SIMOTICS N-compact Нестандартные двигатели

SIMOTICS N-compact: Series 1LA8, 1PQ8, 1LL8

The three-phase motor series SIMOTICS N-compact covers outputs up to 1250 kW (at 50 Hz) in the non-standard range. A number of technical features provide this motor series with its ruggedness and long service life and ensure the highest level of availability, for example, motor protection with PTC thermistors with 6 embedded temperature sensors for alarm and tripping is standard.

SIMOTICS N-compact motors are also characterized by their high output for small frame size. The consequence of this is an extremely compact design that can be used to save space in a number of industrial applications.

SIMOTICS N-compact motors are not only optimized in terms of their construction, but also in terms of their efficiency, so they also contribute towards lower energy consumption.

Apart from mains-fed operation, the SIMOTICS N-compact motors are also specially designed for converter-fed operation, for example, insulated bearings are used at the non-drive-end NDE for converter-fed operation as standard to prevent damage being caused as a result of bearing currents. In combination with frequency converters from the SINAMICS and SIMOVERT MASTERDRIVES product series, they build up perfectly interacting drive systems for variable-speed drive applications.

Versions in the SIMOTICS N-compact series

Series 1LA8

The motors are asynchronous squirrel-cage motors with compact dimensions in fin-cooled design. They are designed for direct connection to the three-phase supply and for converterfed operation.

1LA8 for mains-fed operation	1LA8 for converter-fed operation
Designed for operation on the three-phase supply Degree of protection: IP55 Cooling method: IC 411, self-ventilated • Housing: Cast iron	Converter-fed operation, optimized for the SINAMICS and SIMOVERT MASTERDRIVES drive systems Degree of protection: IP55 Cooling method: IC 411, self-ventilated Housing: Cast iron With standard insulation for voltages ≤ 500 V or with special insulation for 690 V

Series 1PQ8

The motors are asynchronous squirrel-cage motors with compact dimensions in fin-cooled design with forced ventilation. As these motors are forced-ventilated, no derating or only relatively minor derating (depending on their speed range) is required for operation at constant load torque and with wide speed ranges. The motors are designed for converter-fed operation with the SINAMICS and SIMOVERT MASTERDRIVES drive system.

1PQ8 for converter-fed operation
Converter-fed operation Degree of protection: IP55 Cooling method: IC 416, forced ventilation Housing: Cast iron With standard insulation for voltages ≤ 500 V or with special insulation for 690 V

Series 1LL8

The motors of series 1LL8 are asynchronous squirrel-cage motors with compact dimensions in an open fin-cooled design with self-cooling. They are similar in construction to 1LA8 motors. IP23 degree of protection is achieved by opening the internal cooling circuit which enables it to be supplied with external cooling air. This can increase the performance by up to 25 % as compared to the 1LA8. They are designed for direct connection to the three-phase supply and for converter-fed operation.

Motors of the 1LL8 type series are intended for installation indoors. They must not be subjected to humid, salty or corrosive atmospheres.

1LL8 for mains-fed operation	1LL8 for converter-fed operation
Designed for operation on the three-phase supply Degree of protection: IP23 Cooling method: IC 01, self-ventilated Housing: Cast iron	Converter-fed operation Degree of protection: IP23 Cooling method: IC 01, self-ventilated Housing: Cast iron

Versions with special insulation for > 500 V and operation without an output filter on the frequency converter are only available on request.

Standardline

4-pole 1LA8 motors up to 500 kW are available with a reduced range of options as the Standardline.

Benefits to the customer:

• Much shorter delivery time
• Can be configured with a variety of options, retaining a high degree of flexibility.

Applications

Standardline low-voltage motors are optimized for applications in pump, fan and compressor drives. The low-voltage motors are specially constructed for use in complete, coordinated drive systems comprising the motor and a SINAMICS G150 frequency converter.

Standardline motors can be ordered using order code B20.

