Siemens
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Êàòàëîã ÑÀ01 2018
(4872) 700-366
skenergo@mail.ru

Guide to selecting a closed-loop control variant

SINAMICS S closed-loop control properties

Criteria for assessing control quality

Explanations, definitions

Rise time

The rise time is the period which elapses between an abrupt change in a setpoint and the moment the actual value first reaches the tolerance band (2 %) around the setpoint.
The dead time is the period which elapses between the abrupt change in the setpoint and the moment the actual value begins to increase. The dead time is partially determined by the read-in, processing and output cycles of the digital closed-loop control. Where the dead time constitutes a significant proportion of the rise time, it must be separately identified.

Characteristic angular frequency ‑3 dB

The limit frequency is a measure of the dynamic response of a closed-loop control. A pure sinusoidal setpoint is input to calculate the limit frequency; no part of the control loop must reach the limit. The actual value is measured under steady-state conditions and the ratio between the amplitudes of actual value and setpoint is recorded.
-3 dB limit frequency: Frequency at which the absolute value of the actual value drops by 3 dB (to 71 %) for the first time. The closed-loop control can manage frequencies up to this value and remain stable.

Ripple

The ripple is the undesirable characteristic of the actual value which is superimposed on the mean value (useful signal). Oscillating torque is another term used in relation to torque. Typical oscillating torques are caused by certain motor slot arrangements, by limited encoder resolution or by the limited resolution of the voltage control of the IGBT power unit. The torque ripple is also reflected in the speed ripple as being indirectly proportional to the mass inertia of the drive.

Accuracy

The accuracy defines the magnitude of the average, repeatable deviation between the actual value and setpoint under rated operating conditions. Deviations between the actual value and setpoint are caused by internal inaccuracies in the measuring and control systems. External influencing factors, such as temperature or speed, are not included in the accuracy assessment. The closed-loop and open-loop controls should be optimized with respect to the relevant variable.



SINAMICS S performance characteristics

Characteristics

Servo Control

Vector Control

V/f control

Notes

Typical application

  • Drives with high dynamic motion control
  • Angular-locked synchronism with isochronous PROFIBUS/PROFINET in conjunction with SIMOTION
  • For use in machine tools and clocked production machines
  • Variable-speed drives with high speed and torque stability in general machinery construction
  • Especially suitable for asynchronous (induction) motors and reluctance motors (1FP1)
  • Drives with low requirements on dynamic response and accuracy
  • Group drives running with a high degree of precision, e.g. on textile machines with SIEMOSYN motors

Mixed operation of Servo Control and Vector Control is not possible on CU320-2. Mixed operation is possible for V/f control modes.

Dynamic response

Very high

High

Low

Highest dynamic response with 1FK7 High Dynamic synchronous motors and Servo Control.

Control modes with encoder

Position control/
Speed control/
Torque control

Position control/
Speed control/
Torque control

None

SIMOTION D with Servo Control is standard for motion control.

Control modes without encoder

Speed control

Speed control/torque control

All V/f control modes

With Servo for asynchronous (induction) motors only.
With V/f control, the speed can be kept constant by means of selectable slip compensation.

Asynchronous motor (induction motor)

Synchronous motor

Reluctance motor (1FP1)

Torque motor

Linear motor

Yes

Yes

No

Yes

Yes

Yes

Yes

Yes

Yes

No

Yes

No

No

No

No

V/f control (textiles) is recommended for SIEMOSYN motors.

Permissible ratio of motor rated current to rated current of Motor Module

1:1 to 1:4

1.3:1 to 1:4

1:1 to 1:12

For Servo Control and Vector Control, maximum control quality up to 1:4. Between 1:4 and 1:8, increasing restrictions regarding torque and rotational accuracy. V/f control is recommended for < 1:8.

Maximum number of parallel-connected motors per Motor Module

4

8

Unlimited in theory

Motors with identical power ratings can only be connected in parallel if they are asynchronous (induction) motors.
With V/f Control, the motors can have different power ratings.

