IRF IRKDL240

Bulletin I27094 rev. C 10/06
IRK.L240 SERIES
MAGN-A-pak™
™ Power Modules
FAST RECOVERY DIODES
Features
Fast recovery time characteristics
Electrically isolated base plate
Industrial standard package
Simplified mechanical designs, rapid assembly
High surge capability
Large creepage distances
3000 V RMS isolating voltage
UL E78996 approved
RoHS Compliant
250A
Description
The IRK.L240 Series of MAGN-A-paks uses fast recovery power diodes in four basic configurations. The
semiconductors are electrically isolated from the
metal base, allowing common heatsinks and compact
assemblies to be built. Application includes power
supplies, battery chargers, welders, motor controls
and general industrial current rectification. These
modules are intended for those applications where
fast recovery characteristics are required.
Major Ratings and Characteristics
Parameters
250
240
A
100
100
°C
392
377
A
@ 50Hz
8000
7500
A
@ 60Hz
8400
7850
A
@ 50Hz
322
280
KA2s
@ 60Hz
294
256
KA2s
3220
2800
KA 2√s
@ TC
IF(RMS)
I2t
I2√t
VRRM
TJ
Units
S30
IF(AV)
IFSM
IRK.L240
S10/S20
range
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up to 2500
V
-40 to 150
o
C
1
IRK.L240 Series
Bulletin I27094 rev. C 10/06
ELECTRICAL SPECIFICATIONS
Voltage Ratings
Type number
IRK.L240
Voltage
Code
trr
Code
VRRM , maximum repetitive
peak reverse voltage
V
VRSM , maximum non-repetitive
peak reverse voltage
V
06
S10
600
700
10
S10
1000
1100
12
S20
1200
1300
14
S20
1400
1500
20
S30
2000
2100
25
S30
2500
2600
IRRM max.
@ 150°C
mA
50
Forward Conduction
IF(AV)
Parameter
IRK.L240
S10/S20 S30
Max. average forward current
@ Case temperature
250
100
IF(RMS) Max. RMS forward current
IFSM
Max. peak, one-cycle forward,
non-repetitive surge current
I2t
Maximum I2t for fusing
I2√t
Maximum I2√t for fusing
VF(TO)1 Low level value of threshold
voltage
VF(TO)2 High level value of threshold
voltage
r f1
Low level value of forward
slope resistance
r f2
High level value of forward
slope resistance
VFM
Max. forward voltage drop
240
100
Units
Conditions
A
C
180o conduction, half sine wave
o
392
377
A
as AC switch
8000
8400
6750
7500
7850
6300
A
t = 10ms No voltage
t = 8.3ms reapplied
t = 10ms 100% VRRM
7100
6600
322
280
294
256
t = 8.3ms reapplied
228
198
t = 10ms 100% VRRM
208
181
3220
2800
KA2√s
0.98
0.98
V
(16.7% x π x IF(AV) < I < π x IF(AV))TJ = TJ max
1.31
1.31
V
(I > π x IF(AV)), TJ = TJ max.
0.75
0.97
mΩ
(16.7% x π x IF(AV) < I < π x IF(AV))TJ = TJ max
0.41
0.60
mΩ
(I > π x IF(AV)), TJ = TJ max.
1.57
1.75
V
KA2s
t = 8.3ms reapplied
Sinusoidal half wave,
t = 10ms No voltage
Initial TJ = T J max
t = 8.3ms reapplied
t = 0.1 to 10ms, no voltage reapplied
IFM = 800, T J = 150 oC tp = 10 ms
Av. power = VF(TO) x IF(AV) + rf x (IF(RMS))2
Blocking
IRRM
Max. peak reverse leakage current
VINS
RMS isolation voltage
2
50
mA
3000
V
TJ = 150 oC, leakage current
50Hz, circuit to base, all terminals shorted, 25°C, t = 1s
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IRK.L240 Series
Bulletin I27094 rev. C 10/06
Thermal and Mechanical Specifications
TJ
Max. junction operating temperature
-40 to 150
o
C
Tstg
Max. storage temperature range
-40 to 150
o
C
RthJ-C Max. internal thermal resistance
0.125
K/W
Per junction, DC operation
0.02
K/W
Mounting surface flat, smooth and greased
Per module
4 to 6
Nm
8 to 10
850 (30)
MAGN-A-pak
Nm
g (oz)
junction to case
RthC-S Thermal resistance, case
to heatsink
T
Mounting torque ±10%
MAP to heatsink
A mounting compound is recommended and the torqshould
be rechecked after a period of about 3 hours to allow for
the
wt
Busbar to MAP
Approximate weight
Case style
spread of the compound
DR Conduction (per Junction)
(The following table shows the increment of thermal resistence R thJC when devices operate at different conduction angles
than DC)
Conduction angle
Sinusoidal conduction
180 o
0.008
0.007
K/W
120 o
0.010
0.011
K/W
90 o
0.013
0.015
K/W
60 o
0.019
0.020
K/W
o
0.032
0.033
K/W
30
Rectangular conduction Units
Conditions
TJ = TJ max.
