Sinamics
Page
Function Manual
FH1, 07/2007
Applications Basic information about Drive system Appendix
Prescribed Usage
Safety Guidelines
Qualified Personnel
Trademarks
Usage phases and their tools/documents as an example
Usage phase Document/tool
Sinamics documentation
Search guides
Target group
Benefits
Foreword
Asian and Australian time zones
Technical Support
European and African time zones
America time zone
Internet address for Sinamics EC Declaration of Conformity
Notation for faults and alarms examples
Questions on the manual
Notation
ESD Notes
Safety instructions
Foreword
Page
Contents
Contents
18.3
18.2
158
159
219
289
282
288
11.5
451
11.4.2
460
11.4.1
11.4.3
535
553
Introduction
Features
Active Infeed
General
Infeed Active Infeed
Schematic structure
Active Infeed closed-loop control Booksize
Supply voltage p0210 380-400 401-415 416-440 460 480
Commissioning
Infeed 1.1 Active Infeed
Active Infeed closed-loop control Chassis
Kdvvlv
Function diagrams see Sinamics S List Manual
Integration
Overview of key parameters see Sinamics S List Manual
Line and DC link identification
Identification methods
Acknowledge error
Active Infeed open-loop control
Switching on the Active Line Module
Switching off the Active Line Module
370
Control and status messages
Binector input Display of internal
Internal status Parameter PROFIdrive telegram Word
Harmonics controller
Example setting the harmonics controller
Reactive current control
Index P3624 harmonics controller order P3625 scaling
Overview key parameters
Smart Infeed
Smart Infeed closed-loop control
Infeed Smart Infeed
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Function diagrams see Sinamics S List Manual
Overview of key parameters Sinamics S List Manual
Smart Infeed open-loop control
Switching on the Smart Line Module
Switching off the Smart Line Module
Binector input
Control word
Basic Infeed
Basic Infeed open-loop control
Infeed Basic Infeed
7HPSHUDWXUH
UDNLQJUHVLVWRU
Function diagrams see Sinamics S List Manual
Switching on the Basic Line Module
Switching off the Basic Line Module
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Control word 370
Line contactor control
Infeed Line contactor control
Internal status word
Example of commissioning line contactor control Assumption
Commissioning steps
Infeed 1.4 Line contactor control
Pre-charging and bypass contactor chassis
Procedure during power ON/OFF Power on
Power OFF
Infeed Pre-charging and bypass contactor chassis
Derating function for chassis units
Functional principle
Infeed 1.6 Derating function for chassis units
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Pulse parallel infeeds two-winding transformer
Pulse parallel infeeds three-winding transformer
0DLQV
Extended setpoint channel
Setpoint sources
Description
Properties of the extended setpoint channel
Extended setpoint channel 2.2 Description
6LJQDO
Jog
Extended setpoint channel 2.3 Jog
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Function chart jog 1 and jog
Jog properties
Jog sequence
32521
Parameterization with Starter
Display parameters
Fixed speed setpoints
Properties
Extended setpoint channel 2.4 Fixed speed setpoints
Motorized potentiometer
Properties for manual mode p1041 =
Properties for automatic mode p1041 =
Extended setpoint channel 2.5 Motorized potentiometer
Overview of key parameters see Sinamics S List Manual
6XSSOHPHQWDU\VHWSRLQW
Main/supplementary setpoint and setpoint modification
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Suppression bandwidths and setpoint limits
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Ramp-function generator
Suppression bandwidths
Extended setpoint channel Ramp-function generator
Properties of the simple ramp function generator
Properties of the extended ramp function generator
Extended setpoint channel 2.9 Ramp-function generator
Ramp function generator tracking
With ramp function generator tracking
Signal overview see Sinamics S List Manual
Without ramp function generator tracking
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12 Starter icon for ramp function generator
Speed controller
Limits
Speed setpoint filter
Servo control Speed setpoint filter
Servo control 3.3 Speed controller adaptation
Speed controller adaptation
Parameterization
\QDPLFUHVSRQVH
Example of speed-dependent adaptation
Servo control Speed controller adaptation
Speed-dependent Kpn/Tnn adaptation
Commissioning of torque control mode
Torque-controlled operation
Servo control 3.4 Torque-controlled operation
OFF responses
Servo control Torque-controlled operation
Torque setpoint limitation