Setpoint resolution position controller

31 bit + sign

31 bit + sign

 

Setpoint resolution speed/frequency

31 bit + sign

31 bit + sign

0.001 Hz

 

Setpoint resolution torque

31 bit + sign

31 bit + sign

 

Maximum output frequency

 

 

 

Values valid for the factory setting High output frequencies can only be achieved when using suitable motors and the appropriate parameterization.

For synchronous motors, observe the voltage limit (2 kV) and use a VPM module.

Only for asynchronous (induction) motors: When using edge modulation, 600 Hz is possible at 4 kHz, or
300 Hz at 2 kHz and
200 Hz at 1.25 kHz.

  • For current controller clock
    cycle/pulse frequency

660 Hz 1)
with 125 Î¼s/4 kHz

330 Hz
with 250 Î¼s/4 kHz

400 Hz
with 250 Î¼s/4 kHz

  • For current controller clock
    cycle/pulse frequency
    (chassis frame sizes FX and GX)

330 Hz
with 250 Î¼s/2 kHz

160 Hz
with 250 Î¼s/2 kHz

200 Hz
with 250 Î¼s/2 kHz

  • For current controller clock
    cycle/pulse frequency
    (chassis frame sizes HX and JX)

Not permitted

100 Hz
with 400 Î¼s/1.25 kHz

100 Hz
with 400 Î¼s/1.25 kHz

Maximum field weakening

 

 

 

With Servo Control combined with encoder and appropriate special motors, field weakening up to 16 times the field-weakening threshold speed is possible.

These values refer to 1FT7/1FK7 synchronous motors.
Note voltage limit (kE factor) for third-party motors.

  • For asynchronous (induction) motors

5 times

5 times

4 times

  • For synchronous motors

2 times

2 times

  • For reluctance motors (1FP1)

2 times



1) The high output frequency option is required to enable output frequencies above 550 Hz. For additional information see section Control Units, and on the Internet at https://support.industry.siemens.com/cs/document/104020669

Fundamental closed-loop control characteristics of SINAMICS S

  • Booksize format, pulse frequency 4 kHz, closed-loop torque control

 

Servo Control

Vector Control

Notes

Synchronous motor

1FK7 with R14DQ 1)

1FT7

Vector Control is not designed as an operating mode for 1FK7/1FT7 synchronous motors.

 

Controller cycle

125 Î¼s

125 Î¼s

 

 

Rise time (without delay)

0.7 ms

0.5 ms

 

At a speed operating range from 50 rpm for resolver.

Characteristic angular frequency -3 dB

650 Hz

900 Hz

 

In this case, the dynamic response is determined primarily by the encoder system.

Torque ripple

3 % of M0

0.6 % of M0

 

For a speed operating range of 20 rpm up to rated speed.
A ripple of < 1 % is possible with an absolute encoder ≤ 1 rpm.
Not possible with resolver.

Torque accuracy

± 1.5 % of M0

± 1.5 % of M0

 

Measured value averaged over 3 s.
With motor identification and friction compensation.
In the torque operating range up to ± M0.
Speed operating range 1:10 up to rated speed.
Attention: External influences such as motor temperature can cause an additional long-time inaccuracy (constancy) of about ±2.5 %.
Approx. ±1 % lower accuracy in field-weakening range.

Asynchronous (induction) motor

1PH8
without encoder

1PH8
with incremental encoder 1024 S/R

1PH8
without encoder

1PH8
with incremental encoder 1024 S/R

 

Controller cycle

125 Î¼s

125 Î¼s

250 Î¼s

250 Î¼s

 

Total rise time (without delay)

0.8 ms

2 ms

1.2 ms

With encoderless operation in speed operating range 1:10, with encoder 50 rpm and above up to rated speed.

Characteristic angular frequency -3 dB

600 Hz

250 Hz

400 Hz

With encoderless operation in speed operating range 1:10.
The dynamic response is improved when using an encoder (feedback signal).

Torque ripple

1.5 % of Mrated

2 % of Mrated

2 % of Mrated

With encoderless operation in speed operating range 1:20, with encoder 20 rpm and above up to rated speed.