Scope of the Standardline

• 4-pole version
• Power range 250 to 500 kW
• Types 1LA8315, 1LA8317, 1LA8353, 1LA8355 and 1LA8357
• Type of construction code 0 (IM B3)
• For mains-fed operation: Voltage code 6 (400 VΔ/690 VY) or 5 (500 VΔ)
• For converter-fed operation: Voltage code 4 (400 VΔ), 8 (400 VΔ/690 VY) or 5 (500 VΔ)
• Can be ordered for converter-fed operation, but not in the 690 V version
• Possible order codes: A23, A61, A72, G50, H70, H73, K09, K10, K45, K46, K57, K83, K84, K85, L00, L97, M58 (frame size 315 only), M88 and Y53

Spectrum of N-compact 1LA/1LL/1PQ Non-standard motors – Standard degree of protection IP55 (exception: 1LLA motors with IP23); optionally IP56 or IP65

Motor version	Motor type (cast-iron)	Motor type – Frame size – Rated output at 50 Hz (values in kW) or 60 Hz (values in hp)
		71	80	90	100	112	132	160	180	200	225	250	280	315 S/M/L	315 L1LG6 318-.M,1LG6 312-.M	315	355	400	450
Mains-fed operation	1LA8	–	–	–	–	–	–	–	–	–	–	–	–	–	–	1LA8 160 … 1000 kW
	1LL8	–	–	–	–	–	–	–	–	–	–	–	–	–	–	1LL8 200 … 1250 kW
Converter-fed operation	1LA8	–	–	–	–	–	–	–	–	–	–	–	–	–	–	1LA8 145 … 1000 kW
	1LL8	–	–	–	–	–	–	–	–	–	–	–	–	–	–	1LL8 180 … 1250 kW
	1PQ8	–	–	–	–	–	–	–	–	–	–	–	–	–	–	1PQ8 145 … 1000 kW

 

Особенности

SIMOTICS N-compact Нестандартные двигатели

Non-standard motors from Siemens offer the user numerous advantages:

• The optimized efficiency results in lower operating costs.
• The high output/size ratio ensures low space requirements combined with low weight.
• The cast-iron housing and bearing plates are extremely rigid and rugged and can therefore be subjected to considerable stress and have excellent vibration damping properties and are resistant to corrosion.
• The bearings are designed for maximum reliability, which results in good vibration characteristics, a long service life and low maintenance costs.
• The DURIGNIT IR 2000 insulation system with VPI or current-UV impregnation results in high reliability, a long service life and high resistance to stress, for example, during starting or under overload conditions.
• Due to the low noise emission level, the stringent requirements of worker protection are fulfilled without the need for additional measures.

 

Область применения

SIMOTICS N-compact Нестандартные двигатели

Thanks to the many options, the motor series SIMOTICS N-compact covers applications in a wide range of different sectors: Chemicals, paper, water/waste water, steel and shipbuilding are just a few examples. The available types of construction are IM B3, IM B35 and IM V1 according to DIN EN 60034-7. The degree of protection is IP55 as standard, but IP23 for motor series 1LL8.

The 1PQ8 motors are specially designed for variable-speed applications with constant torque. The mounted separately driven fan provides a constantly high cooling air flow at any speed. These motors can therefore be continuously operated at low speed and high torque simultaneously.

The low-voltage motor series SIMOTICS N-compact is also available in a through-ventilated version to IP23 degree of protection. This 1LL8 motor series boasts an output 25 % higher than that of the closed 1LA8 motor series for the same frame size.The 1LL8 motor is therefore useful for applications in which a closed 1LA8 motor is not essential and when the ambient conditions permit the use of a through-ventilated machine (IC 01 cooling method, IP23 degree of protection). Motors of the 1LL8 type series are only intended for installation indoors.They must not be subjected to humid, salty or corrosive atmospheres.

 

Дизайн

SIMOTICS N-compact Нестандартные двигатели

The basic structure of the non-standard motors is shown in the following sectional diagrams.

