The document describes the M/VTM Series Servo Drive AVB200A100. It is designed to drive brushless DC motors for vehicle applications with a peak current of 200A and continuous current of 125A. It can interface with digital controllers or operate independently, accepting various command and feedback inputs. Key features include adjustable parameters, operating mode selection, and safety protections.
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Advanced motion controls avb200a100
1. M/V™ Series Servo Drive AVB200A100
Description
Power Range
AVB200A100 servo amplifiers are designed to drive brushless DC motors at a high switching frequency for vehicle applications. It is fully protected against over- voltage, over-current, over-heating, under-voltage and short-circuits. This model interfaces with digital controllers or can be used as a stand-alone drive and requires only a single unregulated DC power supply or battery. A single red/green LED and a single digital output indicate operating status. Loop gain, current limit, input gain, offset, command ramping, deadband can be adjusted using 14-turn potentiometers. The offset adjusting potentiometer can also be used as an on-board input signal for testing purposes. It will accept tachometer input, quadrature encoder inputs, or Hall sensor inputs for velocity control.
Peak Current 200 A
Continuous Current 125 A
Supply Voltage 20 - 80 VDC
Features
Four Quadrant Regenerative Operation
Ramped Command Input Adjustment
Adjustable Deadband Range
Drive Brushed or Brushless Motors
Compact Size, High Power Density
Selectable 120/60 Hall Commutation Phasing
Offset Adjustment Potentiometer
Ingress Protection Rating: IP65
Electromagnetic Holding Brake Output
Selectable Inhibit/Enable Logic
Adjustable Current Limits
Multiple Modes of Operation
MODES OF OPERATION
Current
Voltage
Duty Cycle (Open Loop)
IR Compensation
Velocity
Hall Velocity
COMMAND SOURCE
0 - 5V Analog
o Wigwag
o Inverted
0 – 5 kΩ
o 2-wire Pots
o 3-wire Pots
o Wigwag
o Inverted
FEEDBACK SUPPORTED
Halls
Incremental Encoder
Tachometer (±60 DC)
INPUTS/OUTPUTS
Inhibit/Enable Input
Forward and Reverse Inputs
Push Brake Release Inputs
Speed Limit Pot Input
Current Monitor Output
Velocity Monitor Output
Fault Output
COMPLIANCES & AGENCY APPROVALS
UL
cUL
RoHS
CE Pending
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2. M/V™ Series Servo Drive AVB200A100
BLOCK DIAGRAM
POT1VARIABLERC-BLOCKLOOP INTEGRATORVELOCITYCURRENT LOOPPOT6POT3 SW2-3 POT5 SW2-1SW2-2 SW1-1POT4SW1-4SW1-5SW1-320k10k..310kCW- + 10K- +20.8kPWM ANDCONTROLLOGIC10nF SW1-2 SW1-7Peak/Cont. CURRENTLIMIT100kP1-5PGNDSW3-1..55nF..82nFCF1*SW3-6..10DC-TO-DCSW1-9COMMANDLIMITERRAMP+5VISW2-4DEADBANDCW10K10k- + CW5k20k+5VIP1-12INH/ENABLE5k100k+5V-5V10kHALL/ENCCONV. 10k10kOFFINPUT COMMAND SELECTIONOFFONWIG-WAG INPUT DIRECTION2-WIRE POTENTIOMETERSW2SINGLE INPUT DIRECTION1OFFONONOFFON4FULL SPEED REVERSESTANDARD INPUTHALF SPEED REVERSE23-WIRE POTENTIOMETERINVERTED INPUT310k P1-15P1-20P1-13P1-14P1-21 10K P1-19 10k SW1-8SW1-6 SENSECURRENTCURRENTMONITORINTERNALCONVERTERDC-TO-DC P1-17 OFFN/AONOFFOFFONN/AONONOFFOFFOFF P1-23P1-7P1-22P1-8 10k10kQ2222220k+5VI+5VI50k HVIN BRAKE RF2* LIMITCWU31OFF=60ON=120U34RF1*IR-COMPENSATIONPOT2MOTOR AMAINH SELH-BRIDGEH1,H2,H3MCMOTOR C3-PhaseMOTOR BMB DEG ENC A,B2.2uFCF2* CURRENT100k0.47uFPGNDB+ B- AVB200A100 FUNCTIONAL BLOCK DIAGRAMKEYSWITCHP1-6HVINSW1-10CONVERSIONP1-1THROTTLEINPUTP1-16P1-100 to +/-30% SPEED/COMMAND LIMITFORWARDREF INLOOP GAINVELOCITYOFFONU20U32OFFSETTESTCWMax: 1.8s/VMin: 0.1s/VENC A,B+5VHE H3ENCAENCBH2H1INH/ENABLEDC-BUS CURRENTFAULT VOLTAGE FEEDBACKDRIVES ARE SHIPPED IN CURRENT MODE WITH MAXIMUM CURRENT SETTINGSLED GREEN -NORMAL OPERATION, LED RED -FAULTFOR OTHER SWITCH FUNCTIONS SEE SWITCH DESCRIPTIONRECOMMENDED SETTINGS FOR CURRENT MODE -POT1 FULLY CCW, POT3 FULLY CW* OPTIONAL USER INSTALLED THROUGH HOLE COMPONENTSDUTY CYCLE FEEDBACK MONITOR H1,H2,H3VELOCITY MODE SELECTOR+5VHE CURRENT LOOP OFF=VM VelDirCurr/Vel ON=CMCURRENT FEEDBACKSW1-5SW1-4 VELOCITY MONITOR MODE SELECTIONSW1-3P1-3POT-LOW (3mA)P1-4OFFOFFN/AOFFN/A -NOT APPLICABLEIR COMPENSATION** X -DEPENDENT ON APPLICATIONOFFENCODER VELOCITYCURRENTVOLTAGEHALL VELOCITYDUTY CYCLE BRAKE OUT (3A) TACH-IN+5VHE (250mA) BRAKE RETURN24V/200Hz PWM XXX SW1-7N/AXONOFFOFFOFFSW1-6OFFOFFONOFFP1-2SGNDREVERSEP1-11POT-HIGH (3mA) FAULTFAULT-OUTP1-18SGNDP1-9DIRECTIONLOGICN/AN/ATACHOMETERONXOFF** IR COMPENSATION MODE REQUIRES USER INSTALLED RESISTOR RF1 ON THE PCB
Information on Approvals and Compliances
US and Canadian safety compliance with UL 508c, the industrial standard for power conversion electronics. UL registered under file number E140173. Note that machine components compliant with UL are considered UL registered as opposed to UL listed as would be the case for commercial products.
RoHS (Reduction of Hazardous Substances) is intended to prevent hazardous substances such as lead from being manufactured in electrical and electronic equipment.
ELECTROMATE
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3. M/V™ Series Servo Drive AVB200A100
SPECIFICATIONS
Power Specifications
Description
Units
Value
DC Supply Voltage Range
VDC
20 - 80
DC Bus Over Voltage Limit
VDC
92
DC Bus Under Voltage Limit
VDC
16
Logic Supply Voltage (Keyswitch)
VDC
20 - 80
Maximum Peak Output Current1
A
200
Maximum Continuous Output Current
A
125
Max. Continuous Output Power
W
9500
Max. Continuous Power Dissipation
W
500
Internal Bus Capacitance
μF
6000
Minimum Load Inductance (Line-To-Line) 2
μH
250
Switching Frequency
kHz
14.6
Maximum Output PWM Duty Cycle
%
100
Control Specifications
Description
Units
Value
Command Sources
-
0 - 5 V Analog, 0 - 5 kΩ
Feedback Supported
-
Halls, Incremental Encoder, Tachometer (±60 VDC)
Commutation Methods
-
Trapezoidal
Modes of Operation
-
Current, Voltage, IR Compensation, Duty Cycle, Hall Velocity, Velocity
Motors Supported
-
Single Phase (Brushed, Voice Coil, Inductive Load), Three Phase (Brushless)
Hardware Protection
-
Over Current, Over Temperature, Over Voltage, Short Circuit (Phase-Phase & Phase-Ground), Under Voltage
Mechanical Specifications
Description
Units
Value
Agency Approvals
-
cUL, UL, RoHS, CE Pending
Size (H x W x D)
mm (in)
203.2 x 139.7 x 59.7 (8.0 x 5.5 x 2.4)
Size (H x W x D) with 23-pin mating connector installed
mm (in)
203.2 x 139.7 x 74.0 (8.0 x 5.5 x 2.9)
Weight
g (oz)
1638.60 (57.80)
Heatsink (Base) Temperature Range3
°C (°F)
0 - 75 (32 - 167)
Storage Temperature Range
°C (°F)
-20 - 85 (-4 - 185)
Cooling System3
-
Natural Convection
Form Factor
-
Vehicle Mount
IP Rating
-
65
I/O Connector
-
23-pin, AMPSEAL connector
MOTOR POWER Connector
-
3 Individual M6 threaded terminals
POWER Connector
-
2 Individual M6 threaded terminals
Notes
1. Maximum duration of peak current is ~10 seconds for zero-to-peak current commands. Peak-to-peak current commands should not be performed.
