Leadshine Microstep DM860 User’s Manual

June 8, 2024
Microrostep

User’s Manual
For
DM860

Introduction, Features and Applications

Introduction
The DM860 is a fully digital stepper drive developed with advanced DSP control algorithm based on the latest motion control technology. It has achieved a unique level of system smoothness, providing optimal torque and nulls mid-range instability.

Compared with traditional analog drives, DM860 can drive a stepper motor at much lower noise,
lower heating, and smoother movement. Its unique features make DM860 an ideal choice for high requirement applications.

Features

  • Anti-Resonance provides optimal torque and nulls mid-range instability
  •  Multi-Stepping  allows  a low-resolution step  input to  produce  a higher  micro-step  output,  thus offers  smoother motor movement
  • 16 selectable micro-step resolutions including 400, 800, 1600, 3200, 6400, 12800, 25600, 51200, 1000, 2000, 4000,
  • 5000, 8000, 10000, 20000, 40000
  • Input voltage 24-80VDC
  • 8 selectable peak current including 2.40A, 3.08A, 3.77A, 4.45A, 5.14A, 5.83A, 6.52A, 7.20A
  • Pulse input frequency up to 200 KHz, TTL compatible and optically isolated input
  • Automatic idle-current reduction
  • Suitable for 2-phase and 4-phase motors
  • Over-voltage, over-current protections

Applications

Suitable for a wide range of stepping motors, from NEMA size 17 to 42. It can be used in various kinds of machines, such as X-Y tables, engraving machines, labeling machines, laser cutters, pick-place devices, and so on. Particularly adapt to the applications desired with low noise, low heating, high speed, and high precision.

Specifications

Electrical Specifications (T j = 25    /77   )

Parameters|

DM860

---|---

Min

| Typical| Max|

Unit

Output Current

| 1.0| –| 7.2 (Peak)| A

Input Voltage

| +24| +68| +80| VDC

Logic Signal Current

| 7| 10| 16| mA
Pulse input frequency| 0| –| 200|

kHz

Pulse Width| 2.5| –| –|

uS

Operating Environment and other Specifications

Cooling

| Natural Cooling or Forced cooling
---|---

Environment

|

Avoid dust, oil fog and corrosive gases

Ambient Temperature

|

0℃  -   50℃

Operating Environment

| Humidity| 40%RH  -    90%RH

Operating Temperature

|

70℃Max

Vibration|

5.9m/s2 Max

Storage Temperature

|

-20℃  -   65℃

Weight|

Approx. 620g (21.7oz)

Mechanical Specifications ( unit: mm [inch] )

Mechanical Specifications

Figure 1: Mechanical specifications
*Recommend using side mounting for better heat dissipation

Elimination of Heat

  • Driver’s reliable working temperature should be <70℃(158℉), and motor working temperature should be <80℃(176℉);
  • It is recommended to use automatic idle-current mode, namely current automatically reduce to 50% when motor stops, so as to reduce driver heating and motor heating;
  • It is recommended to mount the driver vertically to maximize heat sink area. Use forced cooling method to cool the system if necessary.

Pin Assignment and Description

The DM860 has two connectors, connector P1 for control signals connections, and connector P2 for power and motor connections. The following tables are brief descriptions of the two connectors. More detailed descriptions of the pins and related issues are presented in section 4, 5, 9.

Connector P1 Configurations

Pin Function|

D e t ail s

---|---
P U L+| Pulse  signal:  In single  pulse  (pulse/direction) mode,  this  input  represents  pulse  signal,  eac rising or falling edge active; 4.5-5V
P U L
D IR+| DIR  signal:  In  single-pulse  mode,  this  signal  has low/high  voltage  levels,  representing  tw directions  of  motor  rotation;
D I R
E NA +| Enable signal:  This signal is used for enabling/disabling the driver. High level (NPN control signal, PNP and differential control signals are on the contrary, namely low level for enabling.) for enabling the driver and low level for disabling the driver. Usually left UNCONNECTED (ENABLED).
E NA

Connector P2 Configurations

Pin Function

|

Details

---|---

VDC

|

Power supply, 24 ~ 80 VDC, Including voltage fluctuation and EMF voltage.

