NI SMD-7613/7614/7615/7616 User Manual

USER MANUAL
NI SMD-7613/7614/7615/7616
This manual contains information about the configuration and use of the National
Instruments SMD-7613, SMD-7614, SMD-7615, and SMD-7616. They are referred to
inclusively in this manual as the NI SMD-761x.
Note This manual is not applicable for NI SMD-7610/7611/7612 devices. Refer to
to the unique documentation for information related to the NI SMD-7610/7611/7612.
Functionality on these devices are roughly equivalent. The NI SMD-7613/7615 operates from
18 to 53 VDC, and has a running current of up to 5 A per phase. The SMD-7614/7616 operates
from 18 to 88 VDC, and runs current up to 10 A per phase. The SMD-7615/7616 features
encoder feedback.
Contents
Safety Information .................................................................................................................... 2
Block Diagram.......................................................................................................................... 3
Getting Started.......................................................................................................................... 3
Mounting the Drive .................................................................................................................. 4
Connecting the Power Supply .................................................................................................. 4
Choosing a Power Supply......................................................................................................... 5
Voltage.............................................................................................................................. 5
Current .............................................................................................................................. 5
Regeneration..................................................................................................................... 7
Connecting the Drive Using Ethernet....................................................................................... 7
Motor Wiring Recommendations ............................................................................................. 12
Four Lead Motors ............................................................................................................. 13
Six Lead Motors ............................................................................................................... 13
Eight Lead Motors ............................................................................................................ 14
Connecting Input Signals.......................................................................................................... 15
STEP and DIR Inputs ....................................................................................................... 17
Single Ended Inputs.......................................................................................................... 19
Connecting Limit Switches and Sensors .......................................................................... 21
Analog Inputs ................................................................................................................... 22
Connecting an Encoder (SMD-7615/7616) .............................................................................. 23
Programmable Outputs ............................................................................................................. 25
Configuring the Drive............................................................................................................... 28
Motor ................................................................................................................................ 28
Control .............................................................................................................................. 29
I/O Configuration ............................................................................................................. 31
Self Test............................................................................................................................ 31
Torque Speed Curves................................................................................................................ 32
Motor Heating........................................................................................................................... 38
Drive Heating............................................................................................................................ 47
Mechanical Outline................................................................................................................... 48
Technical Specifications ........................................................................................................... 48
Alarm Codes ............................................................................................................................. 50
Safety Information
Only qualified personnel are permitted to transport, assemble, commission, and maintain this
equipment. Properly qualified personnel are persons who are familiar with the transport,
assembly, installation, commissioning and operation of motors, and who have the appropriate
qualifications for their jobs. The qualified personnel must know and observe the following
standards and regulations:
•
IEC 364 resp. CENELEC HD 384 or DIN VDE 0100
•
IEC report 664 or DIN VDE 0110
•
National regulations for safety and accident prevention or VBG 4
To minimize the risk of potential safety problems, you should follow all applicable local and
national codes that regulate the installation and operation of your equipment. These codes vary
from area to area and it is your responsibility to determine which codes should be followed, and
to verify that the equipment, installation, and operation are in compliance with the latest revision
of these codes.
Equipment damage or serious injury to personnel can result from the failure to follow all
applicable codes and standards. We do not guarantee the products described in this publication
are suitable for your particular application, nor do we assume any responsibility for your product
design, installation, or operation.
•
Read all available documentation before assembly and commissioning. Incorrect handling
of products in this manual can result in injury and damage to persons and machinery.
Strictly adhere to the technical information on the installation requirements.
•
It is vital to ensure that all system components are connected to earth ground. Electrical
safety is impossible without a low-resistance earth connection.
•
The SMD-761x contains electrostatically sensitive components that can be damaged by
incorrect handling. Discharge yourself before touching the product. Avoid contact with
high insulating materials (artificial fabrics, plastic film, etc.). Place the product on a
conductive surface.
•
During operation keep all covers and cabinet doors shut. Otherwise, there are deadly
hazards that could possibility cause severe damage to health or the product.
•
In operation, depending on the degree of enclosure protection, the product can have bare
components that are live or have hot surfaces. Control and power cables can carry a high
voltage even when the motor is not rotating.
•
Never pull out or plug in the product while the system is live. There is a danger of electric
arcing and danger to persons and contacts.
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•
After powering down the product, wait at least ten minutes before touching live sections of
the equipment or undoing connections (e.g., contacts, screwed connections). Capacitors
can store dangerous voltages for long periods of time after power has been switched off. To
be safe, measure the contact points with a meter before touching.
Be alert to the potential for personal injury. Follow the recommended precautions and safe
operating practices. Safety notices in this manual provide important information. Read and be
familiar with these instructions before attempting installation, operation, or maintenance. The
purpose of this section is to alert users to possible safety hazards associated with this equipment
and the precautions that need to be taken to reduce the risk of personal injury and damage to the
equipment. Failure to observe these precautions could result in serious bodily injury, damage to
the equipment, or operational difficulty.
Block Diagram
Figure 1. NI SMD-761x Block Diagram
External Power Supply
7613/7615: 24-48 VDC
7614/7616: 24-80 VDC
Internal
Logic Supply
INPUT X1
INPUT X2
Status
INPUT X3
INPUT X4
INPUT X5
INPUT X6
X7/CWLIM
MOSFET
PWM
Power
Amplifier
Optical
Isolation
Motor
X8/CCWLIM
OUTPUT Y1
OUTPUT Y2
Encoder
OUTPUT Y3
DSP
OUTPUT Y4
7615/7616
Only
ANALOG IN1
Ethernet
ANALOG IN2
Getting Started
You need the following to use your NI SMD-761x stepper drive:

a 24 to 48 VDC power supply (80 V max for NI SMD-7614/7616). Refer to Choosing a
Power Supply for help in choosing the right power supply

one of the recommended motors
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
a small flat blade screwdriver for tightening the connectors

a source of step signals, such as a PLC or motion controller
The connectors and other points of interest are illustrated below. These are detailed later in the
manual.
Figure 2 shows an overview of the connectors on the NI SMD-7613/7614/7615/7616 stepper
drive.
Figure 2. NI SMD-7613/7614/7615/7616 Stepper Drive Connectors
2
3
4
5
6
7
1
1
2
3
4
Chassis Grounding Screw
Motor and Power Supply Connector
Encoder Feedback (SMD-7615/7616)
Input and Output Signals
5
6
7
Ethernet Connector
Drive Status LEDs
Rotary Switch
Mounting the Drive
You can mount your drive on the wide or the narrow side of the chassis using #6 screws. If
possible, the drive should be securely fastened to a smooth, flat metal surface that will help
conduct heat away from the chassis. If this is not possible, then forced airflow from a fan may
be required to prevent the drive from overheating. Refer to Drive Heating for more information.