Sectional diagram of 1LA8

Sectional diagram of 1PQ8

Sectional diagram of 1LL8

In conventional fin-cooled motors, the one-sided external ventilation naturally results in an uneven temperature distribution – this is however not the case with SIMOTICS N-compact motors with their additional internal air-flow channels. This cools, in particular, the stator winding heads, the rotor winding and the drive-end bearings. The resulting reduction in thermal loading increases the operating reliability and lengthens the service life.The internal air-flow channels increase the efficiency of the ventilation which means that the external air-flow can be reduced. The lower volumetric flow and air-flow optimization of all guide channels results in a low level of fan noise.

 

Технические данные

SIMOTICS N-compact Нестандартные двигатели

Rating plate

According to DIN EN 60034-1, the approximate overall weight is specified on the rating plate for all motors of frame size 90 and above (from approx. 30 kg).For all motors, an additional rating plate can be supplied loose, order code K31. An extra rating plate for identification codes is also possible, order code Y82. In the standard version, the rating plate is available in English and German.

Example of rating plate for 1LA8 mains-fed operation (IE2)

Example of rating plate for 1LA8 mains-fed operation (IE3)

Example of rating plate for 1LA8 converter-fed operation

All motors which comply with the international standard IEC 60034-30:2008 (Rotating electrical machines – Part 30: Efficiency classes of single-speed, three-phase, cage-induction motors (IE code)) display the efficiency class and the efficiency on the rating plate. This efficiency is based, according to the above standard, on the losses determined in accordance with standard part IEC 60034-2-1:2007.

Explosion-proof motors, order codes M35 and M39 for Zone 22 as well as M72 and M73 for Zone 2, display the corresponding identification on an extra rating plate.

Example for extra rating plate for Zone 22 (mains-fed and converter-fed operation)

Example for extra rating plate for Zone 2 (mains-fed and converter-fed operation)

Converter-fed operation

The motors are equipped with standard rotors and are suitable for mains-fed or converter-fed operation. All motors can therefore be operated with a converter, in principle. Special measures are necessary in the case of some motors, especially when non-Siemens converters are used. All data is applicable to a 50 Hz sinusoidal supply.

Rated voltage

The tolerance for the rated voltage is in accordance with DIN EN 60034-1 in all cases, a rated voltage range is not specified.

Motor protection

A motor protection function can be implemented using the I2t sensing circuit implemented in the converter software.

If required, more precise motor protection can be afforded by direct temperature measurement using KTY84 sensors, PT100 resistance thermometers or PTC thermistors in the motor winding. Some converters from Siemens determine the motor temperature using the resistance of the temperature sensor. They can be set to a required temperature for alarm and tripping.If PT100 resistance thermometers are ordered for cooling temperature monitoring (order code A61) or KTY84 temperature sensors (order code A23), the standard thermistors are omitted. Combination of A12 and A61 or A12 and A23 is possible, additional charge on request.Evaluation of the KTY or PT100 sensor is performed as described above, for example, in the converter. For motors for mains-fed operation, the 3RS10 temperature monitoring device that forms part of the protective equipment must be ordered separately, for further details, see Catalog IC 10.

Insulation

The standard insulation of the motors is designed such that converter-fed operation is possible without limitation at voltages ≤ 500 V. This also applies for operation with a pulse-controlled AC converter with voltage rise times ts > 0.1 μs at the motor terminals. All motors with voltage codes 4, 5 and 8 must be operated under these preconditions on a converter.

This does not apply to motors with voltages > 500 up to 690 V, that must have special insulation for operation on a pulse-controlled AC converter (SINAMICS, SIMOVERT MASTERDRIVES) without a converter circuit (du/dt filter or sine-wave filter), i.e. when 10th position of the Order No. = "M").

For converter-fed operation with the outputs specified in the Catalog, the motors are used according to temperature class 155 (F), i.e. in this case neither a service factor > 1 nor an increased coolant temperature is possible (order codes C11, C12 and C13 cannot be ordered).