Torque accuracy

± 3.5 % of Mrated

± 2 % of Mrated

± 1.5 % of Mrated

Measured value averaged over 3 s.
With motor identification and friction compensation, temperature effects compensated by KTY84 and mass model.
In torque operating range up to ± Mrated.
Approx. additional inaccuracy of ± 2.5 % in field-weakening range.
Servo: Speed operating range 1:10 referred to rated speed.
Vector: Speed operating range 1:50 referred to rated speed.



1) R14DQ: Resolver 14 bit (resolution 16384, internally 2-pole).

  • Booksize format, pulse frequency 4 kHz, closed-loop speed control

 

Servo Control

Vector Control

Notes

Synchronous motor

1FK7 with R14DQ 1)

1FT7

Vector Control is not designed as an operating mode for 1FK7/1FT7 synchronous motors.

 

Controller cycle

125 Î¼s

125 Î¼s

 

 

Total rise time (without delay)

3.5 ms

2.3 ms

 

With encoderless operation in speed operating range 1:10, with encoder 50 rpm and above up to rated speed.

Characteristic angular frequency -3 dB

140 Hz

250 Hz

 

In this case, the dynamic response is determined primarily by the encoder system.

Speed ripple

See note

See note

 

Determined primarily by the total mass moment of inertia, the torque ripple and especially the mechanical configuration.
It is therefore not possible to specify a generally applicable value.

Speed accuracy

≤ 0.001 % of nrated

≤ 0.001 % of nrated

 

Determined primarily by the resolution of the control deviation and encoder evaluation in the converter. This is implemented on a 32-bit basis for SINAMICS.

Asynchronous (induction) motor

1PH8
without encoder

1PH8
with incremental encoder 1024 S/R

1PH8
without encoder

1PH8
with incremental encoder 1024 S/R

 

Controller cycle

125 Î¼s

125 Î¼s

250 Î¼s

250 Î¼s

 

Total rise time (without delay)

12 ms

5 ms

20 ms

10 ms

With encoderless operation in speed operating range 1:10, with encoder 50 rpm and above up to rated speed.

Characteristic angular frequency -3 dB

40 Hz

120 Hz

50 Hz

80 Hz

With encoderless operation in speed operating range 1:10.
The dynamic response is enhanced by an encoder feedback.
Servo with encoder is slightly more favorable than Vector with encoder, as the speed controller cycle with Servo is quicker.

Speed ripple

See note

See note

See note

See note

Determined primarily by the total mass moment of inertia, the torque ripple and especially the mechanical configuration.
It is therefore not possible to specify a generally applicable value.

Speed accuracy

0.1 Ã— fslip

≤ 0.001 % of nrated

0.05 Ã— fslip

≤ 0.001 % of nrated

Without encoder: Determined primarily by the accuracy of the calculation model for the torque-producing current and rated slip of the asynchronous (induction) motor (see table "Typical slip values").
With speed operating range 1:50 (Vector) or 1:10 (Servo) and with activated temperature evaluation.



1) R14DQ: Resolver 14 bit (resolution 16384, internally 2-pole).

  • Blocksize, booksize compact, booksize and chassis, pulse frequency 4 kHz, position control

 

Servo Control

Vector Control

Notes

Synchronous motor

1FT7

1FK7

Vector Control is not designed as an operating mode for 1FT7/1FK7 synchronous motors.

 

Position controller cycle

1 ms

1 ms

 

 

Resolution

4.19×106
incr./rev.

16384
incr./rev.

 

Correspondingly better with multi-pole resolver.

Achievable positioning accuracy in relation to the motor shaft

105 â€¦ 106
incr./rev.

4096
incr./rev.

 

In practice, the resolution must be higher than the required positioning accuracy by a factor of 4 to 10. These values are approximate nominal values only.

  • In relation to the motor shaft, approx.

