeffective efficientlyway. and in a costeffective way.

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Currents: drive output w/o filter sine wave filter output

3.3.1 Differential mode sine wave filter

There are basically two types of sine wave filters. For the ma- jority of the applications, the basic versions are the differential mode (also called symmetric) sine wave filter types FN5020, FN5040, FN5040HV and FN5045 from Schaffner. Motor drive with differential mode sine wave filter Differential mode sine wave output filters connected directly to Motor drive with differential mode sine wave filter the motor drive output have, above all, the following ad- The residual ripple of the signal can be adjusted by using the values of the vantages: LTh ande residualC. An optimum ripple cost-benefitof the signal ratio can is beoftenadjus reachedted by at ausin rippleg th voltagee

I Protect motor winding insulation against dv/dt voltage spikes ofvalues 3 % to of5 %.the L and C. An optimum cost-benefit ratio is often and overvoltage reached at a ripple voltage of 3 % to 5 %. U1 U2 I Reduction of the additional magnetic losses and eddy current losses in the motor V1 V2 I Reduction of motor heating W1 W2 I Reduction of the additional losses of the motor drives PE PE I Reduction of motor bearing currents caused by circulating currents Drive Motor I Reduction of the acoustic noise of the motor Differential mode CL sine wave filter Differential mode LC sine wave filter I Reduction of electromagnetic emissions of motor cables 3.3.2 Sinus plus (differential and common mode) sine wave filter In some cases, additional measures with motor drives applications are nec- essary. To counter effects or requirements such as Bearing damage caused by common mode currents (shaft currents)  Parasitic earth currents Avoid shielded motor cables (e. g. for retrofit installations) Motors not having conform motor drives insulation prerequisite (e. g. for retrofit installations) Limited maximum possible motor cable length

14 9 > Sine Wave Filter - Application and Selection 9 > Sine Wave Filter - Application and Selection

