Emerson | Epsilon Eb Digital Servo Drive | Installation manual | Emerson Epsilon Eb Digital Servo Drive Installation Manual

Epsilon Eb Digital Servo Drive
Installation Manual
P/N: 400501-05
Revision: A2
Date: October 1, 2001
© Control Techniques Drives, Inc. 2000, 2001
Epsilon Eb
Digital Servo Drive
Installation Manual
Information furnished by Control Techniques Drives Inc. (Control Techniques) is believed to be
accurate and reliable. However, no responsibility is assumed by Control Techniques for its use.
Control Techniques reserves the right to change the design or operation of the equipment described
herein and any associated motion products without notice. Control Techniques also assumes no
responsibility for any errors that may appear in this document. Information in this document is subject
to change without notice.
P/N: 400501-05
Revision: A2
Date: October 1, 2001
© Control Techniques Drives, Inc. 2000, 2001
© Control Techniques Drives, Inc. 2000, 2001
Part Number: 400501-05
Revision: A2
Date: October 1, 2001
Printed in United States of America
Information in this document is subject to change without notice. No part of this document may be
reproduced or transmitted in any form or by any means, electronic or mechanical, for any purpose,
without the express written permission of Control Techniques.
The following are trademarks of Control Techniques and may not be reproduced in any fashion without
written approval of Control Techniques: EMERSON Motion Control, EMERSON Motion Control
Power Tools, AXIMA, “Motion Made Easy.”
Control Techniques is a divison of EMERSON Co.
Control Techniques, Inc. is not affliated with Microsoft Corporation, over of hte Microsoft, Windows,
and Windows NT trademarks.
IBM is a registered trademark of International Business Machines Corportation.
Modbus is a registered trademark of Gould, Inc.
Data Highway Plus is a trademark of Allen-Bradley
Schaffner is a trademark of Schaffner.
DeviceNet is a trademark of Open DeviceNet Vendor Association.
This document has been prepared to conform to the current released version of theproduct. Because of our
extensive development efforts and our desire to further improve and enhance the product, inconsistencies may
exist between the product and documentation in some instances. Call your customer support representative if you
encounter an inconsistency.
ii
Customer Service
Control Techniques
12005 Technology Drive
Eden Prairie, Minnesota 55344-3620
U.S.A.
Telephone: (952) 995-8000 or (800) 397-3786
It is Control Techniques’ goal to ensure your greatest possible satisfaction with the operation
of our products. We are dedicated to providing fast, friendly, and accurate assistance. That is
why we offer you so many ways to get the support you need. Whether it’s by phone, fax or
modem, you can access Control Techniques support information 24 hours a day, seven days
a week. Our wide range of services include:
FAX
(952) 995-8011
You can FAX questions and comments to Control Techniques. Just send a FAX to the number
listed above.
Website and Email
www.emersonct.com
Website: www.emersonct.com
Email: info@emersonct.com
If you have Internet capabilities, you also have access to technical support using our website.
The website includes technical notes, frequently asked questions, release notes and other
technical documentation. This direct technical support connection lets you request assistance
and exchange software files electronically.
Technical Support
(952) 995-8033 or (800) 397-3786
Email: service@emersonct.com
Control Techniques’ “Motion Made Easy” products are backed by a team of professionals
who will service your installation wherever it may be. Our technical service center in Eden
Prairie, Minnesota is ready to help you solve those occasional problems over the telephone.
Our technical service center is available 24 hours a day for emergency service to help speed
any problem solving. Also, all hardware replacement parts, should they ever be needed, are
available through our service organization.
When you call, please be at your computer, have your documentation in hand, and be
prepared to provide the following information:
•
Product version number, found by choosing About from the Help menu.
•
The type of controller or product you are using.
iii
•
Exact wording of any messages that appear on your screen.
•
What you were doing when the problem occurred.
•
How you tried to solve the problem.
Need on-site help? Control Techniques provides service, in most cases, the next day. Just call
Control Techniques’ technical service center when on-site service or maintenance is required.
Training Services
(952) 995-8000 or (800) 397-3786
Email: training@emersonct.com
Control Techniques maintains a highly trained staff of instructors to familiarize customers
with Control Techniques’ “Motion Made Easy” products and their applications. A number of
courses are offered, many of which can be taught in your plant upon request.
Application Engineering
(952) 995-8000 or (800) 397-3786
Email: applengr@emersonct.com
An experienced staff of factory application engineers provides complete customer support for
tough or complex applications. Our engineers offer you a broad base of experience and
knowledge of electronic motion control applications.
Customer Service (Sales)
(952) 995-8000 or (800) 397-3786
Email: sales@emersonct.com
Authorized Control Techniques distributors may place orders directly with our Customer
Service department. Contact the customer Service department at this number for the
distributor nearest you.
Document Conventions
Manual conventions have been established to help you learn to use this manual quickly and
easily. As much as possible, these conventions correspond to those found in other
MicrosoftÒ WindowsÒ documentation.
Menu names and options are printed in bold type: the File menu.
Dialog box names begin with uppercase letters: the Axis Limits dialog box.
Dialog box field names are in quotes: “Field Name.”
Button names are in italic: OK button.
Source code is printed in Courier font: Case ERMS.
iv
In addition, you will find the following typographic conventions throughout this manual.
This
Represents
bold
Characters that you must type exactly as they appear. For example, if
you are directed to type a:setup, you should type all the bold characters
exactly as they are printed.
italic
Place holders for information you must provide. For example, if you are
directed to type filename, you should type the actual name for a file
instead of the word shown in italic type.
ALL CAPITALS
Directory names, file names, key names, and acronyms.
SMALL CAPS
Non-printable ASCII control characters.
KEY1+KEY2
example: (Alt+F)
A plus sign (+) between key names means to press and hold down the
first key while you press the second key.
KEY1,KEY2
example: (Alt,F)
A comma (,) between key names means to press and release the keys one
after the other.
Note
For the purpose of this manual and product, “Note” indicates essential information about
the product or the respective part of the manual.
Epsilon Only
For the purpose of this manual and product, the “Epsilon” symbol indicates information
about the Epsilon drive specifically.
Throughout this manual, the word “drive” refers to an Epsilon or E Series drive.
“Warning” indicates a potentially hazardous situation that, if not avoided, could result in
death or serious injury.
“Caution” indicates a potentially hazardous situation that, if not avoided, may result in
minor or moderate injury.
“Caution” used without the safety alert symbol indicates a potentially hazardous situation
that, if not avoided, may result in property damage.
v
Safety Instructions
General Warning
Failure to follow safe installation guidelines can cause death or serious injury. The voltages
used in the product can cause severe electric shock and/or burns and could be lethal. Extreme
care is necessary at all times when working with or adjacent to the product. The installation
must comply with all relevant safety legislation in the country of use.
Qualified Person
For the purpose of this manual and product, a “qualified person” is one who is familiar with
the installation, construction and operation of the equipment and the hazards involved. In
addition, this individual has the following qualifications:
•
Is trained and authorized to energize, de-energize, clear and ground and tag circuits and
equipment in accordance with established safety practices.
•
Is trained in the proper care and use of protective equipment in accordance with
established safety practices.
•
Is trained in rendering first aid.
Reference Materials
The following related reference and installation manuals may be useful with your particuliar
system.
vi
•
Epsilon Eb and E Series En Drives Reference Manual (P/N 400501-01)
•
PowerTools Software User’s Guide (P/N 400503-01)
•
Epsilon and E Series Drive Parameters Reference Manual (P/N 400504-01)
Epsilon Eb Digital Servo Drive Installation
Manual
Safety Considerations
Safety Precautions
This product is intended for professional incorporation into a complete system. If you install
the product incorrectly, it may present a safety hazard. The product and system may use high
voltages and currents, carry a high level of stored electrical energy, or are used to control
mechanical equipment that can cause injury.
You should give close attention to the electrical installation and system design to avoid
hazards either in normal operation or in the event of equipment malfunction. System design,
installation, commissioning and maintenance must be carried out by personnel who have the
necessary training and experience. Read and follow this safety information and instruction
manual carefully.
Enclosure
This product is intended to be mounted in an enclosure that prevents access except by trained
and authorized personnel and prevents the ingress of contamination. This product is designed
for use in an environment classified as pollution degree 2 in accordance with IEC664-1. This
means that only dry, non-conducting contamination is acceptable.
Setup, Commissioning and Maintenance
It is essential that you give careful consideration to changes to drive settings. Depending on
the application, a change could have an impact on safety. You must take appropriate
precautions against inadvertent changes or tampering. Restoring default parameters in certain
applications may cause unpredictable or hazardous operation.
Safety of Machinery
Within the European Union all machinery in which this product is used must comply with
Directive 89/392/EEC, Safety of Machinery.
The product has been designed and tested to a high standard, and failures are very unlikely.
However the level of integrity offered by the product’s control function – for example stop/
start, forward/reverse and maximum speed – is not sufficient for use in safety-critical
applications without additional independent channels of protection. All applications where
malfunction could cause injury or loss of life must be subject to a risk assessment, and further
protection must be provided where needed.
General warning
Failure to follow safe installation guidelines can cause death or serious injury. The voltages used in
this unit can cause severe electric shock and/or burns, and could be lethal. Extreme care is necessary
vii
Epsilon Eb Digital Servo Drive Installation Manual
at all times when working with or adjacent to this equipment. The installation must comply with all
relevant safety legislation in the country of use.
AC supply isolation device
The AC supply must be removed from the drive using an approved isolation device or disconnect
before any servicing work is performed, other than adjustments to the settings or parameters
specified in the manual. The drive contains capacitors which remain charged to a potentially lethal
voltage after the supply has been removed. Allow at least 6 minutes for the Epsilon 205, 3 minutes
for Epsilon 202/203 and 30 seconds for E Series drives after removing the supply before carrying
out any work which may involve contact with electrical connections to the drive.
Products connected by plug and socket
A special hazard may exist where the drive is incorporated into a product which is connected to the
AC supply by a plug and socket. When unplugged, the pins of the plug may be connected to the
drive input, which is only separated from the charge stored in the bus capacitor by semiconductor
devices. To avoid any possibility of electric shock from the pins, if they are accessible, a means
must be provided for automatically disconnecting the plug from the drive (e.g., a latching
contactor).
Grounding (Earthing, equipotential bonding)
The drive must be grounded by a conductor sufficient to carry all possible fault current in the event
of a fault. The ground connections shown in the manual must be followed.
Fuses
Fuses or over-current protection must be provided at the input in accordance with the instructions
in the manual.
Isolation of control circuits
The installer must ensure that the external control circuits are isolated from human contact by at
least one layer of insulation rated for use at the applied AC supply voltage.
viii
Underwriters Laboratories Listed
LISTED 51Y8
IND. CONT. EQ.
