MSK MSK3001

ISO-9001 CERTIFIED BY DSCC
M.S.KENNEDY CORP.
THREE PHASE BRIDGE
MOSFET POWER MODULE
3001
4707 Dey Road Liverpool, N.Y. 13088
(315) 701-6751
FEATURES:
Pin Compatible with IRFT001
P and N Channel MOSFETs for Ease of Drive
Isolated Package for Direct Heat Sinking, Excellent Thermal Conductivity
Avalanche Rated Devices
Interfaces Directly with Most Brushless Motor Drive IC's
100 Volt, 5 Amp Full Three Phase Bridge at 25°C
DESCRIPTION:
The MSK 3001 is a three phase bridge power circuit packaged in a space efficient isolated ceramic tab power SIP
package. Consisting of P-Channel MOSFETs for the top transistors and N-Channel MOSFETs for the bottom transistors, the MSK 3001 will interface directly with most brushless motor drive IC's without special gate driving requirements. The MSK 3001 uses M.S.Kennedy's proven power hybrid technology to bring a cost effective high performance circuit for use in today's sophisticated servo motor and disk drive systems. The MSK 3001 is a replacement
for the IRFT001 with only minor differences in mechanical and electrical specifications.
EQUIVALENT SCHEMATIC
TYPICAL APPLICATIONS
PIN-OUT INFORMATION
1
2
3
4
5
6
Three Phase Brushless DC Motor Servo Control
Disk Drive Spindle Control
Fin Actuator Control
Az-El Antenna Control
1
Source 1,3,5
Gate 1
Gate 2
Drain 1,2
Gate 3
Drain 3,4
11
10
9
8
7
Source 2,4,6
Gate 6
Drain 5,6
Gate 5
Gate 4
Rev. B 7/00
ABSOLUTE MAXIMUM RATINGS
VDSS
VDGDR
Drain to Source Voltage
Drain to Gate Voltage
(RGS=1MΩ)
Gate to Source Voltage
(Continuous)
Continuous Current
Pulsed Current
Thermal Resistance
(Junction to Case)
○
VGS
○
○
ID
IDM
RTH-JC
○
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100V MAX
Single Pulse Avalanche Energy
(Q1,Q3,Q5)
91mJ
(Q2,Q4,Q6)
210mJ
Junction Temperature
+175°C MAX
Storage Temperature
-55°C to +150°C
Case Operating Temperature Range -55°C to +125°C
Lead Temperature Range
(10 Seconds)
300°C MAX
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100V MAX
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±20V MAX
5.6A MAX
22A MAX
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TJ
TST
TC
TLD
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6°C/W
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ELECTRICAL SPECIFICATIONS
Parameter
Test Conditions 4
Drain-Source Breakdown Voltage
VDS=100V VGS=0V (Q1,Q3,Q5)
Drain-Source Leakage Current
VDS=-100V VGS=0V (Q2,Q4,Q6)
Gate-Source Leakage Current
VGS=±20V VDS=0 (All Transistors)
VDS=VGS ID=250µA (Q1,Q3,Q5)
Gate-Source Threshold Voltage
VDS=VGS ID=250µA (Q2,Q4,Q6)
VGS=10V ID=5.6A (Q1,Q3,Q5)
Drain-Source On Resistance 2
VGS=-10V ID=-3.4A (Q2,Q4,Q6)
VGS=10V ID=5.6A (Q1,Q3,Q5)
Drain-Source On Resistance 3
VGS=10V ID=-3.4A (Q2,Q4,Q6)
VDS=25V ID=5.7A (Q1,Q3,Q5)
1
Forward Transconductance
VGS=0 ID=0.25mA (All Transistors)
VDS=-50V ID=-3.4A (Q2,Q4,Q6)
MSK3001
Units
Min.
100
2.0
-2.0
2.7
1.5
Typ.
0.18
0.37
-
Max.