3.3.2 Sinus plus (differential and common mode) Shielding 3.3.2 Sinus plus (differential and common mode) Shielding sine wave filter Shielding of certain conductors is necessary to prevent inter- sine wave filter In some cases, additional measures with motor drives applica- Shieldingference en ofer certaingy radiation conductor into thes is environ necessarmeyntto. prevent inter- ference energy radiation into the environment. tionsIn some are cases,necessar additionaly. To counter measures effectswith or mot requiror drivesementsap sucplica-h I Cable must be shielded between the inverter output and filter tionsas are necessary. To counter effects or requirements such inpI Cableut (U, must V, W),be connectshielded thebetcaweblene presethe invnterdirectlter outputy to theandinfilter- as verter.input (U, V, W), connect the cable present directly to the in- I Bearing damage caused by common mode currents (shaft verter. IcurrentsBearing) damage caused by common mode currents (shaft I Motor cable between the filter output (U1, V1, W1) and the currents) ImotorMotor itsel cablef doesbetw noeent hatheve to filter be output screene (U1,d (unles V1, W1s specia) and thel in- I Parasitic earth currents motorstallation itsel ref qudoesirements not ha apply)ve to be screened (unless special in- I Parasitic earth currents I Avoid shielded motor cables (e.g. for retrofit installations) stallation requirements apply) I The shield must be solidly connected at both ends to the I Avoid shielded motor cables (e.g. for retrofit installations) I Motors not having conform motor drives insulation prerequi- housingsI The shield (e.mug. housingst be solidl of filtery connected and motor) at both ends to the IsiMotorste (e.g. not for havingretrofit installations) conform motor drives insulation prerequi- housings (e.g. housing of filter and motor) I All shield connections must exhibit the largest possible im- site (e.g. for retrofit installations) I Limited maximum possible motor cable length peI Allda shielnce,d i.e.connectio solid, lansrgemust area exhibit connections the largest possible im- I Limited maximum possible motor cable length pedance, i.e. solid, large area connections Sinus plus is a highly developed modular sine wave filter con- Sinus plus is a highly developed modular sine wave filter concept from Sinuscept fromplus Schaffner is a highly thatdeveloped is unique modin theular mar sineketwatodave filtery. Co con-n- Schaffner that is unique in the market today. Consisting of a traditional Feedback to the dc link ceptsistinfromg of a Schaffnertraditional thatdifferenti is uniqueal (sinymtheme martric)ket andtodaany.additionalCon- Feedback to the dc link differential (symmetric) and an additional common mode (asymmetric) If only one connection to the dc link is brought out of the invert- sistincommong of modea tradition (asymal metric)differenti sineal (swaymveme filtertric) module, and an additional it can be sine wave filter module, it can be customized exactly to any requirement. erIf onl ("+y" onore "-")co thennnectio then dcto thelink dccabl linekconnectiois broughtns outfrom of the the invert- filter customizcommoned mode exactly (asym tometric)any requ sineiremewantve. Th filterrough module,innovative it can be Through innovative circuits and an additional connection to the DC link, (ideren ("+tified" or "-")by then"DC+ the" and dc"DC- link ca")bl muste connectio be connectedns from togethe the filterr to customizcircuits anedd an exactly addition to anyal connectionrequirement to. theThroughDC link,inno thevative addi- the additional module is capable of sending the common mode interfer- (idtheen "+tified" or "-"by inverter"DC+" and connection."DC-") mustA lo bewer connectedswitching togethefrequencr yto tionacircuitsl module and anis additioncapableal ofconnection sending the to thecomDCmonlink,mod thee inter- addi- ences directly to the very place they originated. theor a "+pure" orbl "-"ock inverter modulation connection. is unsuiAtablloweeranswditresultsching freque in thencin-y tional module is capable of sending the common mode inter- ferences directly to the very place they originated. orvertera pure beingblockswitched modulation off wi isth uns theui errortable messandagresultse "over incurrent" the in- ferences directly to the very place they originated. orverter "earth being connswecitchedtion". off with the error message "overcurrent" or "earth connection". FN 530 combines both solutions in one box. Operated in com- FNbinat530ion, combines this solution bothresults solutio inns thein folloonewibox.ng Operatedadditional inadcom-- binvantages:ation, this solution results in the following additional ad- vantages: I Complete elimination of bearing damage I Complete elimination of bearing damage I The possibility of using unshielded motor cables without any reductiI The possibilitons in imymunitof usingy unshielded motor cables without any reductions in immunity Drive with differential mode and add-on common mode filter modules I Practically no more limitations with regard to the maximum Drive with differential mode and add-on common mode filter modules cablI Practicalle lengthy no more limitations with regard to the maximum Drive with differential mode and add-on common mode filter modules cable length I Almost complete elimination of the pulse currents to earth I Almost complete elimination of the pulse currents to earth I No interference influence of neighbouring cables and equip- ImentNo interference influence of neighbouring cables and equip- ment I Elimination of the additional losses in the frequency converter I Elimination of the additional losses in the frequency converter I Reduction in the suppression efforts on the input side. Since IfrequReductioencyn coinnvertersthe sup arepression operated efforts in ground-referred on the input side.neSinct- e wofrequrks,en evercy coynvertersmeasure aretaken operatedon the in outp ground-referredut side also influencesnet- DriveDrive with differential-differential- and and common commonmode mode all-in-one all-in-one sine wave sine filtewaver filter theworks, behaviour every me onasur thee inputtaken sidone (andthe outp viceutversidesa). als Sinceo influences hardly Drive with differential- and common mode all-in-one sine wave filter theany behaviourpulsed interference on the input currents side (and flow victoe thevereasarth). Sincewhen harSindlyus This procedure is in keeping with the basic principle of interfer- This procedure is in keeping with the basic principle of interference sup- anPlusy pulse is usedd,interferencethe asymme currentstric part flo ofw theto theEMCea mainsrth wheninputSin filterus enceThis procedure suppression is in techniques: keeping wi taketh the the basic necessar principly measurese of interfer- at pression techniques: take the necessary measures at the source of the Pluscan be is useredud,cethed, resultin asymmeg tricin totalpart cost of the savings. EMC mains input filter theence source suppre ofssion the noise techniques:, not at the take drain. the necessar Sinus Plusy measures can be at noise, not at the drain. Sinus Plus can be considered as a modular system can be reduced, resulting in total cost savings. considerethe sourced ofas thea modular noise, notsystemat the in drain.which Sin thuse differentPlus canialbefilter in which the differential filter part (FN5020, FN5040 and FN5045) can be considerepart (FN 5020,d as aFNmodular5040 ansydstemFN5045) in wh canich thbee connectedifferentiadlauton-filter connected autonomously and the common mode part (FN5030) may be For further technical specification and information please con- omouspart (FNly 5020,and thFeNcommon5040 and modeFN5045) part (FN50 can be30 connecte) may bedadauton-ded added or as an all-in-one type sine wave filter (FN530). Fosulrt furtherthe datas technicheetsal ofspecifica the corretispondingon and infor prodmauctstion publisheplease con-d in oromous as anly alandl-in-one the commontype sine modewave part filter (FN50 (FN53030).) may be added sulthet downloadthe datasheseetsction of of thewww.schaffner.c corresponding promoducts published in or as an all-in-one type sine wave filter (FN530). Shielding the download section of www.schaffner.com Shielding of certain conductors is necessary to prevent interference en- ergy radiation into the environment.

Cable must be shielded between the inverter output and filter input (U, V, W), connect the cable present directly to the inverter Motor cable between the filter output (U1, V1, W1) and the motor itself does not have to be screened (unless special installation requirements apply) The shield must be solidly connected at both ends to the housings (e. g. housing of filter and motor) All shield connections must exhibit the largest possible impedance, i.e. solid, large area connections

15 Feedback to the dc link If only one connection to the dc link is brought out of the inverter (“+” or “–”) then the dc link cable connections from the filter (identified by “DC+” and “DC-”) must be connected together to the “+” or “–” inverter connection. A lower switching frequency or a pure block modulation is unsuitable and results in the inverter being switched off with the error message “overcur- rent” or “earth connection”.