Servo control 3.5 Torque setpoint limitation
Servo control Torque setpoint limitation
Variants of torque limitation
Fixed and variable torque limit settings
Selection Torque limitation mode
Servo control
Examples
Example Torque limits with or without offset
Activating the torque limits
0BRIIVHW
Current controller
Servo control 3.6 Current controller
Current controller adaptation
Closed-loop current control
Current and torque limitation
Flux controller for induction motor
Display parameters
Current setpoint filter
Servo control Current setpoint filter
IQBQ
Transfer function
Servo control 3.7 Current setpoint filter
IQB
Phase frequency curve
Band-stop with infinite notch depth
Starter filter parameters
Band-stop with defined notch depth
Band-stop with defined reduction
General low-pass with reduction
Transfer function general 2nd-order filter
Current setpoint filters
V/f control for diagnostics
Prerequisites for V/f control
Servo control 3.9 V/f control for diagnostics
Structure of V/f control
Commissioning V/f control
Characteristic
Servo control V/f control for diagnostics
Optimizing the current controller
Optimizing the current and speed controller
General information
Optimizing the speed controller
Parameter overview
Sensorless operation without an encoder
Example of speed setpoint step change
Servo control Sensorless operation without an encoder
Behavior once pulses have been canceled
Servo control 3.11 Sensorless operation without an encoder
2SHQORRS
2SHUZLWKHQFRGHU
Series reactor
Commissioning/optimization
Motor data identification
Servo control Motor data identification
Servo control 3.12 Motor data identification
Motor data
Type plate data
Induction motor Permanent-magnet synchronous motor
Induction motor
Motor data identification induction motor
Parameters to control the MotID
Rotating measurement
Determined data gamma Data that are accepted p1910 =
Determined data gamma Data that are accepted p1960 =
Motor data identification synchronous motor
Synchronous motor
Determined data Data that are accepted p1910 =
0RWRU0RGXOH Deoh
Determined data Data that are accepted p1960 =
Rotating measurement
Pole position identification
Standstill measurement
Servo control Pole position identification
Servo control 3.13 Pole position identification
Pole position determination with zero marks
Suitable zero marks are
Overview of key parameters
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PXVWEHXVHG
Vdc control
Angular commutation offset commissioning support p1990
Servo control 3.14 Vdc control
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Description of Vdcmin control p1240 = 2
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9GFBPD
Description of Vdcmin control without braking p1240 = 8
Description of Vdcmax control p1240 = 1
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Description of Vdcmax control without acceleration p1240 = 7
Dynamic Servo Control DSC
Servo control Dynamic Servo Control DSC
Activating
Deactivating
Servo control 3.15 Dynamic Servo Control DSC
Diagnostics
Speed setpoint filter
External encoder systems except motor encoder
Application examples
Signals
Travel to fixed stop
Servo control 3.16 Travel to fixed stop
Servo control Travel to fixed stop
Signal chart
Commissioning for PROFIdrive telegrams 2 to
Signal name
MESSAGEW.1
Vertical axes
Servo control Vertical axes
Page
Vector control
Sensorless vector control Slvc
Switchover conditions for Slvc
Vector control Sensorless vector control Slvc
ORVHGORRS
Vector control 4.1 Sensorless vector control Slvc
6WDUW
2SHQORRS
Vector control with encoder
Benefits of vector control with an encoder
Vector control Vector control with encoder
Motor model change
Speed controller
Vector control 4.3 Speed controller
Vector control Speed controller
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6SHHGDFWXDOYDOXH
Vector control 4.4 Speed controller adaptation
Vector control Speed controller adaptation
9HFWRU
SBQ
$GDSWLYHFRQWUROUDQJH
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Speed controller pre-control and reference model
Speed-dependent Kpn/Tnn adaptation VC only
Dynamic response reduction field weakening Slvc only
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6SHHG
Reference model
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Droop
For reference model
Vector control 4.6 Droop
Prerequisites
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Torque control
Vector control 4.7 Torque control
Vector control Torque control
11 Closed-loop speed/torque control
Torque setpoint
Torque limiting
Vector control Torque limiting
