Anaheim Discounted Package PKG341DPNCBL User Manual
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910 East Orangefair Ln. Anaheim, CA 92801 Tel. (714) 992-6990 Fax. (714) 992-0471 www.anaheimautomation.com PKG-341-DPN-CBL System Diagram and Specifications L010881 Included Components: 34Y112S-LW8-MS Stepper Motor DPN10601 10Amp Stepper Driver Pack CBL-18AWG-04C-010-MS Motor Cable Sheet1 Page 1 0 18 36 54 72 90 108 126 144 162 180 0 60 120 180 240 300 360 420 480 540 600 0 5 10 15 20 25 30 35 40 45 50 POWER (Watts) TORQUE (oz -in) SPEED (RPS) 34Y112S-LW8, MBC10641(DPN10601), 120VAC, Div By 8, Series TORQUE POWER
FEATURES SPECIFICATIONS/DIMENSIONS 910 East Orangefair Ln. Anaheim, CA 92801 Tel. (714) 992-6990 Fax. (714) 992-0471 www.anaheimautomation.com The 34Y112S-LW8-MS High Torque Stepper Motor offers a great value without sacrificing quality. This motor was designed to offer the highest possible torque while minimizing vibration and audible noise. It is wired in series with a Molex 4 pin Mini-Fit Jr. receptacle. A 10 ft. 4 conductor, 18 AWG cable with mating 4 pin Mini-Fit Jr plug is included in the PKG-341-DPN-CBL stepper/motor package. 34Y112S-LW8-MS - High Torque Stepper Motor34Y112S-LW8-MS - High Torque Stepper Motor • NEMA 34 Frame Size • Holding Torque - 637 oz-in • 1.8° Step Angle • High Step Accuracy and Resolution • Low Vibration and Noise • CE Certified RoHS Compliant Model #NEMA Size Holding Torque(oz-in) Bipolar Current (A) Bipolar Resistance (ohms) Bipolar Voltage (v) Bipolar Inductance (mH) Rotor Inertia (oz-in-sec2) Shaft Diameter (in) Weight (lbs) Length (in) 34Y112S-LW8-MS 34637 4.3 0.78 3.35 6.8.0198 0.55.13.15 Specifications Step Angle Accuracy: ± 5% (Full Step, No Load) Insulation Resistance:100M Ohm Min, 500VDC Resistance Accuracy: ± 10% Dielectric Strength:500VDC for 1 minute Inductance Accuracy: ± 20% Shaft Radial Play:0.02” Max (1.0 lbs) Temperature Rise: 80°C Max (2 Phases On) End Play:0.08” Max (1.0 lbs) Ambient Temperature: -20° to +50° C Max Radial Force:49.5 lbs (0.79” from flange) Insulation Type: Class B Max Axial Force:13.5 lbs-Force Pin #Lead Wire Connection Lead Wire Color 1 Phase 1 (A) Black 2 Phase 3 (A\) Orange 3 Phase 2 (B) Red 4 Phase 4 (B\) Yellow Soldered Together White/Black & White/Orange Soldered Together White/Red & White/Yellow
3 Table of Contents Section 1: Introduction ........................................................................\ ................................................................... 4 Description........................................................................\ ........................................................................\ ................. 4 Electrical Specifications ........................................................................\ ..................................................................... 5 Wiring Diagrams ........................................................................\ ........................................................................\ ........ 5 Terminal Descriptions - Driver ........................................................................\ ........................................................... 6 Motor Ground ........................................................................\ ........................................................................\ ............ 6 Terminal Descriptions - Controller ........................................................................\ ..................................................... 7 Connector Descriptions - Controller ........................................................................\ .................................................. 7 Slide Switch Descriptions - Controller ........................................................................\ ............................................... 7 Section 2: Driver Functions ........................................................................\ ............................................................ 8 Microstep Selection - Driver DIP Switch Settings ........................................................................\ .............................. 8 Setting the Output Current ........................................................................\ ................................................................. 9 Reducing Output Current ........................................................................\ ................................................................... 9 Short-Circuit, Mis-Wire, and Over-Current Conditions ........................................................................\ ...................... 9 Section 3: Controller Functions ........................................................................\ ................................................... 10 Methods of Communication ........................................................................\ ............................................................. 10 Baud Rate ........................................................................\ ........................................................................\ ................ 10 RS232 Protocol - Controller SW1 in RS232 position ........................................................................\ ....................... 10 RS485 Protocol - Controller SW1 in RS485 position ........................................................................\ ...................... 10 Axis Selection ........................................................................\ ........................................................................\ .......... 11 Controller Status LED ........................................................................\ ...................................................................... 11 Technical Support ........................................................................\ ........................................................................\ .... 11 Section 4: SMC60WIN Software ........................................................................\ ................................................... 16 File Menu ........................................................................\ ........................................................................\ ................. 17 Setup Menu ........................................................................\ ........................................................................\ ............. 17 Setup - Axis Menu ........................................................................