SGS Thomson Microelectronics STPS3L60U, STPS3L60RL, STPS3L60QRL, STPS3L60Q Datasheet

®

MAIN PRODUCT CHARACTERISTICS

STPS3L60/Q/U

POWER SCHOTTKY RECTIFIER

I

F(AV)

V

RRM

3A

60 V

Tj (max) 150°C

(max) 0.61 V

V

F

FEATURES AND BENEFITS

NEGLIGIBLE SWITCHING LOSSES

■

LOW THERMAL RESISTANCE

■

AVALANCHE CAPABILITY SPECIFIED

■

DO-201AD
STPS3L60

DO-15

STPS3L60Q

DESCRIPTION

Axial and Surface Mount Power Schottky rectifier
suited for Switch Mode Power Supplies and high
frequency DC to DC converters. Packaged in
DO-201AD, DO-15 and SMB, this device is
intended for use in low voltage, high frequency
inverters and small battery chargers.

SMB

STPS3L60U

For applications where there are space
constraints, e.g Telecom battery charger.

ABSOLUTE RATINGS (limiting values)

Symbol Parameter Value Unit

V

RRM

I

F(RMS)

I

F(AV)

Repetitive peak reverse voltage
RMS forward current
Average forward current TL= 105°C δ = 0.5

60 V
10 A

3A

(DO-201AD, SMB)
T

= 75°C δ = 0.5

L

(DO-15)

I

FSM

P

ARM

T

stg

T

j

dV/dt

Surge non repetitive forward current tp= 10 ms Sinusoidal
Repetitive peak avalanche power tp = 1µs Tj = 25°C
Storage temperature range
Maximum operating junction temperature *
Critical rate of rise of reverse voltage

100 A

2000 W

- 65 to + 150 °C
150 °C

10000 V/µs

dPtot

*:

<

dTj Rth j a

July 2003 - Ed: 5A

thermal runaway condition for a diode on its ownheatsink

−1()

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STPS3L60/Q/U

THERMAL RESISTANCES

Symbol Parameter Value Unit

R

th(j-l)

Junction to leads Lead length = 10 mm DO-201AD

SMB
DO-15

STATIC ELECTRICAL CHARACTERISTICS

Symbol Parameter Tests conditions Min. Typ. Max. Unit

I

*

R

V

F

Pulse test : * tp = 380 µs, δ <2%

Reverse leakage current Tj= 25°C VR=V

= 100°C

T

j

= 125°C

T

j

*

Forward voltage drop Tj= 25°C IF=3A

= 100°C

T

j

= 125°C

T

j

= 25°C IF=6A

T

j

= 100°C

T

j

= 125°C

T

j

RRM

20 °C/W
20
35

150 µA

415mA

14 30

0.62 V

0.53 0.61

0.51 0.59

0.79

0.62 0.71

0.6 0.69

To evaluate the maximum conduction losses use the following equation:
P=0.44xI

Fig. 1: Average forward power dissipation versus
average forward current.

P (W)

F(AV)

2.5

2.0

1.5

1.0

0.5

0.0

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0

F(AV)

δ = 0.05

+0.05xI

δ = 0.1

δ = 0.2

I (A)

F(AV)

F2(RMS)

δ = 0.5

δ

=tp/T

δ = 1

T

Fig. 2-1: Average forward current versus ambient
temperature (δ = 0.5) (DO-201AD, SMB).

I (A)

F(AV)

3.5

3.0

2.5

2.0

1.5

1.0

tp

0.5

0.0

T

=tp/T

δ

0 25 50 75 100 125 150

tp

R=R

th(j-a) th(j-I)

R =80°C/W

th(j-a)

T (°C)

amb

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