Philips BYV34-500, BYV34-400, BYV34-300 Datasheet

Philips Semiconductors Product specification

Dual rectifier diodes BYV34 series
ultrafast

FEATURES SYMBOL QUICK REFERENCE DATA

• Low forward volt drop V

• Fast switching

• Soft recovery characteristic V

• High thermal cycling performance

a1

13

a2

• Low thermal resistance I

k

2

= 300 V/ 400 V/ 500 V

R

≤ 1.05 V

F

= 20 A

O(AV)

trr ≤ 60 ns

GENERAL DESCRIPTION PINNING SOT78 (TO220AB)

Dual, common cathode, ultra-fast, PIN DESCRIPTION
epitaxial rectifier diodes intended
for use as output rectifiers in high 1 anode 1
frequency switched mode power
supplies. 2 cathode

TheBYV34series issupplied in the 3 anode 2
conventional leaded SOT78
(TO220AB) package. tab cathode

tab

123

LIMITING VALUES

Limiting values in accordance with the Absolute Maximum System (IEC 134).

SYMBOL PARAMETER CONDITIONS MIN. MAX. UNIT

V
V
V

I

O(AV)

I

FRM

I

FSM

T
T

RRM
RWM
R

stg
j

Peak repetitive reverse voltage - 300 400 500 V
Crest working reverse voltage - 300 400 500 V
Continuous reverse voltage Tmb ≤ 138˚C - 300 400 500 V

Average rectified output current square wave; δ = 0.5; - 20 A
(both diodes conducting)

1

Tmb ≤ 115 ˚C
Repetitive peak forward current t = 25 µs; δ = 0.5; - 20 A
per diode Tmb ≤ 115 ˚C
Non-repetitive peak forward t = 10 ms - 120 A
current per diode. t = 8.3 ms - 132 A

sinusoidal; with reapplied

V

RRM(max)

Storage temperature -40 150 ˚C
Operating junction temperature - 150 ˚C

BYV34 -300 -400 -500

THERMAL RESISTANCES

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

R

th j-hs

R

th j-a

1 Neglecting switching and reverse current losses

October 1998 1 Rev 1.400

Thermal resistance junction to per diode - - 2.4 K/W
heatsink both diodes conducting - - 1.6 K/W
Thermal resistance junction to in free air. - 60 - K/W
ambient

Philips Semiconductors Product specification

Dual rectifier diodes BYV34 series
ultrafast

ELECTRICAL CHARACTERISTICS

characteristics are per diode at Tj = 25 ˚C unless otherwise stated

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

V

F

I

R

Q

s

t

rr

I

rrm

V

fr

Forward voltage IF = 10 A; Tj = 150˚C - 0.87 1.05 V

IF = 20 A - 1.10 1.35 V
Reverse current VR = V

Reverse recovery charge IF = 2 A to VR ≥ 30 V; - 50 60 nC

VR = V

RRM

; Tj = 100 ˚C - 0.2 0.6 mA

RRM

-1050µA

dIF/dt = 20 A/µs
Reverse recovery time IF = 1 A to VR ≥ 30 V; - 50 60 ns

dIF/dt = 100 A/µs
Peak reverse recovery current IF = 10 A to VR ≥ 30 V; - 4.0 5.0 A

dIF/dt = 50 A/µs; Tj = 100˚C
Forward recovery voltage IF = 10 A; dIF/dt = 10 A/µs - 2.5 - V

4

BYV34

0.2

IF(AV) / A

BYV34

2.8

0.5

2.2

I

F(AV)

Tmb(max) / C

p

t

T

=I

F(RMS)

Tmb(max) / C

1.9

D = 1.0

D =

x √D.

a = 1.57

p

t
T

t

F(AV)

102

114

126

138

150

) per

121.1

126

130.8

135.6

140.4

I

F

dI

F

dt

t

rr

time

Q

s

I

R

I

rrm

10%

Fig.1. Definition of trr, Qs and I

100%

rrm

PF / W

20

Vo = 0.9400 V
Rs = 0.0100 Ohms

15

10

0.1

5

0

0 5 10 15

Fig.3. Maximum forward dissipation PF = f(I

diode; square wave where I

I

F

time

V

F

12

10

8

6

4

PF / W

conduction
angle
degrees

30
60
90
120
180

form
factor

a

4

2.8

2.2

1.9

1.57

Vo = 0.94 V
Rs = 0.01 Ohms

Fig.2. Definition of V

V

fr

V

F

time

fr

2

0

0246810

IF(AV) / A

Fig.4. Maximum forward dissipation PF = f(I

F(AV)

145.2

150

) per

diode; sinusoidal current waveform where a = form

factor = I

F(RMS)

/ I

F(AV)

.

October 1998 2 Rev 1.400