FN530 combines both solutions in one box. Operated in combination, this solution results in the following additional advantages:

Complete elimination of bearing damage The possibility of using unshielded motor cables without any reductions in immunity Practically no more limitations with regard to the maximum cable length Almost complete elimination of the pulse currents to earth No interference influence of neighbouring cables and equipment Elimination of the additional losses in the frequency converter Reduction in the suppression efforts on the input side. Since frequency converters are operated in ground-referred networks, every measure taken on the output side also influences the behaviour on the input side (and vice versa). Since hardly any pulsed interference currents flow to the earth when Sinus Plus is used, the asymmetric part of the EMC mains input filter can be reduced, resulting in total cost savings.

For further technical specification and information please consult the data- sheets of the corresponding products published in the download section of www.schaffner.com

4. Sine wave filter selection

4.1 Current and voltage rating Schaffner’s standard sine wave filters are designed to be applied with most commonly used standard motor drives and motors available on the global market. For dedicated and special requirements Schaffner does design cus- tomized sine wave filters adapted to the specific needs.

In principle the nominal motor current and the duty cycle is defining the size of the output filter. Schaffner filters are rated for 150 % overload for 1 minute, ones per hour. Above 150 % rated current the saturation of the inductance can be reached and destroy the capacitors.

It is recommended that the rated current of the sine wave filter shall be equal to or greater than the nominal motor current and should correspond and be compatible with the ratings and duty cycle capability of the motor drive.

For motor drives feeding isolation transformers select a sine wave filter with a current rating equal or greater than that of the transformer primary current.

16 With regard to the voltage, Schaffner offers sine wave filter for 400 VAC, 500 VAC, 600 VAC and 690 VAC applications. Even for short cable installations, at voltages > 500 VAC sine wave filter are recommended, to protect the motor winding insulation against high voltage peaks.

In cases the motor drive selection has been made prior to the sine wave filter selection, the usual way is to size the sine wave filter to the corresponding mo- tor drive. Nevertheless, the proper power selection depends on one side upon the drives related specifications, e. g. rated current, voltage, line frequency, mo- tor drives switching frequency, motor frequency, the ambient conditions (tem- perature, altitude) and on the other side on the motor and application perfor- mance requirements. In addition the motor cable length, cable type, motor type, and some particular application requirements needs to be considered.

max. current [%] 110

100

90

80

70

60

50

40

30

20 20 40 60 80 100 120 140 160 180 200 220 Motor frequency [Hz]

max. current

Derating curve: maximum current vs. motor frequency for FN5040

4.2 Frequency The frequency is an important factor when selecting output filter. Depend- ing on the type of filter, three different frequencies are relevant.

Supply frequency. The frequency of the AC mains supply network, typi- cally 50 or 60 Hz. The operating frequency of the filter is determined by the behaviour of the capacitors. Depending on the voltage/frequency characteristic of the capacitor, it might be possible to operate a filter at a higher frequency but with a reduced input voltage. Switching frequency. The frequency used to switch the IGBTs in the out- put stage of a frequency converter. This frequency has a direct relation to the power loss in the converter and to the output components.

Higher switching frequencies have following effects: – increasing the switching losses of the semiconductors -> temperature rise of motor drive -> derating to be considered – reducing the audible noise level – increasing the leakage currents – reducing the harmonic motor current and motor temperature

17 Generally speaking, lower frequencies result in lower motor drive losses and lower leakage currents.

For an output filter, it is also necessary to consider the relation between the motor drive switching frequency and the resonance frequency of the sine wave filter. The Schaffner sine wave filters are always designed in such a way that the resonance frequency is at least 2.5 times lower than the lowest switching frequency. It is important that the minimum switching frequency adjusted in the motor drive is respected according to the specified minimum switching frequency of the sine wave filter (refer the product datasheet).

Motor frequency. The simulated supply frequency of the frequency con- verter. This frequency determines the rotational speed of the motor. Most applications operate at 50/60 Hz motor fields, but applications with high- er rotational speeds also exist (high-speed spindle drives up to 2000 Hz).

Sine wave filters usually have a better performance compared to dv/dt chokes or dv/dt filters. The resonance frequency of the sine wave filter must be at least 2.5–3 times lower than the motor drive switching frequency.

4.3 Required drives settings The nominal switching frequency of the motor drive can vary or be ad- justed and therefore need to be considered from the beginning for the sine wave filter selection.

The motor drive must be suitable to be operated with sine wave filter and therefore shall be adjusted with a constant switching frequency. The mode of operation must be “scalar“ (V/Hz) with a fixed switching frequency. Check the drives manufacturer manual whether special settings are neces- sary. In any doubt contact the drives manufacturer.

