SI7136DP-T1-GE3_技术文档

Si7136DP

Vishay Siliconix

N-Channel 20-V (D-S) MOSFET

FEATURES

PRODUCT SUMMARY

•

Halogen-free According to IEC 61249-2-21

Available

V_DS(V)

R_DS(on)(Ω)

Q_g(Typ.)

I

_D(A)^a

30

0.0032 at V_GS= 10 V

0.0045 at V_GS= 4.5 V

•

Ultra-Low On-Resistance Using High

Density TrenchFET^®Gen II Power

MOSFET Technology

20

24.5

30

PowerPAK SO-8

•

Q_gOptimized

• 100 % R_gTested

• 100 % UIS Tested

D

S

6.15 mm

5.15 mm

1

S

2

S

APPLICATIONS

3

G

4

• Low-Side DC/DC Conversion

- Notebook

D

8

G

D

7

- Server

- Workstation

D

6

D

5

Bottom View

Ordering Information: Si7136DP-T1-E3 (Lead (Pb)-free)

Si7136DP-T1-GE3 (Lead (Pb)-free and Halogen-free)

S

N-Channel MOSFET

ABSOLUTE MAXIMUM RATINGS T = 25 °C, unless otherwise noted

A

Parameter

Drain-Source Voltage

Gate-Source Voltage

Symbol

V_DS

V_GS

Limit

20

Unit

V

T

_C= 25 °C

_C= 70 °C

30

29.5^{b, c}

20^{b, c}

70

Continuous Drain Current (T_J= 150 °C)

I_D

T_A= 25 °C

T_A= 70 °C

A

I_DM

I_S

Pulsed Drain Current

T_C= 25 °C

30

4.5^{b, c}

30

Continuous Source-Drain Diode Current

T_A= 25 °C

I_AS

E_AS

Avalanche Current

L = 0.1 mH

Single-Pulse Avalanche Energy

45

mJ

W

T_C= 25 °C

T_C= 70 °C

T_A= 25 °C

T_A= 70 °C

39

25

5^{b, c}

3.2^{b, c}

P_D

Maximum Power Dissipation

T_J, T_stg

Operating Junction and Storage Temperature Range

Soldering Recommendations (Peak Temperature)^{d, e}

- 55 to 150

°C

260

THERMAL RESISTANCE RATINGS

Parameter

Symbol

Typical

Maximum

Unit

Maximum Junction-to-Ambient^{b, f}

Maximum Junction-to-Case (Drain)

t ≤ 10 s

Steady State

R_thJA

R_thJC

20

25

°C/W

2.1

3.2

Notes:

a. Based on T_C= 25 °C.

b. Surface mounted on 1" x 1" FR4 board.

c. t = 10 s.

d. See Solder Profile (www.vishay.com/doc?73461). The PowerPAK SO-8 is a leadless package. The end of the lead terminal is exposed

copper (not plated) as a result of the singulation process in manufacturing. A solder fillet at the exposed copper tip cannot be guaranteed and

is not required to ensure adequate bottom side solder interconnection.

e. Rework Conditions: manual soldering with a soldering iron is not recommended for leadless components.

f. Maximum under steady state conditions is 70 °C/W.

Document Number: 73601

S09-0222-Rev. B, 09-Feb-09

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1

Si7136DP

Vishay Siliconix

SPECIFICATIONS T = 25 °C, unless otherwise noted

J

Parameter

Symbol

Test Conditions

Min.

Typ.

Max.

