Brushless DC Motor Driver Module in a Power Flatpack 100

SENSITRON
SEMICONDUCTOR
SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
TECHNICAL DATA
DATA SHEET 1023, REV. E
Brushless DC Motor Driver Module in a Power Flatpack
100-250V, 40 Amp
FEATURES:
• Fully integrated 3-Phase Brushless DC Motor Control Subsystem includes power stage, non-isolated
driver stage, and controller stage
• MOSFET Output Stage
• 40A Average Phase Current with 10V to150V Maximum Bus Voltage
• Internal Precision Current Sense Resistor (10W max. dissipation)
• Cycle by cycle current limiting.
• Fixed frequency PWM from zero speed to full speed.
• Closed-loop Speed Control of Motor
• Direction Input for direction reversal of Motor
• Tacho output with average output proportional to speed
• Brake Input for Dynamic Braking of Motor
• Overvoltage/Coast Input for Shutdown of All Power Switches
• Enable/Disable input with Soft Start for Safe Motor Starting
• Hermetic or non-hermetic device (3.10" x 2.10" x 0.385")
• Hermetic Device Part # (SMC6M40-XX)
• Non-Hermetic Device Part # (SMC6M40-XX-1)
APPLICATIONS:
• Fans and Pumps
• Hoists
• Actuator Systems
DESCRIPTION:
The SMC6M40-XX is an, integrated three-phase brushless DC motor controller/driver subsystems housed
in a 43 pin power flatpack. The SMC6M40-XX is best used as a two quadrant speed controller for
controlling/driving fans, pumps, and motors in applications which require small size. Many integral control
features provide the user much flexibility in adapting the SMC6M40-XX to specific system requirements.
The small size of the complete subsystem is ideal for aerospace, military, high-end industrial, and medical
applications.
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SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
SENSITRON
SEMICONDUCTOR
TECHNICAL DATA
DATA SHEET 1023, REV. E
COMMUTATION TRUTH TABLE
This table shows the Phase Output state versus the state of the Hall-Effect and Direction Inputs. The commutation
o
coding shown reflects Hall-Effect sensors that are spaced at 120 mechanical increments. Also, internal protection
logic disables all three Phase Outputs when the Hall-Effect Inputs are set to an illegal condition (i.e., all logic low or all
logic high).
DIGITAL INPUTS
Dir
1
1
1
1
1
1
0
0
0
0
0
0
X
X
H1
0
0
0
1
1
1
1
1
1
0
0
0
0
1
Part Number
H2
0
1
1
1
0
0
0
0
1
1
1
0
0
1
PHASE OUTPUTS
H3
1
1
0
0
0
1
1
0
0
0
1
1
0
1
A
Hi-Z
Sink
Sink
Hi-Z
Source
Source
Sink
Sink
Hi-Z
Source
Source
Hi-Z
Hi-Z
Hi-Z
B
Sink
Hi-Z
Source
Source
Hi-Z
Sink
Source
Hi-Z
Sink
Sink
Hi-Z
Source
Hi-Z
Hi-Z
C
.
Source
Source
Hi-Z
Sink
Sink
Hi-Z
Hi-Z
Source
Source
Hi-Z
Sink
Sink
Hi-Z
Hi-Z
Motor
Supply
Voltage
Motor
Peak
Voltage
Average
Output
Current
Peak
Output
Current
Rds(on)
SMC6M40-10-YY
60
100
40
60
15
Yes
SMC6M40-10-1-YY
60
100
40
60
15
No
SMC6M40-25-YY
150
250
40
60
60
Yes
SMC6M40-25-1-YY
150
250
40
60
60
No
Hermetic?
ID =20A
PART NUMBER/SELECTOR GUIDE TABLE
Current Sense Resistor value and lead bend options shall be:
SMC6M40-XX-1-YYZ where YY is the sense resistor value and Z is the lead bend option if needed
Part number SMC6M40-XX-1-10B has a 10mOhm resistor, and option B lead bend.
For an open frame without a cover add –O to the part number.