Ensure the drives switching frequency is set to the required minimum switch- ing frequency (refer filter selection table of corresponding product datasheet).

Following are the product specific rating selection guidelines with regard to the maximum permissible cable length in relation with the minimum PWM switching frequency:

Motor cable length [m] 2200 2000 1800 1600 1400 1200 1000 800 600 400 200 0 4.5 8 10–17 24–62 75–260 410–660 750–1200 Type current [A]

max. length for min. PWM x 2 max. length for min. PWM Selection curve for 500 VAC sine wave filter FN5040 and FN5045 series

18 2500

2000

1500

1000

500

0 13–45 75–260 300–1320 Filter current rating (A) max. length for min. PWM max. length for min. PWM x 2

Selection curve for 690 VAC sine wave filter FN5040 HV series

*In case a step-up transformer is used, then the length is meant to be be- tween the filter and transformer.

Sine wave filters, unlike dV/dt filters, can be applied for higher switching frequencies (some types up to 16 kHz) than the nominal switching frequen- cy, but lower switching frequencies close to the resonance frequency of the sine wave filter will damage the capacitors. Ensure that the switching frequency of the motor drive is always higher than the minimum allowed switching frequency as shown in following table.

Schaffner’s sine wave filters support lower minimum switching frequencies, therefore a derating of the motor drive is not necessary and does reduce the overall system cost. The minimum switching frequency is compatible with typical motor drives on the market. With reduced motor cable length max. switching frequency up to 16 kHz are allowed.

Filter Version Typival motor Minimum Voltage Version & Current Range power switching frequency fPWM 400 V/4.5 to 48 A 1.1 to 22 kW 4 kHz 400 V/62 to 480 A 30 to 250 kW 3 kHz 400 V/660 to 1200 A 315 to 630 kW 2 kHz 690 V/13 to 300 A 7.5 to 2560 kW 2 kHz 690 V/430 to 1320 A 355 to 1200 kW 1.5 kHz

19 Following special motor drive considerations need to be taken into ac- count in combination with sine wave filters:

Motor drives operating at reduced switching frequency or using block pulsing at particular operation points (e. g. at low motor speed or high load conditions) must not be used or the feature be disabled Sine wave output filter may not be used with servo drives, because they normally are current controlled devices Check the recommended motor drive output frequency levels and ad- justments when non-regenerative/regenerative drives with or without brake choppers are used Automatic frequency adaptation modes need to be disabled within the motor drive Protective functions and features of the motor drive, such as overcurrent, short circuit, motor phase loss or imbalance may be impaired in combi- nation with sine wave filter and/or long motor cables

CAUTION: If the motor drives settings are not correct the filter may be damaged.

4.4 Voltage drop considerations The voltage drop across the sine wave filter must be taken into account when dimensioning the motor and the drive.

At constant motor power level the current will increase above the rated current. For constant operation at this level, which means above the field weakening point or at high overload conditions are limiting or reducing the motor performance. It is recommended to consider the voltage drop impact when dimensioning the motor and the motor drive.

The voltage drop at full load can not be neglected and therefore the motor will not receive the full voltage at nominal speed.

The additional voltage drop of long motor cables does also influence the selection and dimensioning of the motor and the drive.

Schaffner’s sine wave filters have an impedance of 8–10 % at nominal volt- age, frequency and rated current. They are designed for motor frequency operation up to 70 Hz (up to 200 Hz with derating according graph on page 17).

Voltage drops need to be considered when the motor drives protective functions, such as overcurrent, short circuit, motor phase imbalance, motor phase loss or predictive monitoring features need to be set accordingly. Please refer to the corresponding motor drive manual or application guide.

Due to the charging action of the sine wave filter capacitors through DC currents coming from the motor drive (DC braking, DC injection for mo- tor parameter/characteristics measurements) a short circuit trip within the motor drive could be provoked or the measurement values could be im- paired. For those cases some parameters within the motor drive need to be programmed and set accordingly. Contact your motor drives manual or supplier.

20 5. Application examples

Typical applications requiring sine wave filters:

Motor drive with long motor cable Motor drive with multiple motors in parallel Retrofit installations with motor drives Step-up transformer applications for LV-drives control of MV-motors

5.1 Motor drive with long motor cable For motor drives controlling a motor over a long distance with a shielded motor cable can lead to the effect of high parasitic capacitive currents flow- ing across the shield. Those unwanted currents must as well be supplied by the frequency converter or motor drive. The result of this can be that a motor drive of the next higher rating has to be used that is able to supply both the currents required by the load and the parasitic currents via the earthing.

When using a sine wave filter the maximum motor cable length does de- pend on the motor drive switching frequency.