Vector control 4.9 Vdc control
Description
Properties
Description of Vdcmin control
73RZHU
Description of Vdcmax control
6ZLWFKRQOHYHO
Current controller adaptation
Vector control 4.10 Current setpoint filter
Motor data identification and rotating measurement
Motor identification p1910
Data determined using p1910
0RWRU0RGXOH DEOHDQG
Deoh 6HULHV
Carrying out motor identification
Rotating measurement p1960
Carrying out the rotating measurement p1960
Motor data identification at standstill
Efficiency optimization
Vector control 4.13 Efficiency optimization
Ltvhws
Instructions for commissioning induction motors ASM
Induction motors, rotating
Parameter Description Remark
Supplementary conditions
0RWRU
Permanent-magnet synchronous motors, rotating
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˭ ຘ
Description Remark
˭ ຘ N7 QRP
151
Automatic encoder adjustment
Encoder adjustment using a zero mark
Integration
Pole position identification
Flying restart
Vector control 4.16 Flying restart
155
Synchronization
Vector control Synchronization
Prerequisite
Simulation operation
Description
Vector control 4.18 Simulation operation
Vector control Redundance operation power units
Redundance operation power units
Features
Commissioning
Bypass
Prerequisites
Vector control 4.20 Bypass
Bypass with synchronization with overlap p1260 =
Commissioning the bypass function
1HWZRUN RQYHUWHUZLWK9ROWDJH
Example
Parameter Description
5HDFWRU
26 Signal diagram, bypass with synchronization with overlap
Bypass with synchronization, without overlap p1260 =
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Bypass without synchronization p1260 =
1HWZRUN Rqyhuwhu
3URWHFWLYHGHYLFH QWHUORFNHGDJDLQVW VLPXOWDQHRXVO\FORVLQJ
Synchronization
167
Page
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Introduction
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Prwru
FCC
Vector V/f control r0108.2 = Introduction
Meaning
RDG
Application / property
Voltage boost
Vector V/f control r0108.2 = 0 5.2 Voltage boost
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IOLQHDU
Permanent voltage boost p1310
Voltage boost at acceleration p1311
IQ
Vector V/f control r0108.2 =
Voltage boost
Dfwlyh VHW
Slip compensation
Vector V/f control r0108.2 = 0 5.3 Slip compensation
Vector V/f control r0108.2 = 0 5.4 Vdc control
9GFBFWUO7Q
Switching Vdcmin control on/off kinetic buffering
PLQ
177
Function diagrams see Sinamics S List Manual
Changing over units
Restrictions
Groups of units
Reference parameters/normalizations
Function in Starter
Basic functions Reference parameters/normalizations
Scaling for vector object
Using Starter offline
Size Scaling parameter Default at initial commissioning
Basic functions 6.2 Reference parameters/normalizations
Scaling for servo object
Scaling for object AInf
Scaling for object BInf
Example of a sub-topology
Modular machine concept
Overview of important parameters refer to the List Manual
Basic functions
Basic functions Modular machine concept
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Sinusoidal filter
Usage restrictions for sinusoidal filters
Basic functions Sinusoidal filter
Order no Name Setting
Dv/dt filter plus VPL
Basic functions Dv/dt filter plus VPL
Direction reversal without changing the setpoint
Automatic restart vector, servo, infeed
Basic functions Automatic restart vector, servo, infeed
Automatic restart mode
P1210 Mode Meaning
Starting attempts p1211 and waiting time p1212
Monitoring time line supply return p1213
191
External armature short-circuit braking
Internal voltage protection booksize
193
Internal armature short-circuit braking booksize/DC brake
Internal armature short-circuit synchronous motors
DC brake induction motors
Activation of DC brake by BI
DC braking as fault response
QB6WDUW
197
OFF3 torque limits
Basic functions OFF3 torque limits
Technology function friction characteristic
Commissioning via parameters
Simple brake control
Commissioning via Starter
Basic functions Simple brake control
Function chart simple brake control
Basic functions 6.11 Simple brake control
Simple brake control r0108.14 =
Relative system runtime
Runtime operating hours counter
Total system runtime
Actual motor operating hours
Parking an axis
Parking axis and parking sensor
Parking a sensor
Basic functions Parking axis and parking sensor
Example parking sensor
Example parking axis and parking sensor
Example parking axis
Basic functions 6.13 Parking axis and parking sensor
Function chart parking sensor
Overview key parameters
Terminology
Position tracking
General Information
Basic functions 6.14 Position tracking