Recovery Characteristics
Typ. values @ T J = 150oC
Test conditions
Code
S10
Ipk
di/dt
Vr
Qrr
Irr
(A)
(A/μs)
(V)
(μC)
(A)
500
100
50
135
100
S20
''
"
"
250
145
S30
''
"
"
360
200
IFM
trr
t
di
dt
Qrr
IRM (REC)
Ordering Information Table
Device Code
IRK
D
L
240
1
2
3
4
-
25
S30
5
6
1
-
Module type
2
-
Circuit configuration (See Outline Table)
3
-
L = Fast recovery diode
4
-
Current rating
5
-
Voltage code: Code x 100 = VRRM (See Voltage Ratings Table)
6
-
trr code (See Recovery Characteristics Table)
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S10 = 1000 ns
S20 = 2000 ns
S30 = 3000 ns
3
IRK.L240 Series
Bulletin I27094 rev. C 10/06
Outline Table
IRKC...
150
IRK.L240..S10/ S20 Series
R thJC (DC) = 0.125 K/ W
140
130
Conduction Angle
120
110
30°
100
60°
90°
120°
90
180°
80
0
50
100
150
200
250
Average Forward Current (A)
Fig. 1 - Current Ratings Characteristics
4
IRKJ...
300
Maximum Allowable Case Temperature (°C)
Maximum Allowable Case Temperature (°C)
IRKD...
All dimensions in millimeters (inches)
Dimensions are nominal
Full engineering drawings are available on request
UL identification number for cathode wire: UL 1385
UL identification number for package: UL 94V0
IRKE...
150
IRK.L240..S10/ S20 Series
R thJC(DC) = 0.125 K/ W
140
130
120
Conduction Period
110
30°
60°
100
90°
120°
90
180°
DC
80
0
50 100 150 200 250 300 350 400 450
Average Forward Current (A)
Fig. 2 - Current Ratings Characteristics
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IRK.L240 Series
400
180°
120°
90°
60°
30°
350
300
250
RMS Limit
200
150
Conduction Angle
100
IRK.L240..S10/ S20 Series
Per Junc tion TJ = 150°C
50
0
0
50
100
150
200
250
Maximum Average Forward Pow er Loss (W)
Maximum Average Forward Power Loss (W)
Bulletin I27094 rev. C 10/06
600
DC
180°
120°
90°
60°
30°
500
400
300
RMS Limit
200
Conduction Period
100
IRK.L240..S10/ S20 Series
TJ = 150°C Per Junc tion
0
0
50
Average Forward Current (A)
8000
At Any Rated Load Condition And With
Rated VRRM App lied Following Surge.
7000
Initial T J= 150°C
@ 60 Hz 0.0083 s
@ 50 Hz 0.0100 s
6000
5000
4000
3000
IRK.L240..S10/ S20 Series
Per Junc tion
2000
10
Fig. 4 - Forward Power Loss Characteristics
Peak Half Sine Wave Forward Current (A)
Peak Half Sine Wave Forward Current (A)
Fig. 3 - Forward Power Loss Characteristics
1
100
8500
Maximum Non Repetitive Surge Current
Versus Pulse Train Dura tion.
Initial T J = 150°C
No Vo ltage Reap plied
Rated V RRMReap plied
7500
6500
5500
4500
3500
2500
IRK.L240..S10/ S20 Series
Per Junction
1500
0.01
0.1
IRK.L240..S30 Series
R thJC(DC) = 0.125 K/ W
130
Conduction Angle
120
110
30°
100
60°
90°
90
120°
180°
80
0
50
100
150
200
Average Forward Current (A)
Fig. 7 - Current Ratings Characteristics
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250
Fig. 6 - Maximum Non-Repetitive Surge Current
Maximum Allowable Case Temperature (°C)
Maximum Allowable Case Temperature (°C)
Fig. 5 - Maximum Non-Repetitive Surge Current
150
1
Pulse Train Dura tion (s)
Number Of Equa l Amplitude Half Cyc le Current Pulses (N)
140
100 150 200 250 300 350 400
Average Forward Current (A)
150
IRK.L240..S30 Series
R thJC (DC) = 0.125 K/ W
140
130
120
Conduc tion Period
110
30°
60°
100
90°
120°
90
180°
DC
80
0
50
100 150 200 250 300 350 400
Average Forward Current (A)
Fig. 8 - Current Ratings Characteristics
5
IRK.L240 Series
400
180°
120°
90°
60°
30°
350
300
250
RMSLimit
200
150
Conduc tion Angle
100
IRK.L240..S30 Series
Per Junc tion
TJ = 150°C
50
0
0
50
100
150
200
250
Maximum Averag e Forward Power Loss (W)
Maximum Average Forward Power Loss (W)
Bulletin I27094 rev. C 10/06
550
DC
180°
120°
90°
60°
30°
500
450
400
350
300
250 RMS Limit
200
Cond uc tion Period
150
IRK.L240..S30 Series
Per Junc tion
TJ = 150°C
100
50
0
0
50
Average Forward Current (A)
Average Forward Current (A)
7000
At Any Ra ted Loa d Co nd ition And With
Ra ted V RRMAp plied Following Surge.