•
Never use your drive in a space where there is no air flow or where other devices cause the
surrounding air to be more than 50 °C.
•
Never put the drive where it can get wet or where metal or other electrically conductive
particles can get on the circuitry.
•
Always provide air flow around the drive. When mounting multiple drives near each other,
maintain at least one half inch of space between drives.
Connecting the Power Supply
If you need information about choosing a power supply, refer to Choosing a Power Supply.
•
Connect the power supply “+” terminal to the connector terminal labeled “V+”.
•
Connect power supply “-” to the connector terminal labeled “V-”.
•
The green ground screw on the corner of the chassis should be connected to earth ground.
•
Use 18 or 20 gauge wire.
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The NI SMD-761x drives contain an internal fuse that connects to the power supply + terminal.
This fuse is not user replaceable. If you want to install a user serviceable fuse in your system,
install a fast acting, 7 A fuse in line with the + power supply lead.
Caution Do not reverse the wires. Reverse connection will destroy your drive and
void your warranty.
If you plan to use a regulated power supply you may encounter a problem with regeneration. If
you rapidly decelerate a load from a high speed, much of the kinetic energy of that load is
transferred back to the power supply. This can trip the overvoltage protection of a switching
power supply, causing it to shut down. NI offers the SMD-7700 regeneration clamp to solve this
problem. If in doubt, buy an SMD-7700 for your first installation. If the regen LED on the
SMD-7700 never flashes, you don’t need the clamp.
Choosing a Power Supply
When choosing a power supply, there are many things to consider. If you are manufacturing
equipment that will be sold to others, you probably want a supply with all the safety agency
approvals. If size and weight are an issue, get a switching supply.
And you must decide what size of power supply (in terms of voltage and current) is needed for
your application.
National Instruments offers two power supplies that are excellent matches for the NI SMD-761x
drives: PS-12 24V, 6.3A) and PS-13 (48V, 6.7A).
Voltage
The motor can provide more torque at higher speeds if a higher power supply voltage is used.
Refer to the Torque Speed Curves section for guidance.
If you choose an unregulated power supply, make sure the no load voltage of the supply does not
exceed the drive’s maximum input voltage specification.
Current
The maximum supply current you could ever need is two times the motor current. However, you
will generally need a lot less than that, depending on the motor type, voltage, speed and load
conditions. That’s because the NI SMD-761x uses a switching amplifier, converting a high
voltage and low current into lower voltage and higher current. The more the power supply
voltage exceeds the motor voltage, the less current you’ll need from the power supply. A motor
running from a 48 volt supply can be expected to draw only half the supply current that it would
with a 24 volt supply.
We recommend the following selection procedure:
1.
If you plan to use only a few drives, get a power supply with at least twice per phase current
rating of the step motor. Example: for a motor that’s rated for 2 A/phase use a 4 A power
supply.
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2.
If you are designing for mass production and must minimize cost, get one power supply
with more than twice the rated current of the motor. Install the motor in the application and
monitor the current coming out of the power supply and into the drive at various motor
loads. This will tell you how much current you really need so you can design in a lower cost
power supply.
Tables 1 lists the relevant specifications for suggested motors. Please consider this information
when choosing a power supply.
Table 1. NI SMD-7613/7615 Power Supply Current
Holding
Torque
6
Motor
oz-in
kg-cm
Drive
Current
Setting (A)
ST11-1
7.0
0.50
1.2
1.4
1.4
8
ST11-2
15.0
1.08
1.2
2.0
2.6
18
ST14-1
26.0
1.87
1.2
4.3
5.5
20
ST17-1
31.4
2.26
1.6
2.1
2.8
35
ST17-2
51.0
3.67
2.0
1.7
3.6
54
ST17-3
62.8
4.52
2.0
1.7
3.0
68
ST23-1
76.6
5.52
3.4
0.7
1.4
120
ST23-4
177
12.7
5.0
0.4
1.2
300
ST23-6
264
19.0
5.0
0.5
1.6
480
ST23-8
354
25.48
6.0
0.5
2.2
750
ST24-1
123.2
8.87
3.36
0.73
1.6
260
ST24-2
177
12.74
4.8
0.43
1.1
450
ST24-3
354
24.48
4.8
0.65
2.4
900
ST34-2
650
46.8
10.0
0.19
1.3
1400
ST34-5
1200
86.4
9.7
0.27
2.2
2680
ST34-8
1845
133
10.0
0.27
2.4
4000
ST34-1
396.5
28.55
7.56
0.24
1.7
1100
ST34-4
849.6
61.18
7.56
0.33
2.7
1850
ST34-7
1260
90.75
6.72
0.63
5.4
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Resistance
(Ω)
Inductance
(mH)
Rotor
Inertia
(g-cm2)
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Regeneration
When a motor rapidly decelerates from high speed under load, the kinetic energy may be
reconverted into electrical energy and transferred back to the power supply. When using
regulated power supplies, this can trip the overvoltage protection and lead to a shutdown, or
cause damage to the system. Unregulated power supplies do not typically have overvoltage
protection, and may store regenerated energy in capacitors.
Connecting the Drive Using Ethernet
The drive requires only a CAT5 Ethernet cable connection to connect to your PC. You can
connect the drive directly to your PC’s network card, to an auxiliary network card in your PC,
or to a router or network switch.
1.
Physically connect the device to your network (or directly to the PC).
2.
Set the drive IP address.
3.
Set the appropriate networking properties on your PC.
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Your device includes a 16 position rotary switch for setting its IP address. The factory default
address for each switch setting is shown in the table below.
Table 2. IP Address Rotary Switch Settings
Position
IP Address
0
10.10.10.10
1
192.168.1.10
2
192.168.1.20
3
192.168.1.30
4
192.168.0.40
5
192.168.0.50
6
192.168.0.60
7
192.168.0.70
8
192.168.0.80
9
192.168.0.90
A
192.168.0.100
B
192.168.0.110
C
192.168.0.120
D
192.168.0.130
E
192.168.0.140
F
DHCP
The IP address corresponding to positions 1 through E can be changed using the NI Stepper
Configuration Utility software. Setting 0 is always 10.10.10.10, the universal recovery address.
Setting F is DHCP, which commands the device to get an IP address from a DHCP server on the
network. The IP address automatically assigned by the DHCP server may be dynamic or static
depending on how the administrator has configured DHCP. The DHCP setting is reserved for
advanced users.
Your PC, or any other equipment that you use to communicate with the device, will also have a
unique address.
On the device switch settings 1 through E use the standard class B subnet mask
(i.e., 255.255.0.0). The mask for the universal recovery address is the standard class A
(i.e., 255.0.0.0).
