Anaheim Stepper DPD60001 Users Guide

							USERS MANUAL 
MODEL DPD60001
MICROSTEP DRIVER PACK  
ANAHEIM AUTOMATION
910 E. Orangefair Lane
Anaheim, CA 92801
TEL (714) 992-6990
FAX (714) 992-0471
http://www.anaheimautomation.com
e-mail: [email protected]
May 1997 #L010024COPYRIGHT
Copyright 1997 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 indemnifies 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 specifications.  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 first.
Warranty provisions may be voided if the products are subjected to physical
damage or abuse.
    
Anaheim Automation will repair or replace at its option, any of its products
which have been found to be defective and are within the warranty period,
provided that the item is shipped freight prepaid, with RMA (return material
authorization), to Anaheim Automations plant in Anaheim, California.
TECHNICAL SUPPORT
Should you have problems using the equipment covered by this manual, please
read the manual to see if it will answer the questions you have.  If you need
assistance beyond what this manual can provide, contact your Local
Distributor,or Anaheim Automation direct..
For complete terms of sales, please see Anaheim Automation’s published Terms and
Conditions. 
						

							12TABLE OF CONTENTSINTRODUCTION   
PAGE
INTRODUCTION............................2
ORDERING INFORMATION......................3
DESCRIPTION .............................5
DRIVER TERMINAL  DESCRIPTION .......5
POTENTIOMETER SETTINGS............5
SPECIFICATIONS......................6
 OUTPUT CURRENT.........................7
DETERMINING OUTPUT CURRENT.......7
SETTING OUTPUT CURRENT............7
REDUCING OUTPUT CURRENT.......... 8
MOTOR SELECTION ........................9    
STEP MOTOR CONFIGURATION.........9
STEP MOTOR CONNECTION...........11
ANAHEIM AUTOMATION 
STEP MOTOR SELECTION ..................12
MICROSTEP SELECTION ...................13
OPTICALLY  ISOLATED INPUTS  .............14
TIMING...................................14
FAULT PROTECTION.......................15
TORQUE/SPEED CURVES...................16The DPD60001 is a high performance, low cost MICROSTEP Driver Pack that
incorporates advanced surface mount and ASIC technology.  The DPD60001
is compact, easy to interface, and powerful enough to handle the most
demanding applications. Recognizing that cost and size are important criteria
in many low and medium power applications, Anaheim Automation designed
the DPD60001  to meet those needs and offer innovative features. 
The DPD60001 will deliver a peak current of 5.5 Amperes per phase at 75
Volts, providing outstanding motor performance. This advanced technology
reduces ripple current while maintaining the 20kHz chopping frequency in the
motor, causing less heat in both the motor and drive. 
Various step resolutions can be implemented by the on-board dip switches.
These divisions range from 400 steps per revolution to 51,200 steps per
revolution, and are available in both binary and decimal numbers.  The bipolar
drive configuration handles 4, 6 and 8 lead motors.  Protection devices have
been added to this driver for All-Way-Short-Circuit, Over/Under Voltage, and
Excessive-Temperature conditions.  If an error (short-circuit or excessive-
temperature) occurs,  a ‘Fault Output’ is available to  inform the machine
control of a problem.  An ‘At Full Step’ output enables the control to know when
the motor is positioned in one of the natural step angles of the motor (typically
every 1.8°).
Driver Pack features include:
#Low Cost
#Small Size (6.0x 6.875x 5.1)
#Output Current 5.5 Amps Peak
#400 to 51,200 steps/rev
#Short Circuit Protection
#Excessive-Temperature Protection
#No Minimum Inductance
#Optical Isolation
#Integrated 200 Watt Power Supply 
						

							346 Amp Microstep Driver Packs     DPD60001     Driver Pack
4 Amp Microstep DriverMDM40001   Modular Driver
6 Amp Microstep DriverMDM60001   Modular Driver
10 Amp Microstep DriverMDM10001   Modular Driver
40VDC Power SupplyPSA40V4A    (For MDM40001)
40VDC Power SupplyPSA40V8A    (For MDM40001)
40VDC Power SupplyPSA40V8A-2 (For MDM40001)
65VDC Power SupplyPSA65V5A    (For MDM60001)
65VDC Power SupplyPSA65V5A-2 (For MDM60001)
80VDC Power SupplyPSA80V4A    (For MDM10001)
Shielded Motor CableAA129010S DPD60001 DIMENSIONS
ORDERING INFORMATION FOR ANAHEIM AUTOMATION
MICROSTEP DRIVERS AND ACCESSORIES 
Driver Pack features described on page 2.TERMINAL CONNECTION DESCRIPTIONS 
Pin#Description
1Phase 4: of the Step Motor
2Phase 2: of the Step Motor
3Phase 3: of the Step Motor
4Phase 1: of the Step Motor
5Clock: A negative going edge on this isolated input advances the motor
one increment. The size of the increment is dependent on the Microstep
Select Inputs of Switch 1.
6Direction: This isolated input is used to change the direction of the motor.
Logic High is CW and Logic Low is CCW.  Physical direction also
depends on the connection of the motor windings. 
70VDC: Supply Voltage Ground. ( Return )
8On/Off: This isolated input is used to enable/disable the output section of
the driver. When HIGH (open) the outputs are enabled. However, this
input does not inhibit the step clock. Therefore the outputs will be updated
by the number of clock pulses (if any) applied to the driver while it had
been disabled.
9Reset: When LOW, this isolated input will reset the driver (outputs will
disable). When released, the driver will be at its initial state.
10+5Volt: +5Vdc is supplied to users to power other external operations.
Table1: Terminal Block  CONNECTOR DESCRIPTIONS 
POTENTIOMETER  DESCRIPTIONS  
PotDescription
ReducedReduce Current: Phase Current Reduction.  This
 CurrentPOTENTIOMETER will proportionately reduce the current in
both windings (1 second after the last step).  The amount of
current reduction will depend on the potentiometer setting used.
(Refer to Table 3)  
RunningRunning (Adjust) Current: Phase Current Adjustment input. 
 CurrentThis POTENTIOMETER adjusts the maximum Phase Current
in the motor.
Table 2:  Running Current and Reduced Current  Potentiometers 
						