2. Lower inductance is acceptable for bus voltages well below maximum. Use external inductance to meet requirements.
3. Additional cooling and/or heatsink is required to achieve rated performance. Thermal grease recommended between baseplate and external heatsink.
Mating Connector Kit
Mating connector housing, socket contacts, and seal plugs can be ordered as a kit using ADVANCED Motion Controls’ part number KC-23AMPSEAL01. ELECTROMATE
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4. M/V™ Series Servo Drive AVB200A100
PIN FUNCTIONS
I/O - Signal Connector
Pin
Name
Description / Notes
I/O
1
THROTTLE IN
0 – 5 V reference command input or 0 – 5 kΩ resistance command input. Do not perform peak-to-peak current commands.
I
2
SIGNAL GROUND
SGND
3
POT HIGH
+5V @ 3 mA. For customer use. Reference to Signal Ground. Becomes disabled when 2- wire pot command is selected (SW2-2 = OFF)
O
4
POT LOW
Signal Ground.
SGND
5
POWER GROUND
Power Ground
PGND
6
KEYSWITCH
Master switch for the drive. Logic power input supply. Voltage range equal to DC Supply Voltage Range (see specifications table). This must be ON for the drive to function. Reference to Power Ground.
I
7
BRAKE
Brake Output. This output will energize when the Keyswitch is ON and the drive is enabled. Outputs up to 24V, 3A max. Reference to Brake Return.
O
8
BRAKE RETURN
Brake Return
I
9
SIGNAL GROUND
Signal Ground
SGND
10
FORWARD
When not in Wigwag mode, with only one input active at a time, Forward and Reverse inputs selects the direction of motion. Pull low (Signal Ground) to activate. When the drive is disabled or faulted, activating both Pins at the same time will energize Brake Output (Pin7). Activating only one input when the drive is disabled or faulted will not energize Brake Output.
I
11
REVERSE
I
12
INHIBIT/ENABLE
This TTL level input signal turns off all power devices of the “H” bridge when pulled to Signal Ground with SW1-9=ON. If SW1-9=OFF, pulling this pin to Signal Ground will enable the drive.
I
13
HALL 1
Hall sensor inputs. Logic levels: maximum low level input is 1.5 VDC, minimum high level input is 3.5 VDC. Reference to Power Ground.
I
14
HALL 2
I
15
HALL 3
I
16
SPEED/COMMAND LIMIT
Sets the maximum speed/command limit (command type dependent on the mode of operation). Voltage value at this pin will act as the upper limit available for the throttle input command
I
17
VELOCITY MONITOR
1V = 21.5 kHz Encoder Frequency; 1V = 100 Hz Hall Sensor Frequency. Reference to Power Ground.
O
18
FAULT OUT
This output activates during short circuit, over-voltage, under voltage, inhibit, over- temperature and power-on reset. A red LED also indicates a fault condition. Reference to Signal Ground. Can be used with an external voltage supply and LED for visual fault indication.
O
19
DC BUS CURRENT MONITOR
Scaling factor = 27.4 A/V. This output represents the actual power supply DC Bus current. Reference to Power Ground.
O
20
ENCODER A
Encoder Channel A. Reference to Power Ground.
I
21
ENCODER B
Encoder Channel B. Reference to Power Ground.
I
22
+5V OUT
+5V @ 150mA. For customer use. Reference to Power Ground.
O
23
TACH
Tachometer Input, 60k ohm input resistance, ± 60 V max. Reference to Power Ground.
I
MOTOR POWER - Power Connector
Terminal
Name
Description / Notes
I/O
MA
MOTOR A
Motor Phase A
O
MB
MOTOR B
Motor Phase B
O
MC
MOTOR C
Motor Phase C
O
POWER - Power Connector
Terminal
Name
Description / Notes
I/O
B-
BATT - / POWER GROUND
Power Ground
PGND
B+
BATT +
DC Power Input. Battery Power.
I
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5. M/V™ Series Servo Drive AVB200A100
HARDWARE SETTINGS
Switch Functions
SW1
Switch
Description
Setting
On
Off
1
Test / Offset controls the sensitivity of the “offset” pot. This is used as an on-board reference signal in test mode.
Test
Offset
2
120/60 degree commutation phasing.