Connecting motors

When connecting the motors, it is important to consider the restrictions for mains-fed machines as well as the maximum conductor cross-sections permitted for the converter.

Ventilation/noise generation

The fan noise can increase at speeds that are higher than the rated speed of self-ventilated motors (this is not the case for forced-ventilated motors 1PQ8). To increase motor utilization at low speeds it is recommended that forced-ventilated 1PQ8 motors are used.

Technical data of the separately driven fans for 1PQ8 motors
Frame sizeFS	P rated, 50 Hz kW kW	P rated, 60 Hz kWkW	I rated, 400 V,50 Hz A	I rated, 460 V,50 Hz A
315	0.75	1.23	3.4	3.3
355, 400	1.3	2.2	6.4	6.2
450	3.0	4.2	8.2	7.7

In general, for converter-fed operation, the noise level is higher than that specified in the Catalog (exception: 1PQ8). The increase depends on the converter type and can lie between 5 and 10 dB(A) depending on the frame size and number of poles of the motor.

Mechanical stress and grease lifetime

When motors are operated at speeds above the rated speed, the running smoothness and the bearings are subjected to greater mechanical stress. This reduces the service life of the grease and bearings. More detailed information on request.

Bearings

To prevent damage being caused as a result of bearing currents, insulated bearings are used at the non-drive-end (NDE) of 1LA8, 1LL8 and 1PQ8 motors for converter-fed operation in the standard version (this can be recognized when 9th position of Order No. = "P").

When operating multiphase induction machines on a converter, an electrical bearing stress results from a capacitive induced voltage via the bearing lubricating film, depending on the principle being used. The physical cause of this is the common-mode voltage at the converter output that is inherent in the control method for a converter: The sum of the three phase voltages is – in contrast to straightforward mains-fed operation – not equal to zero at every point in time. The high-frequency, pulse-shaped common-mode voltage brings about a residual current, which closes back to the converter's DC link via the machine's internal capacitances, the machine housing and the grounding circuit. The machine's internal capacitances include the main insulation winding capacitance, the geometric capacitance between the rotor and stator, the lubricating film capacitance and the capacitance of any bearing insulation that may be present. The level of the currents due to the internal capacitances is proportional to the gradients, i.e. the voltage variation of the DC voltage (i(t) = C ⋅ du/dt).

In order to apply currents to the motor which are sinusoidal as far as possible (smooth running, oscillation torques, stray losses), a high clock frequency is required for the converter's output voltage. The related (very steep) switching edges of the converter output voltage (and also, therefore, of the common-mode voltage) cause correspondingly high capacitive currents and voltages on the machine's internal capacitances.

The voltage that is injected capacitively across the bearing can result, in the worst case, in stochastic arcing through the lubrication film of the bearing and prematurely age or damage the bearing. (The current pulses caused by arcing in the lubrication film are known as EDM currents (Electrostatic Discharge Machining) in the technical literature.)

This physical effect, which occurs in isolated cases, has mostly been observed in connection with larger motors.

EMC-compliant installation of the drive system is a basic prerequisite for preventing premature bearing damage as a result of bearing currents.

The most important measures for reducing bearing currents:

• Insulated motor bearings at the non-drive-end NDE (standard for 1LA8, 1LL8 and 1PQ8 for converter-fed operation)
• Use of cables with a symmetrical cable cross-section:

• Preference given to a supply with insulated neutral point (IT system)
• Use of grounding cables with low impedance in a large frequency range (DC up to approximately 70 MHz): for example, plaited copper ribbon cables, HF litz wires
• Separate HF equipotential-bonding cable between motor housing and driven machine
• Separate HF equipotential-bonding cable between motor housing and converter PE busbar
• 360° HF contacting of the cable shield on the motor housing and the converter PE busbar. This can be achieved using EMC screwed glands on the motor end and EMC shield clips on the converter end, for example
• Using motor reactors at the converter
• Common-mode filters at the converter output

Thermal torque limits

In the case of self-ventilated motors, such as series 1LA8 and 1LL8, the thermally admissible load torques are reduced for continuous operation for speeds below the rated speed. This must be taken into account in those applications in particular that are not subjected to a load torque that is dependent on the square of the speed. Also in the case of forced-air cooled motors of series 1PQ8, the maximum load torques are reduced slightly for high speed ranges.