>>> refer to chapter 4.3 Required drive settings

5.2 Motor drive with multiple motors in parallel The operation of several motors connected in parallel to one frequency converter is problematic. The parallel connection of several shielded cables results in a relatively high total capacitance and thus correspondingly high shield currents. The parallel connection of several drives, however, is ac- companied by even more problems. Parasitic currents across the motor and the entire system can considerably affect the reliability of the whole system.

For such configurations it is recommended to use a sine wave filter cov- ering the symmetrical and asymmetrical aspects as described in chapter 3.3.2 Sinus Plus symmetrical and asymmetrical sine wave output filter.

5.3 Retrofit installations with motor drives For existing installation where long motor cables and old motors want to be kept and be modernized with a variable speed motor drive equipment following issues would need to be considered before making a final instal- lation choice.

The cable layout should be checked and all the insulations on the cable and the motor shall be measured against each other phase and to ground/ chassis and PE and still be conform to the newest installation norms.

In any case, even a shielded cable is installed, then it is recommended to use a sine wave filter covering the differential (symmetrical) and common mode (asymmetrical) aspects as described in chapter 3.3.2 Sinus Plus dif- ferential and common mode sine wave output filter.

21 5.4 LV motor drive with MV-motor or step-down/step-up transformer application With a step-up isolation transformer* a cost effective LV motor drive can control a MV motor. This application requires a sine wave filter to ensure that the step-up transformer is fed by a sine wave voltage. Otherwise the transformer power losses would be high and overheat the transformer. In addition the voltage spikes would overstress the winding isolation and sig- nificantly reduce the life time of the transformer. The additional advantage of this system is, that there is no limitation (other than cable voltage drop and losses) of the cable length between the step-up transformer and the MV-motor.

T1 U1 F1 T2 M1 0.69 kV B1 0.39 kV 6 kV Frequency 6 kV Inverter

Diagram is showing a step-up motor drive system consisting the step- down transformer T1, the LV-circuit breaker B1, the motor drive U1, the sine wave filter F1, step-up transformer T2 and the MV-motor M1.

The cable length between the sine wave filter F1 and the step-up trans- former T2 can be treated in the same way as recommended by Schaffner for the LV-motor cable length. For the cable between the transformer T2 and the MV-motor for EMC considerations unshielded cable can be used, but need to be chosen to fit the application requirements.

The motor drives protective functions and predictive monitoring features need to be considered with regard to the sine wave filter, the step-up transformer and cable length impact.

In particular the earth/ground fault protection of the motor drives does not protect the secondary side of the step-up transformer. For this another protective device needs to be installed.

For the transformer dimensioning the starting torque/current of the MV- motor, the cable length and the voltage drop over the sine wave filter need to be considered.

* Note: an autotransformer is not allowed.

6. Mounting and installation guidelines

6.1 Important safety considerations Note: Ensure that all protective earth and ground connections are made at the lowest possible impedance. Remove paint or other isolation materials to achieve good electrical contact. To keep common mode/high frequen- cy effects low a proper large surface connection is required.

Note: For safety reasons, open style or IP00 LC sine wave filters must be installed in cabinets or rooms, to prevent access of non-qualified persons to the filters.

22 Warning: Do not operate the filter outside of specifications.

Note: LC sine wave filters must be mounted in a clean, dry location which protects the product from any liquids, corrosive vapours, dust, abrasive de- bris and aggressive gases.

6.2 General application notes

NOTICE Filter suitability for a given application must ultimately be determined by the user (the party that is putting the filter into operation) on a case by case basis. Schaffner will not assume liability for any consequential downtimes or damages resulting from use of filters outside their specifications.

NOTICE Output filters must be mounted in a clean, dry location (enclosures, cabi- nets, closed rooms). Contaminants such as oils, liquids, corrosive vapours, abrasive debris, dust and aggressive gases must be kept away of the filter and enclosure.

Standard products Standard catalogue filters must be used for the published applications and operated within the published technical specifications.

Custom products Custom filters must be used for the bespoke application and operated within the provided and mutually agreed technical specifications.

NOTICE Output filters are design-in products by definition. Their functionality and suitability must be determined with a proper design-in process, involving electrical, mechanical and thermal verification within the final equipment.

Filter installation, start-up, operation and maintenance (if any) have to be carried out by a trained, certified and authorized electrician or technician, who is familiar with the safety proce- dures in electrical systems, if needed in accordance with NEC and all local electrical codes and regulations and in particular of three-phase power systems.

High voltage potentials are involved in the operation of this product. Always remove power before touching energized and electrical conductive parts of the filter, and let ample time elapse for the capacitors to discharge to safe levels (< 42 V). Residual voltages are to be measured both line to line and line to earth.

Always connect the filter to protective earth (PE) first, and then continue with the wiring of phase terminals. When decommis- sioning the filter, remove the PE connection at the end. The sine wave filter must not be operating without connected motor.