The Epsilon Digital Servo Drives are marked with the “UL Listed” label after passing a
rigorous set of design and testing criteria developed by UL (UL508C). This label indicates
that UL certifies this product to be safe when installed according to the installation guidelines
and used within the product specifications.
The “conditions of acceptability” required by UL are:
•
The Epsilon drive surrounding air ambient temperature must be 40° C (104° F) or less.
•
Epsilon drive surrounding air ambient temperature can be up to 50°C (122° F) with 3%
linear derating for every degree above 40° C (104° F).
•
This product is suitable for use on a circuit of delivering not more than 5000 RMS
symmetrical amperes, 240 volts maximum.
•
Motors must incorporate an overload protection device such as an overtemperature
switch.
Drive Overload Protection
The drive output current overload protection is provided by the drive and is not adjustable.
This overload protection is based on maximum continuous output current capacity. It will
allow up to 200 percent of the drive rated current to be delivered for the amount of time
determined by the following chart.
Rated output current (Amps RMS)
Drive Model
Continuous
Peak
Eb-202
1.8
3.6
Eb-203
3
6
Eb-205
5.0
10.0
ix
Drive Output Current vs. Time graph
60
Time (seconds)
50
40
30
20
10
0
100
125
150
175
200
% Drive Rated Current
CE Declaration of Conformity
The Epsilon Digital Servo Drives are marked with the “Conformite Europeenne Mark” (CE
mark) after passing a rigorous set of design and testing criteria. This label indicates that this
product meets safety and noise immunity and emissions (EMC) standards when installed
according to the installation guidelines and used within the product specifications.
x
Declaration of Conformity
Control Techniques
Manufacturer’s Name:
12005 Technology Drive
Eden Prairie, MN 55344
USA
Manufacturer’s Address:
Declares that the following products:
Epsilon Digital Servo Drive
Products Description:
Model Number:
Eb-202, Ei-202, Eb-203, Ei-203, Eb-205 and Ei-205
System Options:
This declaration covers the above products with the ECI-44 Screw
Terminal Interface.
Conforms to the following product specification:
Electomagnetic Compatibility (EMC):
EN 55011/1991 Class A Group 1, CISPR 11/1990 Class A Group 1
EN 61800-3, 1996:
IEC 1000-4-2/1995; EN 61000-4-2, 6kV CD
IEC 1000-4-3/1995; EN 61000-4-3, ENV 50140/1993, 80% AM,
10V/m @ 3 m
IEC 1000-4-4/1995; EN 61000-4-4, 2 kV ALL LINES
EN 61000-4-5, 1kV L-L, 2kV L-G
EN 61000-4-11, 300 ms/1000 ms 100% DIP
ENV 50204/1995, Pulse, 900 MHz, 50% DTY, 200 Hz
Supplementary information:
The products herewith comply with the requirements of the Low Voltage Directive (LVD) 73/23/EEC and EMC
Directive 89/336/EEC
This electronic drive product is intended to be used with an appropriate motor, electrical protection components and
other equipment to form a complete end product or system. It must only be installed by a professional assembler
who is familiar with requirements for safety and electromagnetic compatibility (“EMC”). The assembler is
responsible for ensuring that the end product or system complies with all the relevant laws in the country where it is
to be used. Refer to the product manual for installation guidelines.
August 18, 1999
Bradley Schwartz/ VP Engineering
European Contact:
Date
Sobetra Automation
Langeveldpark Lot 10
P. Dasterleusstraat 2
1600 St. Pieters Leeuw, Belgium
xi
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Epsilon Eb Digital Servo Drive Installation
Manual
Table of Contents
Reference Materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . vi
Safety Considerations
Safety Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . vii
Enclosure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . vii
Setup, Commissioning and Maintenance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . vii
Safety of Machinery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . vii
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . viii
Introduction
Epsilon Eb Digital Servo Drive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Installation
Basic Installation Notes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Electromagnetic Compatibility (EMC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Environmental Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Wiring Notes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Mechanical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Drive Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Motor Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Electrical Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Power Supply Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Transformer Sizing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Line Fusing and Wire Size . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Input Power Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Alternate Power Supply Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Motor Power Wiring. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Motor Feedback Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Input/Output and Drive Enable Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Command Connector Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Command Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Analog Command Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Encoder Output Signal Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
Pulse Mode Wiring, Differential Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
Pulse Mode Wiring, Single Ended Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Serial Communications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
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Epsilon Eb Digital Servo Drive Installation Manual
Modbus Communications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Multi-Drop Communications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Diagnostics and Troubleshooting
Diagnostic Display . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Fault Codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Fault Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Diagnostic Analog Output Test Points . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Drive Faults . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Resetting Faults . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Viewing Active Drive Faults . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Rebooting the Drive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Watch Window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
View Motor Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
33
34
35
38
39
40
40
40
40
42
Options and Accessories
Epsilon Eb Digital Servo Drive. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
ECI-44 External Connector Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
STI-EIO Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
Specifications
Drive Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Drive and Motor Combination Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Motor Brake Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
IP Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Encoder Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Speed Torque Curves . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Epsilon Drive Dimensions: Eb 202, Eb-203, Eb-205 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
MG Motor Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
NT Motor Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cable Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CMDX-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CMDO-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CDRO-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
AX-CEN-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
EIO-XXX Cable. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
TIA-XXX Cable. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
DDS-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
TERM-H (Head) Terminator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
TERM-T (Tail) Terminator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
xiv
47
49
50
51
52
52
53
56
57
61
65
66
67
68
69
70
70
71
71
72
CMDS-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
CMMS-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
CFCS-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
CFCO-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
CFOS-XXX Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75
Vendor Contact Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76
Index
xv
Epsilon Eb Digital Servo Drive Installation Manual
xvi
Epsilon Eb Digital Servo Drive Installation
Manual
Introduction
Epsilon Eb Digital Servo Drive
The Epsilon drives are standalone, fully digital brushless servo drives designed and built to
reliably provide high performance and flexibility without sacrificing ease of use.
The use of State-Space algorithms make tuning very simple and forgiving. The drives are
designed to operate with up to a 10:1 inertia mismatch right out of the box. Higher (50:1 and
more) inertial mismatches are possible with two simple parameter settings.
The drives can be quickly configured to many applications in less than 5 minutes with
PowerTools software on a PC running Windows 95, 98, or NT 4.0.
Complete diagnostics are provided for quick troubleshooting. A diagnostic display on the
front of the drive informs the user of the operational or fault status. The last 10 faults are
stored in non-volatile memory along with a time stamp for easy recall.
Epsilon drives operate at 42 to 264 VAC standalone or at 24 to 375 VDC with an A.P.S.
(Alternate Power Supply) and are available in two power ratings. The drive will fit in a 6 inch
deep enclosure with cables connected.
Drive Model
Power Rating
Continuous Current
Peak Current
Epsilon Eb-202
650 W
1.8 amps
3.6 amps
Epsilon Eb-203
1100 W
3.0 amps
6.0 amps
Epsilon Eb-205
1750 W
5.0 amps
10.0 amps
The MG and NT motors that are matched to the Epsilon drives provide low inertia, high
power to size ratios, and encoder feedback for accurate positioning.
Features
•
Digital drive design using DSP, ASIC, and surface mount technologies
•
Epsilon input power is rated at 42 to 264 VAC (12 to 264 VAC or 12 to 375 VDC when
using an A.P.S.)
•
Small mounting footprint
•
Auxiliary logic power supply capability
•
Five optically isolated inputs and three optically isolated outputs
•
Built-in RS-232C to RS-485 converter for multi-drop applications
•
RS-232C/485 serial communications interface using industry standard Modbus®
protocol up to 19.2 kbaud
•
Diagnostic and operating mode status display
1
Epsilon Eb Digital Servo Drive Installation Manual
•
Extensive fault sensing and diagnostics, including storage and time stamping of the last
ten faults
•
Maximum input response time is 500 µs for command and input functions
•
Peak torque up to three times continuous motor torque rating 200% for 5 seconds
•
Sinusoidal commutation for efficiency and motor smooth motion
•
No potentiometers or selector switches
•
No tuning needed for no-load up to 10:1 inertia mismatch
•
High performance tuning based on inertia ratio, friction and response with PowerTools
software (available separately)
•
High resolution encoder
•
Four velocity presets
•
Programmable pulse follower ratio
•
Pulse mode input type selectable between differential and single-ended
•
Removable connectors for easy installation
•
Single cable connection to Control Techniques’ AXIMA 2000 and 4000 multi-axis
controllers
•
Scalable Encoder Output in one line per revolution increments
•
Travel Limit Function in Torque mode
•
Access to bus voltage for external shunt
•
Able to operate non-Control Techniques motors with encoders
Figure 1:
2
Epsilon Eb Drives Feature Location
Epsilon Eb Digital Servo Drive Installation
Manual
Installation
Basic Installation Notes
You are required to follow all safety precautions during startup such as providing proper
equipment grounding, correctly fused power, and an effective Emergency Stop circuit which
can immediately remove power in the case of a malfunction. See the “Safety Considerations”
section for more information.
Electromagnetic Compatibility (EMC)
Drives are designed to meet the requirements of EMC. Under extreme conditions a drive
might cause or suffer from disturbances due to electromagnetic interaction with other
equipment. It is the responsibility of the installer to ensure that the equipment or system into
which the drive is incorporated complies with the relevant EMC legislation in the country of
use.
The following instructions provide you with installation guidance designed to help you meet
the requirements of the EMC Directive 89/336/EEC.
Adhering to the following guidelines will greatly improve the electromagnetic compatibility
of your system; however, final responsibility for EMC compliance rests with the machine
builder, and Control Techniques cannot guarantee your system will meet tested emission or
immunity requirements.
If you need to meet EMC compliance requirements, EMI/RFI line filters must be used to
control conducted and radiated emissions as well as improve conducted immunity.
Physical location of these filters is very important in achieving these benefits. The filter
output wires should be kept as short as possible (12 inches is suggested) and routed away from
the filter input wires. In addition:
•
Choose an enclosure made of a conductive material such as steel, aluminum, or stainless
steel.
•
Devices mounted to the enclosure mounting plate, which depend on their mounting
surfaces for grounding, must have the paint removed from their mounting surfaces and the
mating area on the mounting plate to ensure a good ground. See “Achieving Low
Impedance Connections” on page 4 for more information.
•
If grounding is required for cable grommets, connectors, and/or conduit fittings at
locations where cables are mounted through the enclosure wall, paint must be removed
from the enclosure surface at the contact points.
•
AC line filter input and output wires and cables should be shielded, and all shields must
be grounded to the enclosure.