Features Measuring gear characteristics
Measuring gear
Basic functions Position tracking
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Measuring gearbox configuration p0411
Virtual multiturn encoder p0412
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Tolerance window p0413
Terminal Module 41 TM41
Basic functions Terminal Module 41 TM41
General description
Basic functions 6.15 Terminal Module 41 TM41
14 Block diagram of the incremental encoder emulation
Hardware requirements
Commissioning steps
6592&21752
Incremental encoder emulation using a speed setpoint p4400 =
Updating the firmware
Basic functions 6.16 Updating the firmware
Upgrade the project
Upgrading firmware and the project in Starter
Basic functions Updating the firmware
Function modules Definition and commissioning
Commissioning via parameter only with BOP20
Technology controller
Function modules Technology controller
Fill level control
Commissioning with Starter
Examples
Function modules 7.2 Technology controller
Parameter Designation Example
7HFBFWU.S 7HFBFWU7Q
Motorized potentiometer
Closed-loop control
Function modules Extended monitoring functions
Extended monitoring functions
Description of load monitoring
7RUTXH1P@
Speed setpoint monitoring
Function modules 7.3 Extended monitoring functions
Extended brake control
Function modules Extended brake control
Operating brake for crane drives
Starting against applied brake
Emergency brake
Function modules 7.4 Extended brake control
Example, operating brake for a crane drive
Release/apply brake
Configuration, control/status words
Standstill zero-speed monitoring
Free modules
Signal name Binector input
Signal name Parameters
Control and status messages for extended brake control
Function modules 7.5 Braking Module
Braking Module
Braking Module function module
RQWURO8QLW
Acknowledgement of faults
Fast DC link discharge booksize
Cooling system
Cooling system function module
Function modules 7.6 Cooling system
234
Extended torque control kT estimator, Servo
Description of the kT estimator
Motor/drive converter identification
Position actual value conditioning
General features
Closed-loop position control
KT estimator
Function modules Closed-loop position control
Position actual value sensing with rotary encoders
239
Indexed actual value acquisition Properties
Load gear position tracking Features
Example of position area extension
Configuration of the load gear p2720
10 Position tracking p2721 =
Virtual multiturn encoder p2721
Tolerance window p2722
Integration Function diagrams see Sinamics S List Manual
Position controller
Monitoring functions
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Measuring probe evaluation and reference mark search
Integration
Basic positioner
Function modules 7.9 Basic positioner
Function modules Basic positioner
Mechanical system
DFNODVKS
P2604 Traversing direction Switch in compensation value
Positive None Negative Immediately
Limits
Maximum velocity
Software limit switches
Maximum acceleration/deceleration
Stop cam
Jerk limitation
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Function diagram overview see Sinamics S List Manual
9HORFLW\
Referencing
Absolute encoder adjustment
Set reference point
Reference point approach for incremental measurement systems
Search for reference, travel to reference cam
18 Example homing with reference cam
263
On-the-fly homing
Search for reference, Travel to reference point
265
Instructions for switching data sets
Traversing blocks
EDS5 EDS6 EDS7
Positioning Fixed Endstop Endlesspos Endlessneg Wait Goto
0101, Continueexternalalarm
Intermediate stop and reject traversing task
Fixed Stop
Waiting
Travel to fixed stop
Introduction
Fixed stop reached
Cancel
Fixed stop is not reached
Integration Function diagram overview see List Manual
Vertical axes
Direct setpoint input MDI
MDI mode with the use of PROFIdrive telegram
LHGYHORFLW\VHWSRLQW
Intermediate stop and canceling traversing block
7 Jog
Traversing command active r2684.15
Status signals
Tracking mode active r2683.0
Setpoint static r2683.2
Following error in tolerance r2684.8
Direct output 1 r2683.10 Direct output 2 r2683.11
Target position reached r2684.10
Acknowledgement, traversing block activated r2684.12
DCC axial winder
Reference point set r2684.11
Velocity limiting active r2683.1
Function blocks
Calculation of the moment of inertia for torque pre-control
Dn/dt
Parameters for the function diagrams for torque pre-control
P03410...n Motor moment of inertia / MotID Mmom inert
R1493 Moment of inertia, total
R1538 Upper effective torque limit / Mmax upper eff
