User guide
Table Of Contents
- 1 Safety Information
- 2 Product Information
- 3 Mechanical Installation
- 4 Electrical Installation
- 4.1 Electrical connections/ Power connections
- 4.2 Ground connections
- 4.3 AC supply requirements
- 4.4 Line reactors
- 4.5 Auxiliary AC supply and connections
- 4.6 Separating the Auxiliary Supply
- 4.7 Control 120 Vac supply
- 4.8 Control 24 Vdc supply
- 4.9 Cable and fuse size ratings
- 4.10 External suppressor resistor
- 4.11 Ground leakage
- 4.12 EMC (Electromagnetic compatibility)
- 4.13 Serial communications connections
- 4.14 Shield connections
- 4.15 Control connections
- 4.16 General
- 4.17 Connecting an encoder
- 5 Getting Started
- 5.1 Understanding the display
- 5.2 Keypad operation
- 5.3 Menu 0 (sub block)
- 5.4 Pre-defined sub blocks
- 5.5 Menu 0 (linear)
- 5.6 Menu structure
- 5.7 Advanced menus
- 5.8 Saving parameters
- 5.9 Restoring parameter defaults
- 5.10 Displaying parameters with non- default values only
- 5.11 Displaying destination parameters only
- 5.12 Parameter access level and security
- 5.13 Serial communications
- 6 Basic parameters
- 7 Running the Motor
- 8 Optimization
- 9 SMARTCARD Operation
- 9.1 Introduction
- 9.2 Easy saving and reading
- 9.3 Transferring data
- 9.3.1 Writing to the SMARTCARD
- 9.3.2 Reading from the SMARTCARD
- 9.3.3 Auto saving parameter changes
- 9.3.4 Booting up from the SMARTCARD on every power up (Pr 11.42 (SE09, 0.30) = boot (4))
- 9.3.5 Booting up from the SMARTCARD on every power up (Pr xx.00 = 2001)
- 9.3.6 Comparing drive full parameter set with the SMARTCARD values
- 9.3.7 7yyy / 9999 - Erasing data from the SMARTCARD
- 9.3.8 9666 / 9555 - Set / clear SMARTCARD warning suppression flag
- 9.3.9 9888 / 9777 - Set / clear the SMARTCARD read only flag
- 9.4 Data block header information
- 9.5 SMARTCARD parameters
- 9.6 SMARTCARD trips
- 10 Onboard PLC
- 11 Advanced Parameters
- 11.1 Menu 1: Speed reference
- 11.2 Menu 2: Ramps
- 11.3 Menu 3: Speed feedback and speed control
- 11.4 Menu 4: Torque and current control
- 11.5 Menu 5: Motor and field control
- 11.6 Menu 6: Sequencer and clock
- 11.7 Menu 7: Analog I/O
- 11.8 Menu 8: Digital I/O
- 11.9 Menu 9: Programmable logic, motorized pot and binary sum
- 11.10 Menu 10: Status and trips
- 11.11 Menu 11: General drive set-up
- 11.12 Menu 12: Threshold detectors, variable selectors and brake control function
- 11.13 Menu 13: Position control
- 11.14 Menu 14: User PID controller
- 11.15 Menus 15, 16 and 17: Solutions Module slots
- 11.16 SM-I/O120V Solutions Module parameter settings
- 11.17 Menu 18: Application menu 1
- 11.18 Menu 19: Application menu 2
- 11.19 Menu 20: Application menu 3
- 11.20 Menu 21: Second motor parameters
- 11.21 Menu 22: Additional Menu 0 set-up
- 11.22 Menu 23: Header selections
- 11.23 Advanced features
- 12 Technical Data
- 12.1 Drive technical data
- 12.1.1 Power and current ratings
- 12.1.2 Power dissipation
- 12.1.3 AC Supply requirements
- 12.1.4 Supply types
- 12.1.5 SCR bridge AC Supply
- 12.1.6 Auxiliary AC supply
- 12.1.7 Line reactors
- 12.1.8 Temperature, humidity and cooling method
- 12.1.9 Storage
- 12.1.10 Altitude
- 12.1.11 IP Rating
- 12.1.12 Corrosive gasses
- 12.1.13 RoHS compliance
- 12.1.14 Vibration
- 12.1.15 Start up time
- 12.1.16 Output speed range
- 12.1.17 Accuracy
- 12.1.18 Acoustic noise
- 12.1.19 Overall dimensions
- 12.1.20 Weights
- 12.2 Cable and fuse size ratings
- 12.3 Optional external EMC filters
- 12.1 Drive technical data
- 13 Diagnostics
- 14 UL Information
- List of tables
- Index
Safety
Information
Product
Information
Mechanical
Installation
Electrical
Installation
Getting
Started
Basic
parameters
Running the
Motor
Optimization
SMARTCARD
Operation
Onboard
PLC
Advanced
Parameters
Technical
Data
Diagnostics
UL
Information
46 Quantum MP User Guide
www.emersonct.com Issue: A3
If a drive is on the end of the network chain then pins 1 and 8 should be
linked together. This will connect an internal 120Ω termination resistor
between RXTX and RX\TX\. (If the end unit is not a drive or the user
wishes to use their own termination resistor, a 120Ω termination resistor
should be connected between RXTX and RX\TX\ at the end unit.)