Unit

Static

V_DS

ΔV_DS/T_J

ΔV_GS(th)/T_J

V_GS(th)

V_GS= 0 V, I_D= 250 µA

I_D= 1 µA to 250 µA

Drain-Source Breakdown Voltage

20

V

_DSTemperature Coefficient

20

- 7

mV/°C

V_GS(th)Temperature Coefficient

Gate-Source Threshold Voltage

Gate-Source Leakage

V_DS= V_GS, I_D= 250 µA

1.0

30

3.0

100

1

V

I_GSS

V_DS= 0 V, V_GS

=

20 V

nA

V_DS= 20 V, V_GS= 0 V

V_DS= 20 V, V_GS= 0 V, T_J= 55 °C

V_DS≥ 5 V, V_GS= 10 V

I_DSS

I_D(on)

R_DS(on)

g_fs

Zero Gate Voltage Drain Current

µA

A

10

On-State Drain Current^a

V_GS= 10 V, I_D= 20 A

0.0026

0.0036

92

0.0032

0.0045

Drain-Source On-State Resistance^a

Forward Transconductance^a

Ω

S

V_GS= 4.5 V, I_D= 17 A

V_DS= 15 V, I_D= 20 A

Dynamic^b

C_iss

C_oss

C_rss

Input Capacitance

3380

797

335

51.5

24.5

10.3

6.5

0.8

31

V

_DS= 10 V, V_GS= 0 V, f = 1 MHz

Output Capacitance

pF

Reverse Transfer Capacitance

V_DS= 10 V, V_GS= 10 V, I_D= 10 A

V_DS= 10 V, V_GS= 4.5 V, I_D= 10 A

f = 1 MHz

78

Q_g

Total Gate Charge

37

nC

Q_gs

Q_gd

R_g

Gate-Source Charge

Gate-Drain Charge

Gate Resistance

1.2

50

100

45

15

30

65

55

15

Ω

t_d(on)

t_r

t_d(off)

t_f

t_d(on)

t_r

t_d(off)

t_f

Turn-On Delay Time

Rise Time

67

V

_DD= 10 V, R_L= 2 Ω

I_D≅ 5 A, V_GEN= 4.5 V, R_g= 1 Ω

Turn-Off Delay Time

Fall Time

30

9

ns

Turn-On Delay Time

Rise Time

19

42

V

_DD= 10 V, R_L= 2 Ω

I_D≅ 5 A, V_GEN= 10 V, R_g= 1 Ω

Turn-Off Delay Time

Fall Time

37

9

Drain-Source Body Diode Characteristics

Continuous Source-Drain Diode Current

I_S

I_SM

V_SD

t_rr

T_C= 25 °C

I_S= 2.7 A

30

70

1.1

65

60

A

Pulse Diode Forward Current^a

Body Diode Voltage

0.72

43

V

Body Diode Reverse Recovery Time

Body Diode Reverse Recovery Charge

Reverse Recovery Fall Time

Reverse Recovery Rise Time

ns

nC

Q_rr

t_a

37

I_F= 23 A, dI/dt = 100 A/µs, T_J= 25 °C

17

ns

t_b

26

Notes:

a. Pulse test; pulse width ≤ 300 µs, duty cycle ≤ 2 %

b. Guaranteed by design, not subject to production testing.

Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation

of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum

rating conditions for extended periods may affect device reliability.

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Document Number: 73601

S09-0222-Rev. B, 09-Feb-09

Si7136DP

Vishay Siliconix

TYPICAL CHARACTERISTICS 25 °C, unless otherwise noted

60

1.2

1.0

0.8

0.6

0.4

0.2

0.0

V

GS

= 10 V thru 4 V

50

40

30

20

10

0

25 °C

T

C

= 125 °C

3 V

- 55 °C

0.0

0.5

1.0

1.5

2.0

2.5

3.0

0

1

2

3

4

5

V

DS

- Drain-to-Source Voltage (V)

V

GS

- Gate-to-Source Voltage (V)

Output Characteristics

Transfer Characteristics

4500

3600

2700

1800

900

0.0050

0.0044

0.0038

C

iss

V

GS

= 4.5 V

0.0032

0.0026

V

GS

= 10 V

C

oss

C

rss

0

0.0020

0

10

20

30

40

50

60

0

4

8

12

16

20

I

D

- Drain Current (A)

V

DS

- Drain-to-Source Voltage (V)