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Option 1: Connect a Drive to Your LAN
If you have a spare port on a switch or router and if you are able to set your device to an IP
address that is compatible with your network, and not used by anything else, this is a simple way
to get connected. This technique also allows you to connect multiple devices to your PC. If you
are on a corporate network, check with your system administrator before connecting anything
new to the network. He or she should be able assign you a suitable address and help you get
going.
Figure 3. Example Network Configuration
NIC
LAN
Switch
or
Router
PC
Drive
Many networks use dynamic addressing where a DHCP server assigns addresses on demand.
The address you choose for your device might get assigned to something else by the DHCP
server at another time.
Once you’ve chosen an appropriate IP address for your device, set the rotary switch according
to the address table above. If none of the default addresses are acceptable for your network, you
can enter a new table of IP addresses using the NI Stepper Configuration Utility. If your network
uses addresses starting with 192.168.0, the most common subnet, you will want to choose an
address from switch settings 4 through E. Another common subnet is 192.168.1. If your
network uses addresses in this range, the compatible default selections are 1, 2 and 3. If your PC
address is not in one of the above private subnets, you will have to change your subnet mask to
255.255.0.0 in order to communicate with your device. To change your subnet mask:
1.
2.
Open Network Connections.
a.
Windows 8.1/8/7/Vista—Open Control Panel. From the icon view, open Network
and Sharing Center, then click Change Adapter Settings.
b.
Windows XP—Right-click My Network Places and select Properties.
Right-click your network interface card (NIC) and select Properties.
a.
b.
Windows 8.1/8/7/Vista—Scroll down and select (TCP/IPv4), then click Properties.
Windows XP—Scroll down and select Internet Properties (TCP/IP), then click
Properties.
3.
4.
If the Obtain an IP address automatically option is selected, your PC is getting an IP
address and a subnet mask from the DHCP server. Cancel this dialog and proceed to the
Using DHCP section.
If the option Use the following IP address is selected, change the subnet mask to
255.255.0.0 and click OK.
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Using DHCP
If you want to use your device on a network where all or most of the devices use dynamic IP
addresses supplied by a DHCP server, set the rotary switch to “F”. When the device is connected
to the network and powered on, it will obtain an IP address and a subnet mask from the server
that is compatible with your PC. However, you will not know what address the server assigns to
the device. The NI Stepper Configuration Utility can find your device using the Drive Discovery
feature, as long as your network isn’t too large. When the device connected to the network is
powered on, select Drive Discovery from the Drive menu to launch the Network Interface
Dialog dialog box.
Figure 4. Network Interface Dialog Box
Normally, Drive Discovery only detects one network interface card (NIC), and selects it
automatically. If you are using a laptop and have both wireless and wired network connections,
a second NIC may appear. Please select the NIC that you use to connect to the network to which
you’ve connected your device. Then click OK. Drive Discovery notifies you as soon as it has
detected a device.
If you think this is the correct device, click Yes. If you are not sure, click Not Sure and Drive
Discovery will look for additional devices on you network. Once you have told Drive Discovery
which device is yours, it automatically enters the device IP address in the IP address text box so
that you are ready to communicate.
Option 2: Connect a device Directly to Your PC
1.
Connect one end of a CAT5 Ethernet cable into the LAN card (NIC) on your PC and the
other into the device. You don’t need a special crossover cable; the device automatically
detects the direct connection and make the necessary physical layer changes.
2.
Set the IP address on the device to 10.10.10.10 by setting the rotary switch to position 0.
3.
To set the IP address of your PC:
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a.
Windows 8.1/8/7/Vista—Open Control Panel. From the icon view, open Network
and Sharing Center, then click Change Adapter Settings.
b.
Windows XP—Right-click My Network Places and select Properties.
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4.
Right-click your network interface card (NIC) and select Properties.
a.
b.
Windows 8.1/8/7/Vista—Scroll down and select (TCP/IPv4), then click Properties.
Windows XP—Scroll down and select Internet Properties (TCP/IP), then click
Properties.
5.
Select Use the following IP address and enter the address 10.10.10.11. This assigns
your PC an IP address that is on the same subnet as the device. Windows directs any traffic
intended for the device’s IP address to this interface card.
6.
Next, enter the subnet mask as 255.255.255.0.
7.
Leave Default gateway blank. This prevents your PC from looking for a router on this
subnet.
Note Because you are connected directly to the device, anytime the device is not
powered you will receive a small message bubble in the corner of your screen saying
“The network cable is unplugged.”
Option 3: Use Two Network Interface Cards (NICs)
This technique allows you to keep your PC connected to your LAN, but keeps the device off the
LAN, preventing possible IP conflicts or excessive traffic.
1.
If you use a desktop PC and have a spare card slot, install a second NIC and connect it
directly to the device using a CAT5 cable. You don’t need a special “crossover cable”; the
device will automatically detect the direct connection and make the necessary physical
layer changes.
2.
If you use a laptop and only connect to your LAN using wireless networking, you can use
the built-in RJ45 Ethernet connection as your second NIC.
3.
Set the IP address on the device to 10.10.10.10 by setting the rotary switch to position 0.
4.
To set the IP address of your PC:
5.
a.
Windows 8.1/8/7/Vista—Open Control Panel. From the icon view, open Network
and Sharing Center, then click Change Adapter Settings.
b.
Windows XP—Right-click My Network Places and select Properties.
Right-click your network interface card (NIC) and select Properties.
a.
b.
Windows 8.1/8/7/Vista—Scroll down and select (TCP/IPv4), then click Properties.
Windows XP—Scroll down and select Internet Properties (TCP/IP), then click
Properties.
6.
Select Use the following IP address and enter the address 10.10.10.11. This assigns
your PC an IP address that is on the same subnet as the device. Windows directs any traffic
intended for the device’s IP address to this interface card.
7.
Next, enter the subnet mask as 255.255.255.0.
8.
Leave Default gateway blank. This prevents your PC from looking for a router on this subnet.
Note Because you are connected directly to the device, anytime the device is not
powered you will receive a small message bubble in the corner of your screen saying
“The network cable is unplugged.”
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Motor Wiring Recommendations
This section explains how to connect motors to the NI SMD-761x. Refer to your motor
documentation for any special considerations that may affect your configuration.
Maintain at least 2 in. separation between the power supply cable and input lines or encoder
feedback. All power supply cables should be properly shielded, and the shield grounded at the
power supply. Signal cables should be shielded, and grounded as close as possible to the signal
source.
Caution
Never connect or disconnect the motor while the system is powered on.
Ensure any shield or grounding strap on the motor is connected to the chassis
ground screw located near the motor/power connector.
Note
Figure 5. Motor/Power Connector
Figure 6. Grounding Screw on the Chassis
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Four Lead Motors
Four lead motors can only be configured according to the following diagram.
Note Motor wire colors are correct for NI stepper motors compatible with the
NI SMD-761x. These wire colors may not match a third-party stepper motor.
