SEMICONDUCTOR
NK3D60..(R) Series
THREE PHASE DIODE MODULE
RoHS
RoHS
Features
1. NK3D60..(R) series Diode modules are
designed for 3 phase rectification
2. Voltage rating up to 1600V
3. High surge capability
Ordering code
NK3D
(1)
60
(2)
06
(3)
(R)
(4)
93.5
80
3 screws M5
26.5max
3
2
1
Half Bridge
30
21
9
(1) For Three Phase Diode modules
(2) Maximum average forward current , A
(3) Voltage code , V ( code x 10 = / V RRM )
(4) Blank - for common cathode to base plate
R- for common anode to base plate
12.5
NK3D
Base Plate
2- 6.5
16.5
23
23
NK3D..(R)
Base Plate
All dimensions in millimeters(inches)
Electrical Characteristics
Parameter
I F(AV)
I
Average forward current
Condition
180 half sine wave , 50 Hz
Single side cooled , Tc =115 C
Single side cooled , Tc =115 C
t p =10 ms V RMS = V RRM x 1.1
V R = V RRM
Max. Value
60
94
200 to 1600
8
1200
7
Unit
A
F(RMS)
V RRM
I RRM
I FSM
I t
V FM
V FO
rf
Tstg
2
R.M.S. Forward current
Repetitive peak reverse voltage
Repetitive peak reverse current
Peak one-cycle surge
( non-repetitive forward current )
Max. Permissible surge energy
Peak forward voltage drop
Forward conduction threshold voltage
Forward conduction slope resistance
Storage temperature range
Thermal resistance
Approximate weight
Busbar to module ( M 5 )
10 ms duration
V R = 0.6 V RRM
6.5
A
V
mA
A
KA S
V
V
m
Ω
C
C/ W
g
NM
NM
2
I FM = 180A
1.6
0.8
4.78
-40 to 150
R th(J-C)
Wt
Single side cooled
0.7
170
T
Module to heatsink ( M 6 )
A mounting compound is recommened.
Torque should be rechecked after a
period of 3 hours.
2.7
2.7
SEMICONDUCTOR
NK3D60..(R) Series
RoHS
RoHS
3
Transient thermal impedance , C/W
Instantaneous forward voltage , V
Fig.1
Peak forward voltage Vs. Peak forward current
Fig.2
٠٥٠.
Max.junction to case thermal impedance Vs. Time
0.5
2.5
Tj=150 C
2
0.4
0.3
1.5
0.2
1
0.1
0.5
10
100
1000
0
0.001
0.01
0.1
1
10
Instantaneous forward current , A
Time , S
Fig.3
Max.power dissipation Vs. Mean forward current
Mean forward dissipation , W
120
160
Fig.4
Max.case temperature Vs. Mean forward current
Case Temperature , C
140
120
Conduction Angle
0
180
1 phase
3 phase
0
180
90
Conduction Angle
100
80
60
40
20
60
6 phase
30
6 phase 3 phase1 phase
0
30
60
90
120
150
0
0
20
40
60
80
0
Mean forward current , A
Mean forward current , A
Fig.5
Max.power dissipation Vs. Mean forward current
Mean forward dissipation , W
90
360
160
Fig.6
Max.case temperature Vs. Mean forward current
360
120
Conduction Angle
1 phase
60
Conduction Angle
3 phase
6 phase
30
Case Temperature , C
DC
80
40
6 phase 3 phase1 phase
0
0
20
40
60
80
0
0
70
140
210
280
DC
350
Mean forward current , A
Mean forward current , A