Capacitance

On-Resistance vs. Drain Current and Gate Voltage

10

1.6

1.4

1.2

1.0

0.8

0.6

V

= 10 V

= 20 A

GS

I

D

I

D

= 10 A

8

6

4

2

0

V

= 5 V

DS

V

= 4.5 V

= 17 A

GS

V

DS

= 10 V

I

D

V

DS

= 15 V

0

12

24

36

48

60

- 50 - 25

0

25

50

75

100 125 150

Q

g

- Total Gate Charge (nC)

T - Junction Temperature (°C)

J

On-Resistance vs. Junction Temperature

Gate Charge

Document Number: 73601

S09-0222-Rev. B, 09-Feb-09

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Si7136DP

Vishay Siliconix

TYPICAL CHARACTERISTICS 25 °C, unless otherwise noted

0.020

100 000

10 000

0.016

0.012

0.008

0.004

0.000

T

= 150 °C

J

1000

0.1

125 °C

T

= 25 °C

J

0.01

25 °C

3

0.001

0

1

2

4

5

6

7

8

9

10

0.0

0.2

0.4

0.6

0.8

1.0

V

GS

- Gate-to-Source Voltage (V)

V

SD

- Source-to-Drain Voltage (V)

On-Resistance vs. Gate-to-Source Voltage

Source-Drain Diode Forward Voltage

0.5

0.2

200

160

120

80

- 0.1

- 0.4

- 0.7

- 1.0

I

= 5 mA

D

I

= 250 µA

D

40

0

- 50 - 25

0

25

50

75

100 125 150

-3

-2

-1

10

1

T

J

- Temperature (°C)

Time (s)

Single Pulse Power

Threshold Voltage

100

Limited by

R_DS(on)

*

1 ms

10

1

10 ms

100 ms

1 s

10 s

0.1

DC

T

A

= 25 °C

Single Pulse

0.01

0.1

1

10

100

is specified

V

- Drain-to-Source Voltage (V)

DS

* V

minimum V

at which R

DS(on)

GS

Safe Operating Area, Junction-to-Ambient

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Document Number: 73601

S09-0222-Rev. B, 09-Feb-09

Si7136DP

Vishay Siliconix

TYPICAL CHARACTERISTICS 25 °C, unless otherwise noted

100

80

60

40

Limited by Package

20

0

25

50

75

100

125

150

T

C

- Case Temperature (°C)

Current Derating*

50

40

30

20

10

0

2.5

2.0

1.5

1.0

0.5

0.0

0

25

50

75

100

125

150

0

25

50

T - Ambient Temperature (°C)

A

75

100

125

150

T

C

- Case Temperature (°C)

Power Junction-to-Case

Power Junction-to-Ambient

* The power dissipation P_Dis based on T_J(max)= 150 °C, using junction-to-case thermal resistance, and is more useful in settling the upper

dissipation limit for cases where additional heatsinking is used. It is used to determine the current rating, when this rating falls below the package

limit.

Document Number: 73601

S09-0222-Rev. B, 09-Feb-09

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Si7136DP

Vishay Siliconix

TYPICAL CHARACTERISTICS 25 °C, unless otherwise noted

1

Duty Cycle = 0.5

0.2

Notes:

0.1

P

DM

0.05

t

1

t

2

t

1

1. Duty Cycle, D =

2

0.02

2. Per Unit Base = R

= 70 C/W

thJA

(t)

3. T - T = P

Z

JM

A

DM thJA

Single Pulse

4. Surface Mounted

0.01

-4

-3

-2

-1

10

Square Wave Pulse Duration (s)

Normalized Thermal Transient Impedance, Junction-to-Ambient

1

10

100

1000

1

0.5

0.2

0.1

0.02

0.05

Single Pulse

0.01

-4

-3

-2

-1

10

Square Wave Pulse Duration (s)

Normalized Thermal Transient Impedance, Junction-to-Case

10

1

Vishay Siliconix maintains worldwide manufacturing capability. Products may be manufactured at one of several qualified locations. Reliability data for Silicon

Technology and Package Reliability represent a composite of all qualified locations. For related documents such as package/tape drawings, part marking, and

reliability data, see www.vishay.com/ppg?73601.