120 degree phasing
60 degree phasing
3
Mode Select. Refer to Mode Selection Table
Duty-Cycle / Hall
Voltage / Encoder
4
Mode Select. Refer to Mode Selection Table
Hall / Encoder
Duty-Cycle / Voltage
5
Mode Select. Refer to Mode Selection Table
Tach Mode
Other Modes
6
Mode Select. Refer to Mode Selection Table
Current Mode
Velocity Modes
7
Velocity Integrator Capacitor
More Capacitance
(ON for Hall Velocity Mode)
Less Capacitance
8
Velocity Feedback Polarity (for Hall or Encoder Velocity Mode)
One Direction
Opposite Direction
9
Inhibit / Enable Logic Select
Ground Inhibit pin to Inhibit
Ground Inhibit enable motor outputs
10
Ramp Enable
Enable Command Ramping
No Command Ramping
Mode Selection Table
Operating modes can be selected by setting SW1 DIP switches according to the following table.
Mode
SW1-1
SW1-2
SW1-3
SW1-4
SW1-5
SW1-6
SW1-7
SW1-8
SW1-9
SW1-10
CURRENT
X
X
X
X
OFF
ON
X
X
X
X
DUTY CYCLE
X
X
ON
OFF
OFF
OFF
X
X
X
X
VOLTAGE
X
X
OFF
OFF
OFF
OFF
X
X
X
X
IR COMPENSATION*
X
X
OFF
OFF
OFF
OFF
X
X
X
X
HALL VELOCITY
X
X
ON
ON
OFF
OFF
ON
X
X
X
ENCODER VELOCITY
X
X
OFF
ON
OFF
OFF
X
X
X
X
TACHOMETER
X
X
X
X
ON
OFF
X
X
X
X
X = does not affect mode
* IR Comp Mode requires the addition of an IR Comp resistor RF1 on the PCB.
Input Command Type Selection Table
The input command type can be selected by setting SW2 DIP switches according to the following table.
SW2
Switch
Description
Setting
On
Off
1
Wigwag / Single-Ended Command Input
Wigwag
Single-ended
2
3-Wire / 2-Wire External Potentiometer Command Source
3-Wire
2-Wire**
3
Standard / Inverted Inputs
Standard
Inverted Inputs
4
Half Speed Reverse
Half Speed
Same Speed
**When 2-Wire is selected, Pot High (pin 3) becomes disabled. As an additional protection in 2-Wire setting, whenever the command input exceeds the acceptable range (0-5V or 0-5kΩ) the output command will be disabled until the command input is reset to a zero output command.
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6. M/V™ Series Servo Drive AVB200A100
Current Loop Tuning Values
SW3 DIP switches add additional resistance and capacitance to the current loop tuning circuitry. SW3 switches 1-5 add additional parallel capacitance to the current loop integrator capacitor, and SW3 switches 6-10 add additional series resistance to the current loop gain resistor (see Block Diagram). Capacitance and resistance values are given in the tables below along with the appropriate DIP switch settings.
SW3
Switch
Additional Current Loop Integrator Capacitance (μF)
SHORT
.082
.077
.072
.067
.062
.057
.052
.047
.035
.030
.025
.020
.015
.010
.005
OPEN
1
ON
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
2
ON
ON
ON
OFF
OFF
ON
ON
OFF
OFF
ON
ON
OFF
OFF
ON
ON
OFF
OFF
3
ON
ON
ON
ON
ON
OFF
OFF
OFF
OFF
ON
ON
ON
ON
OFF
OFF
OFF
OFF
4
ON
ON
ON
ON
ON
ON
ON
ON
ON
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
5
ON
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
SW3
Switch
Additional Current Loop Gain Resistance (kΩ)
0
10
20
30
40
50
60
70
80
90
100
110
120
130
140
150
6
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
7
ON
ON
OFF
OFF
ON
ON
OFF
OFF
ON
ON
OFF
OFF
ON
ON
OFF
OFF
8
ON
ON
ON
ON
OFF
OFF
OFF
OFF
ON
ON
ON
ON
OFF
OFF
OFF
OFF
9
ON
ON
ON
ON
ON
ON
ON
ON
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
10
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
Switch (continued)
160
170
180
190
200
210
220
230
240
250
260
270
280
290
300
310
6
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
7
ON
ON
OFF
OFF
ON
ON
OFF
OFF
ON
ON
OFF
OFF
ON
ON
OFF
OFF
8
ON
ON
ON
ON
OFF
OFF
OFF
OFF
ON
ON
ON
ON
OFF
OFF
OFF
OFF
9
ON
ON
ON
ON
ON
ON
ON
ON
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
10
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
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7. M/V™ Series Servo Drive AVB200A100
Potentiometer Functions
Potentiometer
Description
Turning CW
Pot 1
Loop gain adjustment in duty cycle and velocity modes. Turn this pot fully CCW in current mode.