							56SPECIFICATIONS
ABSOLUTE MAXIMUM RATINGS 
INPUT VOLTAGE125 VAC
OUTPUT CURRENT6 AMPS PEAK
DRIVER PLATE TEMPERATURE70° C
STORAGE TEMPERATURE-40° TO +125° C
INPUT CURRENT (PINS 5,6,8,9)15 mA 
ELECTRICAL SPECIFICATIONS  (TA=25E EC, V+ = 75VDC)
ITEMTESTMINTYPMAXUNITS
CONDITION
Input Voltage105115125V
Phase Output CurrentRMS1    4A
Phase Output CurrentPeak1.46A
Quiescent Current Outputs Floating13mA
Active PowerIout=4 Amps9W
DissipationRMS
Input Sink Current Input Pins7mA
5,6,8,9
Input Forward Voltage1.41.7V
+5Vdc OutputOutput Pin 105V
+5Vdc OutputOutput Pin 1050mA
Input Reverse5V
Breakdown Voltage
Clock Pulse WidthOff Time215nS
Clock Pulse WidthOn Time50nS
Direction ChangeExecution Time100nS
Microstep SelectExecution Time100nS
Change
ResetPulse Width500nSDETERMINING OUTPUT CURRENT
The output current for the motor used when microstepping is determined
differently from that of a halfstep/fullstep unipolar driver.  In the DPD60001
Driver Pack, a sine/cosine output current is used in rotating the motor.  The
output current for a given motor is determined by the motors current rating and
the configuration for how the motor is hooked up.  The current adjustment
potentiometer (Running Current) is used to set the output current of the
DPD60001.  This sets the peak output current  of the sine/cosine waves.  The
specified motor current (which is the RMS value) is multiplied by a factor of 0.7,
1.0,  or 1.4 depending on the motor configuration (series, half-coil, or parallel).
SETTING OUTPUT CURRENT
The output current on the DPD60001 is set by the Running Current
Potentiometer.  
This resistance determines the per Phase Peak output current of the driver.
Running CurrentCurrent
Potentiometer Setting(Amps)
11.4
22
33
44
44.5
55
5.55.5
TABLE 3: Running Current Settings   
						

							78REDUCING OUTPUT CURRENTSTEP MOTOR CONFIGURATIONS
The amount of current per Phase in the reduction mode is related to the valueconfiguration requires different current settings. Different lead configurations
of the current adjustment potentiometer (Running Current) and the currentand the procedures to determine their output current are shown below .
reduction potentiometer (Reduced Current).  When the current reduction circuit
is activated, the Reduced Current resistance is paralleled with the Running
Current resistance.  This lowers the total resistance value, and thus lowers the6 Lead Motors 
selected Phase output current by a percentage. When configuring a 6 lead motor in a half-coil configuration (connected from
Pot1.4 AMPS2 AMPS3 AMPS4 AMPS5 AMPS5.5 AMPS
150%42%32%26%22%21%
261%53%43%36%31%30%
370%64%54%46%41%39%
475%70%61%54%48%46%
580%75%67%59%54%52%
682%78%71%64%58%56%
784%81%75%68%63%61%
886%84%77%71%66%64%
989%88%83%78%74%72%
TABLE 4: Percentage of I(peak) settings on Reduced Current Potentiometer
MOTOR SELECTION
The DPD60001 Driver Pack contains a bipolar Microstep driver working equally
well with 4, 6 or 8 Lead Step Motors ( Series, Half Coil, or Parallel Motor
Configurations respectively).
Motors with low current ratings and high inductance will perform better at low
speeds, providing higher low-end torque. Motors with high current ratings and
low inductance will perform better at higher speeds, providing higher high-end
torque. Since the DPD60001 is a constant current source, it is not necessary
to use a motor that is rated at the same voltage as the supply  voltage.  It  is
important that the DPD60001 be set to the appropriate current level based on
the motor being used.Step motors can be purchased in configurations of 4, 6 or 8 leads. Eachone end of the coil to the center tap) use the specified per Phase (or unipolar)
current rating to determine the current adjustment pot setting.  This
configuration will provide more torque at higher speeds.
When configuring the motor in a series configuration (connected from end to
end with the center tap floating) multiply the per Phase (or unipolar) current
rating by 0.7. Use this result to determine the current adjustment pot setting.
WARNING! Step motors will run hot even when configured correctly. Damage
may occur to the motor if a higher than specified current is used.  Most
specified motor currents are maximum values.  Care should be taken to not
exceed these ratings. 
						