0.00072 °

0.1 °

 

 

Asynchronous (induction) motor

1PH8
with AM22DQ 1)

1PH8
with incremental encoder 1024 S/R

1PH8
with AM22DQ 1)

1PH8
with incremental encoder 1024 S/R

 

Position controller cycle

1 ms

1 ms

2 ms

2 ms

 

Resolution

4.19×106
incr./rev.

4096
incr./rev.

4.19×106
incr./rev.

4096
incr./rev.

 

Attainable positioning accuracy

105 â€¦ 106
incr./rev.

1024
incr./rev.

105 â€¦ 106
incr./rev.

512
incr./rev.

In practice, the resolution must be higher than the required positioning accuracy by a factor of 4 to 10. These values are approximate nominal values only.
Vector is less accurate than servo by a factor of approximately 2.

  • In relation to the motor shaft, approx.

0.00072 °

0.35 °

0.00072 °

0.7 °

 



1) AM22DQ: Absolute encoder 22 bit singleturn (resolution 4194304, encoder-internal 2048 S/R) + 12 bit multiturn (traversing range 4096 revolutions).

  • Chassis format, pulse frequency 2 kHz, closed-loop torque control

 

Servo Control

Vector Control

Notes

Synchronous motor

1FT7
without encoder

1FT7 with AM22DQ 1)

Vector Control is not designed as an operating mode for 1FT7 synchronous motors.

 

Controller cycle

250 Î¼s

250 Î¼s

 

 

Total rise time (without delay)

1.2 ms

 

 

Characteristic angular frequency -3 dB

400 Hz

 

In this case, the dynamic response is determined primarily by the encoder system.

Torque ripple

1.3 % of M0

 

A ripple of < 1 % is possible with an absolute encoder ≤ 1 rpm.
Not possible with resolver.

Torque accuracy

± 1.5 % of M0

 

Measured value averaged over 3 s.
With motor identification and friction compensation. In torque operating range up to ± M0.
Speed operating range 1:10 up to rated speed.
Attention: External influences such as motor temperature can cause an additional long-time inaccuracy (constancy) of about ±2.5 %.
Approx. ±1 % lower accuracy in field-weakening range.

Asynchronous (induction) motor

1PH8
without encoder

1PH8
with incremental encoder 1024 S/R

1PH8
without encoder

1PH8
with incremental encoder 1024 S/R

 

Controller cycle

250 Î¼s

250 Î¼s

250 Î¼s

250 Î¼s

 

Total rise time (without delay)

1.6 ms

2.5 ms

1.6 ms

With encoderless operation in speed operating range 1:10, with encoder 50 rpm and above up to rated speed.

Characteristic angular frequency -3 dB

350 Hz

200 Hz

300 Hz

With encoderless operation in speed operating range 1:10.
The dynamic response is improved when using an encoder (feedback signal).

Torque ripple

2 % of Mrated

2.5 % of Mrated

2 % of Mrated

With encoderless operation in speed operating range 1:20, with encoder 20 rpm and above up to rated speed.

Torque accuracy

± 3.5 % of Mrated

± 2 % of Mrated

± 1.5 % of Mrated

Measured value averaged over 3 s.
With motor identification and friction compensation, temperature effects compensated by KTY84 and mass model.
In torque operating range up to ± Mrated. Approx. additional inaccuracy of ± 2.5 % in field-weakening range.
Servo: Speed operating range 1:10 referred to rated speed.
Vector: Speed operating range 1:50 referred to rated speed.



1) AM22DQ: Absolute encoder 22 bit singleturn (resolution 4194304, encoder-internal 2048 S/R) + 12 bit multiturn (traversing range 4096 revolutions).

  • Chassis format, pulse frequency 2 kHz, closed-loop speed control

 

Servo Control

Vector Control

Notes

Synchronous motor

1FT7
without encoder

1FT7 with AM22DQ 1)

Vector Control is not designed as an operating mode for 1FT7 synchronous motors.

 

Controller cycle

250 Î¼s

250 Î¼s

 

 

Total rise time (without delay)

5 ms

 

With encoderless operation in speed operating range 1:10, with encoder 50 rpm and above up to rated speed.