3
Epsilon Eb Digital Servo Drive Installation Manual
Achieving Low Impedance Connections
Noise immunity can be improved and emissions reduced by making sure that all the
components have a low impedance connection to the same ground point. A low impedance
connection is one that conducts high frequency current with very little resistance. Impedance
cannot be accurately measured with a standard ohmmeter, because an ohmmeter measures
DC resistance. For example, a 12-inch-long, 8-gauge,round wire has a significatly higher
impedance than a 12-inch-long, 12-gauge, flat braided conductor. A short wire has less
impedance than a larger one.
Low impedance connections can be achieved by bringing large areas of conductive surfaces
into direct contact with each other. In most cases this requires paint removal because a ground
connection through bolt threads is not sufficient. However, component materials should be
conductive, compatible, and exhibit good atmospheric corrosion resistance to prevent loss
through corrosion, which will hinder the low impedance connection. Enclosure
manufacturers offer corrosion resistant, unpainted mounting plates to help.
Bringing components into direct contact cannot always be achieved. In these situations a
conductor must be relied upon to provide a low impedance path between components.
Remember a flat braided wire has lower impedance than a round wire of a large guage rating.
A low impedance connection should exist among the following components:
•
Enclosure and mounting plate
•
Servo amplifier chassis and mounting plate
•
EMI/RFI AC line filter chassis and mounting plate
•
Other interface equipment chassis and mounting plate
•
Other interface equipment chassis and electrical connectors
•
Enclosure and conduit fittings or electrical connectors
•
Enclosure mounting plate and earth ground
•
Motor frame and conduit fittings or electrical connectors
•
Encoder chassis and electrical connector
A good rule to follow when specifying conductors for high frequency applications is to use a
metal strap with a length to width ratio that is less than 3:1.
4
Installation
AC Line Filters
The AC line filters used during Control Techniques’ compliance testing are listed below.
These filters are capable of supplying the drive input power to the specified drive under
maximum output power conditions.
Epsilon
E Series
Eb-202, Eb-203
Eb-205
Schaffner Part #
Control Techniques Part #
Rating
FN2070-10/08
960307-01
10A, 240V, 1 Ø
EN-204
FS5278-16/08
960305-01
EN-208
FS5278-16/08
960305-01
EN-214
FN-258/16
960304-01
16A, 240V, 1 Ø
16A, 480V, 3 Ø
Alternately, Control Techniques has also seen good results with the following line filters:
Drive
Part #
Rating
Corcom 20EQ1
20A, 240V, 1 Ø
Schaffner FN 2070-6-06
6A, 240V, 1 Ø
EN-204
EN-208
Eb-202, Eb-203, Eb-205
Eb-202
AC Line Filter Installation Notes
•
EMC criteria can be met in installations where multiple drives are supplied through a
single filter, however, it is the installers responsibility to verify EMC compliance.
Questions on this subject should be directed to the filter manufacturer.
•
It is critical that you keep the filter inputs routed away from any electrical noise sources
to prevent noise from being induced into them and carried out of the enclosure.
5
Epsilon Eb Digital Servo Drive Installation Manual
Cable to Enclosure Shielding
Shielded motor, feedback, serial communications, and external encoder cables were used for
Control Technicques’ compliance testing and are necessary to meet the EMC requirements.
Each cable shield was grounded at the enclosure wall by the type of grommet described earlier
and shown in the figure below.
Figure 2:
Control Techniques
Cable Model
Shielded Cable
Grommet Kit Part #
Conduit Dimension
Hole Size
Actual Hole Size
Motor Cable, 16 Ga
CMDS
CGS-050
1/2" pipe
7/8"
Motor Cable, 12 Ga
CMMS
CGS-050
1/2" pipe
7/8"
Feedback Cable
CFOS
CGS-050
1/2" pipe
7/8"
Flex Motor Cable, 16 Ga
CMDF
CGS-050
1/2" pipe
7/8"
Flex Motor Cable, 12 Ga
CMMF
CGS-075
3/4" pipe
1 1/16"
Cable Type
Flex Feedback Cable
External Encoder
AC Power
6
Through Wall Shield Grommet
CFCF, CFOF
CGS-063
3/4" pipe
1 1/16"
ENCO
CGS-038
1/2" pipe
7/8"
user supplied
user supplied
Installation
Figure 3:
AC Filter and Cable Connections for Epsilon Drives
Environmental Considerations
If the product will be subjected to atmospheric contaminants such as moisture, oils,
conductive dust, chemical contaminants, and metallic particles, you must mount it vertically
in a metal NEMA type 12 enclosure.
If the ambient temperature inside the enclosure will exceed 40° C (104° F), you must consider
forced air cooling.
Note
For Epsilon drives, surrounding air ambient temperature can be up to 50°C (122° F) with
3% linear derating for every degree above 40° C (104° F)
The amount of cooling depends on the size of the enclosure, the thermal transfer of the
enclosure to the ambient air, and the amount of power being dissipated inside the enclosure.
Consult your enclosure manufacturer for assistance with determining cooling requirements.
7
Epsilon Eb Digital Servo Drive Installation Manual
Wiring Notes
•
To avoid problems associated with EMI (electromagnetic interference), you should route
high power lines (AC input power and motor power) away from low power lines (encoder
feedback, serial communications, etc.).
•
If a neutral wire (not the same as Earth Ground), is supplied from the building distribution
panel it should never be bonded with PE wire in the enclosure.
•
You should consider future troubleshooting and repair when installing all wiring. All
wiring should be either color coded and/or tagged with industrial wire tabs.
•
As a general rule, the minimum cable bend radius is ten times the cable outer diameter.
•
All wiring and cables, stationary and moving, must be protected from abrasion.
•
Ground wires should not be shared with other equipment.
•
Ensure that metal to metal contact is made between the enclosure ground lug and the metal
enclosure, not simply through the mounting bolt and threads.
•
All inductive coils must be suppressed with appropriate devices, such as diodes or
resistor/capacitor (RC) networks.
Mechanical Installation
Drive Mounting
Drives must be back mounted vertically on a metal surface such as a NEMA enclosure. A
minimum spacing of two inches must be maintained above and below the drive for
ventilation. Side by side drive spacing requirements vary by drive size and RMS loading.
Additional space may be necessary for wiring and cable connections.
For drive dimensions, weights and mounting specifications, see the "Specifications" section.
Motor Mounting
Motors should be mounted firmly to a metal mounting surface to ensure maximum heat
transfer for maximum power output and to provide a good ground.
For motor dimensions, weights and mounting specifications, see the “Specifications” chapter.
8
Installation
Electrical Installation
Figure 4:
Typical System Grounding Diagram
9
Epsilon Eb Digital Servo Drive Installation Manual
Power Supply Requirements
The examples below show AC power connections for single phase and three phase drives.
These examples are shown for reference only. Local electrical codes should be consulted
before installation.
The Protective Earth (PE) wire connection is mandatory for human safety and proper
operation. This connection must not be fused or interrupted by any means. Failure to
follow proper PE wiring can cause death or serious injury.
Epsilon Only
The Eb-202, Eb-203 and Eb-205 drives require 42 to 264 VAC single-phase power. An
Epsilon drive can be connected to any pair of power phases on a 1 Ø or 3 Ø power source
that is grounded as shown in the following diagrams.
Epsilon Only
If using an APS Logic Power input and the Low DC Bus fault is disabled, minimum
supply voltage to an Epsilon can be reduced to 15 VAC on the AC inputs or 24 VDC on
the Bus +/- connections.
Note
The maximum voltage applied to the drive terminals must not exceed 264 VAC phase to
phase and phase to PE ground. This can be accomplished by referencing the AC supply
to earth ground.
Do not connect or disconnect the AC power by inserting or removing the AC power
connector. Using the connector in this manner, even once, will damage the connector,
making it unusable.
AC Supplies NOT Requiring Transformers
If the distribution transformer is configured as shown in the figures below, the AC power
supply can be connected directly to the amplifier terminals.
10
Installation
Figure 5:
Earth Grounded WYE Distribution Transformer
Figure 6:
Earth Grounded Delta Distribution Transformer
AC Supplies Requiring Transformers
If the distribution transformer is configured as shown in the figures below, an isolation
transformer is required.
If an isolation transformer is used between the power distribution point and the drives, the
transformer secondary must be grounded for safety reasons as shown in the figures below.
11
Epsilon Eb Digital Servo Drive Installation Manual
12
Figure 7:
Three Phase Delta (with mid-phase GND) Distribution to a Three-Phase
Delta/WYE Isolation Transformer
Figure 8:
Three Phase WYE (ungrounded) Distribution to a Three-Phase Delta/WYE
Isolation Transformer
Figure 9:
Delta to Delta Isolation Transformer
Installation
Figure 10:
Single Phase Power Supply Connections
Transformer Sizing
If your application requires a transformer, use the following table for sizing the KVA rating.
The values in the table are based on “worst case” power usage and can be considered a
conservative recommendation. You can down-size the values only if the maximum power
usage is less than the transformer continuous power rating. Other factors that may influence
the required KVA rating are high transformer ambient temperatures (>40° C or >104° F) and
drive operation near the maximum speeds.
Drive/Motor Combination
Suggested KVA Rating
Eb-202/NT-207
1.0
Eb-203/NT-207
1.0
Eb-202/NT-212
1.2
Eb-203/NT-212
1.7
Eb-203/MG-316
2.3
Eb-205 / MG-340
3.0
Transformer output voltage drop may become a limiting factor at motor speeds and loads near
maximum ratings. Typically, higher KVA transformers have lower voltage drop due to lower
impedance.
13
Epsilon Eb Digital Servo Drive Installation Manual
Line Fusing and Wire Size
You must incorporate over current protection for the incoming AC power with the minimum
rating shown below. Control Techniques recommends Bussman type: LPN or equivalent.
Drive Model
External AC Line Fuse
Recommended Minimum AC/PE Line
Wire Gauge
Eb-202
LPN 6 Amp
16 AWG
Eb-203
LPN 8 Amp
16 AWG
Eb-205
LPN 12 Amp
16 AWG
Drive Model
Input Voltage
(VAC)
Frequenc
y (Hz)
240 / 1 Ø
47 - 63
Eb-202
Eb-203
Eb-205
Input Current
(Amps RMS) at
full drive output
current
4.3
6.5
10.8
Inrush Current (Amps)
1 st Cycle
2nd Cycle
140 (2 ms)
20 (2 ms)
140 (5 ms)
30 (2 ms)
Epsilon Only
This inrush current specification assumes the drive has been powered off for at least eight
minutes at 40° C ambient or five minutes at 25° C ambient. If this amount of time has not
elapsed since power off, the inrush current will be higher.
14
Installation
Input Power Connections
Epsilon Only
Power must be "Off" for a minimum of 6 minutes for the Epsilon drive before unplugging
the power connection, to ensure the bus voltage has bled down to a safe level (below 50
VDC).
Figure 11:
Epsilon AC Power Wiring Diagram
Do not connect or disconnect AC power by inserting or removing the AC power
connector. Using the connector in this manner, even once, will damage the connector
making it unusable.