23 Follow the general installation notes closely. Ensure that cooling slots (if any) are free from obstructions that could inhibit effi- cient air circulation. Operate the filter within its electrical, me- chanical, thermal and ambient specifications15 > Sineat all Wavtimes.e Filter - Application and Selection

Special attention should be paid to cable dimensioning, fuses, grounding, shutdown, disconnection, and overcurrent protec- tion.

6.3 General installation notes 6.4 Mechanical mounting Output filters are lossy electrical components. Filter surfaces and terminals may get hot under full load operating conditions Lift the filter with appropriate crane using lifting eye bolts (if I Please read and follow the safety and application notes and can exceed surface temperature > 80 °C. available) – smaller types may be lifted manually by two per- above. sons (no lifting eye bolt applicable).

Always practice the safety procedures definedI Carefully by yourinspect company the shippin g container and the product prior and by applicable national electric codes whento the handling, installation. install In case- of visual damage, don’t install the filter and file a claim with the freight carrier involved. ing, operating or maintaining electrical equipment. I Filters may be heavy. Follow the instructions for lifting heavy In case of uncertainty and questions pleaseequipment contact defined your localby your company. Schaffner partner for assistance. I Mount the filter to a conductive surface free of paint/lacquer. Use an appropriately sized threaded bolt for every mounting 6.3 General installation notes hole/slot provided by the filter flange. The strength class of the bolt must be determined by the installer, depending upon filter Please read and follow the safety and application notes above. For units ≥75A the separate capacitor banks can be mounted weight and the material of the mounting surface. Carefully inspect the shipping container and the product prior to the aside the inductance with a minimum air distance of 150mm. installation. In case of visual damage, don’t install theI Connect filter and the file filter a claim to the protective earth (PE) terminal(s). Due to the heat dissipation of the inductance it is not recom- with the freight carrier involved. Remove all line side power, then connect the phase terminal mended to mount the capacitor bank above or on top of the (s) and capacitor bank (if separate) to the designated termi- inductance. Filters may be heavy. Follow the instructions for lifting heavy equipment nals of the filter. The output filter label indicates the connection defined by your company. Permitted mounting positions: FN 5045 up to 115 A: sides (inverter or motor side). Mount the filter to a conductive surface free of paint/lacquer. Use an ap- propriately sized threaded bolt for every mountingI Fo hole/slotr the electrical provided connection of the filter terminals, apply the recommended on the filter label and/or in the pub- by the filter flange. The strength class of the bolt must be determined lished filter datasheets. by the installer, depending upon filter weight and the material of the mounting surface. I Cable or busbar cross sections have to be chosen in accord- Connect the filter to the protective earth (PE) terminal(s).ance wi Removeth nation alallan lined international electric codes and appli- cable product standards governing the equipment that will side power, then connect the phase terminal(s) and capacitor bank (if Prohibited mounting positions: incorporate the filter. separate) to the designated terminals of the filter. The output filter label indicates the connection sides (inverter or motor side).I Some filters provide additional terminals, e.g. for over- temperature monitoring. These features have to be properly For the electrical connection of the filter terminals, apply the torques rec- used before energizing the filter. If uncertain, please consult ommended on the filter label and/or in the published filter datasheets. your local Schaffner representative. Cable or busbar cross sections have to be chosen in accordance with The pictures above show permitted and prohibited mounting national and international electric codes and positions. The mounting on a vertical plate (top left picture) is applicableproduct standards governing the limited to IP00 products with a maximum weight of 25 kg or for equipment that will incorporate the filter. IP20 products of Some filters provide additional terminals, e. g. FN 5045 series (far right picture) up to 115 A. Use all available for overtemperature monitoring. These fea- mounting holes and select the correct screws and washers in tures have to be properly used before energiz- order to ensure a reliable mounting and to do justice to the ing the filter. If uncertain, please consult your weight of these products. Apply torques appropriate for the local Schaffner representative. strength class of the screws and washers you are using. Spec- ifications can be obtained from the supplier of the screws and washers.

24 15 > Sine Wave Filter - Application and Selection 15 > Sine Wave Filter - Application and Selection

