29 amp, 75v, 3 phase mosfet bridge with intelligent integrated gate

MIL-PRF-38534 CERTIFIED
M.S.KENNEDY CORP.
29 AMP, 75V, 3 PHASE MOSFET
BRIDGE WITH INTELLIGENT
INTEGRATED GATE DRIVE
4401
4707 Dey Road Liverpool, N.Y. 13088
(315) 701-6751
FEATURES:
75 Volt Motor Supply Voltage
29 Amp Output Switch Capability, All N-Channel MOSFET Output Bridge
100% Duty Cycle High Side Conduction Capable
Suitable for PWM Applications from DC to 100KHz
Shoot-Through/Cross Conduction Protection
Undervoltage Lockout Protection
Programmable Dead-Time Control
Low Active Enable for Bridge Shutdown Control
Non-Hermetic Isolated Case for High Voltage Isolation
Available with 4 Lead Bend Options
DESCRIPTION:
The MSK 4401 is a 3 phase MOSFET bridge plus drivers in a convenient isolated plastic power package. The
module is capable of 29 amps of output current and 75 volts of DC bus voltage. It has a full line of protection
features, including undervoltage lockout protection of the bias voltage, cross conduction control and a user programmable dead-time control for shoot-through elimination. In addition, the bridge may shut down by using the ENABLE
control. The MSK 4401 provides good thermal conductivity for the MOSFETs due to isolated plate design that allows
direct heat sinking of the device without insulators.
EQUIVALENT SCHEMATIC
PIN-OUT INFORMATION
TYPICAL APPLICATIONS
3 Phase Brushless DC
Servo Control
Fin Actuator Control
Gimbal Control
3 Phase AC
Induction Motor Control
HVAC Blower Control
1
2
3
4
5
6
7
8
9
10
1
BH
BL
AL
AH
SWR
VBIAS
EN
CL
CH
GND
20
19
18
17
16
15
14
13
12
11
AØ
AØ
V+
V+
BØ
BØ
CØ
CØ
RSENSE
RSENSE
Rev. H 1/11
ABSOLUTE MAXIMUM RATINGS
V+ High Voltage Supply 6
VBIAS Bias Supply
VIND Logic Input Voltages
IOUT Continuous Output Curren
IPK
Peak Output Current
AØ, BØ, CØ
RSENSE
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-3V transient to +75V
-0.3V to +16V
-0.3V to VBIAS +0.3V
29A
41A
-3V transient to +75V
-3V transient to +3V
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5
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θJC Thermal Resistance
TST (Output Switches @125°C)
TLD Storage Temperature Range
Lead Temperature Range
TC (10 Seconds)
TJ Case Operating Temperature
Junction Temperature
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ELECTRICAL SPECIFICATIONS
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3.0°C/W
-55°C to +125°C
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+300°C
-40°C to +85°C
+150°C
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Tc=+25°C unless otherwise specified
Test Conditions 2
Parameter
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MSK 4401
Min.
Typ.
Max.
Units
CONTROL SECTION
VBIAS Quiescent Current
All Inputs Off
-
6
8
mAmp
VBIAS Operating Current
f=20KHz, 50% Duty Cycle
-
12.5
25
mAmp
Undervoltage Threshold (Falling)
5.6
6.6
7.6
Volts
Undervoltage Threshold (Rising)
6.1
7.1
8.1
Volts
-
-
0.8
Volts
2.7
-
-
Volts
Low Level Input Voltage
1
High Level Input Voltage 1
Low Level Input Current 1
VIN=0V
55
100
140
μAmp
High Level Input Current 1
VIN=5V
-10
-
+10
μAmp
ID=250μA, All Inputs Off
70
-
-
V
VDS=70V
-
-
250
μAmp
ID=29A
-
-
1.25
V
ID=29A
-
-
0.013
Ω
V+=29V, RL=1Ω
-
120
-
nSec
OUTPUT BRIDGE
Drain-Source Breakdown Voltage 1
Drain-Source Leakage Current 3
Drain-Source On Voltage
3
Drain-Source On Resistance 4
(Each FET, for thermal calculations only)
SWITCHING CHARACTERISTICS
Rise Time 1
ID=29A
-
81
-
nSec
Enable Turn-On Prop Delay (Lower) 1
SWR Resistor=∞
-
0.5
2
μSec
Enable Turn-Off Prop Delay (Lower) 1
SWR Resistor=∞
-
5
8
μSec
Enable Turn-On Prop Delay (Upper) 1
SWR Resistor=∞
-
5
8
μSec
Enable Turn-Off Prop Delay (Upper) 1
Fall Time 1
SWR Resistor=∞
-
0.5
2
μSec
Dead Time
SWR=Open
3.0
5.0
7.0
μSec
Dead Time
SWR=12K
0.3
0.6
1.2
μSec
ISD=29A
-
2.5
-
Volts
ISD=10A, di/dt=100A/μS
-
120
-
nSec
SOURCE-DRAIN DIODE CHARACTERISTICS
Forward Voltage 1
Reverse Recovery Time 1
NOTES:
1
2
3
4
5
6
Guaranteed by design but not tested. Typical parameters are representative of actual device performance but are for reference only.