\ ........................................................................\ ... 17 Program Menu ........................................................................\ ........................................................................\ ......... 18 Program - Autostart Program Menu ........................................................................\ ................................................. 18 Edit Menu ........................................................................\ ........................................................................\ ................ 18 Help Menu ........................................................................\ ........................................................................\ ............... 19 “The Unit is Connected” / “The Unit is NOT Connected” ........................................................................\ ................. 19 Toolbar ........................................................................\ ........................................................................\ ..................... 20 Tab Sheets ........................................................................\ ........................................................................\ ............... 20 Add/Change/Insert Commands ........................................................................\ ....................................................... 25 Calculator ........................................................................\ ........................................................................\ ................ 30 Section 5: Direct Talk Mode ........................................................................\ .......................................................... 31 Section 6: Troubleshooting ........................................................................\ .......................................................... 41 Error Codes ........................................................................\ ........................................................................\ ............. 42 Section 7: Sample Programs ........................................................................\ ........................................................ 43 Appendix: ASCII Table for Direct Mode ........................................................................\ ........................................... 45 DPN10601 - 10Amp Driver Pack With Programmable IndexerDPN10601 - 10Amp Driver Pack With Programmable Indexer
4 Section 1: Introduction The DPN10601 is a single-axis 10Amp bipolar microstep driver/controller containing 2 Kbytes of non- volatile stored programming space, quadrature encoder feedback, and a 300W transformer, mounted in a sheet metal enclosure. It provides flexible, independent control of bipolar stepper motors with a current range from 1.5 to 10.0 amps/phase with microstepping resolutions from 200 steps per revolution to 12,800 steps per revolution from a computer, or any machine controller with a serial port. It is also capable of standalone operation, making it an embedded machine controller. The easy to use Windows software, SMC60WIN, can be used to directly control motion and to program the DPN10601. The DPN10601 also has the ability for real time functions. The DPN10601 has 40 commands, which are easy-to-remember for direct movement of the stepper motor and communicates via either an RS232 or RS485 bidirectional serial data bus. Up to 99 DPN10601’s can be networked from one communications port on your PC or PLC, utilizing the RS485 communications pro- tocol. Special functions of the controller include 8 programmable open collector outputs and 6 TTL, CMOS and 24V compatible inputs, a quadrature encoder input with the ability to autocorrect, an analog input to control either maximum speed or absolute position, registration mark indexing during a slew command, an output that will trigger during an index command at an absolute position, and a thumbwheel input for indexing a motor. The DPN10601 can be powered from 90-265 VAC, 50/60Hz, Description The MBC10641 driver in the DPN10601 is a microstep motor driver that can drive motors rated from 1.5 to 10.0 amps/phase. It can handle 4, 6 and 8-lead motors in a bipolar fashion. The DPN10601’s driver features motor current ON/OFF capabilities and a Reduced Current Enable to automatically reduces motor current to 70% of the set value after the last step is made (20msec delay). With the DPN10601, various step resolutions can be implemented by the onboard dip switch. These divisions range from 200 steps per revolution to 12,800 steps per revolution. Protection devices have been added to this driver for short circuit, open circuit, over voltage, under voltage and over temperature conditions. The driver has built-in features to indicate power on (Green LED), Clocks being received (Yellow LED) and fault conditions (Red LED). The PCL601 controller in the DPN10601 provides independent programming of acceleration/deceleration, base speed (start up speed), max speed (running speed), jog speed, and the number of steps to be taken in both relative and absolute positioning modes. On absolute positioning moves, the DPN10601 automatically determines the proper direction to go and the number of steps to take. The relative positioning will move a number of steps in the direction that the user defines. The DPN10601 also has specific functions such as encoder feed back, autocorrection, index-on-the-fly and output-on-the-fly . An analog input can be used to set either the maximum speed or goto an absolute position based between the upper and lower programmable limits. A seven decade thumbwheel switch can be read for relative indexing. The DPN10601 also has a high level programming command set that includes: branching, looping, conditional statements, time delays, text strings, and I/O which the user can use in the programming mode to fully control all machine functionality. A home input, a set of bidirectional hard and soft limit switch inputs and bidirectional jog inputs are provided for each axis. These features are generally required in most machine control designs. 6 testable TTL, CMOS and 24V compatible inputs and 8 programmable open-collector outputs are provided per axis. The I/O may be used for monitoring and controlling machine operation and/ or interaxis coordination. The I/O are accessible independent of the busy state of the axis controls. The DPN10601 has a built-in programmable reset circuit. Reset is automatic on power-up, or by pressing the external reset button.