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Document Number: 73601

S09-0222-Rev. B, 09-Feb-09

Package Information

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Vishay Siliconix

PowerPAK^®SO-8, (Single/Dual)

L

H

E2

K

E4

W

1

2

3

4

Z

2

3

4

D

L1

E3

A1

Backside View of Single Pad

L

H

K

E2

E4

2

E1

E

Detail Z

1

2

3

4

D1

D2

Notes

1. Inch will govern.

E3

2

Dimensions exclusive of mold gate burrs.

Backside View of Dual Pad

3. Dimensions exclusive of mold flash and cutting burrs.

MILLIMETERS

INCHES

NOM.

0.041

DIM.

MIN.

NOM.

1.04

MAX.

1.12

0.05

0.51

0.33

5.26

5.00

3.91

1.68

MIN.

0.038

0

MAX.

0.044

0.002

0.020

0.013

0.207

0.197

0.154

0.066

A

A1

b

0.97

-

0.33

0.23

5.05

4.80

3.56

1.32

0.41

0.013

0.009

0.199

0.189

0.140

0.052

0.016

c

0.28

0.011

D

5.15

0.203

D1

D2

D3

D4

D5

E

4.90

0.193

3.76

0.148

1.50

0.059

0.57 typ.

3.98 typ.

6.15

0.0225 typ.

0.157 typ.

0.242

6.05

5.79

3.48

3.68

6.25

5.99

3.84

3.91

0.238

0.228

0.137

0.145

0.246

0.236

0.151

0.154

E1

E2

E3

E4

e

5.89

0.232

3.66

0.144

3.78

0.149

0.75 typ.

1.27 BSC

1.27 typ.

-

0.030 typ.

0.050 BSC

0.050 typ.

-

K

K1

H

0.56

0.51

0.06

0°

-

0.022

0.020

0.002

0°

-

0.61

0.71

0.20

12°

0.024

0.028

0.008

12°

L

0.61

0.024

L1



0.13

0.005

-

W

M

0.15

0.25

0.36

0.006

0.010

0.014

0.125 typ.

0.005 typ.

ECN: S17-0173-Rev. L, 13-Feb-17

DWG: 5881

Revison: 13-Feb-17

Document Number: 71655

1

THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT

ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

VISHAY SILICONIX

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Power MOSFETs

Application Note AN821

PowerPAK^®SO-8 Mounting and Thermal Considerations

by Wharton McDaniel

PowerPAK SO-8 SINGLE MOUNTING

MOSFETs for switching applications are now available with

die on resistances around 1 m and with the capability to

handle 85 A. While these die capabilities represent a major

advance over what was available just a few years ago, it is

important for power MOSFET packaging technology to keep

pace. It should be obvious that degradation of a high

performance die by the package is undesirable. PowerPAK

is a new package technology that addresses these issues.

In this application note, PowerPAK’s construction is

described. Following this mounting information is presented

including land patterns and soldering profiles for maximum

reliability. Finally, thermal and electrical performance is

discussed.

The PowerPAK single is simple to use. The pin arrangement

(drain, source, gate pins) and the pin dimensions are the

same as standard SO-8 devices (see figure 2). Therefore, the

PowerPAK connection pads match directly to those of the

SO-8. The only difference is the extended drain connection

area. To take immediate advantage of the PowerPAK SO-8

single devices, they can be mounted to existing SO-8 land

patterns.

THE PowerPAK PACKAGE

The PowerPAK package was developed around the SO-8

package (figure 1). The PowerPAK SO-8 utilizes the same

footprint and the same pin-outs as the standard SO-8. This

allows PowerPAK to be substituted directly for a standard

SO-8 package. Being a leadless package, PowerPAK SO-8

utilizes the entire SO-8 footprint, freeing space normally

occupied by the leads, and thus allowing it to hold a larger

die than a standard SO-8. In fact, this larger die is slightly

larger than a full sized DPAK die. The bottom of the die

attach pad is exposed for the purpose of providing a direct,

low resistance thermal path to the substrate the device is

mounted on. Finally, the package height is lower than the

standard SO-8, making it an excellent choice for

applications with space constraints.