							9104 Lead Motors  TYPICAL APPLICATION HOOK-UP
Use the specified series motor current to determine the current adjustment
resistor value.   Four-lead motors are usually rated with their appropriate series
current, as opposed to the Phase Current which is the rating for 6 and 8 lead
motors.  
8 Lead Motors
Series Connection: When configuring the motor windings in series, multiply
the per Phase (or unipolar) current rating by 0.7. Use this result to determine
the current adjustment pot setting.
Parallel Connection: When configuring the motor windings in parallel, multiply
the per Phase (or unipolar) current rating by 1.4. Use this result to determine
the current adjustment pot setting.
NOTE: After the current has been determined, according to the motor
connections above, follow the procedure Determining Output Current on page
7 to find the current value.  Then use Table 3 to choose the proper pot setting.WARNING: Do not connect or disconnect motor wires while power is applied! 
						

							1112Anaheim Automation Standard Step Motor Selection Guide MICROSTEP SELECTION
  Part Number Motor Current
suffix:
single shaft - “S”
dual shaft - “D”(Unipolar Rating) 
 [ Amps ]
23D1042.0
23D1083.9
23D2041.8
23D2094.7
23D3062.9
23D3094.6
34D1063.0
34D1094.8
34D2073.5
34D2094.6
34D307 3.5
34D3115.5
       TABLE 5:Standard AA Motor per Phase ratings.
Note: Anaheim Automation also carries a full line of high torque step
motors. Contact your local distributor or Anaheim Automation for a
specification sheet. The number of microsteps per step is selected by the dip switch(SW1).  Table
6 shows the standard resolution values  along with the associated settings for
these switches.  The standard waveforms are sinusoidal.
ResolutionSteps/Switch 1Switch 2Switch 3Switch 4
     Rev
2400ONONONON
4800OFFONONON
81,600ONOFFONON
163,200OFFOFFONON
326,400ONONOFFON
6412,800OFFONOFFON
12825,600ONOFFOFFON
25651,200OFFOFFOFFON
51,000ONONONOFF
102,000OFFONONOFF
255,000ONOFFONOFF
5010,000OFFOFFONOFF
12525,000ONONOFFOFF
25050,000OFFONOFFOpen
TABLE 5: Mode Selections
Note: The Microstep Mode Select switches are located on the               top cover of the DPD60001.   
						

							1314OPTICALLY ISOLATED INPUTSFAULT PROTECTION
The following inputs to the DPD60001 Driver Pack are Optically Isolated.The DPD60001 Driver Pack is internally protected against over temperature,
ItemPin #
Clock5
Direction6
On/Off8
Reset9
Note: All inputs musts be able to sink a minimum of 7mA.
TIMING
The Direction and Microstep Resolution Select inputs are synchronized with the
negative going edge of the Step Clock input.  When the Step Clock input goes
low, the Direction and Microstep Select inputs are latched and further changes
to the inputs are ignored until the next falling edge of the Step Clock input.
After the Direction and the Microstep Select inputs signals are latched, the
DPD60001 looks to see if any changes have occurred.  If a change has
occurred, the DPD60001 will execute the change before taking the next step.
Only AFTER the change has been executed will the step be taken.  If no
change has occurred the DPD60001 will simply take the next step. This feature
works as an automatic debounce for the Direction and Microstep Select inputs.
The Reset and Enable(PWR) inputs are asynchronous to any input and can be
changed at any time.The Reset requires a minimum pulse width of 500 nS.over/under voltage, and short circuits. The over temperature set point is
between 60EC and 70EC. 
The short circuit protection consists of PHASE to PHASE, PHASE to
GROUND, and +V to PHASE.
In the condition where the DC voltage of the driver drops below +23 volts the
driver’s output stage will be disabled.  When the driver’s DC voltage rises back
above 24 volts, the driver will automatically re-enable the outputs (if previously
enabled).
In the condition where the DC voltage of the driver exceeds approximately 82
volts, the driver will execute a  fault.
If any fault is detected by the DPD60001, the motor outputs will be disabled and
can not be re-enabled without resetting or powering down the driver.  At the
same time the open collector FAULT output is activated, as well as the red
FAULT LED .
OVER TEMPERATURE PROTECTION
The DPD60001 Microstep Driver Pack is a power device and is designed to
protect itself from overheating.  It does this by monitoring the surface
temperature of the drive plate and will automatically shutdown if the
temperature reaches 65°C (152°F).
To prevent shutdowns, proper ventilation is required to maximize  the air flow
into  the Driver Pack. 
						

							15STANDARD STEP MOTOR    STANDARD STEP MOTOR
TORQUE/SPEED CURVESTORQUE/SPEED CURVES 
						

							NOTES