15
Epsilon Eb Digital Servo Drive Installation Manual
Figure 12:
Epsilon Auxiliary Power Supply Wiring Diagram
Alternate Power Supply Wiring
An Alternate Power Supply (APS) allows the drive to retain motor position information and
serial communications when the main AC power supply is disconnected. You must reset the
drive, either using the reset button or a reset input, after AC power is re-applied if the backup
supplies have been active.
Enabling APS power is done by sliding open the access panel on the side of the drive. Then
move the jumper into the APS position using needle nose pliers.
Use static control procedures when handling the jumper inside the drive case.
The APS input is isolated from all other circuits on the Epsilon drive including the DC bus,
logic and I/O. This permits you to use one common 24 VDC power supply for multiple drives
without concern for ground loops and noise coupling between drives. The APS connection
will generate some high frequency ripple (.25 Amps at 80 khz) on the APS power lines. This
may disturb sensitive equipment that shares the same power supply.
16
Installation
APS Input Specification
Voltage Range
Current
Inrush Current
18-30 VDC
0.5 A maximum
0.7 A peak
( 0.4 A maximum
0.6 A peak if external
encoder is not used )
80 A for 1 ms if not limited by
power supply
Using the APS supply input to power the drive logic and motor encoder allows the drive bus
to operate at DC voltages below 42 VAC (60 VDC bus). The drive will operate down to 12
VDC on the bus (10 VAC on L1 and L2). However the low DC bus monitoring must be
disabled to prevent faults at these low DC bus voltage levels. This can be done with
PowerTools software on the Advanced tab in Detailed Setup mode.
Do not wire AC line into the APS input. Doing so will damage the drive.
Do not open the APS jumper access panel until at least six minutes after the main AC
power has been removed from the L1 and L2 terminals.
Note
Connecting 24V common on the APS to chassis ground reduces offset voltage in Analog
Diagnostic Outputs.
17
Epsilon Eb Digital Servo Drive Installation Manual
Figure 13:
Multiple APS Wiring Diagram
Motor Power Wiring
Motors are equipped with up to three male MS (Military Style) connectors, one for stator
connections, one for encoder connections and one for the brake (if so equipped).
Stator connections from the drive to the motor are made with the CMDS cable which has a
female MS style connector on the motor end and four individual wires and shield that connect
to the motor power connector on the bottom of the drive.
Figure 14:
18
Epsilon Motor Power Wiring Diagram
Installation
Note
The motor ground wire and shields must be run all the way back to the amplifier terminal
and must not be connected to any other conductor, shield or ground.
Motor Feedback Wiring
Encoder feedback connections are made with the CFCS cable. This cable has an MS style
connector on the motor end and a 26-pin high density “D” connector on the drive end.
For A, A, B, B and Z, Z pairs, the CFCS cable uses low capacitance (~10 pf/ft) wire to get a
characteristic impedance of 120 ohms. This impedance match is important to minimize signal
loss and ringing.
Figure 15:
Motor Feedback Connector Pinout
Motor Brake Wiring
Motors equipped with brakes have a three-pin MS style connector. The Control Techniques
brake power cable (model CBMS-XXX) has an MS style connector on the motor end and
three wire leads on the amplifier end (see wiring diagram below).
You must provide a DC power supply rated at +24 VDC with a 2 amp minimum current
capacity for the brake. If you use this voltage source to power other accessories such as I/O
or more than one brake, you must increase its current capability.
19
Epsilon Eb Digital Servo Drive Installation Manual
CBMS-xxx Cable
Black -
Bottom View
Output #3
17
16
Drive Enable
I/O Supply
Customer
supplied drive
enable contact
32
I/O Common
31
J5
Single point
PE ground.
C
B
K1
A
Internal
to Motor
2 Amp
Fuse
34
33
I/O Supply
I/O Common
20
A2
A1
14
1 Amp
Fuse
11
Relay:
EMC #BRM-1
Red +
- +
24 VDC
Figure 16:
Epsilon Brake Wiring Diagram using the Command Connector
Figure 17:
Epsilon Brake Wiring Diagram using the I/O Connector
Motor
Connected to
grounded
mounting panel.
Installation
Input/Output and Drive Enable Wiring
Drives are equipped with five optically isolated input lines (one is dedicated to a drive enable
function) and three optically isolated output lines. They are designed to operate from a +10
to 30 VDC source. All inputs and outputs are configured as sourcing. You are responsible for
choosing a load that will limit each output’s current to less than 150 mA.
Figure 18:
Epsilon Input/Output Wiring Diagram
Epsilon Only
The I/O connector is a 26-pin male connector on the front of the drive. Control Techniques
offers a low profile interface plug and cable (EIO-xxx) for connections.
21
Epsilon Eb Digital Servo Drive Installation Manual
Figure 19:
Epsilon I/O to Command Connector Internal Connections
Note
If loads are applied to the same output signal on both Command Connector and I/O
Connector, the sum total current loading must be limited to 150 mA per output signal.
Command Connector Wiring
All command and digital I/O signals are available using the 44-pin Command Connector.
If you are interfacing your drive(s) to an AXIMA 2000 or 4000 multi-axis controller, simply
connect the 44-pin connector of your AX-CEN-XXX cable to the drive and the 25-pin
connector to the AXIMA multi-axis controller.
If you are interfacing your drive(s) to an AXIMA or any other motion controller, you may use
either the CDRO-XXX or CMDO-XXX cables or the optional External Connection Interface
22
Installation
(ECI-44) which provides a convenient screw terminal connection strip. Connect one end of
the CMDX command cable to your drive and the other end to the ECI-44.
Shield
Connected to
Connector Shell
Command Connector
(RED/BRN)
1
(BRN/RED)
(BLK/BLU)
2
3
4
(BLU/BLK)
(ORG/YEL)
Input #1
Input #2
Input #3
10 Ohm
Input #4
6
RS 485+
(YEL/ORG)
(PRP/BLU)
21
8
RS 485-
(BLU/PRP)
(RED/BLU)
9
11
Encoder Output Channel A/
Encoder Supply +5 Volts - Output. 200 mA
(BLU/RED)
(BLK/GRN)
12
16
Encoder Common
(GRN/BLK)
(BLK/BRN)
17
18
19
Output #3
23
24
25
39
Encoder Output Channel B
(BRN/BLK)
(PRP/ORG)
(ORG/PRP)
(BLK/RED)
(RED/BLK)
(PRP/GRN)
27
41
(GRN/PRP)
(YEL/BLU)
34
32
(BLU/YEL)
(YEL/BRN)
Encoder Output Channel A
Drive Enable Input
Output #2
Output #1
Encoder Output Channel B/
Do Not Connect
Do Not Connect
Do Not Connect
Do Not Connect
I/O Supply +
I/O Common -
(BRN/YEL)
(PRP/BRN)
33
31
37
I/O Supply +
I/O Common Encoder Output Channel Z
(BRN/PRP)
(PRP/GRY)
38
40
Do Not Connect
(GRY/PRP)
(WHT/BLU)
26
14
15
(BLU/WHT)
(WHT/GRN)
43
44
(GRN/WHT)
(WHT/RED)
29
28
(RED/WHT)
(GRY/YEL)
(YEL/GRY)
36
20
35
= Twisted Pair
Figure 20:
PE
Encoder Output Channel Z/
Do Not Connect
Do Not Connect
Do Not Connect
Diagnostics Output Channel 1
Diagnostics Output Channel 2
Diagnostic Output Common
+15 Out (Test Only)
Do Not Connect
Do Not Connect
Do Not Connect
7
10
Do Not Connect
13
5
Do Not Connect
Do Not Connect
22
Do Not Connect
30
Do Not Connect
42
Do Not Connect
Do Not Connect
Command Connector (J5) Pinout and CMDO-XXX Wire Colors
For information about Command Connector pinout and CMDO-XXX cable wire colors, see
the “Specifications” chapter.
Function
Pin Numbers
Electrical Characteristics
Inputs and Drive Enable
1, 2, 3, 4, 16
10-30 V (“On”) 0-3 V (“Off”) optically isolated
Outputs
17, 18, 19
10-30 VDC sourcing 150 mA
I/O Supply
33, 34
10 - 30 VDC @ 1 Amp maximum
I/O Common
31, 32
I/O return
23
Epsilon Eb Digital Servo Drive Installation Manual
Function
Pin Numbers
Electrical Characteristics
Pulse Inputs Differential
25, 26, 27, 39, 40,
41
5 V, 200 mV differential, 60 mV hysteresis, RS-422
compatible
Pulse Inputs Single Ended
20, 36
TTL, 330 ohm pull-ups to internal 5 V, 1.5 V = low, 3.5 V
= high
Encoder Supply Output +5
V
11
+5 V (200mA) output self-resetting fused internally
Encoder Common 0 V
12
0.0 V, 10 ohms away from PE
Encoder Out
8, 9, 23, 24, 37, 38
Differential line driver output (RS 422)
Analog In
14, 15
± 10 VDC differential command
Diagnostic Output
43, 44
± 10 VDC 10 mA maximum. Analog diagnostic output, ref.
to pin 29
Diagnostic Output
Common
29
0.0 V, 10 ohms away from PE
0 ohms away from Encoder Common 0V (pin 12)
RS 485 ±
6, 21
Same signals as the Serial Connector
+15 out
28
10 mA supply. ref. pin 29 (for test purposes only.)
Command Cables
The CMDO, CMDX and CDRO cables are all cables that plug into the Command Connector.
The CMDO and CMDX cables both use the same straight connector style, same color code
and carry the full complement of signals available from the Command Connector. The
difference is the CMDO cable has a male connector on one end with open wires on the other
while the CMDX cable has male connectors on both ends.
For information about CMDO-XXX and CMDX-XXX (18 pair cable) cable wire colors see
the “Specifications” chapter.
Note
Some CMDO and CMDX cables may have White/Yellow and Yellow/White wires in
place of the White/Orange and Orange/White shown in the figure above (pins 6 and 21).
The CDRO cable includes only the most commonly used signals to reduce the cable outer
dimension and has a connector at only one end. The 45 degree connector design used on the
CDRO cable also reduces the enclosure spacing requirement below the drive.
For information about the CDRO-XXX (13 pair) cable wire colors, see the “Specifications”
chapter.
24
Installation
Analog Command Wiring
Figure 21:
Analog Command, Differential Wiring Diagram
Command Connector
Figure 22:
Analog Command, Single Ended Wiring Diagram
25
Epsilon Eb Digital Servo Drive Installation Manual
Encoder Output Signal Wiring
The Epsilon drive encoder outputs meet RS-422 line driver specifications and can drive up to
ten RS-422 signal recievers.
The default encoder output resolution is set so it outputs the actual motor encoder resolutions.