VBIAS=+12V, V+=28V, RSENSE A,B=Ground, DIS=0V, EN=0V, SWR=open unless otherwise specified.
Measured using a 300μSec pulse with a 2% duty cycle.
On Resistance is specified for the internal MOSFET for thermal calculations. It does not include the package pin resistance.
Continuous operation at or above absolute maximum ratings may adversly effect the device performance and/or life cycle.
When applying power to the device, apply the low voltage followed by the high voltage or alternatively, apply both at the
same time. Do not apply high voltage without low voltage present.
2
Rev. H 1/11
APPLICATION NOTES
MSK 4401 PIN DESCRIPTIONS
AL,BL,CL - Are the lowside logic level digital inputs. These
three inputs control the three lowside bridge transistors. If the
highside inputs are low, then the lowside inputs will control
both the lowside and the highside of the bridge, with deadtime
set by the SWR resistor. EN will override these inputs, forcing
all outputs low. These inputs can be driven by logic up to 15V
(less than VBIAS). An internal pullup to VBIAS will hold each
input high if the pins are not driven.
AH,BH,CH - Are the highside logic level digital inputs. These
three inputs control the three highside bridge transistors. Unless the deadtime is disabled by connecting SWR to ground, the
lowside input of each phase will override the corresponding
highside input. If SWR is the lowside input of each phase will
override the corresponding highside input. In this condition,
tied to ground, deadtime is disabled and the outputs follow the
inputs. In this condition, shoot-through must be avoided externally. EN will override all inputs, forcing outputs low.
BUS VOLTAGE FILTER CAPACITORS
The size and placement of the capacitors for the main voltage
bus for the motor will have an effect on the noise filtered throughout the rest of the system. Series RLC tuned circuit is being
created by the inductance of the wire (about 30nH per inch),
the filter capacitance, and all of the resistances (wire resistance
and the capacitor ESR) of the overall power circuit. Voltage
spikes from the back EMF if the motor ride on top of the bus
voltage. All of this must be taken into account when laying out
the system. A first capacitor of high quality and low ESR should
be placed as close to the hybrid circuit as possible. Along with
that, a capacitor of 5x to 10x the first value should be added
(and that second capacitor should have some ESR) and/or a
resistor should be added to help with the damping of the voltage spikes. Be careful of the ripple current in all the capacitors.
Excessive ripple current, beyond what the capacitor is rated
for, will destroy the capacitor.
VBIAS - Is the positive supply for the gate drive. This pin should
be decoupled to ground with at least a 22μF capacitor in parallel
with a 0.1μF ceramic capacitor.
GROUND - Is the return for the VBIAS supply. This pin should
be connected to the return of the lowside MOSFETs or the bottom of the sense resistor at the bottom of the bridge. The gate
drive current must return through this pin, so trace lengths should
be kept to a minimum. All grounds should be returned to the
bottom of the bridge or sense resistor in a star fashion. This
will eliminate ground loops.