Parameters of the function diagram for torque limitation
P14970...n CI Moment of inertia, scaling / Mmom inert scal
R1539 Lower effective torque limit / Mmax lower eff
287
Parallel connection of chassis power units vector
Application examples
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LQHUHDFWRU LQH0RGXOH 0RWRU0RGXOH
0RWRU0RGXOH
L4
Power unit protection, general
Protection against Precautions Responses
OFF2
Thermal monitoring and overload responses
Block protection
Monitoring and protective functions 8.3 Block protection
Stall protection only for vector control
Block protection
Thermal motor protection
0RWRUVWDOOHG
Function diagrams for thermal motor protection
Temperature measurement via KTY
Temperature measurement via PTC
Sensor monitoring for cable breakage / short-circuit
Parameters for thermal motor protection
Page
Explanations, standards, and terminology
Safety Integrated
General information
Standards and Directives
Safety Integrated basic functions General information
Two-channel monitoring structure
Supported functions
Prerequisites for the extended functions
Parameter, Checksum, Version, Password
Properties of Safety Integrated parameters
Safety Integrated versions
Checking the checksum
From FW2.5 the following applies
Password
Parameter overview for password see Sinamics S List Manual
Forced dormant error detection
Safety instructions
Safety Integrated basic functions 9.2 Safety instructions
Please note the following during switch-on
Functional features of Safe Torque Off
Safety Integrated basic functions 9.3 Safe Torque Off STO
Safe Torque Off STO
Enabling the Safe Torque Off STO function
Selecting/deselecting Safe Torque Off
Response time with the Safe Torque Off function
Status for Safe Torque Off
Parameter overview see List Manual
Examples, Booksize
Functional features of Safe Stop
Safe Stop 1 SS1, time controlled
Release of the SS1 function
Safe Brake Control SBC
Status for Safe Stop
Functional features of Safe Brake Control SBC
Enabling the Safe Brake Control SBC function
Two-channel brake control
Response time with the Safe Brake Control function
5HOD\
Overview of the safety function terminals for Sinamics S120
Switch-off signal path
Terminals for STO, SS1 time-controlled, SBC
Grouping drives not for CU310
Example Terminal groups
General information about commissioning safety functions
Commissioning the STO, SBC and SS1 functions
Commissioning notes
Power on
Prerequisites for commissioning the safety functions
Standard commissioning of the safety functions
Replacing Motor Modules with the current FW release
Procedure for commissioning STO, SBC and SS1
Set terminals for Safe torque off STO
Safety Integrated basic functions
Parameter Description/comments Enable Safe Stop 1 function
Set F-DI changeover tolerance time
Stop a
Adjust specified checksums
Set the new Safety password
Paths
Safety faults
Stop response
Acknowledging the safety faults
Stop response Action Effect Triggered
Stop F
General information about acceptance
Description of faults and alarms
Acceptance test and certificate
Acceptance test
Functional test
Documentation
Scope of a complete acceptance test Documentation
Completion of certificate
Drive number FW version SI version
Drive number SI function
Acceptance test for Safe Torque Off STO
Safe Torque Off STO function
Description Status
Acceptance test for Safe Stop 1, time controlled SS1
Safe Stop 1 function SS1, time-controlled
Acceptance test for Safe Brake Control SBC
Safe Brake Control function SBC
Acceptance test and certificate
332
SI parameters
Data backup
Completion of certificate
Checksums
Safety Integrated basic functions 9.9 Application examples
Application examples
Machine manufacturer
Description of functions
LQH0RGXOH
Safety Integrated basic functions Application examples
Behavior for Emergency Stop
Behavior when the protective door is opened
Switching on the drives
Overview of parameters and function diagrams
Description of the parameters
No. of Motor Name Changeable to Module MM
339
Page
General information about PROFIdrive for Sinamics
Features Controller, Supervisor Drive Unit
Communications according to PROFIdrive
Controller, Supervisor, and Drive Unit
Application classes
Interface IF1 and IF2
Application class 1 Standard drive
Application class
Application class 2 Standard drive with technology function
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Application class 3 positioning drive
Application class 4 central motion control
Dynamic Servo Control DSC
Cyclic communication
Telegrams and process data General information
Telegram Description Class
What telegrams are available?