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SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
SENSITRON
SEMICONDUCTOR
TECHNICAL DATA
DATA SHEET 1023, REV. E
ABSOLUTE MAXIMUM RATINGS
Characteristic
Maximum
Motor Supply Voltage SMC6M40-10
SMC6M40-25
Motor Peak Voltage SMC6M40-10
SMC6M40-25
Average Output Current
Peak Output Current
Control Supply Voltage VCC
Logic Input Voltage (Note 1)
Reference Source Current
Logic Input Voltage
Error Amplifier Input (EA1+/EA1-)
Error Amplifier Output Current
Spare Amplifier Input Voltage (EA2+/EA2-)
Spare Amplifier Output Current
Current Sense Amplifier Input Voltage (ISH/ISL)
Current Sense Amplifier Output Current
Tachometer Output Current
PWM Input Voltage
Operating & Storage Junction Temperature
80 V
200
100 V
250V
40 A
60 A
18 V
-0.3 V to +8 V
-30 mA
-0.3 to +8 V
-0.3 to +10 V
±8 mA
-0.3 to +10 V
±8 mAdc
-0.3 V to +6 V
±10 mAdc
+/- 10 mA
- 0.3 V to +6 V
-55 oC to +150 oC
1.0 oC/W
600V DC
300°C
Power Devices Thermal Resistance RthjC
Pin-to-Case Voltage Isolation, at room conditions
Lead Soldering Temperature, 10 seconds maximum, 0.125” from case
* Tcase = 25° C
Recommended Operating Conditions (TC=25 oC)
Characteristic
Maximum
Motor Supply Voltage SMC6M40-10
SMC6M40-25
Average Output Current
for SMC6M40-XX, TC=80oC
Control Supply Voltage VCC
60 V
150 V
30 A
15 V +/-10%
Note 1: Logic Inputs: Direction, Hall Inputs (H1...H3) Over-voltage - Coast, Speed, and Quad Select.
Note 2: The internal current sense resistor is limited to 6 Watt dc power dissipation. Other values are available.
Please contact the factory for more information.
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SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
SENSITRON
SEMICONDUCTOR
TECHNICAL DATA
DATA SHEET 1023, REV. E
PARAMETER SYMBOL CONDITIONS (NOTE 1)
Power Output Section
Drain-Source Leakage Current IDss at 0.8VDss
Diode Forward Voltage VF at IF = 20 A
Diode Reverse Recovery Time trr IF = 20A, di/dt = -100A/usec,
Drain-to-Source On-Resistance Rds(on) ID =20A
100V, 40A Device, SMC6M40-10
250V, 40A Device, SMC6M40-25
VCC =12V Note (3)
Control Section
Control Supply Current Icc at Vcc =12V
Control Turn-On Threshold Vcc(+) Tc over operating range
Driver Turn-On Threshold Vcc(+) Tc over operating range
5V Reference Section
Output Voltage Vref
Output Current Io
Load Regulation Iload = 0mA to –20mA
Error Amplifier / Spare Amplifier Sections
EA1 / EA2 Input Offset Current Ios V(pin 2) = V(pin 4) = 0V
V(pin 3) = V(pin 6) = 0V
EA1 / EA2 Input Bias Current Iin V(pin 2) = V(pin 4) = 0V
V(pin 3) = V(pin 6) = 0V
Input Offset Voltage, VCM=0V
Amplifier Input Common-mode Voltage Range Vcc=12V
Amplifier Output Voltage Range VOH
Amplifier Output Voltage Range VOL
PWM Comparator Section
Propagation Delay Time
Input Common Mode range
Current-Sense Amplifier Section
ISH / ISL Input Voltage Range
Input Offset Voltage
Input Bias Current
Amplifier Voltage Gain
High Level Output Voltage, Iout =-100 uA
Low Level Output Voltage , Iout =100 uA
Output Source Current
Over-Current Comparator
Input Common-mode Range
Propagation Delay Time
Logic Input Section
H1, H2, H3 High-Level Input Voltage Threshold
H1, H2, H3 Input Hysteresis
H1, H2, H3 Input Current, 0.0 < Vin <5.0V
MIN.
TYP.
MAX.