When motors are operated at speeds above their rated speed (operation in the field-weakening range), the maximum load torque is also reduced.

Operating points with speeds lower than one tenth of the rated speed are only possible following consultation. In an inquiry, the load torque, the duration of the load and, if necessary, the frequency (number per time interval) of the occurring load must be specified.

Thermal torque limit characteristic 1LA8

Thermal torque limit characteristic 1PQ8

Thermal torque limit characteristic 1LL8

Technical explanations regarding torque and determination of the start-up time for mains-fed operation

Torque characteristic

The torque generated by a three-phase motor at its shaft varies considerably within the speed range n = 0 to n = ns. The characteristic curve of the torque as a function of the speed of a three-phase motor with squirrel-cage rotor (CL) is shown in the following diagram.

The values for locked-rotor torque and breakdown torque as well as for locked-rotor current for a certain motor can be found in the selection and ordering data.

The limit for the mechanical overload capability is the breakdown torque. According to IEC/EN 60034-1 asynchronous motors must have an overload capability at rated voltage and rated frequency of up to 1.6 times the rated torque for a duration of 15 s.

At rated voltage, the pull-up torque of asynchronous motors must – unless otherwise agreed – at least have the rated torque values specified in the following.

For three-phase motors without pole changing with a rated output equal to or greater than 100 kW the following applies:

• 0.3 times their rated torque and at least 0.5 imes the lockedrotor torque

According to IEC/EN 60034-1, the following tolerances are admissible:

• For locked-rotor torque, from -15 to 25 % of the stated locked-rotor torque
• For locked-rotor current, up to 20 % of the stated locked-rotor current without lower limit
• For breakdown torque, up to -10 % of the stated breakdown torque
• For pull-up torque, -15 % of the guaranteed value.

Taking these tolerances into account, the locked-rotor torque must be sufficiently higher than the breakaway torque of the driven machine; and the motor torque must constantly exceed the load torque during ramp-up until the operating speed is achieved.

In the case of squirrel-cage motors, the locked-rotor torque and breakdown torque are listed in the selection and ordering data as multiples of the rated torque.

The normal practice is to start squirrel-cage motors directly on line. The torque class indicates that with direct-on-line starting, even if there is 5 % undervoltage, it is possible to start up the motor against a load torque of

• 130 % (for CL 13),
• 100 % (for CL 10),
• 70 % (for CL 7),
• 50 % (for CL 5)

of the rated torque.

The rated torque can be calculated as follows:

T rated Rated torque in Nm

n rated Rated speed in rpm

P rated Rated output in kW

The rated speed of the motor differs from the synchronous speed by the slip Srated.

It is:

S rated Slip in %

n S Synchronous speed in rpm

n rated Rated speed in rpm

Calculation of the start-up time for direct on-line starting

The start-up time from n = 0 to n = nop can be approximately determined from the average acceleration torque.

t st Start-up time in s

J Total moment of inertia in kgm2

n op Operating speed in rpm

T aav Average acceleration torque in Nm

The total moment of inertia is made up of the motor moment of inertia plus the moment of inertia of the driven machine and the coupling or belt pulleys and is converted to the speed of the motor shaft.

Limit values for the start-up curve of three-phase squirrel-cage motors for voltages up to and including 690 V are included in IEC/EN 60034.

If no sound start-up is possible due to a high moment of inertia and/or a high load torque, a larger motor or a three-phase motor with a SINAMICS frequency converter can be selected for SIMOTICS N-compact motors.

A mechanical solution for coping with heavy starting is to use a starting coupling, whose application is limited by its capability to absorb heat.