The standard MG and NT motors have 2048 lines per revolution. This resolution is adjustable
in one line per revolution increments with PowerTools software. With the range of one line
per revolution to the actual motor encoder density.
26
Figure 23:
Command Connector Encoder Output Wiring
Figure 24:
Direction Convention Diagram
Installation
Pulse Mode Wiring, Differential Inputs
Figure 25:
Pulse Mode, Differential Output to Differential Input
Figure 26:
Pulse Mode, Single Ended Output to Differential Input
27
Epsilon Eb Digital Servo Drive Installation Manual
Pulse Mode Wiring, Single Ended Inputs
+5
Logic
Power
Pulse
A/
Direct
B
Sinking
Outputs (typ)
Common isolated
from other sources
Figure 27:
Pulse Mode, Single Ended Output to Single Ended Input (twisted pair cable)
+5
Logic
Power
Pulse
A/
Direct
B
Sinking
Outputs (typ)
Common isolated
from other sources
Figure 28:
28
Pulse Mode, Single Ended Output to Single Ended Input (non-twisted pair
cable)
Installation
Figure 29:
Master/Slave Encoder Connections
Note
Epsilon encoder outputs meet RS-422 driver specifications and can drive up to 10 RS-422
signal recievers. Each Epsilon differential pulse input is an RS-422 line recievers. The
default encoder output resolution is 2048 lines per motor revolution. This resolution is
adjustable in one line per revolution increments with PowerTools software. The range is
between 200 and the actual motor encoder density.
29
Epsilon Eb Digital Servo Drive Installation Manual
Serial Communications
Serial communications with the drive is provided through the female DB-9 connector located
on the front of the drive. The serial interface is either three wire non-isolated RS-232C or two
wire non-isolated RS-485. RS-485 is also available through the 44-pin Command Connector.
Figure 30:
Epsilon RS-232 and RS-485 Internal Connections between the Command
Connector and the Serial Communication Connector
When connecting the serial port of your PC to the serial port of the drive, verify that your
PC’s ground is the same as the drive PE ground. Failure to do so can result in damage to
your PC and/or your drive.
Note
Communication errors can usually be avoided by powering the computer or host device
off of a convenience outlet that is mounted in the enclosure and whose neutral and ground
are wired to the same single ended point ground that the drives and controllers are using.
This is sometimes benefical even with battery powered computers.
30
Installation
Modbus Communications
The drive’s serial communication protocol is Modbus RTU slave with a 32 bit data extension.
The Modbus protocol is available on most operator interface panels and PLC’s.
Serial Communications Specifications
Max baud rate
19.2k
Start bit
1
Stop bit
2
Parity
none
Data
8
Control Techniques’ Motion Interface panels are supplied with a Modbus master
communications driver.
Multi-Drop Communications
The RS-485 option (pins 4 and 9) is provided for multi-drop configurations of up to 32 drives.
Control Techniques provides a special multi-drop serial cable which allows you to easily
connect two or more drives.
Figure 31:
Multi-Drop Wiring Diagram
31
Epsilon Eb Digital Servo Drive Installation Manual
TIA Cable
DDS Cable
DDS Cable
TERM-T
TERM-H
RX (232)
TX (232)
Ground
1
2
3
4
5
6
1
2
3
4
5
6
1
2
3
4
5
6
1
2
3
4
5
6
7
8
9
7
8
9
7
8
9
Drive
Serial Port
120
Ohm
Computer
Computer Serial
Port
Drive Serial Port
1
2
3
4
5
6
1
2
3
4
5
6
7
8
9
7
8
9
7
8
9
Drive
Serial Port
Drive
Serial Port
Drive Serial Port
0V
+5
485 -
576
Ohm
TERM-T
TIA Cable
DDS Cable
Top View of Multi-drop Cabling
32
120
Ohm
Drive Serial Port
TERM-H
Figure 32:
576
Ohm
485 +
Multi-Drop Wiring Pinout
DDS Cable
Epsilon Eb Digital Servo Drive Installation
Manual
Diagnostics and Troubleshooting
Diagnostic Display
The diagnostic display on the front of the drive shows drive status and fault codes. When a
fault condition occurs, the drive will display the fault code, overriding the status code. The
decimal point is “On” when the drive is enabled and the Stop input is not active. This indicates
that the drive is ready to run and will respond to motion commands. Commands will not cause
motion unless the decimal point is “On”.
Display Indication
Status
Description
Brake Engaged (Output "Off")
Motor brake is mechanically engaged. This
character will only appear if the Brake output
function is assigned to an output line.
Disabled
Power Stage is disabled.
Position
Pulse mode operation.
Velocity
Velocity mode operation.
Torque
Torque mode operation.
Summation
Summation mode operation.
RMS Foldback
Motor torque is limited to 80 percent.
Stall Foldback
Drive output current is limited to 80 percent of
drive stall current.
33
Epsilon Eb Digital Servo Drive Installation Manual
Display Indication
Status
Ready to Run
Description
Drive enabled, no Stop input.
Fault Codes
A number of diagnostic and fault detection circuits are incorporated to protect the drive. Some
faults, like high DC bus and amplifier or motor over temperature, can be reset with the Reset
button on the front of the drive or the Reset input function. Other faults, such as encoder
faults, can only be reset by cycling power “Off” (wait until the status display turns “Off”),
then power “On.”
The drive accurately tracks motor position during fault conditions. For example, if there is a
Low DC Bus fault where the power stage is disabled, the drive will continue to track the
motor’s position provided the logic power is not interrupted.
The +/- Travel Limit faults are automatically cleared when the fault condition is removed.
The table below lists all the fault codes in priority order from highest to lowest. This means
that if two faults are active, only the higher priority fault will be displayed.
Display
34
Fault
Action to Reset
Bridge Disabled
NVM Invalid
Button or Input
Yes
Drive Overtemp
Cool down,
Cycle Power
Yes
Power Module
Power
Yes
High DC Bus
Button or Input
Yes
Low DC Bus
Button or Input
Yes
Diagnostics and Troubleshooting
Display
Fault
Action to Reset
Bridge Disabled
Encoder State
Power
Yes
Encoder Hardware
Power
Yes
Motor Overtemp
Cool down,
Button or Input
Yes
Overspeed
Button or Input
Yes
Max Following Error
(Position mode)
Button or Input
Yes
Travel Limit +/-
Auto
No
All "On"
Normally "On" for one
second during powerup
Yes
Fault Descriptions
Power Up Test
This fault indicates that the power-up self-test has failed. This fault cannot be reset with the
reset command or reset button.
NVM Invalid
At power-up the drive tests the integrity of the non-volatile memory. This fault is generated
if the contents of the non-volatile memory are invalid.
35
Epsilon Eb Digital Servo Drive Installation Manual
Invalid Configuration
Epsilon Only
This fault will occur if the digital board in the drive does not match the power board
settings. It is only useful during manufacturing. A drive with this fault should be returned
for service.
Drive Overtemp
Indicates the drive IGBT temperature has reached 100° C.
Power Module
This fault is generated when a power stage over-temperature, over-current or loss of power
stage logic supply occurs. This can be the result of a motor short to ground, a short in the
motor windings, a motor cable short or the failure of a switching transistor.
It can also occur if the drive enable input is cycled “Off” and “On” rapidly (>10 Hz).
This fault should not be allowed to occur repeatedly. System changes should be made to
eliminate Z fault events. Drive power stage will become degraded if allowed to continue.
Note
If a cause for Z faults cannot be determined, write down all observations prior to and after
the Z faults and contact Control Techniques Technical Support.
High DC Bus
This fault will occur whenever the voltage on the DC bus exceeds 415 VDC. The most likely
cause of this fault would be an open external shunt fuse, a high AC line condition or an
application that requires an external shunt (e.g., a large load with rapid deceleration).
High DC Bus Threshold
Low DC Bus Treshold
E Series
440
96
Epsilon
415
60
Low DC Bus
This fault will occur whenever the voltage on the DC bus drops below 60 volts. The most
likely cause of this fault is a reduction (or loss) of AC power. A 50 ms debounce time is used
with this fault to avoid faults caused by intermittent power disruption. With and Epsilon drive,
the low DC bus monitoring can be disabled with PowerTools software in the Advanced tab.
36
Diagnostics and Troubleshooting
High DC Bus Threshold
Low DC Bus Treshold
E Series
440
96
Epsilon
415
60
Encoder State
Certain encoder states and state transitions are invalid and will cause the drive to report an
encoder state fault. This is usually the result of noisy encoder feedback caused by poor
shielding.
Encoder Hardware
If any pair of complentary encoder lines are in the same state, an encoder line fault is
generated. The most likely cause is a missing or bad encoder connection.
Motor Overtemp
This fault is generated when the motor thermal switch is open due to motor over-temperature
or incorrect wiring.
Overspeed
This fault occurs in one of two circumstances:
1.
When the actual motor speed exceeds the Overspeed Velocity Limit parameter or 150%
of motor maximum operating speed. This parameter can be accessed with PowerTools
software.
2.
If the combination of command pulse frequency and Pulse Ratio can generate a motor
command speed in excess of the fixed limit of 13000 RPM, an Overspeed Fault will be
activated. In Pulse mode operation and any Summation mode which uses Pulse mode,
the input pulse command frequency is monitored and this calculation is made. For
example, with a Pulse Ratio of 10 pulses per motor revolution, the first pulse received
will cause an Overspeed fault even before there is any motor motion.
Max Following Error
This fault is generated when the following error exceeds the following error limit (default
following error limit is .2 revs). With PowerTools you can change the Following Error Limit
value or disable in the Position tab.
37
Epsilon Eb Digital Servo Drive Installation Manual
Travel Limit +/This fault is caused when either the + or - Travel Limit input function is active.
“All On”
This is a normal condition during power up of the drive. It will last for less than 1 second. If
this display persists, call Control Techniques for service advice.
Normally, “All On” appears for less than one second during power-up. All segments are
dimly lit when power is “Off.” This is normal when an external signal is applied to the
encoder inputs (motor or master) or serial port from an externally powered device. The
signals applied to the inputs cannot exceed 5.5V level required to drive logic common or drive
damage will occur.
Diagnostic Analog Output Test Points
The drive has two 8-bit real-time analog outputs which may be used for diagnostics,
monitoring or control purposes. These outputs are referred to as Channel 1 and Channel 2.
They can be accessed from the Command Connector on the drive or from the Diagnostics
Analog Output Pins located on the front of the drive.
Each Channel can be programmed to the following sources:
Analog Output Source options
•
Velocity Command
•
Velocity Feedback
•
Torque Command (equates to Torque Command Actual parameter)
•
Torque Feedback
•
Following Error
Default Analog Output Source
•
Channel 1 = Velocity Feedback
•
Channel 2 = Torque Command
Output
Source
Offset
Scale
1
Velocity Feedback
0
600 RPM/volt
2
Torque Command
0
30 percent/volt for selected
motor
The DGNE cable was designed to be used with either an oscilloscope or a meter. The wires
are different lengths to avoid shorting to each other. However, if signals do get shorted to
GND, the drive will not be damaged because the circuitry is protected.