GND

|

Power Ground.

A+, A-

|

Motor Phase A

B+, B-

|

Motor Phase B

4. Control Signal Connector (P1) Interface

The DM860 can accept differential and single-ended inputs (including open- collector and PNP output). The DM860 has 3 optically isolated logic inputs which are located on connector P1 to accept line driver control signals. These inputs are isolated to minimize or eliminate electrical noises coupled onto the drive control signals. Recommend use line driver control signals to increase noise immunity of the driver in interference environments. In the following figures, connections to open-collector and PNP signals are illustrated.

Control Signal Connector \(P1\) Interface5. Connecting the Motor

The DM860 can drive any 2-pahse and 4-pahse hybrid stepping motors.
Connections to 4-lead Motors
4 lead motors are the least flexible but easiest to wire. Speed and torque will depend on winding inductance. In setting the driver output current, multiply the specified phase current by 1.4 to determine the peak output current.

Figure 5: 4-lead Motor Connections

Connections to 6-lead Motors

Like 8 lead stepping motors, 6 lead motors have two configurations available for high speed or high torque operation. The higher speed configuration, or half coil,  is so described because it uses one-half of the motor’s inductor windings. The higher torque configuration, or full coil, uses the full windings of the phases.
Half Coil Configurations
As previously stated, the half coil configuration uses 50% of the motor phase windings. This gives lower inductance, hence, lower torque output. Like the parallel connection of 8 lead motor, the torque output will be more stable at higher speeds. This configuration is also referred to as half chopper. In setting the driver output current multiply the specified per phase (or unipolar) current rating by 1.4 to determine the peak output current.

Figure 6: 6-lead motor half coil (higher speed) connections

Full Coil Configurations
The full coil configuration on a six-lead motor should be used in applications where higher torque at lower speeds is desired. This configuration is also referred to as full copper. In full coil mode, the motors should be run at only 70% of their rated current to prevent overheating.

Figure 7: 6-lead motor full coil (higher torque) connections

Connections to 8-lead Motors
8 lead motors offer a high degree of flexibility to the system designer in that they may be connected in series or parallel, thus satisfying a wide range of applications.
Series Connections
A series motor configuration would typically be used in applications where a higher torque at lower speeds is required. Because this configuration has the most inductance, the performance will start to degrade at higher speeds. In series mode, the motors should also be run at only 70% of their rated current to prevent overheating.

Figure 8: 8-lead motor series connections

Parallel Connections
An 8 lead motor in a parallel configuration offers a more stable, but lower torque at lower speeds. But because of the lower inductance, there will be higher torque at higher speeds. Multiply the per phase (or unipolar) current rating by 1.96, or the bipolar current rating by 1.4, to determine the peak output current.

Figure 9: 8-lead motor parallel connections

Power Supply Selection

The DM860 can match medium and small-size stepping motors (from NEMA frame size 17 to 34) made by many motor manufactures around the world. To achieve good driving performances, it is important to select supply voltage and output current properly. Generally speaking, supply voltage determines the high-speed performance of the motor, while output current determines the output torque of the driven motor (particularly at lower speed). Higher supply voltage will allow higher motor speed to be achieved, at the price of more noise and heating. If the motion speed requirement is low, it’s better to use lower supply voltage to decrease noise, heating and improve reliability.

Regulated or Unregulated Power Supply
Both regulated and unregulated power supplies can be used to supply the driver. However, unregulated power supplies are preferred due to their ability to withstand current surge. If regulated power supplies (such as most switching supplies.) are indeed used, it is important to have large current output rating to avoid problems like current clamp, for example using 4A supply for 3A motor-driver operation. On the other hand, if unregulated supply is used, one may use a power supply of lower current rating than that of motor (typically 50% - 70% of motor current). The reason is that the driver draws current from the power supply capacitor of the unregulated supply only during the ON duration of the PWM cycle, but not during the OFF duration. Therefore, the average current withdrawn from power supply is considerably less than motor current. For example, two 3A motors can be well supplied by one power supply of 4A rating.