Characteristic angular frequency -3 dB

100 Hz

 

In this case, the dynamic response is determined primarily by the encoder system.

Speed ripple

See note

 

Determined primarily by the total mass moment of inertia, the torque ripple and especially the mechanical configuration.
It is therefore not possible to specify a generally applicable value.

Speed accuracy

≤ 0.001 % of nrated

 

Determined primarily by the resolution of the control deviation and encoder evaluation in the converter.
This is implemented on a 32-bit basis for SINAMICS.

Asynchronous (induction) motor

1PH8
without encoder

1PH8
with incremental encoder 1024 S/R

1PH8
without encoder

1PH8
with incremental encoder 1024 S/R

 

Controller cycle

250 Î¼s

250 Î¼s

250 Î¼s

250 Î¼s

 

Total rise time (without delay)

21 ms

8 ms

20 ms

12 ms

With encoderless operation in speed operating range 1:10, with encoder 50 rpm and above up to rated speed.

Characteristic angular frequency -3 dB

25 Hz

80 Hz

35 Hz

60 Hz

For encoderless operation in speed operating range 1:10. The dynamic response is improved when using an encoder (feedback signal). Servo with encoder is slightly more favorable than Vector with encoder, as the speed controller cycle with Servo is quicker.

Speed ripple

See note

See note

See note

See note

Determined primarily by the total mass moment of inertia, the torque ripple and especially the mechanical configuration.
It is therefore not possible to specify a generally applicable value.

Speed accuracy

0.1 Ã— fslip

≤ 0.001 % of nrated

0.05 Ã— fslip

≤ 0.001 % of nrated

Without encoder: Determined primarily by the accuracy of the calculation model for the torque-generating current and rated slip of the asynchronous (induction) motor (see table "Typical slip values").
For a speed operating range 1: 50 (Vector) or 1:10 (Servo) and with active temperature evaluation.



1) AM22DQ: Absolute encoder 22 bit singleturn (resolution 4194304, encoder-internal 2048 S/R) + 12 bit multiturn (traversing range 4096 revolutions).

Typical slip values for standard asynchronous motors (induction motors)

Motor output

Slip values

Notes

< 1 kW

6 % of nrated
e.g. motor with 1500 rpm: 90 rpm

The slip values of 1PH asynchronous motors are very similar to those of standard motors

< 10 kW

3 % of nrated
e.g. motor with 1500 rpm: 45 rpm

< 30 kW

2 % of nrated
e.g. motor with 1500 rpm: 30 rpm

< 100 kW

1 % of nrated
e.g. motor with 1500 rpm: 15 rpm

> 500 kW

0.5 % of nrated
e.g. motor with 1500 rpm: 7.5 rpm



CU320‑2: Axis licensing according to performance expansion (firmware version 4.3 and higher)

The CU320-2 is licensed purely according to axis number. The expanded performance is essentially required with four or more servo axes, four or more vector axes and seven or more V/f axes, irrespective of computing capacity.

 

Dynamic response (current controller clock cycle)

Number of axes without performance expansion

Number of axes with performance expansion

Note

Servo Control

62.5 Î¼s

3

3

3 servo axes are possible with a cycle time of 62.5 Î¼s.
The performance expansion is therefore ineffective.

The performance expansion is required with 4 or more servo axes irrespective of computing capacity.

125 Î¼s

3

6

250 Î¼s

3

6

Vector Control

250 Î¼s

3

3

For 250 Î¼s, 3 vector axes are possible.
This means that the performance expansion is not active.

The performance expansion is required with 4 or more vector axes irrespective of computing capacity.

500 Î¼s

3

6

V/f control

250 Î¼s

6

6

For 250 Î¼s, 6 V/f axes are possible.
This means that the performance expansion is not active.

The performance expansion is required with 7 or more V/f axes irrespective of computing capacity.