UNITS
250
1.0
300
uA
V
nSec
15
60
mΩ
9.0
8.0
10.5
9.0
30
11.0
10.0
mA
V
V
4.7
-
5.0
-
5.3
30
30
V
mA
mV
-
6
75
nA
-
100
500
nA
0
10
-
1.5
11
0.1
5
9
0.5
mV
V
V
V
70
2.0
-
150
8.0
nsec
V
-0.5
5
4.75
6.0
300
10
5.0
-
Vcc – 1.0
8
15
5.25
70
-
V
mV
uA
V
V
mV
uA
0.0
40
170
50
260
V
nsec
1.7
0.6
-
1.9
-30
2.1
1.0
-
V
V
uA
Coast, Start/Stop High-Level Input Voltage Threshold
Coast, Start/Stop Low -Level Input Voltage Threshold
3.6
-
-
1.9
V
V
Quad, Brake, Dir in High-Level Input Voltage Threshold
Quad, Brake, Dir in Low-Level Input Voltage Threshold
3.6
-
-
1.9
V
V
Tachometer
Tachometer Output High Level Voh
Tachometer Output Low Level Vol
Tachometer On-Time ton
Tachometer On-Time Variation
4.7
130
5.0
140
5.3
50
150
V
mV
us
0.200
0.250
0.280
V
16
18
20
kHz
135
115
145
125
155
135
Speed Input Threshold Voltage Vth
Oscillator Section
Oscillator Frequency fo
Over-Temperature Shutdown
Trip Temperature
Reset Temperature
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o
C
SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
SENSITRON
SEMICONDUCTOR
TECHNICAL DATA
DATA SHEET 1023, REV. E
SPECIFICATION NOTES:
1- All parameters specified for Ta = 2 C, Vcc = 15Vdc, and all Phase Outputs unloaded. All negative currents shown are sourced
by (flow from) the pin under test
2- Either ISH or ISL may be driven over the range shown.
3- Pulse Test: Pulse Width < 300 µSec, Duty Cycle < 2%.
PINOUTS
PIN#
NAME
PIN#
NAME
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
VCC
EA1 “-” Input
EA2 “+” Input
EA1 “+” Input
+5V Reference Output
EA2 “-” Input
EA2 Output
EA1 Output
Ioc Ref
Direction Out
Iso
ISH
ISL
Quad Select Input
Tachometer Output
Brake Input
Over-voltage/Coast Input
Start/Stop Input
Ground
HC Input
HB Input
HA Input
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
(Case)
Speed Input
Direction Input
CSH
CSL
+VDC Return
+VDC Return
Source C
Source C
Phase C Output
Phase C Output
+VDC
Source B
Source B
Phase B Output
Phase B Output
+VDC
Source A
Source A
Phase A Output
Phase A Output
+VDC
(No Connection)
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SENSITRON
SEMICONDUCTOR
SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
TECHNICAL DATA
DATA SHEET 1023, REV. E
Fig. 2: Mechanical
Fig. 2: Mechanical
Outline For
Outline
Hermetic
For Hermetic
Package,Package,
FLPK1, SMC6M40-XX
SMC6M40-XX
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SENSITRON
SEMICONDUCTOR
SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
TECHNICAL DATA
DATA SHEET 1023, REV. E
Fig. 3: Mechanical Outline For Plastic Case Package, FLPK1-1
SMC6M40-XX-1
For Option B part number is SMC6M40-XX-1-YYB, for Option C part number is SMC6M40-XX-1-YYC,
Where YY is the Current Sense Resistor Value in m Ohms 05,10,30,…..
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SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
SENSITRON
SEMICONDUCTOR
TECHNICAL DATA
DATA SHEET 1023, REV. E
Pin Descriptions
Vcc ( Pin 1 ), is the input biasing supply connection for the controller. Under-voltage lockout
keeps all outputs off for Vcc below 10.5V. Vcc pin should be connected to an isolated 15V
power supply. The return of Vcc is pin 19.
EA1- ( Pin 2 ), is the error amplifier inverting input.
EA2+ ( Pin 3 ), is the non-inverting input of a spare amplifier.
EA1+ ( Pin 4 ), is the error amplifier non-inverting input. EA1- and EA1+ are not internally
committed to allow for a wide variety of uses. They can be connected to Io for current-mode
control, or Tach output for voltage-mode control.
+5V Ref( Pin 5 ), is a 5V reference with 30mA of maximum available output current. This pin
should bypassed to Gnd with 1-5µF capacitor depending on the load current.
EA2- ( Pin 6 ), is the inverting input of a spare amplifier.
EA2 ( Pin 7 ), out is the output of a spare amplifier.
EA1 ( Pin 8 ), out is the output of the error amplifier and is internally connected to the PWM
comparator.