5 Electrical Specifications Power Requirements: 90-265 VAC 50/60Hz Operating Temperature: 0 to 60 degrees C Pulse Output Range: 1 to 50,000 Hz 10uS negative going pulse width Inputs (TTL-CMOS): Logic “0”: 0 to 0.8VDC Logic “1”: 3.5 to 24VDC Analog input 1: 0 to 5VDC Output Current Rating: 10.0 A/phase maximum running 7.0A/phase maximum standstillBaud Rate: 38400 Baud, Fixed Data Format: Half-Duplex, 1 start bit, 8 data bits, no parity, 1 stop bit Outputs (8 programmable): Open Drain Type 40V, 100mA +5VDC Output, 50mA Output1 active low time for output on the fly: 50uS Note: For inductive loads, customers must connect a clamping diode to protect from flyback voltage spikes. Wiring Diagram
6 Terminal Descriptions - Power Options The DPN10601 is powered by an AC line voltages ranging from 90-265VAC. The following figure shows the various line voltages and the wiring for the power connection terminal block. Terminal Descriptions - Driver PositionDescription - Driver Inputs 1 Step Clock Input Anode (+): Internally Connected to controllers +5VDC 2 Step Clock Input Cathode (-): Internally Connected to controllers clock output 3 Direction Anode (+): Internally Connected to controllers +5VDC 4 Direction Cathode (-): Internally Connected to controllers direction output 5 ON/OFF Anode (+): Internally Connected to controllers +5VDC 6 ON/OFF Cathode (-): Internally Connected to controllers on/off output 7 +5 VDC: This non-isolated output can be used to supply up to 50mA of current. 8 0 VDC: +5 VDC return. Position Description - Motor Connection 1 Phase A: Phase 1 of the Step Motor 2 Phase A\: Phase 3 of the Step Motor 3 Phase B: Phase 2 of the Step Motor 4 Phase B\: Phase 4 of the Step Motor 5 Motor Ground Motor Ground Meant to be used in conjunction with the motor cable ground wire. Make sure the connection is only on one end of the motor cable ground wire. If no motor shield is available, and if the motor has no ground wire, the motor ground pin can be left with no connection.
7 Slide Switch Descriptions - Controller Switch NumberDescription SW1 This switch is used to select either RS232 or RS485. Connector Descriptions - Controller Switch Number Description P1 This connector is for the RS-232 communication and is labeled RS-232. J1 This connector is for the thumbwheel module and is labeled TWS. Terminal Descriptions - Controller PositionDescription - RS485 1 A(-) 2 B(+) 3 IGND - This is an isolated ground for RS485 only Position Description - Encoder 1 +5VDC supply for encoder 2 A channel for encoder 3 B channel for encoder 4 Ground return for encoder Position Description - Inputs 1 Input 1 - Analog input 2 Input 2 - Index on the fly input 3 Input 3 4 Input 4 5 Input 5 6 Input 6 7 Ground Position Description - Outputs 1 Output 1 - Output on the fly output 2 Output 2 3 Output 3 4 Output 4 5 Output 5 6 Output 6 7 Output 7 8 Output 8 - Encoder retries error output Position Description - Limit Switch Inputs 1 Home Limit 2 Jog + 3 Jog - 4 Fast Jog 5 Hard Limit + 6 Hard Limit - 7 Soft Limit + 8 Soft Limit - 9 Ground
8 Section 2: Driver Functions Microstep Selection - Driver DIP Switch Settings Switches 2, 3 and 4, of the DIP switch select the number of microsteps per step. The following table shows the standard resolution values along with the associated positions for the select switches. The standard waveforms are sinusoidal. ResolutionSteps/RevSelect 1Select 2 Select 3Select 4 Auto Reduce Current 1 200OFFONONON Disabled 2 400OFFONONOFF Disabled 5 1000 OFFONOFF ON Disabled 8 1600 OFFONOFF OFF Disabled 10 2000OFFOFF ONON Disabled 16 3200OFFOFF ONOFF Disabled 32 6400OFFOFF OFF ON Disabled 64 12800 OFFOFF OFFOFF Disabled 1 200ONON ONON Enabled 2 400ONON ONOFF Enabled 5 1000 ONONOFF ON Enabled 8 1600 ONONOFF OFF Enabled 10 2000 ONOFF ONON Enabled 16 3200 ONOFF ONOFF Enabled 32 6400 ONOFF OFF ON Enabled 64 12800 ONOFF OFFOFF Enabled
9 Setting the Output Current The output current on the DPN10601 is set by an onboard potentiometer. This potentiometer determines the per phase peak output current of the driver. The specified motor current of 4.3A for the 34Y112S- LW8-MS (which is the bipolar value) is multiplied by a factor of 1.4 to determine the current adjust- ment potentiometer value of 6.0Amps or 50%. Peak Current Potentiometer Setting Peak CurrentPotentiometer Setting 1.5A 0%7.0A 60% 2.3A 10%7.9A70% 3.1A 20%8.7A80% 4.0A 30%9.6A90% 5.0A 40% 10A100% 6.0A 50% ---- Reducing Output Current Reducing the output current is accomplished by setting switch 1 of the DIP switch to the ON position and occurs approximately 1 second after the last positive going edge of the step clock input. The amount of current per phase in the reduction mode is approximately 70% of the set current. When the current reduction circuit is activated, the current reduction resistor