Anaheim Stepper MBL600 Users Guide

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MBL600
Bilevel Step Motor Driver
User’s Guide
910 East Orangefair Lane, Anaheim, CA 92801
e-mail: [email protected](714) 992-6990  fax: (714) 992-0471
website: www.anaheimautomation.com
ANAHEIM AUTOMATION 
						

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General Description
The ANAHEIM AUTOMATION MBL600 is an improved version of the MBL628-B series step motor drivers.  
The MBL600 with it compactness and attractive rugged package style employs bilevel (or dual voltage) 
drive technique for high performance operation of step motors providing signifi cantly improved motor speed 
torque output.  New features include selectable “+” or “-” going clock inputs,  transient voltage protection, 
and improved Full-step operation.
Bilevel Drive
The basic function of a step motor driver is to control the motor winding currents.  Motor performance is 
determined by how fast the driver can increase and decrease the winding currents.  A rapid rise in winding 
current is achieved by applying a high voltage directly to a motor.  This rapid rise of current is also referred 
to as the “kick” or operating current.  When a desired current level is reached, a low voltage is applied to 
maintain a suitable holding current level.  When a motor winding is turned off, a rapid decrease in winding 
current is achieved by routing the energy in the collapsing fi eld back to the power supply through a high 
voltage path.  The high voltage supply furnishes the energy necessary to maintain motor output torque at 
high step rates thus providing high mechanical power output.  The low voltage supply provides much of 
the current needed at low step rates and all of the holding current.
Excitation Mode Option
Users have a choice of dual-phase, full-step operation or half-step operation.  Dual-phase, full-step opera-
tion occurs by energizing two phases at a time, rotating a typical motor 1.8° per step.  Half-step operation 
occurs by alternately energizing one, and then two, phases at a time, rotating the motor 0.9° per step.  
Half-step is the recommended mode of operation.  Full-Step operation is only suggested for applications 
that specifi cally require that mode, such as when retrofi tting existing full-step systems.
Step and Direction Control
The MBL600 has two clock options: Clock and Direction, or Dual Clock operation.  Terminal 5 can be 
confi gured as the Direction Input or CCW Clock Input by placing jumper JP1 in the appropriate position 
(see Table 1 and Figure 2).  Pulses applied to the Clock Input cause the motor to step in the clockwise 
direction if the Direction Input is a logic “1”, or the counterclockwise direction if the Direction Input is a 
logic “0”.  Pulses applied to the CCW Input cause the motor to step in the counterclockwise direction.  
Either positive or negative going pulses may be used by setting JP2 to the appropriate position (SeeTable 
1 and Figure 2).
MBL600 Features
• 10 Amperes/Phase Maximum Operating Current
• 7 Amperes/Phase Standstill Motor Current
• Half-Step and Full-Step Operation
• Bilevel Drive Operation
• No RFI or EMI Problems 
• TTL/CMOS Compatible Inputs
• Clock and Direction or Dual Clock Operation
• Motor Turn-Off Input
• Compact and Rugged 
						

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Motor ON/OFF Option
The Motor ON/OFF option allows de-energizing a motor without disturbing the positioning logic.  After 
reenergizing the motor, a routine can continue.  This reduces  motor heating and conserves power,  es-
pecially in applications where motors are stopped for long periods and no holding torque is required.
Motor Connections
Hookup diagrams for a motor driver application are presented in Figure 3 and 4.  Wiring connected to input 
must be separated from motor connections and all other possible sources of interference.
IMPORTANT NOTE: When the wiring from the driver to the step motor extends beyond 25feet, consult 
the factory.
Transient Voltage Suppression 
Transient Voltage Suppression (TVS) Diodes on the motor phase outputs allow for much longer motor cables 
to be used.  Normally when using long motor cables, voltage transients and spikes are created.  These 
transient often exceed the voltage ratings of the output phase transistors, resulting in blown transistors. 
The addition of the TVS Diodes suppresses these transients and protect the transistors against damage.
Determining Low-Voltage Supply Level
The Low Voltage (Vlv) supply furnishes the current necessary for holding (standstill) torque and low-speed 
running torque.  Table 2 shows the current ranges for all compatible Anaheim Automation motors.  Higher 
values for the Low Voltage will produce more holding and low-speed torque.  A proper Vlv will produce a 
standstill current that is 65 to 100% of the rated motor current (i.e. for a motor rated at 1 amp, Vlv should 
be set so that the standstill current is 0.65 to 1 amps).
Verifying Standstill Motor Current
To check the standstill current do the following:
1.  Apply power to the driver with motor connected, but do not apply clock pulses.
2.  Select Full-Step mode (ground terminal 8 to 0V).  This will assure that two phases will be on.
3.  Measure the voltage across resistors R1 and R2.
4.  Multiply the readings by 20 to calculate the standstill current.  (i.e. if the voltage across R1 and 
R2 reads 0.250V, the standstill current is 0.250x20=5.00Amps)
Determining High-Voltage Supply Level
The high-voltage supply (Vhv) can range from 24VDC to 70VDC.  VHV determines high-speed torque 
performance and acceleration.
Adjusting Kick Current
By following the silkscreen instructions on the cover of the MBL600 driver, use a small screwdriver to 
adjust the potentiometer. Line up the arrow to the number corresponding to the motor’s rated current 
(amps/phase). 
						

