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 SHINDENGEN
Schottky Rectifiers (SBD)
SBD Bridges
D15XBS6
60V 15A
FEATURES Thin Single In-Line Package SBD Bridge Low VF
OUTLINE DIMENSIONS
Case : 3S
Unit : mm
RATINGS
Absolute Maximum Ratings (If not specified Tc=25) Item Symbol Conditions Tstg Storage Temperature Tj Operating Junction Temperature VRM Maximum Reverse Voltage VRRSM Pulse width 0.5ms, duty 1/40 Repetitive Peak Surge Reverse Voltage Average Rectified Forward Current IO 50Hz sine wave, R-load With heatsink Tc=59
50Hz sine wave, R-load Peak Surge Forward Current Repetitive Peak Surge Reverse Power Dielectric Strength Mounting Torque
Without heatsink Ta=25
IFSM PRRSM Vdis TOR
50Hz sine wave, Non-repetitive 1cycle peak value, Tj=25 Pulse width 10is, Rating of per diode, Tj=25 Terminals to case, AC 1 minute i Recommended torqueF 0.5Nmj
Ratings -55150 150 60 65 15 2.1 150 330 2 0.8
Unit V V A A W kV Nm
Electrical Characteristics (If not specified Tc=25) Item Symbol Conditions VF IF=7.5A, Pulse measurement, Rating of per diode Forward Voltage IR Reverse Current VR=60V, Pulse measurement, Rating of per diode Junction Capacitance Cj f=1MHz, VR=10V, Rating of per arm AEjc junction to case @ @ With heatsink Thermal Resistance AEjl junction to lead AEja junction to ambient
Ratings Unit Max.0.63 V Max.6 mA TYP 410 pF Max.3.5 Max.6 /W Max.30
Copyright & Copy;2002 Shindengen Electric Mfg.Co.,Ltd.
D15XBS6
50
Forward Voltage
Pulse measurement per diode
20
10
IF [A]
5
Forward Current
2
Tc=150C [MAX] Tc=150C [TYP] Tc= 25C [MAX] Tc= 25C [TYP]
1
0.5
0.2
0.1 0 0.5 1 1.5 2
Forward Voltage VF [V]
D15XBS6
35
Forward Power Dissipation
DC
PF [W]
30 0.5 SIN 0.3 20 0.1 15 0.05 0.2
D=0.8
25
Forward Power Dissipation
10
5
0 0
5
10
15
20
25
Average Rectified Forward Current
IO [A]
Tj =150C
IO 0 tp D=tp/T T
D15XBS6
200
Peak Surge Forward Capability
IFSM
10ms 10ms
1 cycle
IFSM [A]
150
non-repetitive, sine wave, Tj=25C before surge current is applied
Peak Surge Forward Current
100
50
0
1
2
5
10
20
50
100
Number of Cycles
[cycle]
D15XBS6
1000
Reverse Current
Pulse measurement per diode
Tc=150C [TYP] 100 Tc=125C [TYP]
IR [mA]
Tc=100C [TYP] 10 Tc=75C [TYP]
Reverse Current
1
Tc=50C [TYP]
Tc=25C [TYP] 0.1
0.01
0.001
0
10
20
30
40
50
60
Reverse Voltage
VR [V]
D15XBS6
Reverse Power Dissipation
40 35 30 25 20 0.5 15 10 5 0 DC D=0.05 0.1 0.2
Reverse Power Dissipation
PR [W]
0.3
SIN 0.8
0
10
20
30
40
50
60
70
Reverse Voltage
VR [V]
Tj =150C
0 VR tp D=tp/T T
D15XBS6
200
Peak Surge Forward Capability
IFSM
10ms 10ms
1 cycle
IFSM [A]
150
non-repetitive, sine wave, Tj=25C before surge current is applied
Peak Surge Forward Current
100
50
0
1
2
5
10
20
50
100
Number of Cycles
[cycle]
D15XBS6
30
Derating Curve
IO [A]
Heatsink 25
Tc
Tc
DC D=0.8
Average Rectified Forward Current
20 0.5 SIN 0.3 0.2 10 0.1 5 0.05
15
0
0
20
40
60
80
100
120
140
160
Case Temperature
Tc [C]
VR = 30V 0 0
IO
VR tp D=tp/T T
D15XBS6
5
Derating Curve
4
3 D=0.8
2
1
0
0
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IO [A]
PCB
Average Rectified Forward Current
Soldering land 5mm O
DC
SIN
0.5
20
40
60
80
100
120
140
160
Ambient Temperature Ta [C]
VR = 30V
IO 0 0 VR tp D=tp/T T
D15XBS6
10
Repetitive Surge Reverse Power Capability
PRRSM(tp) / PRRSM(tp=10us) Ratio
5
2
1
0.5
0.2
0.1 0.5
1
2
5
10
20
50
100
Pulse Width tp [us]
IRP IR 0.5IRP 0 tp PRRSM = IRP x VRP VR VRP
D15XBS6
Repetitive Surge Reverse Power Derating Curve
120
100
PRRSM Derating [%]
80
60
40
20
0
0
25
50
75
100
125
150
Junction Temperature
Tj [C]
IRP IR 0.5IRP 0 tp PRRSM = IRP x VRP VR VRP


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