Ioc-Ref ( Pin 9 ), is the over-current reference voltage. It is internally set to 1.15V. This
reference can be reduced by connecting a resistor between Ioc Ref and Gnd . The resistor
value is
R= (Ioc-Ref) /(0.05 - 0.043*(Ioc-Ref)) KΩ
(1)
Also, Ioc Ref can be increased by connecting a resistor between Ioc Ref and the 5V
reference. The resistor value is
R= (5.0 – (Ioc-Ref))/(0.043*(Ioc-Ref) – 0.05) KΩ
(2)
This pin is connected to the over-current comparator for cycle-by-cycle current limiting. The
over-current reference voltage is set according to the formula
Ioc-Ref=Rs*Ip*5 volts
(3)
Where Rs is the current sense resistor value in ohms and Ip is peak current limit in amperes.
Dir out ( Pin 10 ), is direction output representing the actual direction of the rotor as
decoded from the hall sensors. There are two valid transitions of the hall sensor inputs; one
translates to a clockwise rotation and another which translates to a counterclockwise rotation.
The polarity of Dir-out is the same as Dir-in while motoring.
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SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
SENSITRON
SEMICONDUCTOR
TECHNICAL DATA
DATA SHEET 1023, REV. E
Is-out ( Pin 11 ), is the absolute value output of the current sense amplifier.
Is-out = ABS(ISL – ISH)
(4)
ISH ( Pin 12 ), is the non-inverting input of the current sense amplifier.
ISL ( Pin 13 ), is the inverting input of the current sense amplifier.
Quad ( Pin 14 ), is the select input of two-quadrant (Quad=0) or four-quadrant (Quad=1)
operation.
Tach-out ( Pin 15 ), is a fixed pulse width variable frequency output proportional to the
motor speed. A pulse is generated at both rising and falling edges of HA, HB, HC inputs. So
this output can be used as a true tachometer for speed feedback with an external filter or
averaging circuit which usually consists of a resistor and capacitor, as shown in Figs 9 & 10.
Brake ( Pin 16 ), is a digital input which causes the device to inter into brake mode. In brake
mode all three low-side switches are turned off and high-side switches are turned on. The
only conditions that can inhibit the high-side command during brake mode are UVLO, the
output of the PWM comparator, Coast input, or Start/Stop input.
Coast ( Pin 17 ), is a digital input that disables all outputs once pulled high. This input is
internally pulled low.
Start/Stop ( Pin 18 ), is a digital input that disables all outputs once pulled low. This input is
pulled high internally. This input can be used as enable/disable input using a switch. If the
switch is opened, the controller is enabled. If the switch is closed to Gnd, the controller is
disabled.
Signal Gnd ( Pin 19 ), is the reference ground for all control signals of the device. All bypass
capacitors, loop compensation components must be connected as close as possible pin 19.
This pin should not be externally connected to the power ground pins 27 and 28.
HC ( Pin 20 ), is hall input of phase C.
HB ( Pin 21 ), is hall input of phase B.
HA ( Pin 22 ), is hall input of phase A.
HA, HB, HC are designed to accept rotor position information from hall sensors positioned
120o apart. Motors with 60o position sensing may be used if one or two of the hall-effect
sensor signals is inverted prior to connection to the hall-effect inputs.
HA, HB, HC inputs are internally pulled up, zener clamped to 6.2V, and filtered.
Speed-in ( Pin 23 ), is a speed input to latch the direction input when the motor is spinning
fast.
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SENSITRON
SEMICONDUCTOR
SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
TECHNICAL DATA
DATA SHEET 1023, REV. E
Dir-in ( Pin 24 ), is the direction digital input. Logic “H’ correspond to forward rotation, and
logic “L” correspond to reversed rotation.
The direction input can be latched by Speed-in input. As long as Speed-in is less than
0.250V, the direction latch is transparent. When Speed-in is higher than 0.250V changing
direction of rotation will enable coast until the Speed-in drops below 0.250V. Direction latch is
recommended in two-quadrant operation mode to allow the motor to coast to a safe speed
before reversing.
CSH ( Pin 25 ),is the positive terminal of the current sense resistor.
CSL ( Pin 26 ),is the negative terminal of the current sense resistor.
The current sense terminals produce a differential voltage equal to the motor current times
the sense resistance (5 or 10 mΩ typical). There is an internal 2nF filter capacitor across pins
25 and 26, There is also a 100 Ω resistor between each pin and each end of the current
sense resistor. Pins 25 and 26 shall be externally connected to pins 12 and 13 to activate
the cycle-by-cycle current limiting.
