ST STPS2030CT, STPS2030CG, STPS2030CR User Manual

®

STPS2030CT/CG/CR

LOW DROP POWER SCHOTTKY RECTIFIER

MAJOR PRODUCTS CHARACTERISTICS

I

F(AV)

V

RRM

2x10A

30 V

Tj (max) 150°C

(max) 0.40 V

V

F

FEATURES AND BENEFITS

VERY SMALL CONDUCTION LOSSES

■

NEGLIGIBLE SWITCHING LOSSES

■

EXTREMELY FAST SWITCHING

■

LOW FORWARD VOLTAGE DROP FOR

■

HIGHER EFFICIENCY
LOW THERMAL RESISTANCE

■

AVALANCHE CAPABILITY SPECIFIED

■

DESCRIPTION

Dual Schottky rectifier suited for switch Mode
Power Supply and high frequency DC to DC
converters.

2

Packaged in TO-220AB, D

PAK and I2PAK, this
device is intended for use in low voltage high
frequency inverters, free wheeling and polarity
protection applications.

A1

A2

K

A2

A1

D2PAK

STPS2030CG

K

A2

K

A1

TO-220AB

STPS2030CT

A2

K

A1

I2PAK

STPS2030CR

ABSOLUTE RATINGS (limiting values, per diode)

Symbol Parameter Value Unit

V

RRM

I

F(RMS)

I

F(AV)

Repetitive peak reverse voltage
RMS forward current
Average forward

current

I

FSM

I

RRM

I

RSM

P

ARM

T

Tj

dV/dt

dPtot

*:

Surge non repetitive forwardcurrent tp = 10 ms Sinusoidal
Peak repetitive reverse current tp=2 µs square F=1kHz
Non repetitive peak reversecurrent tp = 100 µs square
Repetitive peak avalanche power tp = 1µs Tj = 25°C

stg

Storage temperature range
Maximum operating junction temperature*
Critical rate of riseof reverse voltage (rated V

<

dTj Rth j a

July 2003 - Ed: 3A

Tc = 140°C
δ = 0.5

, Tj = 25°C)

R

Per diode
Per device

thermal runaway condition for a diode on its own heatsink

−1()

30 V
30 A
10

20

180 A

1A
2A

3000 W

- 65 to + 150 °C
150 °C

10000 V/µs

A

1/6

STPS2030CT/CG/CR

THERMAL RESISTANCES

Symbol Parameter Value Unit

R

th(j-c)

R

th(c)

Junction to case TO-220AB - D2PAK-I2PAK

STATIC ELECTRICAL CHARACTERISTICS (per diode)

Symbol Parameter Tests Conditions Min. Typ. Max. Unit

I

*

R

V

F

Reverse leakage
current

*

Forward voltage drop Tj= 25°CI

Tj = 25°C VR=V
Tj = 125°C

Tj = 125°C I
Tj=25°CI
Tj = 125°C I

Pulse test : * tp = 380 µs, δ <2%

To evaluate the conduction losses use the following equation :
P=0.28xI

F(AV)

+ 0.012 I

F2(RMS)

Per diode

Total

2.2

1.3

Coupling 0.3 °C/W

RRM

0.15 1.0 mA
80 160

=10A

F

=10A

F

=20A

F

=20A

F

0.44 0.50 V

0.34 0.40

0.50 0.58

0.44 0.52

°C/W

Fig.1:Conductionlossesversus average current.

P (W)

F(AV)

6

5

4

3

2

1

0

012345678910111213

δ = 0.05

δ = 0.1

δ = 0.2

I (A)

F(AV)

δ = 0.5

δ

δ = 1

=tp/T

T

tp

Fig. 3: Normalized avalanche power derating
versus pulse duration.

P(t)

ARM p

P (1µs)

ARM

1

0.1

0.01

t (µs)

0.001

0.10.01 1

p

10 100 1000

Fig. 2: Average forward current versus ambient
temperature(δ = 0.5).

I (A)

F(AV)

11
10

9
8
7
6
5
4
3
2
1
0

0 25 50 75 100 125 150

δ

=tp/T

T

tp

R=R

th(j-a) th(j-c)

R =50°C/W

th(j-a)

T (°C)

amb

Fig. 4: Normalized avalanche power derating

versus junction temperature.

P(t)

ARM p

P (25°C)

ARM

1.2
1

0.8

0.6

0.4

0.2
0

0 25 50 75 100 125 150

T (°C)

j

2/6