38
Diagnostics and Troubleshooting
Note
Connecting the A.P.S. 24V return to chassis ground reduces output offset voltage.
D/A
Black
(GND)
D/A
Yellow
Blue
10 Ohm
2
10 Ohm
2
DGNE Cable
DGNE Cable
Figure 33:
Diagnostic Cable (DGNE) Diagram
Figure 34:
Epsilon Location
GND
GND 1
1
44
29
43
Command Connector
Pin #'s
Drive Faults
The Drive Faults Detected dialog box is automatically displayed whenever a fault occurs.
There are three options in this dialog box: Reset Faults, Ignore Faults and Help.
39
Epsilon Eb Digital Servo Drive Installation Manual
Figure 35:
Drive Faults Detected Dialog Box
Resetting Faults
Some drive faults are automatically reset when the fault condition is cleared. Others require
drive power to be cycled or the drive to be “rebooted” to be cleared. If you wish to continue
working in the PowerTools software without resetting the fault, click the Ignore Fault button.
To reset faults that can be reset with the Reset Faults button, simply click the Reset Faults
button in the Drive Faults Detected dialog box or push the Reset button on the front of the
drive where the fault occurred.
Viewing Active Drive Faults
To view all active drive faults, select the View Faults command from the Device menu. The
dialog box displayed is the same as Active Drive Faults dialog box described above.
Rebooting the Drive
To reboot the drive, cycle power or select the Reboot Drive command from the Device menu.
This command reboots the drive attached to the active Configuration Window.
Watch Window
This feature allows you to customize a window to monitor drive parameters which you select
from a complete list of drive parameters. From this window you can watch the parameters you
selected in real time. This feature is only available when you are online with the drive.
Note
You cannot change the values of the parameters while they are being displayed in the
Watch Window. The parameter in the setup screens will look like they have been changed
when they actually have not. To update a parameter, delete it from the Watch Window
selection.
40
Diagnostics and Troubleshooting
Note
It is normal to have the Watch Window show up with the three motor parameters already
selected if the motor parameters window has been accessed previously. If you do not need
to view them, simply push the Clear All button and select the parameters you wish to
view.
Figure 36:
Watch Window
The Watch Window is accessed by selecting Watch Drive Parameters from the Tools menu
or by clicking on the Watch Window icon on the toolbar.
The Watch Window will automatically appear as soon as you select a parameter from the
Select Drive Parameters dialog box. After you have selected the parameters you wish to
watch, click the Close button. The Select Drive Parameters dialog box will close and the
Watch Window will remain open.
Figure 37:
Select Drive Parameters Dialog Box
41
Epsilon Eb Digital Servo Drive Installation Manual
Group
This list box enables you to view the complete list of parameters or just a group of parameters
you are interested in. The groups include:
Analog Out
Fault Log
Setup
Communication
Home (FM-2 / Ei only)
Status
Digital Inputs
ID
Torque
Digital Outputs
Index (FM-2 / Ei only)
Tuning
Execution
Motor
User Def Motor
Fault Counts
Position
Velocity
Clear All Button
This button is used to clear all the parameter selections that were previously selected.
Save Selections Button
This button saves the parameter selections. This enables you to restore the same list of
parameters for use in future online sessions.
Restore Selections Button
This button restores the parameter selections previously saved. This enables you to restore the
list of parameters you created in a previous online session.
View Motor Parameters
When online with the drive this feature allows you to display a pre-defined Watch Window
to monitor three motor parameters. These parameters are normally used when testing the
setup of a User Defined Motor for commutation accuracy.
Figure 38:
View Motor Parameters Window
The View Motor Parameters window is accessed by selecting View Motor Parameters from
the Tools menu.
42
Epsilon Eb Digital Servo Drive Installation Manual
Options and Accessories
Epsilon Eb Digital Servo Drive
43
Epsilon Eb Digital Servo Drive Installation Manual
ECI-44 External Connector Interface
The ECI-44 allows access to all command and input and output signals. The ECI-44 should
be mounted close to the drive and away from any high voltage wiring. The ECI-44 comes
complete with the hardware necessary for mounting to most DIN rail mounting tracks.
Figure 39:
Dimensions of ECI-44
Note
Shield connection points are connected to the shell of the 44-pin “D” connector on the
ECI-44. Also, the shield connection points of the ECI-44 are also designed to provide a
point for cable strain relief.
Use tie wraps to provide a strain relief and a ground connection at the shield connection
points.
If you do not wish to use the DIN rail mounting hardware, the ECI-44 can be disassembled
and the mounting clips removed.
The ECI-44 wire range is #18 to 24 AWG stranded insulated wire.
Note
Wiring should be done with consideration for future troubleshooting and repair. All
wiring should be either color coded and/or tagged with industrial wire tabs. Low voltage
wiring should be routed away from high voltage wiring.
44
Options and Accessories
STI-EIO Interface
The STI-EIO interface allows access to all digital input and output signals. The STI-EIO
mounts directly to the J3 connector on the drive. See Figure 40 on 45.
Note
Shield connection points are connected to the shell of the 44-pin “D” connector on the
STI EIO.
The STI-EIO wire range is #18 to 24 AWG stranded insulated wire.
Note
Wiring should be done with consideration for future troubleshooting and repair. All
wiring should be either color coded and/or tagged with industrial wire tabs. Low voltage
wiring should be routed away from high voltage wiring.
Figure 40:
Dimensions of STI-EIO
45
Epsilon Eb Digital Servo Drive Installation Manual
Ext Encoder
Supply Output
+ 15 V, 10 mA
Pulse Input A, Single Ended
Pulse Input B, Single Ended
20
EN V+
NC2
NC1
(Connector shell
and strain relief
points)
Figure 41:
46
ECI-44 Signal Connections
Epsilon Eb Digital Servo Drive Installation
Manual
Specifications
Drive Specifications
Epsilon Series
Power Requirements
42 - 264 VAC, 1 Ø, 47 - 63 Hz
240 VAC for rated performance or 12 - 375 VDC when using an A.P.S. Logic Supply Input
and disabled Low DC Bus alarm.
Auxiliary Power Supply/
Auxiliary Logic Power Input
For logic backup, 24 VDC, 0.5A
Switching Frequency
20 kHz
Power Supply Output
5 VDC, 250 mA maximum for master encoder usage
Efficiency - Drive
Eb-202/203: 93% at full rated output power
Eb-205: 95% at full rated output power
Ingress Protection (IP) Rating
Drive: IP20
MG motors: IP65
NT motors: IP65/IP54
Molded motor and feedback cables: IP65
Serial Interface
RS-232 / RS-485
Internal RS-232 to RS-485 converter
Modbus protocol with 32 bit data extention
9600 or 19.2 k baud
Analog command: ±10 VDC 14 bit, 13 bit, 100 kohm impedance, differential
Control Inputs
Digital inputs: (5) 10-30 VDC, 2.8 kohm impedance; current sourcing signal compatible
(active high); max input response time is 500 µs; optically isolated
Input debounce: 0-2000 ms
Diagnostic analog outputs: (2) ±10 VDC (single ended, 20 mA max) 10 bit software
selectable output signals
Control Outputs
Digital outputs: (3) 10-30 VDC 150 mA max, current sourcing, (active high) optically
isolated: Input debounce: Programmable range, 0 to 200 ms
Motor temp sensor (analog): 0 to +5 VDC (single ended), 10 Kohm impedance
Interface: Software selectable differential (RS422) or single ended (TTL Schmitt Trigger)
Maximum input frequency: Differential - 2 MHz per channel; 50% duty cycle (8 MHz
count in quadrature)
Single ended - 1 MHz per channel; 50% duty cycle (4 MHz count in quadrature)
Pulse Mode
Ratio Capabilities: 20 to 163,840,000 PPR
Input Device = AM26C32
Vdiff = 0.1 - 0.2 V
V common mode max = +/- 7 V
Input impedance each input to 0 V = 12 - 17 kohm
47
Epsilon Eb Digital Servo Drive Installation Manual
Epsilon Series
Differential line driver, RS-422 and TTL compatible
Scalable in one line increment resolution up to 2048 lines/rev of the motor (MG and NT)
Encoder Output Signal
Shunt Resistor Capacity/
Regeneration Capacity
Output Device = AM26C31
20 mA per channel, sink and/or source
Vout Hi @ 20 mA = 3.8 - 4.5 V
Vout Lo @ 20 mA = 0.2 - 0.4 V
Vout diff w/100 ohm termination = 2.0 - 3.1 V
Vout common mode w/100 ohm termination = 0.0 - 3.0 V
Iout short circuit = 30 - 130 mA
Internal: At full speed, use full torque decel and 5:1 inertial load for Eb 202/203 with NT212 or Eb-205 with MG-340. Repetition frequency limited only by drive RMS capacity. No
internal shunt resistor.
External: Bus connection provided for external regeneration unit (EMC model RSR-2 with a
20 ohms resistor) 15 ARMS capacity.
Fault Detection Capability
Low DC bus (can be disabled)
High DC bus
Power Stage fault
Logic power
Encoder state
Encoder line break
Drive overtemperature
Motor over temperature
Overspeed
Travel limit (+)
Travel limit (-)
Pulse mode position error
Watchdog timer
Power-up self test failure
Non-volatile memory invalid
Cooling Method
Eb-202, Eb-203, Eb-205: Convection
Ambient temperature range for rated output: 32° F to 104° F (O° C to 40° C)
Maximum ambient operating temperature: 104° F to 122° F (40° C to 50° C) with power
derating of 3%/°C
Environmental
Rated altitude: 3,280 feet (1000 m)
Vibration: 10 - 2000 Hz at 2g
Humidity requirement: 10 - 95% non-condensing
Storage temperature: -13 °F to 167 °F (-25 °C to 75 °C)
Derating
Temperature:
Operation in ambient temperature over 50° C (122° F) not recommended.
Drive output power must be derated by 3 %/°C between 104° F to 122° F (40° C to 50° C)
Derating altitude: Above 3,280.8 ft (1000 m) reduce output by 1% per 328.08 ft (100 m)
Standards and Agency Approvals
48
UL listed
Canadian UL listed
CE Mark: Low voltage directive; EMC directive
Specifications
Epsilon Series
Eb-2023.3 lb (1.5 kg)
Eb-2033.3 lb (1.5 kg)
Eb-2053.7 lb (1.7 kg)
Amplifier Weights
*Add 1 lb for shipping.
Drive and Motor Combination Specifications
Drive
Motor
Cont.