+VDC Rtn ( Pins 27 & 28 ), are the motor supply return. Pins 27 and 28 should not be
connected to the signal Gnd pin 19.
Source Terminals ( Pin 29, 30, 34, 35, 39, 40 ), are the source terminals of the three arms
of the three-phase bridge. These pins shall be shorted together externally using a low
impedance bus to minimize power loss.
Phase C Outputs ( Pin 31, 32 ), are phase C terminals. Both terminals shall be used.
Phase B Outputs ( Pin 36, 37 ), are phase B terminals. Both terminals shall be used.
Phase A Outputs ( Pin 41, 42 ), are phase A terminals. Both terminals shall be used.
+VDC ( Pins 33, 38, 43 ), are the motor input power supply positive terminal. These pins
shall be shorted together externally using a low impedance bus. +VDC bus should bypassed
to +VDC Rtn with adequately voltage-rated low ESR capacitor, whose value can is least 1015µF per ampere of average motor current.
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SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
SENSITRON
SEMICONDUCTOR
TECHNICAL DATA
DATA SHEET 1023, REV. E
Application Information
60o Rotor Position Sensing
SMC6M40-XX is designed to operate with 120o position sensing encoding. In this
format, the three position sensor signals are never simultaneously high or low. Motors
whose sensors provide 60o encoding can be converted to 120o using the circuit shown
in Fig. 4.
Two-Quadrant vs Four-Quadrant
In two-quadrant mode only one switch is modulated at any time while in four-quadrant
operation two switches are modulated. This results in a more efficient controller and less EMI
emission when operating in two-quadrant mode. However, two-quadrant mode has some
limitations as explained below.
Fig. 5 illustrates the four possible quadrants of operation for a motor. Two-quadrant mode
refers to a motor operating in quadrants I and III. With a two-quadrant BDC motor, friction is
the only force to decelerate the load. Four-quadrant control provide controlled operation in all
quadrants, including II and IV, where torque and rotation are of opposite directions.
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SENSITRON
SEMICONDUCTOR
SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
TECHNICAL DATA
DATA SHEET 1023, REV. E
When configured in two-quadrant mode, Quad=0, SMC6M40-XX modulates only the high-side
devices of the output power stage. The current paths within the output stage during the PWM
on and off times are illustrated in Fig. 6. During the on time, both switches S1 and S4 are on,
the current flows through both switches and the motor winding. During the off time, the upper
switch S1 is shut off, and the motor current circulates through the lower switch S4 and D2.
The motor is assumed to be operated in quadrants I or III.
If operation is attempted in quadrants II or IV by changing the Dir input, S1 and S4 are turned
off and S2 and S3 are turned on. Under this condition motor current very quickly decays,
reverses direction and increases until the over-current limit is reached. At this point, S3 turns
off the current circulates in S2 and D4, and continue to rise due to the fact that the back emf
is in-phase with the current because the motor direction has not changed yet. Fig. 7 illustrates
the current path in this case. Under these conditions there is nothing to limit the current other
than the controller and the motor impedance. These circulating currents can result in damage
to the power stage if the load inertia is high.
In four-quadrant mode, Quad=1, both upper and lower switches are modulated. Motor current
always decays during off time, eliminating any uncontrolled circulating current. In addition, the
current always flows through the current sense resistor. Fig. 8 illustrates the current paths
during torque reversal.
It is recommended in two-quadrant operation to utilize the speed input, pin 23, for safe
direction reversal. The direction input can be latched by speed input. As long as Speed-in is
less than 0.250V, the direction latch is transparent. When Speed-in is higher than 0.250V
changing direction of rotation will enable coast until the Speed-in drops below 0.250V. The
Speed-in signal is obtained by low-pass filtering the Tach output, pin 15, using RC filter.
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SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
SENSITRON
SEMICONDUCTOR
TECHNICAL DATA
DATA SHEET 1023, REV. E
Control Modes
Typically, speed regulation is achieved by regulating the average input voltage to the motor,
while torque regulation is achieved by current control. Voltage and current control loops may
be combined to achieve a specific speed-torque curve.
Voltage-Mode Control
Fig. 9 shows the implementation of a typical speed control loop. A voltage command
proportional to the desired speed is applied at pin4 and can be set by a potentiometer, R3.