SWR - Is the pin for controlling the deadtime between the top
and bottom transistors of the bridge. By connecting a pullup
resistor between this pin and VBIAS, various deadtimes can be
obtained. There is and internal 100KΩ pullup resistor connected
internally. By adding additional resistors in externally, reduced
deadtimes can be achieved. By connecting this pin directly to
ground, all deadtime is eliminated. However, care must be taken
to assure that deadtime is being generated by the logic circuitry
driving the inputs. Shoot-through can occur (both the top and
bottom transistors on at the same time for a given phase, causing a short on the V+ supply to ground) destroying the bridge.
BIAS SUPPLY BYPASS CAPACITORS
It is recommended that at least 22μF of capacitance for bypassing the VBIAS voltage that supplies the drive circuitry for
the MSK 4401, along with 0.1μF for helping the high frequency
current pulses needed by the gate driver. If an extremely long
risetime is exhibited by the turn on of the FETs, the extra high
frequency capacitance will help.
GENERAL LAYOUT
Good high frequency PC layout techniques are a must. Traces
wide enough for the current delivered, and placement of the big
capacitors close to the MSK 4401 are very important. The
path for the RSENSE connection through any sense resistor
back to the GND pins must be as short as possible. This path is
the gate drive current path for all the FETs on the lower half of
each phase. A short, low inductance path will aid in the switching time of those FETs.
IN
V+ - Is the power connection for the top of the output bridge.
These pins must be bypassed by a capacitor to ground of a
least 10μF per amp preferrably 100μF per amp of output current
minimum, high quality high frequency bypass capacitance to
help suppress switching noise. Connect both pins for proper
current sharing.
Aÿ , Bÿ , Cÿ - Are the output pins for the three phases of power
bridge. Connect both pins for proper current sharing.
EN - Is the enabling input for the bridge. This digital input,
when pulled low, will enable the bridge, following the inputs
from AL, BL, CL and AH, BH, CH inputs. When pulled high, it
will override all other inputs and disable the bridge. It is internally pulled high to VBIAS, and can be driven by logic levels up
to VBIAS.
RSENSE - Are the connections to the bottom of the bridge. All
power flowing through the bridge will flow through this point,
and can be sensed by connecting a sense resistor from here to
ground. The sense resistor will develop a voltage proportional
to the current flowing. Size the value and power rating of the
sense resistor according to the voltage necessary. 3 volts is the
maximum voltage between this point and ground, or damage to
the hybrid will result. Connect both pins for proper current sharing.
3
LOW POWER STARTUP
When starting up the circuit utilizing the MSK 4401 for the first
time, it is very important to keep certain things in mind. Because
of the small size of the bridge, there is no internal short circuit
protection and a short circuit will destroy the bridge. Any required short circuit protection must be built outside the bridge.
Current and voltage limit the power supply feeding the V+ pins
to the bridge, and monitor the current for any signs of short
circuiting, or shoot-through currents. If there are large current
spikes at the beginning of each switching cycle, there may be
shoot through. Try raising the resistor value of the SWR. This
will lengthen the deadtime and stop shoot-through.
Rev. H 1/11
TYPICLAL APPLICATION SCHEMATIC
TYPICLAL PERFORMANCE CURVES
4
Rev. H 1/11
MECHANICAL SPECIFICATIONS
WEIGHT= 31.7 GRAMS TYPICAL
NOTE: ALL DIMENSIONS ARE ±0.010 INCHES UNLESS OTHERWISE LABELED.
ESD Triangle Indicates Pin 1.
CAUTION: THIS IS A NON-HERMETIC DEVICE. DO NOT EXPOSE PLASTIC HOUSING TO LIQUID
ORDERING INFORMATION
Part
Number
Screening Level
Lead Configuration
MSK4401S
Industrial
Straight
MSK4401D
Industrial
Down
MSK4401U
Industrial
Up
MSK4401G
Industrial
Gull Wing
M.S. Kennedy Corp.
4707 Dey Road, Liverpool, New York 13088
Phone (315) 701-6751
FAX (315) 701-6752
www.mskennedy.com
The information contained herein is believed to be accurate at the time of printing. MSK reserves the right to make
changes to its products or specifications without notice, however, and assumes no liability for the use of its products.
Please visit our website for the most recent revision of this datasheet.
5
Rev. H 1/11