Determination of the average acceleration torque

Start-up procedure for three-phase motors with squirrel-cage rotor

Three-phase motors with squirrel-cage rotors should, as far as possible, be started directly on-line.

• It must be observed that the torque and current curve for a specific motor is predetermined, regardless of the heaviness of start-up.Star/delta start-up of motors with squirrel-cage rotor must be used if small locked-rotor currents (e.g. in the supply conditions of the electric power company) or a particularly low startup torque (soft starting) are required. Locked-rotor torque, breakdown torque and all other torque values as well as the locked-rotor current are 25 to 30 % of the values at direct online starting.
• The motor torque must be sufficiently higher than the load torque during start-up in the star stage. The change from star to delta must not occur before approximately the operating speed.

The first diagram shows a case in which star-delta start-up is not appropriate, because the excessive load torque causes the premature change which in turn causes a high torque and current surge that renders the star-delta starting ineffective.

The torque curve can be approximately reduced by the square of the voltage and the current curve linearly with the voltage by reducing the voltage at the motor terminals with the help of a starting transformer or starting resistors.

A starting with rated current is possible on the converter – second diagram.

Soft starting for motors with squirrel-cage rotor can also be achieved with short-circuit soft starting (a resistor can be connected in one phase during start-up). The locked-rotor torque can be arbitrarily reduced with the help of this circuit. The locked-rotor current without a resistor or reactor is slightly higher in both phases than with direct on-line starting.

This start-up procedure can be achieved more satisfactorily using the electronic motor starter "SIKOSTART" which limits the torque and the current during starting.

Any inquiries regarding start-up procedures must include the following information:

1) Required output and rated speed of the driven machine

2) Planned motor speed

3) Load torque of the driven machine, depending on the speed of the driven machine or the motor speed

4) Total external moment of inertia and rated speed of the driven machine or referred to the motor speed

5) Number of starts in a specific time period and duty cycle or

6) Characteristics and number of operating cycles in a certain time (method of braking)

Start-up times and moments of inertia for 1LA8 motors for mains-fed operation (default values)

The values in the following table are only valid for 1LA8 motors for mains-fed operation and are applicable for continuous heating of 90 % of the rated output at 50 Hz (0.9 x Prated). At 60 Hz, the admissible moments of inertia must be reduced again by about 20 %. The moment of inertia Jadm in the tables is the moment of inertia which the driven machine is allowed to have as a maximum in order to start the motor. For this reason, the moment of inertia of the motor is already taken into account in the selection and ordering data.