500 Î¼s

6

12

Mixed operation

Servo Control plus V/f Control

125 Î¼s/500 Î¼s

3+0; 2+2; 1+4; 0+6

6+0; 5+2; 4+4; 3+6
2+8; 1+10; 0+12

Two V/f axes can be computed instead of a servo or vector axis.

Vector Control plus V/f Control

500 Î¼s/500 Î¼s

3+0; 2+2; 1+4; 0+6

6+0; 5+2; 4+4; 3+6
2+8; 1+10; 0+12



CU320‑2: Possible quantity structures, maximum configurations

In addition to the number of axes, for example, the following functions and hardware components also have an influence on the possible quantity structure (maximum configuration) of the CU320-2:

  • Extended Safety
  • EPos
  • DCC
  • CAN bus
  • High-speed Terminal Modules (task = 250 Î¼s)

The SIZER for Siemens Drives engineering tool can be used to very quickly perform reliability checks on more complex quantity structures.

Influencing variables on minimum required pulse frequency of power unit

Basic requirements such as maximum speed or necessary dynamic response of the control have a direct effect in determining the minimum pulse frequency of the power unit. If the minimum pulse frequency required exceeds the rated pulse frequency, derating must be implemented accordingly (see section SINAMICS S120 drive system).

The following table provides a general overview.

Influencing variables

Minimum pulse frequency

Notes

Servo Control, Vector Control

(required max. output frequency/speed)

100 Hz correspond to:

3000 rpm for Zp = 2
1500 rpm for Zp = 4
428 rpm for Zp = 14
352 rpm for Zp = 17

1.25 kHz

Zp is the number of pole pairs of the motor.

This equals 2 on 1PH asynchronous motors (induction motors).
1FT7/1FK7 synchronous motors have between 3 and 5 pairs of poles.
For torque motors, the numbers of pole pairs are typically 14 and 17.

When edge modulation is used (only possible for asynchronous motors), the output frequency is increased by a factor of 2.

160 Hz correspond to:

4800 rpm for Zp = 2
2400 rpm for Zp = 4
685 rpm for Zp = 14
565 rpm for Zp = 17

2 kHz

200 Hz correspond to:

6000 rpm for Zp = 2
3000 rpm for Zp = 4
856 rpm for Zp = 14
704 rpm for Zp = 17

2.5 kHz

300 Hz correspond to:

9000 rpm for Zp = 2
4500 rpm for Zp = 4
1284 rpm for Zp = 14
1056 rpm for Zp = 17

4 kHz

400 Hz correspond to:

12000 rpm for Zp = 2
6000 rpm for Zp = 4

4 kHz

Notice: For Servo Control with 1FT7/1FK7 motors only.
Note field weakening requirements and suitable encoder system for higher speeds.

V/f control

(required max. output frequency/speed)

100 Hz correspond to:

6000 rpm for Zp = 1
3000 rpm for Zp = 2

1.25 kHz

V/f Control is only intended for asynchronous (induction) motors and SIEMOSYN motors.

Zp is the number of pole pairs of the motor.

This is mainly between 1 and 4 on 1LA/1LG standard asynchronous motors (induction motors).
SIEMOSYN motors have 1 or 2 pole pairs or, with larger shaft heights, 3 pairs.

160 Hz correspond to:

9600 rpm for Zp = 1
4800 rpm for Zp = 2

2 kHz

200 Hz correspond to:

12000 rpm for Zp = 1
6000 rpm for Zp = 2

2.5 kHz

300 Hz correspond to:

18000 rpm for Zp = 1
9000 rpm for Zp = 2

4 kHz

400 Hz correspond to:

24000 rpm for Zp = 1
12000 rpm for Zp = 2

4 kHz

Dynamic response requirement (current controller clock cycle)

125 Î¼s
250 Î¼s
400 Î¼s
500 Î¼s

4 kHz
2 kHz
2.5 kHz
1 kHz

Servo Control requires a minimum pulse frequency of 2 kHz.

Sine-wave filters

4 kHz

Notice: If sine-wave filters are operated at low pulse frequencies, resonance problems can occur and cause the filters to severely overheat.