Increases loop gain
Pot 2
Current limit. This potentiometer adjusts both the continuous and peak current limit while maintaining the continuous to peak ratio (~63%).
Increases current limit
Pot 3
Reference in gain. This potentiometer adjusts the ratio between input signal and output variables (voltage, current, and velocity).
Increases reference input gain
Pot 4
Test/Offset. Used to adjust any imbalance in the input signal or in the drive. When SW1-1 (DIP switch) is ON, the sensitivity of this pot is greatly increased allowing it to be used as an on-board signal source for testing purposes.
Zero speed setting is at the midpoint of this 14-turn pot.
Pot 5
Ramp Time. Sets the ramp time for the command input signal.
Decreases ramp time (faster response time)
Pot 6
Deadband. Adjusts the amount of Deadband up to 30% of the command range.
Decreases deadband
(quicker response to commands)
Note: Potentiometers are approximately linear and have 12 active turns plus 1 inactive turn on each end.
Ramping (Pot 5):
The built-in ramp circuit allows the command input to be ramped linearly. This feature is activated by setting SW1-10 = ON. The ramp time can be set for up to 20 seconds in reaching the max command by adjusting Pot 5 fully counter-clockwise. Ramping rates are linear with respect to time and apply to both directions of motion. For example, if the single-ended command input is only 2.5 Volts, the time to ramp to this voltage would be half the time to ramp to 5 Volts.
Deadband (Pot 6):
Deadband is adjustable through the use of the Deadband Pot for up to 30% of the command range in each direction. Commands within the set Deadband range will have no effect on the output. Once the command is beyond the Deadband, the drive will begin to output power to the motor. The Deadband will have an offset effect on the rest of the command range. Therefore, to reach the maximum command would require increasing the Reference Input Gain (Pot3).
Current Limit Adjustments:
These amplifiers feature separate peak and continuous current limits. The current limit adjustment Pot 2 adjusts both peak and continuous current limit at the same time. Pot 2 has 12 active turns and one inactive turn on each end and is approximately linear. Thus, to adjust the current limit turn the potentiometer counter-clockwise to zero, then turn clockwise to the appropriate value.
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8. M/V™ Series Servo Drive AVB200A100
Through-hole Components†
Location
Description
CF2*
Velocity Loop Integrator. Through-hole capacitor that can be added for more precise velocity loop tuning. See section below on Tuning with Through-hole components for more details.
CF1*
Current Loop Integrator. Through-hole capacitor that can be added for more precise current loop tuning. See section below on Tuning with Through-hole components for more details.
RF2*
Tachometer Gain Scaling. Through-hole resistor that can be added to change the gain of the tachometer input. See section below on Tachometer Gain for more details.
RF1*
IR Compensation Scaling. Through-hole resistor that can be added to configure the amplifier for IR Compensation mode. See section below on IR Compensation Notes for more details.
Tuning With Through-hole Components
In general, the drive will not need to be further tuned with through-hole components. However, for applications requiring more precise tuning than what is offered by the potentiometers and DIP switches, the drive can be manually modified with through- hole capacitors as denoted in the above table. By default, the through-hole locations are not populated when the drive is shipped. Before attempting to add through-hole components to the board, consult the section on loop tuning in the installation notes on the manufacturer’s website. A general rule of thumb to follow when adding through-hole components is:
• A larger capacitor value will increase the integration time, and therefore create a slower response time.
Proper tuning using the through-hole components will require careful observation of the loop response on a digital oscilloscope to find the optimal through-hole component values for the specific application.
Tachometer Gain
Some applications may require an increase in the gain of the tachometer input signal. This occurrence will be most common in designs where the tachometer input has a low voltage to RPM scaling ratio. The drive offers a through-hole location listed in the above table where a resistor can be added to increase the tachometer gain. Use the drive’s block diagram to determine an appropriate resistor value.
IR Compensation
For applications that will use IR Compensation mode, a resistor can be added to the location named in the table above. The combination of the added resistor and correct DIP switch settings will configure the amplifier for IR Compensation mode. While in IR Compensation mode, the amplifier will adjust the duty cycle to compensate for changes in the output current. Consult the amplifier’s functional block diagram and the manufacturer’s website for more information.