Torque
lb-in
(Nm)
Peak
Torque
lb-in
(Nm)
Power
HP @
Rated
Speed
(kWatts)
Inertia
lb-in-sec2
(kg-cm2)
Max
speed
RPM
MG-205
5
(0.56)
13.5
(1.53)
0.31
(0.23)
0.000084
(0.95)
5000
2048
28.3
4.1
(0.46)
MG-208
6.7
(0.76)
13.2
(1.49)
0.53
(0.4)
0.000144
(0.163)
5000
2048
28.3
4.1
(0.46)
NT-207
7.3
(0.82)
15.2
(1.72)
0.45
(0.34)
0.000094
(0.1063)
5000
2048
35
5.124
(0.58)
NT-212
9.2
(1.04)
18
(2.03)
0.71
(0.53)
0.000164
(0.185)
5000
2048
34.7
5.08
(0.57)
MG-205
5
(0.56)
15.0
(1.69)
0.31
(0.23)
0.000084
(0.95)
5000
2048
28.3
4.1
(0.46)
MG-208
9.1
(1.03)
20
(2.26)
0.58
(0.43)
0.000144
(0.163)
5000
2048
28.3
4.1
(0.46)
MG-316
15.8
(1.79)
31.8
(3.59)
1.0
(0.75)
0.000498
(0.562)
4000
2048
37.6
5.5
(0.62)
NT-212
12.5
(1.41)
27
(3.05)
0.8
(0.6)
0.000164
(0.185)
5000
2048
34.7
5.08
(0.57)
NT-212
12.5
(1.41)
30
(3.4)
0.8
(0.6)
0.00164
(0.185)
5000
2048
34.7
5.08
(0.57)
MG-316
18.6
(2.1)
52
(5.9)
1.00
(0.75)
0.000498
(0.562
4000
2048
37.6
5.5
(0.62)
MG-340
39.5
(4.5)
83
(9.4)
1.8
(1.4)
0.00125
(1.414)
3000
2048
55
8.0
(0.90)
Eb-202
Eb-203
Eb-205
Encoder
Motor Ke
resolutio
VRMS/
n
krpm
lines/rev
Motor Kt
lb-in/
ARMS
(Nm/
ARMS)
49
Epsilon Eb Digital Servo Drive Installation Manual
Motor Brake Specifications
Motor
Holding Torque
lb-in (Nm)
Added Inertia
lb-in-sec2 (kg-cm2)
Added Weight
lb (kg)
MGE-2XXCB
10
(1.13)
0.000025
(0.0282)
1.8
(0.55)
MGE-316CB
MGM-340CB
50
(5.6)
0.00015
(0.1693)
2.4
(1.1)
MGE/M-455CB
MG-490CB
MG-4120CB
220
(24.9)
0.000412
(0.4652)
5.8
(2.6)
Motor
Coil Voltage (VDC)
Coil Current (Amps)
Mechanical
Disengagement Time
Mechanical
EngagementTime
MGE-2XXCB
24 (±10%)
0.48 (±10%)
25 ms
40 ms
MGE-316CB
MGM-340CB
24 (±10%)
0.52 (±10%)
100 ms
250 ms
MGE/M-455CB
MG-490CB
MG-4120CB
24 (±10%)
0.88 (±10%)
100 ms
250 ms
Motor Weights
50
Motor
Weight lb (kg) without Brake
Weight lb (kg) with Brake
MGE-205
3.0 (1.36)
N/A
MGE-208
4.0 (1.8)
5.8 (2.6)
MGE-316
8.3 (3.8)
10.7 (4.9)
MGE/M-340
14.6 (6.6)
17.0 (7.7)
MGE/M-455
18.5 (8.4)
24.3 (11.0)
MGE/M-490
27.0 (12.3)
32.8 (14.9)
MGE/M-4120
38.0 (17.3)
43.8 (19.9)
NT-207
3 (1.36)
N/A
NT-212
4 (1.81)
N/A
Specifications
Axial/Radial Loading
Figure 42:
Motor
Max Radial Load (lb.)
Max. Axial Load (lb.)
MGE-205
20
15
MGE-208
20
15
MGE-316
40
25
MGM-340
40
25
MGE/M-455
100
50
MGE/M-490
100
50
MGE/M-4120
100
50
Axial/Radial Loading
IP Ratings
Motor
Rating
MG (all)
IP65
NT-207
IP65
NT-207 (w/o seals)
IP54
NT-212
IP65
NT-212 (w/o seals)
IP54
51
Epsilon Eb Digital Servo Drive Installation Manual
Encoder Specifications
Motor
Density
Output Type
Output
Frequency
Output Signals
Power Supply
MG
and NT
2048
lines/rev
RS422
differential
driver
250 kHz
per channel
A, B, Z, Comm U,
Comm W, Comm V
and all complements
5V, 200 mA
±10%
Power Dissipation
In general, the drive power stages are 90 to 95 percent efficient depending on the actual point
of the torque speed curve the drive is operating. Logic power losses on the Epsilon drive are
11 W with normal loads to 15 W with additional loads such as external encoder and low input
voltage (<22 VDC on A.P.S. or 120 VAC on AC input).
The values shown in the table below represent the typical dissipation that could occur with
the drive/motor combination specified at maximum output power.
Logic Power Losses (typ)
Drive (Pld) (Watts)
Maximum Power Stage
Losses (Pp) (Watts)
Total Power Losses (Watts)
Eb-202 / MG-205
25
36
Eb-202 / NT-207
25
36
Eb-202 / NT-212
30
41
Eb-203 / NT-207
30
41
55
66
Drive Model
Eb-203 / MG-208
Eb-203 / NT-212
11
55
66
Eb-203 / MG-316
60
71
Eb-205 / NT-212
55
66
Eb-205 / MG-316
72
83
Eb-205 / MG-340
88
99
Power Dissipation Calculation
Calculating actual dissipation requirements in an application can help minimize enclosure
cooling requirements, especially in multi-axis systems. To calculate dissipation in a specific
application, use the following formula for each axis and then total them up. This formula is a
generalization and will result in a conservative estimate for power losses.
TPL =
Where:
52
TRMS * Vmax
+ Pld + Psr
1500
Specifications
TPL = Total power losses (Watts)
TRMS = RMS torque for the application (lb-in)
Vmax = Maximum motor speed in application (RPM)
Pld = Logic Power Losses Drive (Watts)
Psr = Shunt Regulation Losses (Watts)-(RSR-2 losses or equivalent)
Note
TRMS * Vmax / 1500 = Power Stage Dissipation = Pp
A more accurate calculation would include even more specifics such as actual torque
delivered at each speed plus actual shunt regulator usage. For help in calculating these please
contact our Application Engineering department with your system profiles and loads.
Speed Torque Curves
Continuous ratings of the MG and NT motors are based on 100°C (212° F) motor case
temperature and 25°C (77° F) ambient temperature with the motor mounted to an aluminum
mounting plate as shown in the table below.
Motor
Mounting Plate Size
MG-205 and 208, NT-207 and 212
6” x 6” x .25”
MG-316 through 490
10” x 10” x .375
MG-4120
12” x 16” x .5”
•
Speed torque curves are based on 240 VAC drive operation.
•
All specifications are ±5 percent due to motor parameter variations.
53
Epsilon Eb Digital Servo Drive Installation Manual
Figure 43:
54
Epsilon Speed Torque Curves, sheet 1 of 2
Specifications
Figure 44:
Epsilon Speed Torque Curves, sheet 2 of 2
55
Epsilon Eb Digital Servo Drive Installation Manual
Epsilon Drive Dimensions: Eb 202, Eb-203, Eb-205
The following table applies to A* and B* as shown in Figure 45.
Drive Model
Dimension A* (shown in inches/mm)
Dimension B* (shown in inches/mm)
Eb-202
2.10 [53.3]
.45 [11.4]
Eb-203
2.10 [53.3]
.45 [11.4]
Eb-205
3.56 [90.42]
.7 [17.78]
Figure 45:
56
Drive Dimesions Eb-202, Eb-203, Eb-205
Specifications
MG Motor Dimensions
MGE-205 and 208 Motors
MGE-205 and 208 Mounting Dimensions inches (mm)
AG
A
BC
AH
U
Max
XD
S Min
205
5.60
(143.0
)
2.25
(57.2)
.46
(11.2)
1.20
(30.5)
.375
(9.525
)
.563
(14.3)
.127
(3.23)
208
6.75
(171.4
)
2.25
(57.2)
.46
(11.2)
1.20
(30.5)
.375
(9.525
)
.563
(14.3)
.127
(3.23)
MGE-205 and 208 Mounting Dimensions inches (mm)
R
C Max
AJ
BB
AK
BF
205
0.300
(7.62)
2.0
(51)
2.625
(66.68)
.063
(1.60)
1.502
(38.15)
.205
(5.21)
208
0.300
(7.62)
2.0
(51)
2.625
(66.68)
.063
(1.60)
1.502
(38.15)
.205
(5.21)
57
Epsilon Eb Digital Servo Drive Installation Manual
MGE-316 and 340 Motors
MGE-316, MGM-316, and MGM-340 Mounting Dimensions
inches (mm)
AG
A
BC
AH
U Max
XD
316
E
7.24
(184.0)
3.31
(84.0)
.44
(11.2)
1.21
(30.7)
.4997
(12.69)
.90
(22.9)
316
M
7.24
(183.9)
3.50
(89.0)
0.44
(11.2)
1.20
(30.5)
.5512
(14.00)
0.79
(20.0)
340
10.24
(260.1)
3.50
(89.0)
.44
(11.2)
1.20
(30.6)
.5512
(14.000)
.787
(20.0)
MGE-316, MGM-316, and MGM-340 Mounting Dimensions
inches (mm)
58
S Min
R
C
Max
AJ
BB
AK
BF
316
E
.1265
(3.213
)
.42
(10.7)
2.50
(64.0)
3.875
(98.43)
.06
(1.600
)
2.877
(73.08
)
.233
(66.0
)
316
M
0.20
(5.08)
0.43
(10.9)
2.5
(64.0)
3.937
(108.0)
0.12
(3.0)
3.15
(80.0)
.276
(7.01
)
340
.197
(5.00)
.429
(10.90
)
2.50
(64.0)
3.937
(100.00
)
.118
(3.00)
3.150
(80.01
)
.276
(7.01
)
Specifications
MGE-455, 490 and 4120 Motors
MGE-455, 490 and 4120 Mounting Dimensions inches (mm)
AG
A
BC
AH
U Max
XD
S Min
455
8.61
(218.7)
5.00
(127.0
)
.53
(13.5
)
190
(48.2
)
.6245
(15.862
)
1.50
(38.1
)
.1875
(4.763
)
490
11.11
(282.10
)
5.00
(127.0
)
.53
(13.5
)
190
(48.2
)
.8750
(22.225
)
1.50
(38.1
)
.1875
(4.763
)
4120
13.61
(345.70
)
5.00
(127.0
)
.53
(13.5
)
190
(48.2
)
.8750
(22.225
)
1.50
(38.1
)
.1875
(4.763
)
MGE-455, 490 and 4120 Mounting Dimensions inches (mm)
R
C Max
AJ
BB
AK
BF
455
.51
(13.0)
3.20
(81.3)
5.875
(149.23)
.10
(2.50)
4.500
(114.30)
3/8-16
UNC
490
.77
(19.6)
3.20
(81.3)
5.875
(149.23)
.10
(2.50)
4.500
(114.30)
3/8-16
UNC
4120
.77
(19.6)
3.20
(81.3)
5.875
(149.23)
.10
(2.50)
4.500
(114.30)
3/8-16
UNC
59
Epsilon Eb Digital Servo Drive Installation Manual
MGM-455, 490 and 4120 Motors
MGE-455, 490 and 4120 Mounting Dimensions mm (inches)
AG
A
BC
AH
U Max
XD
S Min
455
216.0
(8.59)
121.0
(4.764
)
13.0
(.51)
50.5
(1.99
)
19.000
(.7480)
40.0
(1.58
)
6.00
(.236)
490
281.7
(11.09)
121.0
(4.764
)
13.0
(.51)
50.5
(1.99
)
24.000
(9.449)
37.1
(1.46
)
7.963
(.3135
)
4120
343.1
(13.59)
121.0
(4.764
)
13.0
(.51)
50.5
(1.99
)
24.000
(9.449)
37.1
(1.46
)
7.963
(.3135
)
MGE-455, 490 and 4120 Mounting Dimensions mm (inches)
60
R
C Max
AJ
BB
AK
BF
455
15.5
(.61)
70.3
(2.77)
145.00
(5.709)
3.00
(.118)
110.10
(4.331)
10.00
(.394)
490
19.9
(.78)
70.3
(2.77)
145.00
(5.709)
3.00
(.118)
110.10
(4.331)
10.00
(.394)
4120
19.9
(.78)
70.3
(2.77)
145.00
(5.709)
3.00
(.118)
110.10
(4.331)
10.00
(.394)
Specifications
NT Motor Dimensions
NTE-207 Motors; English Face (NEMA 23 with 3/8 inch shaft)
Note
Mounting ears have clearance for #10 or M5 Allen head screw or .3125" or 8mm across
flat hex nut.