Output reactor to motor

Max. frequency: 150 Hz correspond to 4500 rpm for Zp = 2

 

The output reactor can be operated at minimum 2 kHz only.



Core topologies: Component cabling with DRIVE-CLiQ

The components communicate with one another via the standard DRIVE-CLiQ interface.

This couples a Control Unit with the power components, encoders and additional system components, for example Terminal Modules. Setpoints and actual values, control commands, status messages and rating plate data of the components is transferred via DRIVE-CLiQ.

Basic rules for wiring with DRIVE-CLiQ

The following rules apply when wiring components with DRIVE-CLiQ:

  • A maximum of 14 nodes can be connected to a DRIVE-CLiQ socket on the CU320-2 Control Unit
  • Up to 8 nodes can be connected in a line. A line is always seen from the perspective of the Control Unit
  • A maximum of 6 Motor Modules can be operated in a line
  • Ring wiring is not permitted
  • Components must not be double-wired
  • The motor encoder should be connected to the associated Motor Module
  • Up to 9 encoders can be operated on one Control Unit
  • A maximum of 8 Terminal Modules can be connected
  • It is not permissible for the TM54F Terminal Module to be operated on the same DRIVE-CLiQ line as Motor Modules
  • The Terminal Modules TM15, TM17 High Feature and TM41 have faster sampling cycles than the TM31 and TM54F. For this reason, the two groups of Terminal Modules must be connected in separate DRIVE-CLiQ lines.
  • A DRIVE-CLiQ Hub DMC20/DME20 counts as two nodes

DRIVE-CLiQ configuration examples

There is a basic clock cycle within a DRIVE-CLiQ connection. For this reason, only combinations of modules with the same sampling cycle or integer-divisible sampling times can be operated on a DRIVE-CLiQ connection. To simplify the configuring process, it is advisable to supply the Line Module and Motor Modules via separate DRIVE-CLiQ connections.

The power components are supplied with the required DRIVE-CLiQ connecting cable for connection to the adjacent DRIVE-CLiQ node in the axis grouping (line topology). Pre-assembled DRIVE-CLiQ cables in various lengths up to 100 m (328 ft) are available for connecting motor encoders, direct measuring encoders, Terminal Modules, etc.

The DRIVE-CLiQ cable connections inside the control cabinet must not exceed 70 m (230 ft) in length, e.g. connection between the CU320‑2 Control Unit and the first Motor Module or between Motor Modules. The maximum permissible length of DRIVE-CLiQ MOTION-CONNECT cables to external components is 100 m (328 ft).

Example of a line topology for standard solutions

Example of a tree topology for high-performance solutions, e.g. high-speed axes in direct motion control group, selective access to individual axes/axis groupings for maintenance activities, etc.

Preferred wiring of DRIVE-CLiQ connections illustrated using booksize format Active Line Module as example: 250 Î¼s current controller clock cycle Motor Modules: 4 Ã— vector control = current controller clock cycle 500 Î¼s

Wiring illustrated by example of chassis format with different current controller clock cycles

Example of wiring: Power Modules can also be operated on a CU320-2 when connected via a CUA31

















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Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Àðìàòóðà DENDOR

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30


Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Äàò÷èêè è èçìåðèòåëè

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30


Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Ðåãóëÿòîðû è ðåãèñòðàòîðû

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30


Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Ïíåâìàòè÷åñêîå îáîðóäîâàíèå

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30


Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Êðàíû è Êëàïàíû

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30


Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Èçìåðèòåëüíûå ïðèáîðû

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30


Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Ñèñòåìû áåñïðîâîäíîãî óïðàâëåíèÿ «óìíûé äîì»

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30


Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Áåñêîíòàêòíûå âûêëþ÷àòåëè Êîíå÷íûå âûêëþ÷àòåëè Îïòè÷åñêèå äàò÷èêè Ýíêîäåðû

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30


Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
SKW-FS - Óñòàíîâêà óìÿã÷åíèÿ

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30

Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30


Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
SKW-FK - Óñòàíîâêà îáåçæåëåçèâàíèÿ

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