†NOTE: DAMAGE DONE TO THE DRIVE WHILE PERFORMING THESE MODIFICATIONS WILL VOID THE WARRANTY.
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9. M/V™ Series Servo Drive AVB200A100
MECHANICAL INFORMATION
I/O - Signal Connector
Connector Information
23-pin, AMPSEAL connector
Mating Connector
Details
TE Connectivity: Housing P/N 770680-1; Socket Contacts P/N 770854-3 (loose); Seal Plug P/N 770678-1; Crimp Tool P/N 58529-1
Included with Drive
No
1THROTTLE IN15HALL 316SPEED/COMMAND LIMIT2SIGNAL GROUND3POT HIGH4POT LOW5POWER GROUND6KEYSWITCH7BRAKE8BRAKE RETURN14HALL 213HALL 112INHIBIT/ENABLE11REVERSE10FORWARD9SIGNAL GROUND17VELOCITY MONITOR18FAULT OUT19DC BUS CURRENT MONITOR20ENCODER A21ENCODER B22+5V OUT23TACH
MOTOR POWER - Power Connector
Connector Information
Three individual M6 threaded terminal
Mating Connector
Details
M6 screw or bolt with washer
Included with Drive
Yes
POWER - Power Connector
Connector Information
Two individual M6 threaded terminal
Mating Connector
Details
M6 screw or bolt with washer
Included with Drive
Yes
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10. M/V™ Series Servo Drive AVB200A100
WIRING DIAGRAM
MotorEncoderHall SensorsKeyswitch InputKeyswitchReverseForwardInhibitBrake ReturnMain ContactorPower FuseControl FuseBatt+ Batt- / Power GNDBrakeMotor AMotor BMotor CHall 1*+5V SupplyHall 3Hall 2Power GNDEncoder AEncoder B*+5V SupplyFault OutEM BrakePot LowSpeed/Command LimitPot HighBattery 1TachTach - Tach Return / Power GNDThrottle PotSpeed Limit PotThrottle InputNOTE: All Feedback cannot be supported at one time*+5V Supply is only one connection pinON board Status LEDCurrent Monitor or DC Bus CurrentVUdCurrentVelocity MonitorIsolation (on 200V drives) Battery 2 or DC-DC ConverterPower GNDKeyswitch RelayVUdSpeedChassis GNDPower GNDFuseSignal GroundLED+5VDC500 ohm
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12. M/V™ Series Servo Drive AVB200A100
PART NUMBERING INFORMATION
A100200Peak CurrentBrushless MotorB: Motor TypeMaximum peak current rating in AmpsVStandard AnalogBlank: Drive TypeV:Vehicle (0-5V, 0-5K) ABPeak/Continuous RatioContinuous = ~0.6·PeakA: Continuous = PeakC: Maximum Voltage54V Over-Voltage060: 92V Over-Voltage100: 190V Over-Voltage200: Analog Servo Drive
ADVANCED Motion Controls servo drives are available in many configurations. Note that not all possible part number combinations are offered as standard drives. All models listed in the selection tables of the website are readily available, standard product offerings.
ADVANCED Motion Controls also has the capability to promptly develop and deliver specified products for OEMs with volume requests. Our Applications and Engineering Departments will work closely with your design team through all stages of development in order to provide the best servo drive solution for your system. Equipped with on-site manufacturing for quick- turn customs capabilities, ADVANCED Motion Controls utilizes our years of engineering and manufacturing expertise to decrease your costs and time-to-market while increasing system quality and reliability.
Examples of Customized Products
Integration of Drive into Motor Housing
Integrate OEM Circuitry onto Drive PCB
Mount OEM PCB onto Drive Without Cables
Custom Control Loop Tuned to Motor Characteristics
Multi-axis Configuration for Compact System
Custom I/O Interface for System Compatibility
Custom PCB and Baseplate for Optimized Footprint
Preset Switches and Pots to Reduce User Setup
RTV/Epoxy Components for High Vibration
Optimized Switching Frequency
OEM Specified Connectors for Instant Compatibility
Ramped Velocity Command for Smooth Acceleration
OEM Specified Silkscreen for Custom Appearance
Remove Unused Features to Reduce OEM Cost
Increased Thermal Limits for High Temp. Operation
Application Specific Current and Voltage Limits
Feel free to contact Applications Engineering for further information and details.
All specifications in this document are subject to change without written notice. Actual product may differ from pictures provided in this document.
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