Initia l TJ = 150°C
@ 60 Hz 0.0083 s
@ 50 Hz 0.0100 s
5000
4000
3000
IRK.L240..S30 Series
Per Junc tion
2000
1
10
Fig. 10 - Forward Power Loss Characteristics
Peak Half Sine Wave Forward Current (A)
Peak Half Sine Wave Forward Current (A)
Fig. 9 - Forward Power Loss Characteristics
6000
100
8000
Maximum Non Repetitive Surge Current
Versus Pulse Train Dura tion.
Initia l T J = 150°C
No Voltage Rea pplied
Rated V RRM Rea pplied
7000
6000
5000
4000
3000
IRK.L240..S30 Series
Per Junc tion
2000
1000
0.01
0.1
Number Of Equa l Amplitude Half Cyc le Current Pulses (N)
Fig. 12 - Maximum Non-Repetitive Surge
Current
10000
10000
IRK.L240..S10/ S20 Series
Per Junc tion
Instantaneous Forward Current (A)
Instantaneous Forward Current (A)
1
Pulse Train Duration (s)
Fig. 11 - Maximum Non-Repetitive Surge Current
1000
TJ= 25°C
TJ= 150°C
100
1
1.5
2
2.5
3
3.5
Instantaneous Forward Voltage (V)
Fig. 13 - Forward Voltage Drop Characteristics
6
100 150 200 250 300 350 400
IRK.L240..S30 Series
Per Junc tio n
1000
TJ= 25°C
TJ= 150°C
100
0.5
1
1.5
2
2.5
3
3.5
4
4.5
Instantaneous Forward Voltage (V)
Fig. 14 - Forward Voltage Drop Characteristics
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IRK.L240 Series
150
140
130
120
110
100
90
80
70
60
50
40
30
20
10
IRK.L240..S10
TJ = 150° C
I FM = 1000A
500A
200A
100A
50A
10
20
30
40
50
60
70
80
90
100
Maximum Reverse Rec overy Current - Irr (A)
Maximum Reverse Rec overy Charge - Qrr (µC)
Bulletin I27094 rev. C 10/06
Rate Of Fall Of Forward Current - di/ dt (A/ µs)
450
IFM = 1000A
500A
400
350
200A
300
250
100A
200
50A
150
100
50
0
0
50
100
150
200
Rate Of Fall Of Forward Current - di/ dt (A/ µs)
450
500A
400
100A
350
300
250
200
150
IRK.L240..S30 Series
TJ = 150 °C
100
50
0
0
50
100
150
200
Rate Of Fall Of Forward Current - di/ dt (A/ µs)
Fig. 19 - Reverse Recovery Charge Characteristics
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70
60
50
40
30
IRK.L240..S10 Series
TJ = 150 °C
20
10
10
20
30
40
50
60
70
80
90 100
300
IRK.L240..S20
T J = 150 °C
250
I = 1000A
FM
500A
200
200A
100A
150
50A
100
50
0
0
50
100
150
200
Fig. 18 - Reverse Recovery Current Characteristics
Maximum Reverse Recovery Current - Irr (A)
Maximum Reverse Rec overy Charge - Qrr (µC)
IFM = 1000A
80
Rate Of Fall Of Forward Current - di/ dt (A/ µs)
Fig. 17 - Reverse Recovery Charge Characteristics
500
90
Fig. 16 - Reverse Recovery Current Characteristics
Maximum Reverse Recovery Current - Irr (A)
Maximum Reverse Rec overy Charge - Qrr (µC)
IRK.L240..S20
TJ = 150 °C
IFM = 1000A
500A
200A
100A
50A
100
Rate Of Fall Of Forward Current - di/ dt (A/ µs)
Fig. 15 - Reverse Recovery Charge Characteristics
500
110
300
I FM = 1000A
500A
250
100A
200
150
100
IRK.L240..S30 Series
TJ = 150 °C
50
0
0
50
100
150
200
Rate Of Fall Of Forward Current - di/ dt (A/ µs)
Fig. 20 - Reverse Recovery Current Characteristics
7
IRK.L240 Series
Bulletin I27094 rev. C 10/06
Peak Forward Current (A)
1E5
20 joules per pulse
1E4
0.1
0.04
0.02
0.01
1E3
0.2
0.4
1
2
20 joules per pulse