Phase A+
Phase A–
Red
Blue
Figure 7. Four Lead Motor Connection
Yellow
Phase B+
White
Phase B–
Six Lead Motors
Six lead motors can be connected in series or center tap. A series connected motor produces
more torque but it will not be able to run as fast as a motor in center tap configuration. In series
operation, the motor should be operated at 30% less than the rated current to prevent
overheating. Refer to the wiring diagrams below to connect a six lead motor.
Phase A–
Grn/Wht
No connect
White
Green
Phase A+
Figure 8. Six Lead Motor Connected in Series
Red/Wht Phase B+
Black
No connect
Red
Phase B–
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Phase A+
Phase A–
Grn/Wht
Green
White
No connect
Figure 9. Six Lead Motor Connected in Center Tap
Red/Wht No connect
Black
Phase B+
Red
Phase B–
Eight Lead Motors
Eight lead motors can be connected in series or parallel. A series connected motor needs less
current than one that is connected in parallel but it will not be able to run as fast. In series
operation, the motor should be operated at 30% less than the rated current to prevent
overheating. Refer to the wiring diagrams below to connect an eight lead motor.
Black
Phase A–
Org/Wht
Blk/Wht
Orange
Phase A+
Figure 10. Eight Lead Motor Connected in Series
Red
Phase B+
Red/Wht
Yel/Wht
Yellow
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Phase B–
Black
Blk/Wht
Org/Wht
Orange
Phase A–
Phase A+
Figure 11. Eight Lead Motor Connected in Parallel
Red
Red/Wht
Yel/Wht
Phase B+
Phase B–
Yellow
Connecting Input Signals
The NI SMD-761x has three types of input:
•
High speed digital inputs for step and direction commands/encoder following. 5 V logic.
•
Digital inputs for other signals. 12 to 24 V logic.
•
Analog inputs are reserved for furture use.
Note
All inputs except STEP and DIR use 12 to 24 VDC logic.
All drives include eight digital inputs and two analog inputs:
•
CW & CCW Limit: Optional input that can be used to inhibit motion in a given direction,
forcing the motor and load to travel within mechanical limits. It can be configured for active
closed or active open.
•
IN1/STEP & IN2/DIR: Digital signals that can be used for commanding position.
Quadrature signals from encoders can also be used. These inputs can also be connected to
sensors and switches.
•
IN3, IN4, IN5, IN6: Software-prgrammable inputs that can be used for motor enable, alarm
reset, or jogging. These inputs can also be connected to sensors and switches.
•
Analog In: Analog signals that can command velocity or position. Can be configured for
0 to 10 V, 0 to 5 V, ±10 V, or ±5 V, with or without an offset.
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Figure 12. Input Connector Pin Diagram
X8/CCWLIMIT–
X8CCWLIMIT+
X7/CWLIMIT–
X7/CWLIMIT+
Y4–
Y4+
GND
+5V OUT
Y COMMON
Y3/FAULT
Y2/MOTION
Y1/BRAKE
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
GND
X1/STEP+
X1/STEP–
X2/DIR+
X2/DIR–
X COMMON
X3/ENABLE
X4/ALARM RESET
X5/CWJOG
X6/CCWJOG
ANALOG IN2
ANALOG IN1
Figure 13. ISelect Internal Circuitry of the I/O Connector
8
XCOM
7
X3/EN
6
x4/RST
2200Ω
2200Ω
2200Ω
5
X5
2200Ω
4
X6
22
X7/CWLIM+
23
X7/CWLIM–
24
X8/CCWLIM+
25
X8/CCWLIM-
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2200Ω
2200Ω
NI SMD-7613/7614/7615/7616 User Manual
STEP and DIR Inputs
The drive includes two high speed inputs called STEP and DIR. They accept 5 volt single-ended
or differential signals, up to 2 MHz. Normally these inputs connect to an external controller that
provides step & direction command signals. You can also connect a master encoder to the inputs
for following applications. The following section demonstrates example signal connections.
Refer to Motor Wiring Recommendations for cable instructions.
Figure 14. Connecting to Indexer with Sourcing Outputs
Indexer
with
Sourcing
Outputs
+5V OUT
X2/DIR–
DIR
X2/DIR+
IN/OUT 1
X1/STEP–
STEP
X1/STEP+
Figure 15. Connecting to Indexer with Sinking Outputs
Indexer
with
Sinking
Outputs
+5V OUT
X2/DIR+
DIR
X2/DIR–
IN/OUT 1
X1/STEP+
STEP
X1/STEP–
Figure 16. Connecting to Indexer with Differential Outputs
Indexer
with
Differential
Outputs
DIR+
X2/DIR+
DIR–
X2/DIR–
STEP+
X1/STEP+
STEP-
X1/STEP–
IN/OUT 1
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Figure 17. Connecting for Encoder Following
Indexer
with
Differential
Outputs
A+
X1/STEP+
A–
X1/STEP–
B+
X2/DIR+
B-
X2/DIR–
GND
GND
IN/OUT 1
Using 12 to 24 Volt Signals
Most PLC’s don’t use 5 V signals. Use external dropping resistors to connect signals up to 24 V
to the STEP and DIR inputs. For 12 V logic, use 820 Ω, 1/4 W resistors. For 24 V logic, use
2200 Ω, 1/4 W resistors.
Caution Do not exceed an input voltage of 24 VDC. Never apply AC power to an
input terminal.
Connect the resistors according to the following diagrams:
Figure 18. Connecting to PLC with Sourcing (PNP) Outputs
+12-24V
OUT1
PLC
with
Sourcing
Outputs
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X2/DIR+
X1/STEP–
OUT2
X1/STEP+
GND
X2/DIR–
NI SMD-7613/7614/7615/7616 User Manual
761x
Figure 19. Connecting to PLC with Sinking (NPN) Outputs
+12-24V
X2/DIR+
DIR
X2/DIR–
PLC
with
Sinking
Outputs
761x
X1/STEP+
STEP
X1/STEP–
Figure 20. Using Mechanical Switches at 24 Volts
+
X2/DIR+
X2/DIR–
Direction Switch
+24 VDC
Power
Supply
Drive
X1/STEP+
–
X1/STEP–
Run/Stop Switch
(closed=run)
Single Ended Inputs
The SMD-761x includes four single ended, optically isolated input circuits that can be used with
sourcing or sinking signals. These inputs can be used with PLCs, sensors, relays, or mechanical
switches. These inputs require an external power supply.
COM, or common, refers to a connection to a common voltage. This is often
ground, but not always.If using sourcing (PNP) signals, connect COM to the negative
terminal of the power supply. When using sinking (NPN) signals, connect COM to
the positive terminal of the power supply.