Telegram interconnections
Receive process data
Dword
Telegram structure
Structure of the telegrams
Drive object Telegrams p0922
Drive object
Interface Mode
Procedure
Value
Example emergency stop with telegram failure
Settings
Monitoring telegram failure Description
Assumption
Name Signal Data type
Description of control words and setpoints
Overview of control words and setpoints
CTW1 control word
Bit Meaning Comments
STW1 control word 1, positioning mode, p0108.4 =
357
CTW2 control word
ECTW1 control word for Infeed
359
Satzanw positioning mode, p0108.4 =1
PosSTW positioning mode, p0108.4 =1
GnSTW encoder n control word
Nsolla speed setpoint a 16-bit
Nsollb speed setpoint B 32-bit
Xerr position deviation
MDIPos pos MDI position
MDIMode pos MDI mode
KPC position controller gain factor
MDIVel pos MDI velocity
Over pos velocity override
Torquered torque reduction
Overview of status words and actual values
Abbreviation Name Signal
Description of status words and actual values
Comment
STW1 status word
366
STW1 status word 1, positioning mode, p0108.4 =
STW2 status word
Nacta Speed setpoint a 16 bit
Nactb Speed setpoint B 32 bit
Meldw message word
Application
371
MTnZSF/MTnZSS
ESTW1 status word for Infeed
PosZSW
AktSatz
Example of encoder interface
XistP
Control and status words for encoder Description
Encoder n control word GnCTW, n = 1, 2
Signal status, description
Bit
Signal status, description
Example 1 Find reference mark
Example 2 Flying measurement
Encoder 2 control word G2CTW
Encoder 3 control word G3CTW
Encoder n status word GnSTW, n = 1, 2
Name Signal status, description
Encoder 1 actual position value 2 G1XACT2
Bit Name Signal status, description
Encoder 1 actual position value 1 G1XACT1
Communication Profibus DP/PROFINET IO
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Encoder 2 actual position value 1 G2XACT1
Error code in GnXIST2
Encoder 2 status word G2STW
Encoder 2 actual position value 2 G2XACT2
Visualization parameters drive
Encoder 3 actual position value 1 G3XACT1
Encoder 3 actual position value 2 G3XACT2
Central control and status words Description
Custw control word for Control Unit, CU
Receive signals
Transmit signals
Adigital digital outputs
Cuzsw status word for Control Unit, CU
Edigital digital inputs
Sync
Features of the central probe
MTnZSF and MTnZSS
Example central probe
Motion Control with PROFIdrive Description
Overview of closed-loop control
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Structure of the data cycle
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Acyclic communication
General information about acyclic communication Description
DSSOLFD
Characteristics of the parameter channel
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Parameter request Offset
Parameter response Offset
Field Data type Values Comment
395
Error values in DPV1 parameter responses
Error Meaning Comment Additional Value Info
397
398
Example 1 read parameters Prerequisites
Basic procedure
Determining the drive object numbers
Task description
Activity
Information about the parameter request
Information about the parameter response
Version
QBVHWB
Parameter address .. th parameter address
Parameter value .. th parameter value
General information about Profibus
Features Master Slave
Communication via Profibus DP
General information about Profibus for Sinamics
Bus access method
Sequence of drive objects in the telegram
Example telegram structure for cyclic data transmission Task
Example
Configuration settings e.g. HW Config for Simatic S7
Component and telegram structure
DP slave properties overview
DP slave properties details
25 Interfaces and diagnostic LED
Commissioning Profibus
Setting the Profibus address
Device identification
Device master file
Commissioning for VIK-NAMUR
Bus terminating resistor and shielding
Commissioning steps example with Simatic S7
Diagnosis options
Field Value
Simatic HMI addressing
Pro Tool and WinCC flexible
DBB, DBW, DBD
27 Monitoring telegram failure
Example emergency stop with telegram failure Assumption
Settings
Motion Control with Profibus
Sequence
Sequence of data transfer to closed-loop control system
Designations and descriptions for Motion Control