Multiple Drivers
It is recommended to have multiple drivers to share one power supply to reduce cost, if the supply has enough capacity.
To avoid cross-interference, DO NOT daisy-chain the power supply input pins of the drivers. (Instead, please connect them to power supply separately.)

Selecting Supply Voltage
The power MOSFETS inside the DM860 can actually operate within +24 ~ +110VDC, including power input fluctuation and back EMF voltage generated by motor coils during motor shaft deceleration. Higher supply voltage can increase motor torque at higher speeds, thus helpful for avoiding losing steps. However, the higher voltage may cause bigger motor vibration at lower speed, and it may also cause over-voltage protection or even driver damage. Therefore, it is suggested to choose only sufficiently high supply voltage for intended applications, and it is suggested to use power supplies with theoretical output voltage of +20 ~ +68VDC, leaving room for power fluctuation and back-EMF.

Selecting Microstep Resolution and Driver Output Current

This driver uses an 8-bit DIP switch to set microstep resolution, and motor operating current, as shown below:

Microstep Resolution Selection
Microstep resolution is set by SW5, 6, 7, 8 of the DIP switch as shown in the following table:

Microstep

|

Steps/rev.(for 1.8°motor)

|

SW5

|

SW6

|

SW7

|

SW8

---|---|---|---|---|---

2

|

400

|

ON

|

ON

|

ON

|

ON

4

|

800

|

OFF

|

ON

|

ON

|

ON

8

|

1600

|

ON

|

OFF

|

ON

|

ON

16

|

3200

|

OFF

|

OFF

|

ON

|

ON

32

|

6400

|

ON

|

ON

|

OFF

|

ON

64

|

12800

|

OFF

|

ON

|

OFF

|

ON

128

|

25600

|

ON

|

OFF

|

OFF

|

ON

256

|

51200

|

OFF

|

OFF

|

OFF

|

ON

5

|

1000

|

ON

|

ON

|

ON

|

OFF

10

|

2000

|

OFF

|

ON

|

ON

|

OFF

20

|

4000

|

ON

|

OFF

|

ON

|

OFF

25

|

5000

|

OFF

|

OFF

|

ON

|

OFF

40

|

8000

|

ON

|

ON

|

OFF

|

OFF

50

|

10000

|

OFF

|

ON

|

OFF

|

OFF

100

|

20000

|

ON

|

OFF

|

OFF

|

OFF

200

|

40000

|

OFF

|

OFF

|

OFF

|

OFF

Current Settings
For a given motor, higher driver current will make the motor to output more torque, but at the same time causes more heating in the motor and driver. Therefore, the output current is generally set to be such that the motor will not overheat for long time operation.

Since parallel and serial connections of motor coils will significantly change resulting inductance and resistance, it is therefore important to set driver output current depending on motor phase current, motor leads and connection methods. Phase current rating supplied by motor manufacturer is important in selecting driver current, however the selection also depends on leads and connections.
The first three bits (SW1, 2, 3) of the DIP switch are used to set the dynamic current. Select a setting closest to your motor’s required current.

Dynamic Current Setting

REF Current

|

Peak Current

|

SW1

|

SW2

|

SW3

---|---|---|---|---

2.00A

|

2.40A

|

ON

|

ON

|

ON

2.57A

|

3.08A

|

OFF

|

ON

|

ON

3.14A

|

3.77A

|

ON

|

OFF

|

ON

3.71A

|

4.45A

|

OFF

|

OFF

|

ON

4.28A

|

5.14A

|

ON

|

ON

|

OFF

4.86A

|

5.83A

|

OFF

|

ON

|

OFF

5.43A

|

6.52A

|

ON

|

OFF

|

OFF

6.00A

|

7.20A

|

OFF

|

OFF

|

OFF

Notes : Due to motor inductance, the actual current in the coil may be smaller than the dynamic current setting, particularly under high-speed conditions.