4 10
10
0.4
0.2
0.1
0.04
0.02
0.01
1E2
1E1
tp
1E0
1E1
IRK.L240..S10/ S20
Sinusoidal Pulse
TJ = 150 °C
1E2
tp
2
IRK.L240..S10/ S20
Trapezoidal Pulse
TJ = 150 °C
1E4
1E
1E41E
11
1E3
1
4
1E2
1E3
1E4
Pulse Basewidth (µs)
Pulse Basewidth (µs)
Fig. 21 - Maximum Forward Energy Power Loss Characteristics
Peak Forward Current (A)
1E5
tp
IRK.L240..S10/ S20
Sinusoidal Pulse
T C = 90 °C
tp
IRK.L240..S10/ S20
Sinusoidal Pulse
T C = 100 °C
1E4
1E3
20000 10000 5000
1E2
1E1
2500 1500 1000
1E2
400
200
50 Hz
20000 10000 5000 2500 1500 1000
1E1E4
4 1E1E
11
1E3
1E2
400
200
1E3
50 Hz
1E4
Pulse Basewidth (µs)
Pulse Basewidth (µs)
Fig. 22 - Frequency Characteristics
Peak Forward Current (A)
1E5
tp
IRK.L240..S10/ S20
Trapezoidal Pulse
TC= 90 °C
tp
IRK.L240..S10/ S20
Trapezoidal Pulse
TC = 100 °C
1E4
1E3
2500 1500 1000
1E2
1E1
1E2
400
1E3
200
50 Hz
1E1E4
4 1E
1E
11
2500 1500 1000
1E2
400
1E3
200
50 Hz
1E4
Pulse Basewidth (µs)
Pulse Basewidth (µs)
Fig. 23 - Frequency Characteristics
8
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IRK.L240 Series
Bulletin I27094 rev. C 10/06
1E5
Peak Forward Current (A)
20 joules per pulse
1E4
0.4
0.2
0.1
0.04
0.02
0.01
1E3
1
2
4
10
20 joules per p ulse
0.1
0.04
0.02
0.01
1E2
1E1
IRK.L240..S30
Sinusoidal Pulse
T J = 150 °C
tp
1E0
1E1
1E2
tp
1
4
10
IRK.L240..S30
Trapezoidal Pulse
T J= 150 °C
1E1E4
4 1E
1E
11
1E3
0.4
0.2
2
1E2
Pulse Basewidth (µs)
1E3
1E4
Pulse Basewidth (µs)
Fig. 24 - Maximum Forward Energy Power Loss Characteristics
Peak Forward Current (A)
1E5
tp
IRK.L240..S30
Sinusoidal Pulse
T C = 90 °C
tp
IRK.L240..S30
Sinusoidal Pulse
T C = 100 °C
1E4
1E3
20000
10000
1E2
1E1
5000 2500 1500 1000
1E2
400
200
50 Hz
20000 10000
1E1
1E1E
4 41E1
1E3
5000 2500 1500 1000
1E2
400
200
1E3
50 Hz
1E4
Pulse Basewidth (µs)
Pulse Basewidth (µs)
Fig. 25 - Frequency Characteristics
Peak Forward Current (A)
1E5
tp
IRK.L240..S30
Trapezoidal Pulse
T C = 90 °C
tp
IRK.L240..S30
Trapezoidal Pulse
T C = 100 °C
1E4
1E3
5000
1E2
1E1
2500 1500 1000
1E2
400
1E3
200
50 Hz
1E1E
4 41E1
1E1
5000 2500 1500 1000
1E2
400
1E3
200
50 Hz
1E4
Pulse Basewidth (µs)
Pulse Basewidth (µs)
Fig. 26 - Frequency Characteristics
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9
IRK.L240 Series
Transient Thermal Impedance Z thJC(K/ W)
Bulletin I27094 rev. C 10/06
1
Stead y State Value:
R thJC = 0.125 K/ W
0.1
(DC Operation)
0.01
0.001
IRK.L240.. Series
Per Junction
0.0001
0.0001
0.001
0.01
0.1
1
10
100
Square Wave Pulse Duration (s)
Fig. 27 - Thermal Impedance ZthJC Characteristics
10
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IRK.L240 Series
Bulletin I27094 rev. C 10/06
Data and specifications subject to change without notice.
This product has been designed and qualified for Industrial Level.
Qualification Standards can be found on IR's Web site.
IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, USA Tel: (310) 252-7105
TAC Fax: (310) 252-7309
Visit us at www.irf.com for sales contact information. 10/06
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11