Name Value1 Limit value Description
418
Setting criteria for times
Minimum times for reserves
Data Time required µs
User data integrity
Slave-to-slave communications
General information Description
Publisher
Prerequisites and limitations
Subscriber
Links and taps
Applications
Setpoint assignment in the subscriber Setpoints
Example, setpoint assignment
Activation in the Publisher
Configuring telegram ChkCfg
Activating/parameterizing slave-to-slave communications
Activation in the Subscriber
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Settings in HW Config
Commissioning of the Profibus slave-to-slave communication
427
35 Insert new slot
429
38 Telegram assignment for slave-to-slave communication
Commissioning in Starter
41 Display of the telegram extension
433
GSD GeräteStammDaten file GSD File
435
None
OFF1 None OFF2 OFF3
Immediately
Communications via Profinet IO
General information about Profinet IO
General information about Profinet IO for Sinamics
Definition Real Time RT and determinism
Definition Isochronous real time communication IRT
IP address assignment
Addresses Definition MAC address
IP address
Device name
Replacing Control Unit CU320 IO Device
Default router
Data transfer Features
Definition Sub-network mask
Hardware setup
Sequence of drive objects in the data transfer
New device ID for Profinet from FW2.5 SP1
Telegrams
References
Clock generation
DCP flashing
Connecting the supervisor
Routing with CBE20
IRTflex
RT classes
RT classes for Profinet IO Description
IRTtop
Not isochronous
Set RT class
Profinet IO with RT
Data exchange
Refresh time
Profinet IO with IRT Overview
Sync domain
Profinet IO with IRTtop
Send clock/refresh time
Time-scheduled data transmission
Motion Control with Profinet
Motion Control/Isochronous drive link with Profinet
Tdcmin ≤ TDC ≤
Designations and descriptions for Motion Control
Tdcbase =
Tdcmax
TDC TCAValid and TDC ≧ TIOOutput
Parallel operation of communication interfaces for CU320
Assignment of communication interfaces to cyclic interfaces
Feature
Properties of the cyclic interfaces IF1 and IF2
Plugged hardware interface
P8839
Parameters
Additional parameters for IF2
PZD Interface hardware assignment
Alarm
A8550 PZD interface hardware assignment incorrect
Example motor switchover for four motors
Motor changeover
Applications 11.3 Motor changeover
Parameter Settings Remark
Applications Motor changeover
Preconditions
Example of a star/delta switchover
Procedure for switching over the motor data set
Applications
Procedure for star/delta switchover
Parameter Settings Comments
Integration
Application examples with the DMC20
Example, distributed topology
Applications Application examples with the DMC20
Example, hot plugging
Applications 11.4 Application examples with the DMC20
Instructions for offline commissioning with Starter
6LQJOH
Control Units without infeed control
Overview of key parameters see Sinamics S List Manual
Applications 11.5 Control Units without infeed control
DC link line-up with more than one Control Unit
Examples interconnecting Infeed ready
Smart Line Modules without DRIVE-CLiQ 5 kW and 10 kW
Applications Control Units without infeed control
Description
Drive Functions
Parameter
Parameter types
Parameter categories
2SWLRQ%RDUG
Basic information about the drive system 12.1 Parameter
7HUPLQDO0RGXOH
Qihhg
Access level
Resetting parameters
Access level
Saving parameters in a non-volatile memory
Data sets
CDS Command Data Set
CDS Command Data Set
Basic information about the drive system 12.2 Data sets
Example Switching between command data set 0
DDS Drive Data Set
DDS Drive Data Set
EDS Encoder Data Set
Supplementary conditions and recommendations
EDS Encoder Data Set
MDS Motor Data Set
MDS Motor Data Set
Copying a drive data set
Copying a command data set
Examples for a data set assignment
Motor Encoder P0186 P0187 P0188 P0189
Copying the motor data set
Drive objects
Basic information about the drive system 12.3 Drive objects
Configuring drive objects
Overview of drive objects
Bico technology interconnecting signals
Binectors, connectors
Binectors, BI Binector Input, BO Binector Output
Interconnecting signals using Bico technology