61
Epsilon Eb Digital Servo Drive Installation Manual
NTM-207 Motors; Metric Face
Note
Mounting ears have clearance for #10 or M5 Allen head screw or .3125" or 8mm across
flat hex nut.
62
Specifications
NTE-212 Motors; English Face (NEMA 23 with 3/8 inch shaft)
Note
Mounting ears have clearance for #10mm or M5 Allen head screw or .3125" or 8mm
across flat head screw.
63
Epsilon Eb Digital Servo Drive Installation Manual
NTM-212 Motors; Metric Face
Note
Mounting ears have clearance for 10mm across flat hex nut or 13mm O.D. washer.
64
Specifications
Cable Diagrams
CMDX, CMDO, ECI44
CDRO
AX4-CEN
Analog In +
X
X
X
Analog In -
X
X
X
Encoder Out A
X
X
X
Drive Signal
Encoder Out A/
X
X
X
Encoder Out B
X
X
X
Encoder Out B/
X
X
X
Encoder Out Z
X
X
X
X
Encoder Out Z/
X
X
Pulse In A
X
X
Pulse In A/
X
X
Pulse In B
X
X
Pulse In B/
X
X
Pulse In Z
X
Pulse In Z/
X
Pulse In A (single ended)
X
Pulse In B (single ended)
X
I/O Input Drive Enable
X
I/O Input #1
X
I/O Input #2
X
I/O Input #3
X
I/O Input #4
I/O Output #1
I/O Output #2
X
X
X
X
X
X
X
X
X
X
X
X
X
I/O Output #3
X
X
X
I/O Power + In (1st wire)
X
X
X
I/O Power + In (2nd wire)
X
X
X
I/O Power 0V In (1st wire)
X
X
X
I/O Power 0V In (2nd wire)
X
Analog Out 0V
X
X
X
Analog Out #1 +
X
X
X
Analog Out #2 +
X
X
X
External Encoder +5 Power Out (200
ma)
X
X
X
+15V Power Out (10 ma)
X
RS-485 +
X
RS-485 -
X
65
Epsilon Eb Digital Servo Drive Installation Manual
CMDX-XXX Cable
Note
Some CMDX cables may have White/Yellow and Yellow/White wires in place of the
White/Orange and Orange/White shown in the figure above (pins 6 and 21).
66
Specifications
CMDO-XXX Cable
Note
Some CMDO cables may have White/Yellow and Yellow/White wires in place of the
White/Orange and Orange/White shown in the figure above (pins 6 and 21).
67
Epsilon Eb Digital Servo Drive Installation Manual
CDRO-XXX Cable
68
Specifications
AX-CEN-XXX Cable
69
Epsilon Eb Digital Servo Drive Installation Manual
EIO-XXX Cable
Input #1
Drive Enable Input
Input #3
Input #2
Input #5
Input #4
Input #7
Input #6
Input #9
Input #8
Input #11
Input #10
Output #1
Output #2
Output #5
Input #12
Output #3
Output #4
I/O +V
I/O Common
N/C
N/C
N/C
N/C
Output #6
Output #7
TIA-XXX Cable
70
Specifications
DDS-XXX Cable
TERM-H (Head) Terminator
71
Epsilon Eb Digital Servo Drive Installation Manual
TERM-T (Tail) Terminator
Note
See “Multi-Drop Communications” on page 31 for resistor values.
CMDS-XXX Cable
CMMS-XXX Cable
72
Specifications
CFCS-XXX Cable
73
Epsilon Eb Digital Servo Drive Installation Manual
CFCO-XXX Cable
74
Specifications
CFOS-XXX Cable
75
Epsilon Eb Digital Servo Drive Installation Manual
Vendor Contact Information
Schaffner (AC Line Filters)
(800) 367-5566 or (201) 379-7778
www.schaffner.com
Cooper Industries, Inc.
Crouse-Hinds Division (Cable Shield Grommets)
(315) 477-5531
www.crouse-hinds.com
76
Bussman
P.O. Box 14460
St. Lois, MO. 63178-4460
(314) 394-3877
www.bussman.com
Littelfuse
800 E. Northwest Hwy
Des Plaines, IL. 60016
(847) 824-0400
www.littelfuse.com
Wickmann USA
4100 Shirlel Dr.
Atlanta, GA. 30336
(404) 699-7820
www.wickmann.com
Corcom
844 E. Rockland Road
Libertyville, IL 60048
(847) 680-7444
www.corcom.com
Epsilon Eb Digital Servo Drive Installation
Manual
Index
A
AC Line Filter Installation Notes, 5
AC Line Filters, 5
AC Supplies NOT Requiring Transformers, 10
AC Supplies Requiring Transformers, 11
Achieving Low Impedance Connections, 4
Analog Command Wiring, 25
AX-CEN-XXX Cable, 69
Axial/Radial Loading, 51
C
Cable Diagrams, 65
Cable to Enclosure Shielding, 6
CDRO-XXX Cable, 68
CFCO-XXX Cable, 74
CFCS-XXX Cable, 73
CFOS-XXX Cable, 75
CMDO-XXX Cable, 67
CMDS-XXX Cable, 72
CMDX-XXX Cable, 66
CMMS-XXX Cable, 72
Command Cables, 24
Command Connector Wiring, 22
D
DDS-XXX Cable, 71
Declaration of Conformity, x
Diagnostic Analog Output Test Points, 38
Diagnostic Cable (DGNE) Diagram, 39
Diagnostic Display, 33
Diagnostics and Troubleshooting, 33
Drive and Motor Combination Specifications, 49
Drive Enable Wiring, 21
Drive Mounting, 8
Drive overload protection, ix
Drive Specifications, 47
E
ECI-44 External Connector Interface, 44
EIO-XXX Cable, 70
Electrical Installation, 9
Electromagnetic Compatibility, 3
EMC, 3
Encoder Output Signal Wiring, 26
Encoder Specifications, 52
Environmental Considerations, 7
F
Fault Codes, 34
Fault Descriptions, 35
Feature Location, 2
Features, 1
I
Input Power Connections, 15
Input/Output, 21
Installation, 3
Installation Notes, 3
Introduction, 1
IP Ratings, 52
77
Epsilon Eb Digital Servo Drive Installation Manual
L
Pulse Mode Wiring, 27
Line Fusing, 14
R
M
Rebooting the Drive, 40
Resetting Faults, 40
Mechanical Installation, 8
MG Motor Dimensions, 57
MGE-205 and 208 Motors, 57
MGE-316 and 340 Motors, 58
MGE-455, 490 and 4120 Motors, 59, 60
Modbus Communications, 31
Motor Brake Specifications, 50
Motor Brake Wiring, 19
Motor Feedback Wiring, 19
Motor Mounting, 8
Motor Power Wiring, 18
Motor Weights, 50
Multi-Drop Communications, 31
N
NT Motor Dimensions, 61
NTE-207 Motors, 61
NTE-212 Motors, 63
NTM-207 Motors, 62
NTM-212 Motors, 64
O
Options and Accessories, 43
P
Power Dissipation, 52
Power Dissipation Calculation, 52
Power Supply Requirements, 10
78
S
Safety Considerations, vii
Safety Precautions, vii
Serial Communications, 30
Specifications, 47
Speed Torque Curves, 53
STI-EIO, 45
T
TERM-H (Head) Terminator, 71
TERM-T (Tail) Terminator, 72
TIA-XXX Cable, 70
Transformer Sizing, 13
U
Underwriters Laboratories Recognition, ix
V
Vendor Contact Information, 76
View Motor Parameters, 42
Viewing Active Drive Faults, 40
Index
W
Watch Window, 40
Wire Size, 14
Wiring Notes, 8
79
Epsilon Eb Digital Servo Drive Installation Manual
80
Since 1979, the “Motion Made Easy” products, designed and manufactured in
Minnesota U.S.A., are renowned in the motion control industry for their ease of
use, reliability and high performance.
For more information about Control Techniques “Motion Made Easy” products
and services, call (800) 397-3786 or contact our website at
www.emersonct.com.
Control Techniques Drives, Inc
Division of EMERSON Co.
12005 Technology Drive
Eden Prairie, Minnesota 55344
U.S.A.
Customer Service
Phone: (952) 995-8000 or (800) 397-3786
Fax: (952) 995-8129
Technical Support
Phone: (952) 995-8033 or (800) 397-3786
Fax (952) 9995-8020
Printed in U.S.A.
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