Note
Refer to the following diagrams for examples of how to connect the drive to commonly used
devices:
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Figure 21. Connecting to Input Switch or Relay
+
XCOM
12-24 VDC
Power
Supply
Drive
-
X3..X6
Switch or Relay
(closed = logic low)
Figure 22. Connecting Multiple Drives
12-24 VDC
Power
Supply
+
–
OUT+
XCOM
IN/OUT1
Drive
OUT–
X3..X6
Figure 23. Connecting an NPN Type Proximity Sensor to an Input
+
XCOM
+
NPN
Proximity
Sensor
-
12-24 VDC
Power
Supply
Output
-
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X3..X6
Drive
Figure 24. Connecting a PNP Type Proximity Sensor to an Input
+
+
PNP
Proximity
Sensor
-
12-24 VDC
Power
Supply
-
Output
X3..X6
Drive
XCOM
Connecting Limit Switches and Sensors
The CWLIMIT and CCWLIMIT differential inputs can be used to connect end of travel sensors.
You can use signals that are sinking (NPN), sourcing (PNP) or differential (line driver). By
connecting switches or sensors that are triggered by the motion of the motor or load, you can
force the motor to operate within certain limits, preventing damage to your system by traveling
too far.
The limit inputs are optically isolated, allowing you to choose a voltage for your limit circuits of
12 to 24 VDC. This also allows you to have long wires on limit sensors that may be far from the
drive with less risk of introducing noise to the drive electronics.
Refer to the following diagrams for help connecting limit switches and sensors:
Figure 25. Wiring a Mechanical Limit Switch
+
CWLIMIT+
CCWLIMIT+
12-24 VDC
Power
Supply
CCWLIMIT–
–
Drive
CCWLIMIT–
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Figure 26. Wiring a Sinking Output Limit Sensor
+
CW LIMIT+
+
Limit
Sensor
–
DC
Power
Supply
Output
Drive
CW LIMIT–
–
Figure 27. Wiring a Sourcing Output Proximity Sensor
+
+
Proximity
Sensor
-
DC
Power
Supply
Output
-
CW LIMIT+
Drive
CW LIMT–
Analog Inputs
The device features two analog inputs. Each input can accept a signal range of 0-VDC, ±5 VDC,
0 to 10 VDC or ±10 VDC. The drive can be configured to operate at a speed or position
that is proportional to the analog signal.
The following figure represents the internal circuitry of the analog inputs:
Figure 28. Internal Circuitry of Analog Inputs
1
AIN1
Signal
Conditioning
AIN2
Signal
Conditioning
2
13
GND
Caution
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Always use a shielded cable to maintain signal integrity.
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Us the NI Stepper Configuration Utility to configure settins such as signal range, offset,
deadband, and filter frequency.
The following diagram depicts the connection of a potentiometer to the analog input, which
could be used to control the commanded position or velocity.
Figure 29. Potentiometer Connected to Analog Input 1
CW
1-10 kW
pot
CCW
18
+5V OUT
1
AIN
13
GND
2
AIN2
Drive
Connecting an Encoder (SMD-7615/7616)
The encoder connections use a HD-15 connector, which you must connect to your encoder as
shown below.
If your encoder is single ended, connect the encoder outputs to the A+, B+ and Z+ inputs. Leave
A-, B- and Z- unconnected. (Z is the encoder index signal and is optional.)
Figure 30. Encoder Connection Pin Numbering
5
15
1
6
Table 3. Encoder Connection Pin Definition
Pin
Function
1
Encoder A+
2
Encoder A-
3
Encoder B+
4
Encoder B-
5
Encoder Z+
6
Encoder Z-
7
+5 VDC, 200 mA
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Table 3. Encoder Connection Pin Definition (Continued)
Pin
Function
8
GND
9
No Connect
10
No Connect
11
No Connect
12
No Connect
13
No Connect
14
No Connect
15
Shield
The internal circuitry of the encoder connection is depicted below:
5 KΩ
5K Ω
12.5 KΩ
7
5 KΩ
12.5 KΩ
12.5 KΩ
Figure 31. Encoder Connection Pin Numbering
+5V
1
A+
2
A–
3
B+
4
B–
5
Z+
6
8.3 KΩ
8.3 KΩ
8.3 KΩ
Z–
8
GND
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Programmable Outputs
The drive features four digital outputs. These outputs can be set to automically control a motor
brake, to signal a fault condition, to indicate when the motor is moving, or to provide an output
frequency proportional to motor speed (tach signal). Refer to the diagram below for a
representation of the internal cirtucitry of the digital outputs:
Figure 32. Potentiometer Connected to Analog Input 1
14
Y1
17
YCOM
16
Y3
15
Y2
20
Y4+
21
Y4–
The outputs can be used to drive LEDs, relays, and the inputs of other electronic devices like
PLCs and counters. For Y4, the “+” (collector) and “-” (emitter) terminals of each transistor are
available at the connector. This allows you to configure this output for current sourcing or
sinking. The Y1 to 3 outputs can only sink current. The Y COM terminal must be tied to power
supply (-).
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Diagrams of each type of connection follow.
Caution
Do not connect outputs to more than 30 VDC.
Caution
The current through an output terminal must not exceed 100 mA.
Figure 33. Sinking Output Using Y1, Y2, or Y3
+
Y1/2/3
Load
5-24 VDC
Power
Supply
IN/OUT1
–
YCOM
Figure 34. Sinking Output Using Y4
+
Y4 +
Load
5-24 VDC
Power
Supply
IN/OUT1
–
Y4 –
Figure 35. Sourcing Output Using Y1, Y2, or Y3
5-24 VDC
Power
Supply
+
–
PLC
COM
IN/OUT1
Y1/2/3
YCOM
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IN
Figure 36. Sourcing Output Using Y4
5-24 VDC
Power
Supply
–
+
COM
IN/OUT1
PLC
Y4+
IN
Y4–
Figure 37. Driving a Relay Using Y1, Y2, or Y3
Relay
5-24 VDC
Power
Supply
+
Y1/2/3
IN/OUT1
1N4935 suppression diode
–
YCOM
Figure 38. Driving a Relay Using Y4
Relay
+
5-24 VDC
Power
Supply
Y4+
IN/OUT1
1N4935 suppression diode
–
Y4–
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Configuring the Drive
The drive is configured in software with the NI Stepper Configuration Utility, available at
ni.com/downloads. When you have located your device with the utility, you can configure
various aspects of the motor performance and control for your application.
Motor
From the NI Stepper Configuration Utility home screen, click the Motor icon to open the
configuration window.
Figure 39. NI Stepper Configuration Utility Configuration Window
The drive works best with the specially matched motors selectable from the Standard Motor list.
Select the motor you will use and configure the following settings:
Running Current
Seting the Running Current to 100% will achieve maximum torque. However, under some
conditions you might want to reduce the current to save power or lower motor temperature. This
is important if the motor is not mounted to a surface that will help it conduct heat away or if you
expect the ambient temperature to be high.