Connectors, CI Connector Input, CO Connector Output
Symbol Name Description
Interconnecting signals using Bico technology
Notation
Example 2 Connection of OFF3 to several drives
Example 1 Interconnection of digital signals
Sample interconnections
3DUDPHWHUQXPEHU ULYH Remhfw QGHQXPEHU
Bico interconnections to other drives
Connector-binector converter
Bico technology
Copying drives
Signal Parameter Unit Normalization 100 % =
Fixed values for interconnection using Bico technology
Signals for the analog outputs
Scaling
Changing scaling parameters p2000 to p2007
Inputs/outputs
Overview of inputs/outputs
Component Digital Analog Inputs
Digital inputs/outputs
Digital inputs
Digital outputs
Basic information about the drive system Inputs/outputs
Bidirectional digital inputs/outputs
Analog inputs
˩V
Analog outputs
Parameterizing using the BOP20 Basic Operator Panel
General information about the BOP20
Overview of displays and keys
Display
Information on the displays
Information on the keys
Key
Drive object, Control Unit
BOP20 functions
Parameters for BOP All drive objects
Name Description
Displays and using the BOP20
Other drive objects e.g. SERVO, VEKTOR, INFEED, TM41 etc
Operating display
Parameter display
HFLPDOQXPEHU
Value display
Example Changing a parameter
QWHJHUQXPEHU
Example Changing binector and connector input parameters
3DUDPHWHUGLVSOD\
Fault and alarm displays
Displaying faults
1HWIDXOW ULYHQR Iodvklqj Fkdqjh
Bit r0019 Name
Controlling the drive using the BOP20
Displaying alarms
On / OFF OFF1
Examples of replacing components
Action Reaction
Action Reaction Comments
Starter PG
501
Data backup on CompactFlash card
Exchanging a Sinamics Sensor Module Integrated
File names and storage location for the data
Replacing a device
Data transfer from CompactFlash card to Sensor Module
Order number Sinamics Sensor Module Integrated
Actual topology
DRIVE-CLiQ topology
Electronic rating plate
Target topology
Rules for wiring with DRIVE-CLiQ
Comparison of topologies at Power On
General rules
DRIVE-CLiQ rules
507
Component Connecting the motor encoder via DRIVE-CLiQ
Recommended rules
Component VSM connection
6LQJOH 0RWRU 0RGXOH
Rules for FW2.2
Rules for different firmware releases
Rules for FW2.1
Servo Vector
Rules for FW2.3
Servo
Rules for FW2.4
Rules for FW2.5 SP1
Sample wiring for vector drives
$FWLYH LQH 0RGXOH
$FWLYH Qwhuidfh 0RGXOH
Sample wiring of Vector drives connected in parallel
26 Drive line-up chassis with different pulse frequencies
516
Sample wiring Power Modules
Blocksize
Changing the offline topology in Starter
Chassis
Topology tree view Comment
Sample wiring for servo drives
Starter
Sample wiring for vector U/f drives
30 Sample servo topology
Number of controllable drives
31 Sample vector U/f topology
Servo control
Basic information about the drive system
System sampling times
Mixed operation
Setting the sampling times
P0112 P01150 P01151 P01152 P01153 P01154 P01155 P01156
525
Rules for setting the sampling time
Setting the sampling times using p0115
527
Default settings for the sampling times
Number P0112 P01150 P1800 Active Infeed and Smart Infeed
Basic Infeed
Examples when changing sampling times / pulse frequencies
Number P0112 P01150 P1800
Mixed
Starter is in the online mode
Licensing
Basic information about the drive system 12.13 Licensing
Properties of the license key
Generating a license key via the WEB License Manager
Entering the license key
Ascii code
Letter/number Decimal
Overview of key parameters see Sinamics S List Manual
Availability of hardware components
HW component Order number Version Revisions
SW function
Availability of SW functions
Appendix Availability of SW functions
HW component
SW function Servo Vector HW component
SW function Available Servo Vector HW component
DCC SINAMICS, DCC Simotion
Servo Vector HW component
SW function Available Servo Vector HW component Since FW
TM54F
540
List of abbreviations
Appendix List of abbreviations
German meaning English meaning
DAC
FAQ
CSM
DCB
Appendix
LSB
LED
LIN
LSS
PID
Pelv
PEM
PLL
SLM
SIL
SLI
SLP
VSM
VDE
VDI
WEA
Page
Overview of Sinamics Documentation 07/2007
Page
URP
Page
Index
Index
JOG
Edigital
SBC
SS1
VPM
Siemens AG