is paralleled with the current adjustment potentiometer. This lowers the total resistance value, and thus lowers the per Phase output current. WARNING! Step motors will run hot even when configured correctly. Damage may occur to the mo- tor if a higher than specified current is used. Most specified motor currents are maximum values. Care should be taken to not exceed these ratings. Do not connect or disconnect motor wires while power is applied! Short-Circuit, Mis-Wire, and Over-Current Conditions If it is found that there is a condition that causes on over current in the driver phase transistors, the Red LED will turn on solid and power will be shut off to the motor. To reset the drive turn power off, check wiring, and turn power back on. Over-Temperature and Over-Voltage Conditions If it is found that there is an over temperature on the internal heat sink, or an over voltage on the motor bus voltage, the Red LED will blink and power will be shut off to the motor. To reset the drive turn power off, check wiring, and turn power back on.
10 Section 3: Controller Functions Methods of Communication There are two methods for sending commands to the DPN10601. One is to directly talk to the DPN10601 by using Direct Talk Mode. This is usually used with a computer or PLC (Programmable Logic Controller), where the computer or PLC gives the DPN10601 serial commands to off-load its processor. For example: A PLC can utilize its outputs to toggle the DPN10601’s inputs and gain control of variable speeds, variable programs, variable distances, etc. Simply using the DPN10601 as the intelligent pulse generator, a PLC can remove some of the tasks that were not meant for ladder logic or any PLC processing time. The second way to give commands to the DPN10601 is to use the software program SMC60WIN to either manually control, or to write and send programs. This method is used when the DPN10601 is the main controller. For example: A DPN10601 can replace simple motion control and replace I/O functional when minimal quantities of I/O are required to control specific machinery. Simple motion profiles that can operate with 6 or less inputs and 8 or less outputs can utilize a DPN10601 controller. Baud Rate A term used frequently in serial data communications, a “baud” is defined as the reciprocal of the shortest pulse duration in a data word signal, including start, stop, and parity bits. This is often taken to mean the same as “bits per second”, a term that expresses only the number of “data” bits per second. Very often, the parity bit is included as an information or data bit. The DPN10601 accepts a baud rate of 38400 only. RS232 Protocol - Controller SW1 in RS232 position The DPN10601 is a DCE device, therefore it will transmit on pin 2 and receive on pin3 of the DB9 RS- 232 connector . The RS232 serial communication mode is single ended. This means that for each signal there is one wire, and a common ground reference used by all the signals. The DPN10601 does not use handshaking, thus the CTS and RTS lines are internally connected, and the CD, DTR and DSR lines are internally connected inside the DPN10601. The signal line maintains levels of +5VDC to +15VDC and -5VDC to -15VDC. For a valid logic level in the controller, the voltage must be at least +/-3 volts. RS232 works at distances of up to 50 feet maximum. RS232 is susceptible to electrical noise, and should not be used in noisy areas. Always use the shortest cable connection possible. NOTE: Keep controller wiring separated from motor cable/wiring. RS485 Protocol - Controller SW1 in RS485 position The RS485 protocol mode is as follows; On board receivers will remain in active mode indefinitely. Transmitters must be turned off when the unit is not sending data, to prevent the line from sending and receiving data at the same time. Therefore when the PC is transmitting data its driver will be turned on and each of the units connected will have their drivers off. If they are requested to send data back to the PC, the selected unit will turn it’s driver on to send the data and then turn it off after it has completed transmission. Note: The above protocol is done internally between the converter and the DPN10601. The RS485 method of communication allows increased noise immunity and increased communication distance of up to 4000 feet without repeaters. RS485 repeaters allow an additional 4000 feet per repeater. The DPN10601 is designed for two wire configuration. The 2 wire configuration makes use of the tristate capabilities of RS485 to allow a single pair of wires to share transmit and receive signals for half duplex communications. This “two wire” configuration (note that an additional ground conductor must be used) reduces cabling cost. NOTE: Keep control wiring separated from motor cable/wiring.