IRF 129NQ150R

Bulletin PD-20719 rev. A 03/01
129NQ...(R) SERIES
120 Amp
SCHOTTKY RECTIFIER
D-67
Major Ratings and Characteristics
Characteristics
IF(AV) Rectangular
Description/Features
129NQ...(R) Units
120
A
135 to 150
V
10000
A
0.74
V
- 55 to 175
°C
waveform
VRRM range
IFSM
@ tp = 5 µs sine
VF
@120Apk, TJ=125°C
TJ
range
The 129NQ... (R) high current Schottky rectifier module series
has been optimized for low reverse leakage at high
temperature. The proprietary barrier technology allows for
reliable operation up to 175° C junction temperature. Typical
applications are in switching power supplies, converters, freewheeling diodes, and reverse battery protection.
175° C TJ operation
Unique high power, Half-Pak module
Replaces two parallel DO-5's
Easier to mount and lower profile than DO-5's
High purity, high temperature epoxy encapsulation for
enhanced mechanical strength and moisture resistance
Low forward voltage drop
High frequency operation
Guard ring for enhanced ruggedness and long term
reliability
129NQ150
Lug Terminal Anode
Base Cathode
129NQ150R
Lug Terminal Cathode
Base Anode
Outline D-67 HALF PAK Module
Dimensions in millimeters and (inches)
www.irf.com
1
129NQ...(R) Series
Bulletin PD-20719 rev. A 03/01
Voltage Ratings
Part number
VR
129NQ135
129NQ150
135
150
Max. DC Reverse Voltage (V)
VRWM Max. Working Peak Reverse Voltage (V)
Absolute Maximum Ratings
Parameters
129NQ Units
I F(AV) Max. Average Forward Current
* See Fig. 5
120
I FSM Max. Peak One Cycle Non-Repetitive
Surge Current * See Fig. 7
10000
1200
EAS
Non-Repetitive Avalanche Energy
I AR
Repetitive Avalanche Current
A
A
15
mJ
1
A
Conditions
50% duty cycle @ TC = 117° C, rectangular wave form
5µs Sine or 3µs Rect. pulse
10ms Sine or 6ms Rect. pulse
Following any rated
load condition and
with rated VRRMapplied
TJ = 25 °C, IAS = 1 Amps, L = 30 mH
Current decaying linearly to zero in 1 µsec
Frequency limited by TJ max. VA = 1.5 x VR typical
Electrical Specifications
Parameters
129NQ Units
V FM Max. Forward Voltage Drop
(1)
V
@ 120A
1.27
V
@ 240A
0.74
V
@ 120A
0.86
V
@ 240A
Max. Reverse Leakage Current (1)
3
mA
TJ = 25 °C
* See Fig. 2
45
mA
TJ = 125 °C
3000
pF
VR = 5VDC, (test signal range 100Khz to 1Mhz) 25 °C
7.0
nH
From top of terminal hole to mounting plane
10,000
V/ µs
* See Fig. 1
IRM
Conditions
1.07
CT
Max. Junction Capacitance
LS
Typical Series Inductance
dv/dt Max. Voltage Rate of Change
( Rated VR )
TJ = 25 °C
TJ = 125 °C
VR = rated VR
(1) Pulse Width < 300µs, Duty Cycle < 2%
Thermal-Mechanical Specifications
Parameters
129NQ Units
Conditions
TJ
Max. Junction Temperature Range
-55 to 175
Tstg
Max. Storage Temperature Range
-55 to 175
°C
RthJC Max. Thermal Resistance Junction
to Case
0.40
°C/W
DC operation
RthCS Typical Thermal Resistance, Case to
0.15
°C/W
Mounting surface , smooth and greased
°C
* See Fig. 4
Heatsink
wt
Approximate Weight
T
Mounting Torque
Min.
25.6 (0.9) g (oz.)
40 (35)
Terminal Torque
Max.
Min.
58 (50)
58 (50)
Max.
Case Style
2
Non-lubricated threads
Kg-cm
(Ibf-in)
86 (75)
HALF PAK Module
129NQ...(R) Series
Bulletin PD-20719 rev. A 03/01
1000
1000
Reverse Current - I R (mA)
100
10
125˚C
1
100˚C
75˚C
0.1
50˚C
0.01
25˚C
TJ = 175˚C
0.001
0
TJ = 125˚C
30
60
90
120
150
Reverse Voltage - V R (V)
Fig. 2 - Typical Values Of Reverse Current
Vs. Reverse Voltage
TJ = 25˚C
Junction Capacitance - C T (pF)
10000
10
T = 25˚C
J
1000
100
1
0
0.5
1
1.5
2
Forward Voltage Drop - VFM (V)
0
2.5
40
80
120
160
Reverse Voltage - VR (V)
Fig. 3 - Typical Junction Capacitance
Vs. Reverse Voltage
Fig. 1 - Max. Forward Voltage Drop Characteristics
1
Thermal Impedance Z thJC (°C/W)
Instantaneous Forward Current - I F (A)
100
TJ = 175˚C
150˚C
0.1
D = 0.75
D = 0.50
D = 0.33
D = 0.25
D = 0.20
PDM
t1
t2
0.01
Notes:
Single Pulse
(Thermal Resistance)
0.001
0.00001
0.0001
0.001
0.01
1. Duty factor D = t1 / t 2
2. Peak T J = P DM x Z thJC + T C
0.1
1
10
100
t1, Rectangular Pulse Duration (Seconds)
Fig. 4 - Max. Thermal Impedance ZthJC Characteristics
3
129NQ...(R) Series
180
140
160
120
Average Power Loss (Watts)
Allowable Case Temperature (°C)
Bulletin PD-20719 rev. A 03/01
DC
140
120
Square wave (D = 0.50)
100 Rated VR applied
80
D = 0.20
D = 0.25
D = 0.33
D = 0.50
D = 0.75
100
80
RMS Limit
DC
60
40
20
see note (2)
60
0
0
40
80
120
160
200
Average Forward Current - IF(AV)(A)
0
20 40 60 80 100 120 140 160 180
Average Forward Current - I F(AV) (A)
Fig. 5 - Max. Allowable Case Temperature
Vs. Average Forward Current
Fig. 6 - Forward Power Loss Characteristics
Non-Repetitive Surge Current - I FSM (A)
10000
1000
At Any Rated Load Condition
And With Rated VRRM Applied
Following Surge
100
10
100
1000
10000
Square Wave Pulse Duration - t p (microsec)
Fig. 7 - Max. Non-Repetitive Surge Current
L
IRFP460
D UT
Rg = 25 ohm
C UR RE N T
M O N ITO R
H IG H -SPE ED
SW ITC H
FREE-W HE EL
D IO D E
40H FL40S02
Fig. 8 - Unclamped Inductive Test Circuit
(2) Formula used: TC = TJ - (Pd + PdREV) x RthJC ;
Pd = Forward Power Loss = IF(AV) x VFM @ (IF(AV) / D) (see Fig. 6);
PdREV = Inverse Power Loss = VR1 x IR (1 - D); IR @ VR1 = rated VR
4
+
V d = 25 V olt