Step motors produce torque in direct proportion to current, but the amount of heat generated is
roughly proportional to the square of the current. If you operate the motor at 90% of rated
current, the motor provides 90% of the rated torque and approximately 81% as much heat. At
70% current, the torque is reduced to 70% and the heating to about 50%.
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Idle Current/Idle Current Delay
You can reduce motor heating and power consumption by lowering the motor current when it is
not moving. The drive automatically lowers the motor current when it is idle for longer than the
time specified by Idle Current Delay.
The default 50% idle current setting lowers the holding torque to 50% of the specified Running
Current, which is enough to prevent the load from moving in most applications. You can adjust
this value to account for your load and heating requirements.
Load Inertia
The drive includes anti-resonance and electronic damping features which greatly improve motor
performance. To perform optimally, the drive must understand the electromechanical
characteristics of the motor and load. Most of this is completed automatically in the factory
during motor and drive assembly. To further enhance performance, you must specify the innertia
of the load. If you are unsure of this value, you can experimentally find an acceptable value by
entering a multiplier of the rotor inertia.
Control
From the NI Stepper Configuration Utility home screen, click the Motion icon to open the
Motion Control Mode Window. Select the Pulse & Direction Mode button to configure the
following settings:
Figure 40. NI Stepper Configuration Utility Configuration Window
Steps/Rev
You can configure the number of steps per revolution to match the details of your application.
A higher value provides smoother motion, though you may want to configure this value to match
the phsyical parameters of the system such as gearing or screw pitch.
Step Smoothing Filter
At lower step resolutions such as 200 steps per revolution (full step) and 400 steps per revolution
(half step) motors produce more audible noise than when they are microstepped (2000 steps per
revolution and beyond). The drive includes a feature called microstep emulation, also called step
smoothing, that can provide smooth motion when using full and half steps. If the Steps/Rev
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setting is 2000 or higher, this feature is not needed and can be set to the highest possible value,
2500.
The step smoothing process uses a command filter which causes a slight delay, or lag in the
motion. The following figure shows an example of the delay that can occur from using the step
smoothing filter.
Figure 41. Delay Due to Filtering
Input Noise Filter
Electrical noise can negatively affect the STEP signal by causing the drive to interpret one step
pulse as two or more pulses. This results in extra motion and inaccurate motor and load
positioning. To solve this problem, the drive includes a digital noise filter on the STEP and DIR
inputs. The default factory setting of this filter is 7.5 MHz, which is suitable for most
applications.
Your maximum pulse rate equals the highest motor speed multiplied by the number of steps per
revolution. For example:
revs
steps
40 ------------------ × 20, 000 ------------- = 800kHz
sec ond
revs
Consider the maximum pulse rate when deciding whether you must increase the filter frequency.
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I/O Configuration
From the NI Stepper Configuration Utility home screen, click the I/O icon to open the Motion
I/O Configuration window to configure the following settings:
Figure 42. NI Stepper Configuration Utility Configuration Window
Fault Output
The fault output will be triggered if there is a fault condition. This may be a fault within the drive
or a system fault. Not all faults will cause the drive to be disabled. If you are running the
NI Stepper Configuration Utility while an alarm condition develops, a dialog box will give you
details of the fault. Alarms and faults are also displayed by a pattern of red and green flashes on
the drive's front panel LED. Refer to the Alarm Code section for code definitions.
Alarm Reset Input
This parameter allows you to configure an input to reset any alarms that result from a fault. If
this is not enabled, you must reset alarms by cycling power to the drive.
Brake Output
If your motor features a brake, you can configure an output to release the brake when the motor
is enabled. You can configure the delay settings to ensure the brake is fully applied before
disabling the motor.
Motor Enable Input
The Motor Enable input toggles the power stage of the drive. This allows the drive to be powered
on while the motor is inactive.
Self Test
If you are having trouble getting your motor to turn, use the built-in self test from the NI Stepper
Configuration Utility home page. Select the Drive menu item and choose Self Test. Use this
feature to confirm that the motor is wired correctly, selected, and otherwise operational.
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Torque Speed Curves
Figure 43. SMD-761x Torque Curve for ST11 & ST14, 24 V Power Supply
ST11, ST14
24 VDC power supply, 20000 steps/rev
25
ST14-1 (1.2 A/phase)
ST11-2 (1.2 A/phase)
ST11-1 (1.2 A/phase)
20
oz-in
15
10
5
0
0
5
10
15
20
25
30
35
40
rev/sec
Figure 44. SMD-761x Torque Curve for ST17, 24 V Power Supply
ST17
24 VDC power supply, 20000 steps/rev, all motors connected in parallel
100
ST17-3
(2.0 A/phase)
90
ST17-2
(2.0 A/phase)
ST17-1
(1.6 A/phase)
80
70
oz-in
60
50
40
30
20
10
0
0
5
10
15
20
rev/sec
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30
35
40
Figure 45. SMD-761x Torque Curve for ST17, 48 V Power Supply
ST17
48 VDC power supply, 20000 steps/rev, all motors connected in parallel
100
ST17-3
(2.0 A/phase)
90
ST17-2
(2.0 A/phase)
ST17-1
(1.6 A/phase)
80
70
oz-in
60
50
40
30
20
10
0
0
5
10
15
20
25
30
35
40
rev/sec
Figure 46. SMD-761x Torque Curve for ST23, 24V Power Supply
ST23
24 VDC power supply, 20000 steps/rev, all motors connected in parallel
350
300
ST23-8
-
(6.0 A/phase)
ST23-6
(5.0 A/phase)
ST23-4
-
(5.0 A/phase)
ST23-1
(3.4 A/phase)
250
oz-in
200
150
100
50
0
0
5
10
15
20
25
30
35
40
rev/sec
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Figure 47. SMD-761x Torque Curve for ST23, 48 V Power Supply
ST23