Frame size	Type	Locking of brake		Admissible moment of inertia and start-up times when starting up the motor
FS		coldBlocking timetBrs	warmBlocking timetBrs	1x coldMoment of inertiaJadmkgm2	Start-up timetSts	1x warmMoment of inertiaJadmkgm2	Start-up timetSts
Self-ventilated motors for mains-fed operation, cast-iron series 1LA8 – 2-pole: 3000 rpm at 50 Hz
315	1LA8315-2AC..	18	10	125	33.9	48	13.0
315	1LA8317-2AC..	17.5	10	140	33.2	58	13.4
355	1LA8353-2AC..	18	9	175	41.4	33	7.8
355	1LA8355-2AC..	20	10	190	45.8	40	9.7
355	1LA8357-2AC..	15	7.5	180	30.0	40	6.7
400	1LA8403-2AC..	22	13	245	40.2	95	15.7
400	1LA8405-2AC..	19	11	255	37.2	90	13.1
400	1LA8407-2AC..	17	9.5	300	34.9	85	9.9
450	1LA8453-2AE..	21.5	15	178	31.3	83	14.6
450	1LA8455-2AE..	20.5	14	190	30.2	90	14.3
450	1LA8457-2AE..	19	13	200	28.2	95	13.4
Self-ventilated motors for mains-fed operation, cast-iron series 1LA8 – 4-pole: 1500 rpm at 50 Hz
315	1LA8315-4AB..	22	13	590	36.9	350	21.9
315	1LA8317-4AB..	19	11	730	32.3	425	18.8
355	1LA8353-4AB..	20	11	1000	45.7	270	12.4
355	1LA8355-4AB..	18	10	1020	39.6	280	10.9
355	1LA8357-4AB..	19	10.5	1370	41.9	370	11.3
400	1LA8403-4AB..	20.5	11.5	1420	46.2	430	14.0
400	1LA8405-4AB..	20	11	1600	44.5	480	13.3
400	1LA8407-4AB..	19	10.5	1750	43.6	525	13.1
450	1LA8453-4CE..	17.5	10	950	23.7	300	7.5
450	1LA8455-4AC..	18.5	10.5	1200	26.8	370	8.3
450	1LA8457-4AC..	17	9	1160	22.3	380	7.3
Self-ventilated motors for mains-fed operation, cast-iron series 1LA8 – 6-pole: 1000 rpm at 50 Hz
315	1LA8315-6AB..	33	18	1900	57.4	830	25.1
315	1LA8317-6AB..	31	15.5	2300	55.6	1000	24.2
355	1LA8355-6AB..	40	22	2950	62.2	1350	28.5
355	1LA8356-6AB..	37	18	3150	60	1450	27.9
355	1LA8357-6AB..	40	22	3950	62.5	1800	28.5
400	1LA8403-6AB..	34	18.4	3450	51.1	850	12.6
400	1LA8405-6AB..	32	17.5	3500	43.3	900	11.1
400	1LA8407-6AB..	24	12	2200	25.6	740	8.6
450	1LA8453-6AB..	16	7	1400	15.5	560	6.2
450	1LA8455-6AB..	19	8.5	1700	18.1	670	7.1
450	1LA8457-6AB..	16	7	1800	15.9	720	6.4
Self-ventilated motors for mains-fed operation, cast-iron series 1LA8 – 8-pole: 750 rpm at 50 Hz
315	1LA8315-8AB..	40	22	4800	109.5	1950	44.5
315	1LA8317-8AB..	42	23	6800	125.9	2500	46.3
355	1LA8355-8AB..	41	22.5	6200	89.6	3100	44.8
355	1LA8357-8AB..	40	22	7600	88.7	3800	44.3
400	1LA8403-8AB..	55	30	9700	107.5	4400	48.8
400	1LA8405-8AB..	54	29.5	11000	102.9	5400	50.5
400	1LA8407-8AB..	52	28.5	11200	95.4	5400	46.0
450	1LA8453-8AB..	44	25	9800	78.8	2900	23.3
450	1LA8455-8AB..	42	23	10500	71.4	3000	20.4
450	1LA8457-8AB..	44	25	12400	78.1	3700	23.3
Self-ventilated motors for mains-fed operation, cast-iron series 1LA8, IE3 version – 2-pole: 3000 rpm at 50 Hz
315	1LA8315-2EC..	18	10	125	33.9	48	13.0
315	1LA8317-2EC..	17.5	10	140	33.2	58	13.4
355	1LA8353-2EC..	18	9	175	41.4	33	7.8
Self-ventilated motors for mains-fed operation, cast-iron series 1LA8, IE3 version – 4-pole: 1500 rpm at 50 Hz
315	1LA8316-4EB..	28	13	590	36.7	350	21.9
315	1LA8318-4EB..	31	9	730	38.4	330	17.5
355	1LA8353-4EB..	23	9	1000	49.6	270	13.6
Self-ventilated motors for mains-fed operation, cast-iron series 1LA8, IE3 version – 6-pole: 1000 rpm at 50 Hz
315	1LA8317-6EB..	49	17	1900	72.1	830	31.6
315	1LA8318-6EB..	42	16	2300	71	1000	31
355	1LA8355-6EB..	40	22	2950	62.2	1350	28.5
355	1LA8356-6EB..	37	18	3150	60	1450	27.9