25
-100
±100
4.0
-4.0
0.30
0.75
0.21
0.60
-
-
4.5
23
32
23
330
92
54
25
4.8
11
-
nC
nC
nC
nS
nS
nS
nS
pF
pF
pF
-
9.6
29
21
25
390
170
45
18
3.0
9.0
-
nC
nC
nC
nS
nS
nS
nS
pF
pF
pF
-
1.3
-1.6
99
100
0.39
0.33
150
200
0.58
0.66
V
V
nS
nS
µC
µC
V
µA
µA
nA
V
V
Ω
Ω
Ω
Ω
S
S
N-Channel (Q1,Q3,Q5)
1
Total Gate Charge
ID=5.7A
1
VDS=80V
Turn-On Delay Time 1
VDD=50V
Gate-Source Charge
1
Gate-Drain Charge
Rise Time
1
ID=5.7A
Turn-Off Delay Time
Fall Time
VGS=10V
1
RG=22Ω
1
Input Capacitance
RD=8.6Ω
1
VGS=0V
1
Output Capacitance
VDS=25V
Reverse Transfer Capacitance
1
f=1MHz
P-CHANNEL (Q2,Q4,Q6)
Total Gate Charge
1
ID=-6.8A
Gate-Source Charge 1
VDS=-80V
Gate-Drain Charge 1
VGS=-10V
Turn-On Delay Time 1
VDD=-50V
Rise Time
1
ID=-6.8A
1
Turn-Off Delay Time
Fall Time
RG=18Ω
1
Input Capacitance
Output Capacitance
RD=7.1Ω
1
VGS=0V
1
VDS=-25V
Reverse Transfer Capacitance 1
f=1MHz
BODY DIODE
Forward On Voltage
Reverse Recovery Time
Reverse Recovery Charge
NOTES:
1
2
3
4
IS=5.5A VGS=0V (Q1,Q3,Q5)
1
IS=-5.6A VGS=0V (Q2,Q4,Q6)
IS=5.7A di/dt=100A/µS (Q1,Q3,Q5)
1
IS=-6.8A di/dt=100A/µS (Q2,Q4,Q6)
1
IS=5.7A di/dt=100A/µS (Q1,Q3,Q5)
IS=-6.8A di/dt=100A/µS (Q2,Q4,Q6)
This parameter is guaranteed by design but need not be tested. Typical parameters are representative of actual device performance but are for reference only.
Resistance as seen at package pins.
Resistance for die only; use for thermal calculations.
TA=25°C unless otherwise specified.
2
Rev. B 7/00
APPLICATION NOTES
N-CHANNEL GATES (Q1,Q3,Q5)
For driving the N-Channel gates, it is important to keep in mind that it is essentially like driving a capacitance to a sufficient
voltage to get the channel fully on. Driving the gates to +15 volts with respect to their sources assures that the transistors are on.
This will keep the dissipation down to a minimum level [RDS(ON) specified in the data sheet]. How quickly the gate gets turned ON
and OFF will determine the dissipation of the transistor while it is transitioning from OFF to ON, and vice-versa. Turning the gate
ON and OFF too slow will cause excessive dissipation, while turning it ON and OFF too fast will cause excessive switching noise
in the system. It is important to have as low a driving impedance as practical for the size of the transistor. Many motor drive IC's
have sufficient gate drive capability for the MSK 3001. If not, paralleled CMOS standard gates will usually be sufficient. A series
resistor in the gate circuit slows it down, but also suppresses any ringing caused by stray inductances in the MOSFET circuit. The
selection of the resistor is determined by how fast the MOSFET wants to be switched. See Figure 1 for circuit details.
Figure 1
P-CHANNEL GATES (Q2,Q4,Q6)
Most everything applies to driving the P-Channel gates as the N-Channel gates. The only difference is that the P-Channel gate to
source voltage needs to be negative. Most motor drive IC's are set up with an open collector or drain output for directly interfacing
with the P-channel gates. If not, an external common emitter switching transistor configuration (see Figure 2) will turn the PChannel MOSFET on. All the other rules of MOSFET gate drive apply here. For high supply voltages, additional circuitry must be
used to protect the P-Channel gate from excessive voltages.
Figure 2
BRIDGE DRIVE CONSIDERATIONS
It is important that the logic used to turn ON and OFF the various transistors allow sufficient "dead time" between a high side
transistor and its low side transistor to make sure that at no time are they both ON. When they are, this is called "shoot-through",
and it places a momentary short across the power supply. This overly stresses the transistors and causes excessive noise as well.
See Figure 3.
Figure 3
This deadtime should allow for the turn on and turn off time of the transistors, especially when slowing them down with gate
resistors. This situation will be present when switching motor direction, or when sophisticated timing schemes are used for servo
systems such as locked antiphase PWM'ing for high bandwidth operation.
3
Rev. B 7/00
TYPICAL PERFORMANCE CURVES
4
Rev. B 7/00
MECHANICAL SPECIFICATIONS
ALL DIMENSIONS ARE ±0.010 INCHES UNLESS OTHERWISE LABELED.
ORDERING INFORMATION
PART
NUMBER
SCREENING LEVEL
MSK 3001
Industrial
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.
5
Rev. B 7/00