48 VDC power supply, 20000 steps/rev, all motors connected in parallel
350
300
ST23-8
(6.0 A/phase)
ST23-6
(5.0 A/phase)
ST23-4
(5.0 A/phase)
ST23-1
(3.4 A/phase)
250
oz-in
200
150
100
50
0
0
5
10
15
20
25
30
35
40
rev/sec
Figure 48. SMD-761x Torque Curve for ST24, 24V Power Supply
ST24
24 VDC power supply, 20000 steps/rev
350
ST24-3 (4.8 A/phase)
ST24-2 (4.8 A/phase)
300
ST24-1 (3.36 A/phase)
250
oz-in
200
150
100
50
0
0
5
10
15
20
rev/sec
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30
35
40
Figure 49. SMD-761x Torque Curve for ST24, 48V Power Supply
ST24
48 VDC power supply, 20000 steps/rev
350
ST24-3 (4.8 A/phase)
300
ST24-1 (3.36 A/phase)
ST24-2 (4.8 A/phase)
250
oz-in
200
150
100
50
0
0
5
10
15
20
25
30
35
40
rev/sec
Figure 50. SMD-7614/7616 Torque Curve for ST34-2/5/8, 48V Power Supply
ST34-2/5/8 with SMD-7614/7616
24 VDC power supply, 20000 steps/rev, all motors connected in parallel
1400
ST34-8 (10 A/phase)
ST34-5 (9.7 A/phase)
1200
ST34-2 (10 A/phase)
1000
oz-in
800
600
400
200
0
0
5
10
15
20
25
30
35
40
rev/sec
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Figure 51. SMD-7614/7616 Torque Curve for ST34-2/5/8, 48V Power Supply
ST34-2/5/8 with SMD-7614/7616
48 VDC power supply, 20000 steps/rev, all motors connected in parallel
1400
ST34-8 (10 A/phase)
ST34-5 (9.7 A/phase)
1200
ST34-2 (10 A/phase)
1000
oz-in
800
600
400
200
0
0
5
10
15
20
25
30
35
40
rev/sec
Figure 52. SMD-7614/7616 Torque Curve for ST34-2/5/8, 80V Power Supply
ST34-2/5/8 with SMD-7614/7616
80 VDC power supply, 20000 steps/rev, all motors connected in parallel
1400
ST34-8 (10 A/phase)
1200
ST34-2 (10 A/phase)
ST34-5 (9.7 A/phase)
1000
oz-in
800
600
400
200
0
0
5
10
15
20
rev/sec
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30
35
40
Figure 53. SMD-7614/7616 Torque Curve for ST34-1/4/7, 24V Power Supply
ST34-1/4/7 with SMD-7614/7616
24 VDC power supply, 20000 steps/rev, all motors connected in parallel
1000
ST34-7 (6.72 A/phase)
900
ST34-4 (7.56 A/phase)
ST34-1 (7.56 A/phase)
800
700
oz-in
600
500
400
300
200
100
0
0
5
10
15
20
25
30
35
40
rev/sec
Figure 54. SMD-7614/7616 Torque Curve for ST34-1/4/7, 48V Power Supply
ST34-1/4/7 with SMD-7614/7616
48 VDC power supply, 20000 steps/rev, all motors connected in parallel
1000
ST34-7 (6.72 A/phase)
900
ST34-4 (7.56 A/phase)
ST34-1 (7.56 A/phase)
800
700
oz-in
600
500
400
300
200
100
0
0
5
10
15
20
25
30
35
40
rev/sec
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Figure 55. SMD-7614/7616 Torque Curve for ST34-1/4/7, 60V Power Supply
ST34-1/4/7 with SMD-7614/7616
60 VDC power supply, 20000 steps/rev, all motors connected in parallel
1000
ST34-7 (6.72 A/phase)
900
ST34-4 (7.56 A/phase)
ST34-1 (7.56 A/phase)
800
700
oz-in
600
500
400
300
200
100
0
0
5
10
15
20
25
30
35
40
rev/sec
Motor Heating
Step motors convert electrical power from the driver into mechanical power to move a load.
Because step motors are not perfectly efficient, some of the electrical power turns into heat on
its way through the motor. This heating is not so much dependent on the load being driven but
rather the motor speed and power supply voltage. There are certain combinations of speed and
voltage at which a motor cannot be continuously operated without damage.
The following table and figures show the maximum duty cycle versus speed for each motor at
commonly used power supply voltages. Please refer to this information when planning your
application.
A step motor typically reaches maximum temperature after 30 to 45 minutes of operation. If you
run the motor for one minute then let it sit idle for one minute, that is a 50% duty cycle. Five
minutes on and five minutes off is also 50% duty. However, one hour on and one hour off has
the effect of 100% duty because during the first hour the motor will reach full (and possibly
excessive) temperature.
The actual temperature of the motor depends on how much heat is conducted, convected, or
radiated out of it. Our measurements were made in a 40 °C (104 °F) environment with the motor
mounted to an aluminum plate sized to provide a surface area consistent with the motor power
dissipation. Your results may vary.
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Table 4. SMD-761x Maximum Motor Duty Cycle
Max Duty Cycle at 40 °C
Drive Current (A),
peak of sine
24 VDC
ST11-1
1.2
100%
ST11-2
1.2
100%
ST14-1
1.2
See chart
ST17-1
1.6
100%
See chart
ST17-2
2.0
100%
See chart
ST17-3
2.0
100%
See chart
ST23-1
3.4
100%
See chart
ST23-4
5.0
See chart
See chart
ST23-6
5.0
See chart
See chart
ST34-2
10.0
See chart
See chart
ST34-5
9.7
See chart
See chart
ST34-8
10.0
See chart
See chart
Motor
48 VDC
Figure 56. Duty Cycle for the ST17-1 with the SMD-761x, 24 VDC
ST14-1 Max Duty Cycle vs Speed
24 VDC, 1.2A, 40°C Ambient
Mounted on 4.75" x 4.75" x .25" Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
30
40
50
Speed (RPS)
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Figure 57. Duty Cycle for the ST17-1 with the SMD-761x, 48 VDC
ST17-1 Max Duty cycle vs Speed
48 VDC, 1.60 Amps 40°C Ambient
on 4.75 x 4.75 x .25 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
30
40
50
Speed (RPS)
Figure 58. Duty Cycle for the ST17-2 with the SMD-761x, 48 VDC
ST17-2 Max Duty cycle vs Speed
48 VDC, 2.0 Amps 40°C Ambient
on 4.75 x 4.75 x .25 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
Speed (RPS)
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40
50
Figure 59. Duty Cycle for the ST17-3 with the SMD-761x, 48 VDC
ST17-2 Max Duty cycle vs Speed
48 VDC, 2.0 Amps 40°C Ambient
on 4.75 x 4.75 x .25 Aluminum Plate
% Duty Cycle
100
80
60
40
20
0
0
10
20
30
40
50
Speed (RPS)
Figure 60. Duty Cycle for the ST23-1 with the SMD-761x, 48 VDC
ST23-1 Max Duty Cycle vs Speed
48 VDC, 3.4 Amps, 40°C Ambient
on 6.4 x 6.4 x .25 Aluminum Plate
% Duty Cycle
100
80
60
40
20
0
0
10
20
30
40
50
Speed (RPS)
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Figure 61. Duty Cycle for the ST23-4 with the SMD-761x, 24 VDC
ST23-4 Max Duty cycle vs Speed
24VDC, 5.0A, 40°C Ambient
on 6.4 x 6.4 x .25 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
30
40
50
Speed (RPS)
Figure 62. Duty Cycle for the ST23-4 with the SMD-761x, 48 VDC
ST23-4 Max Duty cycle vs Speed
48VDC, 5.0A, 40°C Ambient
on 6.4 x 6.4 x .25 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
Speed (RPS)
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30
40
50
Figure 63. Duty Cycle for the ST23-6 with the SMD-761x, 24 VDC
ST23-6 Max Duty Cycle vs Speed