Standstill Current Setting
SW4 is used for this purpose. OFF meaning that the standstill current is set to be half of the selected dynamic current, and ON meaning that standstill current is set to be the same as the selected dynamic current.
The current automatically reduced to 50% of the selected dynamic current one second after the last pulse. Theoretically, this will reduce motor heating to 36% (due to P=I2*R) of the original value. If the application needs a different standstill current.

Wiring Notes

  • In order to improve the anti-interference performance of the driver, it is recommended to use a twisted pair shield cable.
  • To prevent noise incurred in PUL/DIR signal, pulse/direction signal wires and motor wires should not be tied up together. It is better to separate them by at least 10 cm, otherwise the disturbing signals generated by motor will easily disturb pulse direction signals, causing motor position error, system instability, and other failures.
  • If a power supply serves several drivers, separately connecting the drivers is recommended instead of daisy-chaining.
  • It is prohibited to pull and plug connector P2 while the driver is powered ON because there is high current flowing through motor coils (even when motor is at standstill). Pulling or plugging connector P2 with power on will cause an extremely high back-EMF voltage surge, which may damage the driver.

Typical Connection

A complete stepping system should include stepping motor, stepping driver, power supply and controller (pulse generator). A typical connection is shown as figure 10.

Leadshine Microstep DM860 - Typical Connection

Sequence Chart of Control Signals

In order to avoid some fault operations and deviations, PUL, DIR, and ENA should abide by some rules, shown as following diagram:

Figure 11: Sequence chart of control signals

Remark:

a) t1: ENA must be ahead of DIR by at least 5µs. Usually, ENA+ and ENA- are NC (not connected). See “Connector P1 Configurations” for more information.
b) t2: DIR must be ahead of PUL effective edge by 5µs to ensure correct direction;
c) t3: Pulse width not less than 2.5µs;
d) t4: Low-level width not less than 2.5µs.

Protection Functions

To improve reliability, the driver incorporates some built-in protection features.

Priori t y| Time(s) of Bli n k| Sequence wave of red LED                                           Description
---|---|---
1st| 1| | Over-current protection activated when peak current exceeds the limit.
2nd| 2| | Over-voltage protection activated when drive working voltage is greater than 96VDC

When above protections are active, the motor shaft will be free or the red LED blinks. Reset the driver by repowering it to make it function properly after removing above problems.

Frequently Asked Questions

In the event that your driver doesn’t operate properly, the first step is to identify whether the problem is electrical or mechanical in nature. The next step is to isolate the system component that is causing the problem. As part of this process you may have to disconnect the individual components that make up your system and verify that they operate independently. It is important to document each step in the troubleshooting process. You may need this documentation to refer back to at a later date, and these details will greatly assist our Technical Support staff in determining the problem should you need assistance.
Many of the problems that affect motion control systems can be traced to electrical noise, controller software errors, or mistake in wiring.

Problem Symptoms and Possible Causes ****

Symptoms

|

Possible Problems

---|---
Motor is not rotating| No power
Microstep resolution setting is wrong
DIP switch current setting is wrong
Fault condition exists
The driver is disabled
Motor rotates in the wrong direction| Motor phases may be connected in reverse
The driver in fault| DIP switch current setting is wrong
Something wrong with motor coil
Erratic motor motion| Control signal is too weak
Control signal is interfered
Wrong motor connection
Something wrong with motor coil
Current setting is too small, losing steps
Motor stalls during acceleration| Current setting is too small
Motor is undersized for the application
Acceleration is set too high
Power supply voltage too low
Excessive motor and driver heating| Inadequate heat sinking / cooling
Automatic current reduction function not being utilized
Current is set too high

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