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Jumper Functions/Locations
Function JP1 JP2
Terminal 5 = Direction 2 - 3 X
Terminal 5 = CCW 1 - 2 X
Positive Going Clocks X 2 - 3
Negative Going Clocks X 1 - 2
Standard Product 2 - 3 2 - 3
Torque Speed Curves
Torque curves are shown on the back of this specifi cation sheet.  This data was obtained using a high 
voltage (Vhv) of approximately 60VDC no load.  The low voltage (Vlv) used was an unregulated voltage 
of about 5VDC no load.  Both voltages dropped when loaded.
To obtain more torque at high speeds, Vhv should be increased.  To obtain more torque at standstill and 
low speeds, Vlv should be increased but the motor current at standstill should not exceed the motor’s 
rated current.
Table 1: Jumpers Settings    X=Don’t Care
Motor 
Part 
NumberCurrent 
Rating
(Amps)VLV Range
23D102 1.0 4.5V - 7.0V
23D104 2.0 3.5V - 5.2V
23D108 3.9 2.5V - 3.3V
23D204 1.8 4.1V - 6.2V
23D209 4.7 2.7V - 3.7V
23D306 2.9 4.0V - 5.9V
23D309 4.6 3.2V - 4.5V
34D106 3.0 3.3V - 4.8V
34D109 4.8 2.7V - 3.8V
34D207 3.5 4.0V - 6.2V
34D209 4.6 3.3V - 4.7V
34D213 6.8 3.2V - 4.5V
34D307 3.5 4.0V - 6.0V
34D311 5.5 3.6V - 5.3V
34D314 7.0 3.4V - 4.9V
42D112 6.1 2.9V - 4.0V
42D212 6.1 4.1V - 6.1V
Table 2: Low Voltage Values for 
Anaheim Automation Step Motors.
Dimensions 
						

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Wiring Diagrams 
						

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Specifi cations
Control Inputs:
TTL-Compatible
Logic “0” - 0 to 0.8V
Logic “1” - 3.5 to 5.0V
Clock Inputs: (Terminals 5 & 6)
Pulse Required; 15 microseconds minimum.  The clock input is pulled up internally to +5VDC through a 
10K Ù resistor for negative going clock inputs or pulled down to 0VDC through a 10K Ù resistor for posi-
tive going clock inputs. 
Direction Control: (Terminal 5)
Logic “1” (open) - Clockwise
Logic “0” - Counterclockwise
Excitation Mode Select: (Terminal 8)
Logic “1” - Half-Step
Logic “0” - 2 ö Full-Step
Power ON/OFF: (Terminal 9)
Logic “1” (open) - Motor current on
Logic “0” - Motor current off
Output Current Rating: (Terminals 1, 2, 3, 11, 12 & 13)
6.5Amps per Phase, maximum, over the operating voltage and temperature range.  Motor phase ratings 
of 1.0 Amp minimum are required to meet the minimum kick level.
Power Requirements:
Low-voltage supply (Vlv) typically ranges between 3.5 and 6.5VDC.  The maximum allowable low-voltage 
is 10VDC (See paragraph DETERMINING LOW-VOLTAGE SUPPLY LEVEL)
High-Voltage supply (Vhv) is 55VDC nominal, 10VDC minimum and, 70VDC maximum.  (See paragraph  
DETERMINING HIGH-VOLTAGE SUPPLY LEVEL).
Operating Temperature: (0 to 60°C)
It is recommend that the unit be mounted on a larger aluminum plate, or similar heat-conducting structure, 
whenever possible.  This will prevent the driver from overheating and degrading driver reliability.  Fan 
cooling is also recommended whenever possible.
The MBL600 requires a power supply kit.  Consult the factory for the best driver, power supply and motor 
application.
Anaheim Automation offers a color-coded cable for easy step motor hookups.. This 16 gauge, 6 
conductor cable is PVC insulated, with color-coded conductors; the same color as the leads on 
Anaheim Automation step motors (red, red/white, green, green/white, black and white).  The cable 
is shielded, and available in 25 feet increments, Part Number AA129010-S 
						

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ANAHEIM AUTOMATION
COPYRIGHT 
Copyright 2013 by Anaheim Automation. All rights reserved. No part of this publication may be reproduced, 
transmitted, transcribed, stored in a retrieval system, or translated into any language, in any form or by 
any means, electronic, mechanical, magnetic, optical, chemical, manual, or otherwise, without the prior 
written permission of Anaheim Automation, 910 E. Orangefair Lane, Anaheim, CA 92801. 
DISCLAIMER
Though every effort has been made to supply complete and accurate information in this manual, the 
contents are subject to change without notice or obligation to inform the buyer. In no event will Anaheim 
Automation be liable for direct, indirect, special, incidental, or consequential damages arising out 
of the use or inability to use the product or documentation.  
Anaheim Automation’s general policy does not recommend the use of its’ products in life support applications 
wherein a failure or malfunction of the product may directly threaten life or injury.  Per Anaheim Automation’s 
Terms and Conditions, the user of Anaheim Automation products in life support applications assumes all 
risks of such use and indemnifi es Anaheim Automation against all damages.
LIMITED WARRANTY
All Anaheim Automation products are warranted against defects in workmanship, materials and construction, 
when used under Normal Operating Conditions and when used in accordance with specifi cations.  This 
warranty shall be in effect for a period of twelve months from the date of purchase or eighteen months 
from the date of manufacture, whichever comes fi rst. Warranty provisions may be voided if products 
are subjected to physical modifi cations, damage, abuse, or misuse.
Anaheim Automation will repair or replace at its’ option, any product which has been found to be defective 
and is within the warranty period, provided that the item is shipped freight prepaid, with previous authorization 
(RMA#) to Anaheim Automation’s plant in Anaheim, California. 
TECHNICAL SUPPORT
If you should require technical support or if you have problems using any of the equipment covered by this 
manual, please read the manual completely to see if it will answer the questions you have. If you need 
assistance beyond what this manual can provide, contact your Local Distributor where you purchased the 
unit, or contact the factory direct.