6.3 General installation notes 6.4 Mechanical mounting 6.3 General installation notes 6.4 Mechanical mounting Lift the filter with appropriate crane using lifting eye bolts (if I Please read and follow the safety and application notes availLift theable filter) – smallerwith appropritypesat maye crane be lifted using manliftinuagllyeybye boltstwo pe (ifr- above.I Please read and follow the safety and application notes availsonsable (no)lifting – smallereye bolttype applicable).s may be lifted manually by two per- above. sons (no lifting eye bolt applicable). I Carefully inspect the shipping container and the product prior 6.4 Mechanical mounting toI Carefully the installation.inspect In the case shippin of visualg container damage,and don’tthe product install thpreior Lift the filter with appropriate crane using lifting eye bolts (if available) – filterto the and installation. file a claim Inwi caseth the of visual freight damage,carrier involve don’td. install the smaller types may be lifted manually by two persons (no lifting eye bolt filter and file a claim with the freight carrier involved. applicable). I Filters may be heavy. Follow the instructions for lifting heavy IequipmentFilters ma definedy be heavy.by yourFollow company.the instructions for lifting heavy equipment defined by your company. I Mount the filter to a conductive surface free of paint/lacquer. UseI Mount an ap thepropriately filter to a conductive sized threaded surfacebolt fre fore everof paint/lacquer.y mounting hole/slotUse an ap provipropriatelyded by th sizede filter threaded flange.boThlte for strength every mo classuntin ofg the bolthole/slot must provi be dedeterminedd by theby filterthe flange. installer,Thedep strengthending classupon offilter the For units ≥75A the separate capacitor banks can be mounted weboltight must and be thede materialtermined ofby thethe mounting installer, surfdepacendine. g upon filter Foasider units the≥ inductance75A the separatewith a minimumcapacitor air banks dista cannce be of mount150mm.ed weight and the material of the mounting surface. I Connect the filter to the protective earth (PE) terminal(s). DueasideFor units to the the ≥ inductance75heat A thedissipation separatewith acapacitor of minimum the ind banksuc airtance distacan be itnc is emounted not of 150mm. recom- aside the IRemoConnectve all theline filterside topo thewe protectiver, then connect earth (PE) the phase terminal(s). terminal menDueinductancede tod the to withheat mount adissipation minimum the cap acair ofit distanceor thebank ind ucofab 150tanceove mm. or it on isDue not top to recom- ofthe the heat dis- (s)Remo andve capallaclineitorsidebankpo (ifwe sepr, thenarate) connect to the thedesignated phase termin termi-al menindsipationucdetance.d of to the mount inductance the cap it isac notitor recommendedbank above orto onmount top the of thecapacitor nals(s) and of the cap filter.acitorThbanke output (if sep filterarate) lab toel theindic designatedates the connection termi- indbankuc abovetance. or on top of the inductance. Permitted mounting positions: FN 5045 up to 115 A: nalssides of (inverter the filter. orTh motore output side). filter label indicates the connection Permitted mounting positions: FN 5045 up to 115 A: sides (inverter or motor side). Permitted mounting positions: FN5045 up to 115 A: I For the electrical connection of the filter terminals, apply the 150 mm ItorquesFor the rec electricalommended connectionon the offilter the label filter and/or terminals, in theap pub-ply the 50 mm lishedtorques filter recom datasheets.mended on the filter label and/or in the pub- FN 4045 lished filter datasheets. I Cable or busbar cross sections have to be chosen in accord- 150 mm IanceCablewith or natibusbaronal crossand in sectionsternational have electric to be cochosedesnanind accapplord-i- cableance wi productth nation standardsal and in governiternationalng the electric equipcomedesnt thatand wiapllpli- Prohibited mounting mounting positions:positions: cableincorporate product the standardsfilter. governing the equipment that will Prohibited mounting positions: incorporate the filter. I Some filters provide additional terminals, e.g. for over- ItemperatureSome filters monito providering. additioThesenalfe terminaturesals,ha e.g.ve to for be over- properly temperatureused before ene monitorgizingring. theThese filter.fe Ifatures uncertain,have pleaseto be properl consulty yourused locbealforeScheneaffnerrgizing repre these filter.ntative. If uncertain, please consult your local Schaffner representative. The pictures above show permitted and prohibited mounting The pictures above show permitted and prohibited mounting positions. Thpositions.e picturesThe above mounting showonpearm verticalitted andplate proh (topibited left mou picture)nting is The mounting on a vertical plate (top left picture) is limited to IP00 prod- positions.limited to IP00The mounting products wionthaa verticalmaximplumatewe (topight left of 25 picture) kg or is for ucts with a maximum weight of 25 kg or for IP20 products of FN5045 series IP20limited products to IP00 of products with a maximum weight of 25 kg or for (far right picture) up to 115 A. Use all available mounting holes and select IP20 products of FNthe correct5045 series screws (farand rightwashers picture) in order up to to ensure 115 A. a reliable Use all mounting available and mountingFNto do5045 justice seriesho toles the and(far weight right selec of picture)t thethese correct products. up to scre 115 Applyws A.and Use torqueswa allshers avail appropriateable in mountingorderfor the tostrength ensureholes class aand reli of selab theecle screwst mo theun correct tingand anwashers scred tows do you justiceand are wausing. toshers the Specifica in - orderwetionsight can to of ensurebe these obtained products.a reli fromable the Appmo supplierunlytingtorques ofan thed toappropri screws do justice andate washers. for to the the westrengthight of class these of products. the screws Appanlydtorqueswashers appropri you areat using.e for the Spec- 6.5 Wiring and cabling strengthifications class can be ofobtained the screws fromand thewa suppliershers you of theare scre using.ws Spec-and The filter rating has to be compatible with the drives to which it is con- ificationswashers. can be obtained from the supplier of the screws and nected. All drives manufacturer installation and safety instructions must be washers. fulfilled. The installation and wiring must be in accordance and be conform with the local standards and applicable codes (e. g. NEC).