If the host is connected to a single drive then termination resistors
should not be used unless the baud rate is high.
CT Comms cable
The CT Comms cable can be used on a multi-drop network but should
only be used occasionally for diagnostic and set up purposes. The
network must also be made up entirely of Quantum MPs.
If the CT Comms cable is to be used, then pin 6 (TX enable) should be
connected on all drives and pin 4 (+24V) should be linked to at least 1
drive to supply power to the converter in the cable.
Only one CT Comms cable can be used on a network.
4.14 Shield connections
These instructions must be followed to ensure suppression of radio-
frequency emission and good noise immunity in the encoder circuit. It is
recommended that the instructions for the connection of the encoder
cable be followed closely and, to use the grounding bracket and
grounding clamp supplied with the drive, to terminate the shields at the
drive.
4.14.1 Motor cables
Use of a motor cable with an overall shield for the armature and field
circuits may be needed if there is a critical EMC emissions requirement.
Connect the shield of the motor cable to the ground terminal of the motor
frame using a link that is as short as possible and not exceeding 50mm
(2in) long. A full 360° termination of the shield to the terminal housing of
the motor is beneficial.
4.14.2 Encoder cable
To get the best results from shielding use cable with an overall shield
and separate shields on individual twisted pairs. Refer to section
4.17 Connecting an encoder on page 54.
4.14.3 Control cables
It is recommended that signal cables should be shielded. This is
essential for encoder cables, and strongly recommended for analog
signal cables. For digital signals it is not necessary to use shielded
cables within a panel, but this is recommended for external circuits,
especially for inputs where a momentary signal causes a change of state
(i.e. latching inputs).
4.14.4 Grounding hardware
The drive is supplied with a grounding bracket, to facilitate EMC
compliance. This provides a convenient method for direct grounding of
cable shields without the use of "pig-tails". Cable shields can be bared
and clamped to the grounding bracket using metal clips, clamps or cable
ties. Note that the shield must in all cases be continued through the
clamp to the intended drive terminal in accordance with the connection
details for the specific signal.
A faston tab is located on the grounding bracket for the purpose of
connecting the drive 0V to ground should the user wish to do so.
Figure 4-16 Grounding of signal cable shields using the
grounding bracket
4.15 Control connections
Refer to Figure 4-17 to understand the connection of the different power
connections.
4.15.1 General
Table 4-24 The control connections consist of:
Key:
Function Qty Control parameters available
Terminal
number
Differential analog input 1
Destination, offset, invert,
scaling
5,6
Single ended analog
input
2
Mode, offset, scaling, invert,
destination
7,8
Analog output 2 Source, mode, scaling, 9,10
Digital input 3 Destination, invert, logic select 27, 28, 29
Digital input / output 3
Input / output mode select,
destination / source, invert,
logic select
Relay 2 Source, invert
51, 52, 53
61, 62, 63
Drive enable 1 Logic select 31
+10V User output 1 4
+24V User output 1 22
0V common 6
1, 3, 11, 21,
23, 30
+24V External input 1 2
120V Line 4
C1, C5, C11,
C13
120V Neutral 1 C15
120V Input 6 Destination, invert
C4, C6, C8,
C10, C12,
C14
120V Output 1 Source, invert C16
Destination
parameter:
Indicates the parameter which is being controlled by the
terminal / function