24 VDC, 5.0 Amps, 40°C Ambient
on 6.4 x 6.4 x .25 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
Speed (RPS)
30
40
50
Figure 64. Duty Cycle for the ST23-6 with the SMD-761x, 48 VDC
ST23-6 Max Duty cycle vs Speed
48 VDC, 5.0 Amps 40°C Ambient
on 6.4 x 6.4 x .25 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
30
40
50
Speed (RPS)
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Figure 65. Duty Cycle for the ST34-2 with the SMD-761x, 48 VDC
ST34-2 Max Duty cycle vs Speed
48 VDC, 10.0 Amps 40°C Ambient
on 10 x 10 x .5 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
30
40
50
Speed (RPS)
Figure 66. Duty Cycle for the ST34-2 with the SMD-761x, 80 VDC
ST34-2 Max Duty cycle vs Speed
80 VDC, 10.0 Amps 40°C Ambient
on 10 x 10 x .5 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
Speed (RPS)
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30
40
50
Figure 67. Duty Cycle for the ST34-5 with the SMD-761x, 48 VDC
ST34-5 Max Duty Cycle vs Speed
48 VDC, 10.0 Amps 40°C Ambient
on 10 x 10 x .5 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
Speed (RPS)
30
40
50
Figure 68. Duty Cycle for the ST34-5 with the SMD-761x, 80 VDC
ST34-5 Max Duty cycle vs Speed
80 VDC, 10.0 Amps 40°C Ambient
on 10 x 10 x .5 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
30
40
50
Speed (RPS)
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Figure 69. Duty Cycle for the ST34-8 with the SMD-761x, 48 VDC
ST34-8 Max Duty Cycle vs Speed
48 VDC, 10.0 Amps 40°C Ambient
on 10 x 10 x .5 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
Speed (RPS)
30
40
50
Figure 70. Duty Cycle for the ST34-8 with the SMD-761x, 80 VDC
ST34-8 Max Duty cycle vs Speed
80 VDC, 10.0 Amps 40°C Ambient
on 10 x 10 x .5 Aluminum Plate
100
% Duty Cycle
80
60
40
20
0
0
10
20
Speed (RPS)
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40
50
Drive Heating
While NI SMD-7613/7614/7615/7616 devices efficiently transmit power between the power
supply and motor, they do generate some heat in the process. This will cause the temperature of
the drive to rise above the surrounding air temperature and may also require that the drive be
mounted to a heat conducting metal surface.
To calculate the power dissipation and temperature rise, the following information is provided.
Given:
drive power dissipation Pd versus motor (refer to the figures below)
drive thermal constant RQ
The final drive case temperature is given by:
TC = Ta + RQ* Pd
where Ta is the ambient temperature of the surrounding air. The case of the drive should not be
allowed to exceed 70 °C or the life of the product could be reduced.
Drive thermal constant:
Narrow side of drive mounted on a 3.5” × 13.5” steel plate, 0.070 in. thick: Rθ = 1.0 °C/W
Narrow side of drive mounted on a non-heat conducting surface: Rθ = 2.1 °C/W
Figure 71. Drive Thermal Losses
SMD-7611/7612 Drive Losses
25
60V
48V
24V
Driver Loss (W)
20
15
10
5
0
1
2
3
4
5
Motor Current (A)
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Mechanical Outline
Figure 72. Mechanical Dimensions
1.775
0.663
5.0
0.61
3.00
1.98
6X SLOT 0.16
WIDE, FULL R
4.74
Technical Specifications
Amplifier
Features .....................................................Digital MOSFET. 20 kHz PWM. Suitable for
driving step motors with four, six, or eight leads.
SMD-7613/7615
Supply voltage ..................................12 to 53 VDC
Motor current ....................................0.5 to 5.0 A/phase peak of sine
SMD-7614/7616
Supply voltage ..................................18 to 88 VDC
Motor current ....................................0.5 to 10.0 A/phase peak of sine
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Digital inputs
Step & Direction
Isolation ............................................ Optically isolated, 5 V logic
Digital logic ...................................... 5 V, differential
Internal resistance ............................. 330 Ω
Minimum pulse width....................... 0.5 µsec
Minimum set-up, direction ............... 2 0.5 µsec
Other inputs
Isolation ............................................ Optically isolated, 12 V logic
Digital logic ...................................... 12 to 24 V, differential
Internal resistance ............................. 22000 Ω
Analog inputs
Input voltage ............................................. ±10 VDC
Internal resistance ..................................... 100 kΩ
Output ............................................................... Photodarlington, 100 mA, 30 VDC max.
Voltage drop.............................................. 1.2 V max at 100 mA
+5V Output ....................................................... 5 VDC
Max current............................................... 100 mA
Dimensions ....................................................... 1.775 × 3.0 × 5.0 in. (45 × 76.2 × 127 mm)
Weight............................................................... 10 oz (280 g)
Operating temperature range ............................ 0 °C to 40 °C
Mating connectors
Motor/power supply ................................. Phoenix Contact 1757051 (included)
IN/OUT1................................................... DB-25 male (included)
Encoder feedback ..................................... HD-15 male
Accessories
Regeneration clamp .................................. NI SMD-7700, NI part number 748908-01
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Alarm Codes
In the event of an error, the green LED on the main board will flash one or two times, followed
by a series of red flashes. The pattern repeats until the alarm is cleared.
Table 5. Status LED Blink Code Definitions
Blink sequence
Code
Error
G
Solid green
No alarm, motor disabled
GG (slow)
Flashing green
No alarm, motor enabled
RG
1 red, 1 green
Motor stall (encoder-equipped only)
RGG
1 red, 2 green
Move attempted, drive disabled
RRG
2 red, 1 green
CCW limit
RRGG
2 red, 2 green
CW limit
RRRG
3 red, 1 green
Drive overheating
RRRGG
3 red, 2 green
Internal voltage out of range
RRRRG
4 red, 1 green
Power supply overvoltage
RRRRGG
4 red, 2 green
Power supply underoltage
RRRRRG
5 red, 1 green
Over current /short circuit
RRRRRGG
5 red, 2 green
Motor resistance out of range
RRRRRRG
6 red, 1 green
Open motor winding
RRRRRRGG
6 red, 2 green
Bad encoder signal
RRRRRRRG
7 red, 1 green
Serial communication error
RRRRRRRRG
8 red, 1 green
Internal voltage out of range
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374809A-01
Sep14