25 16 > Sine Wave Filter - Application and Selection

6.5 Wiring and cabling In case sine wave filters are installed in cabinets, the shield of the motor cable needs to be connected at the cabinet entry point. The filter rating has to be compatible with the drives to which it To minimize the coupling capacity and inductivity reserve ca- is connected. All drives manufacturer installation and safety ble length need to be avoided. instructions must be fulfilled. The installation and wiring must be in accordance and be conform with the local standards and Connect spare wires in the cable on both sides to ground for applicable codes (e.g. NEC). adding a supplementary shielding effect.

The typical block schematic below is shown for a motor load Filters with separate capacitor bank must be connected as fol- The typical block schematic below is shown for a motor load but the load but the load can be multiple motors or a transformer instead. lows: Drivescanan bed multiple load cable motors sel orec a transformertion/placeme instead.nt should Drives andbe loadin ac- cable se- lection/placement should be in accordance with all local electrical stan- cordance with all local electrical standards and regulations. Caution: dards and regulations. U1, V1, W1 cable connection towards drive.

U2, V2, W2 cable connection toward motor.

Filter may be damaged when cables are swapped !

In manIn manyy applications applications a a shielded shielded cable cable may may notno bet required be require whend a sine whenwavea sin filtere wa is appliedve filter with is a ap motorplied drive.with Anyhow,a motor duedrive. to other Anyh existingow, in- due toterference other ex influencesisting in ofterfere commonnce mode influences disturbances of common Schaffner modedoes rec- ommend to use shielded motor cables to avoid back-coupling of radiated disturbances Schaffner does recommend to use shielded mo- interferences to the mains cable at the frequency range from 1–30 MHz. tor cables to avoid back-coupling of radiated interferences to the mainsBecause cable of interference at the frequenc reasons, ensurey range that fromthe motor 1-30MHz. cable is installed and arranged separate or with enough distance to other cables or wires. In any Because of interference reasons, ensure that the motor cable case avoid parallel cable layout. In case this is not possible, e. g. encoder- or is installedtachometerand cable,arranged then a metal separate separation or wi shieldth enough or tube distais recommended.nce to other cables or wires. In any case avoid parallel cable layout. In caseIf possible, this is the not sine possible, wave filter e.g.encoder- and the motor or drive tachometer should be cab mountedle, thenon a metalthe samese conductiveparation sh mountingield or tubeplate. At is least recom themended. motor drive and the sine wave filter shall be connected with a flat copper ribbon. Because of If possible,EMI reasons the and sine voltagewave spikes filter at and the thefilter motor input terminals drive should the cable be con- mountenectiond on between the same the motor conductive drive and mounting sine wave plfilterate. needs At leastto be as the short motoras drivepossibleand (max.the 2–3 sine m). waFor veelectromagneticfilter shall be emission connected reasonswi theth shielda flat coppershall be ribbon.connected Because EMC conform of EMI on all reasons ends onan a solidd voltage large connection spikes area with the smallest possible impedance. at the filter input terminals the cable connection between the motor drive and sine wave filter needs to be as short as possi- This EMC measure can only be considered to be efficient, if the ends of the ble (max.cable shield2-3m). areFo putr in electromagnetic proper HF low-impedance emission contact reasons with the the chassis shielofd shallthe motor,be connected the filter and EMCthe frequency conform converter. on all ends on a solid large connection area with the smallest possible impedance. In case sine wave filters are installed in cabinets, the shield of the motor In order to get the maximum benefit out of your output filter Thiscable EMC needs measure to be connected can only at be theconsidere cabinet entryd to point. be efficient, if application and installation, please also consult “Basics in the ends of the cable shield are put in proper HF low- EMC and Power Quality”, published in the download section impedanceTo minimize con tathect couplingwith the capacity chassis and of inductivity the motor, reserve the filtercable and length of www.schaffner.com. the frequencyneed to be avoided. converter. These additional guidelines provide helpful hints for HF- Connect spare wires in the cable on both sides to ground for adding a grounding, shielding, proper cable routing etc. supplementary shielding effect.

26 Filters with separate capacitor bank must be connected as follows:

Caution: U1, V1, W1 cable connection towards drive U2, V2, W2 cable connection toward motor Filter may be damaged when cables are swapped!

U1 U2

V1 V2

W1 W2

PE PE

Drive Motor

In order to get the maximum benefit out of your output filter applica- tion and installation, please also consult “Basics in EMC and Power Qual- ity”, published in the download section of www.schaffner.com.

These additional guidelines provide helpful hints for HF-grounding, shielding, proper cable routing etc. 27 Headquarters, global innovation Sales and application centers and development center

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This document has been carefully checked. However, Schaffner does not assume any liability for errors or

06/2013 EN inaccuracies.

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