The speed feedback signal is obtained by low-pass filtering the Tach, pin15, output using R1
and C1. Small signal compensation of the speed control loop is provided by an internal error
amplifier. The integrating capacitor C2 places a pole at 0 HZ and a zero in conjunction with
R2. This zero can be used to cancel the low-frequency motor pole and to cross the loop with –
20dB gain response.
The output of the error amplifier is connected to the PWM comparator. Since the motor speed
is proportion to the average phase voltage, the speed is controlled via duty cycle control.
For open loop speed control, pin 2 shall be shorted to pin 8. The error amplifier acts as a
voltage follower and buffer to the command input.
Cycle-by-cycle current limiting is provided by connecting pins 25 and 26 to pins 12 and 13.
The over-current limit is set by the over-current reference IocRef at pin 9. This reference is set
internally to 1.15V, and can be altered using a resistor externally, see equations (1) to (4) for
details. The current signal is filtered internally, and amplified with a gain of 5.
Current Mode Control
Fig. 10 shows the implementation of a typical torque control loop. A voltage command
proportional to the desired current is applied at pin 4 and can be set by a potentiometer, R3.
The current feedback signal, Iso at pin11, is obtained by the internal current sensor and the
absolute value amplifier. Small signal compensation of the feedback control loop is provided
by an internal error amplifier. The error amplifier output is connected to the PWM comparator.
Since the torque is proportional to the average phase current, the torque is controlled via duty
cycle control.
It is recommended to set the over-current limit reference IocRef at pin 9 at a value slightly
higher than the maximum peak command current. This will maintain the cycle-by-cycle
current limiting even if the error amplifier saturates during large signal disturbance.
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SENSITRON
SEMICONDUCTOR
SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
TECHNICAL DATA
DATA SHEET 1023, REV. E
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SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
SENSITRON
SEMICONDUCTOR
TECHNICAL DATA
DATA SHEET 1023, REV. E
DC Bus Filtering
To minimize the circuit parasitic inductance effect on the power stage, the layout of Fig. 11 is
suggested. C1, C2, and C3 are 0.1µF to 0.5µF ceramic capacitors, connected across each leg
of the three-phase bridge. Also, a bulk polarized capacitor C4 of 10µF to 15 µF per ampere of
average motor current should be connected across the DC bus.
Cleaning Process:
Suggested precaution following cleaning procedure:
If the parts are to be cleaned in an aqueous based cleaning solution, it is recommended that the
parts be baked immediately after cleaning. This is to remove any moisture that may have
permeated into the device during the cleaning process. For aqueous based solutions, the
recommended process is to bake for at least 2 hours at 125oC.
Do not use solvents based cleaners.
Recommended Soldering Procedure:
Signal pins 1-26: 210C for 10 seconds max
Power pins 27 to 43: 260C for 10 seconds max.
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SENSITRON
SEMICONDUCTOR
SMC6M40-10
SMC6M40-10-1
SMC6M40-25
SMC6M40-25-1
TECHNICAL DATA
DATA SHEET 1023, REV. E
DISCLAIMER:
1- The information given herein, including the specifications and dimensions, is subject to change without prior notice to improve product
characteristics. Before ordering, purchasers are advised to contact the Sensitron Semiconductor sales department for the latest version of the
datasheet(s).
2- In cases where extremely high reliability is required (such as use in nuclear power control, aerospace and aviation, traffic equipment, medical
equipment , and safety equipment) , safety should be ensured by using semiconductor devices that feature assured safety or by means of users’
fail-safe precautions or other arrangement .
3- In no event shall Sensitron Semiconductor be liable for any damages that may result from an accident or any other cause during operation of
the user’s units according to the datasheet(s). Sensitron Semiconductor assumes no responsibility for any intellectual property claims or any
other problems that may result from applications of information, products or circuits described in the datasheets.
4- In no event shall Sensitron Semiconductor be liable for any failure in a semiconductor device or any secondary damage resulting from use at
a value exceeding the absolute maximum rating.
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6- The datasheet(s) may not be reproduced or duplicated, in any form, in whole or part, without the expressed written permission of Sensitron
Semiconductor.
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maintenance of international peace and safety nor are they to be applied to that purpose by their direct purchasers or any third party. When
exporting these products (technologies), the necessary procedures are to be taken in accordance with related laws and regulations.
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