Standard SO-8

PowerPAK SO-8

Fig. 2

The minimum land pattern recommended to take full

advantage of the PowerPAK thermal performance see

Application Note 826, Recommended Minimum Pad

Patterns With Outline Drawing Access for Vishay Siliconix

MOSFETs. Click on the PowerPAK SO-8 single in the index

of this document.

In this figure, the drain land pattern is given to make full

contact to the drain pad on the PowerPAK package.

This land pattern can be extended to the left, right, and top

of the drawn pattern. This extension will serve to increase

the heat dissipation by decreasing the thermal resistance

from the foot of the PowerPAK to the PC board and

therefore to the ambient. Note that increasing the drain land

area beyond a certain point will yield little decrease

in foot-to-board and foot-to-ambient thermal resistance.

Under specific conditions of board configuration, copper

weight and layer stack, experiments have found that

more than about 0.25 in²to 0.5 in²of additional copper

(in addition to the drain land) will yield little improvement in

thermal performance.

Fig. 1 PowerPAK 1212 Devices

Revision: 16-Mai-13

Document Number: 71622

1

For technical questions, contact: powermosfettechsupport@vishay.com

THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT

ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

Application Note AN821

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Vishay Siliconix

PowerPAK^®SO-8 Mounting and Thermal Considerations

For

the

lead

(Pb)-free

solder

profile,

see

PowerPAK SO-8 DUAL

www.vishay.com/doc?73257.

The pin arrangement (drain, source, gate pins) and the pin

dimensions of the PowerPAK SO-8 dual are the same as

standard SO-8 dual devices. Therefore, the PowerPAK

device connection pads match directly to those of the SO-8.

As in the single-channel package, the only exception is the

extended drain connection area. Manufacturers can likewise

take immediate advantage of the PowerPAK SO-8 dual

devices by mounting them to existing SO-8 dual land

patterns.

To take the advantage of the dual PowerPAK SO-8’s

thermal performance, the minimum recommended land

pattern can be found in Application Note 826,

Recommended Minimum Pad Patterns With Outline

Drawing Access for Vishay Siliconix MOSFETs. Click on the

PowerPAK 1212-8 dual in the index of this document.

The gap between the two drain pads is 24 mils. This

matches the spacing of the two drain pads on the

PowerPAK SO-8 dual package.

Fig. 3 Solder Reflow Temperature Profile

Ramp-Up Rate

+ 3 °C /s max.

120 s max.

REFLOW SOLDERING

Temperature at 150 - 200 °C

Temperature Above 217 °C

Maximum Temperature

Vishay Siliconix surface-mount packages meet solder reflow

reliability requirements. Devices are subjected to solder

60 - 150 s

255 + 5/- 0 °C

reflow as

a

test preconditioning and are then

reliability-tested using temperature cycle, bias humidity,

HAST, or pressure pot. The solder reflow temperature profile

used, and the temperatures and time duration, are shown in

figures 3 and 4.

Time at Maximum

Temperature

30 s

Ramp-Down Rate

+ 6 °C/s max.

30 s

260 °C

3 °C(max)

6 °C/s (max.)

217 °C

150 - 200 °C

150 s (max.)

60 s (min.)

Reflow Zone

Pre-Heating Zone

Maximum peak temperature at 240 °C is allowed.

Fig. 4 Solder Reflow Temperatures and Time Durations

Revision: 16-Mai-13

Document Number: 71622

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For technical questions, contact: powermosfettechsupport@vishay.com

THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT

ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

Application Note AN821

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Vishay Siliconix

PowerPAK^®SO-8 Mounting and Thermal Considerations

THERMAL PERFORMANCE

Introduction

Because of the presence of the trough, this result suggests

a minimum performance improvement of 10 °C/W by using

a PowerPAK SO-8 in a standard SO-8 PC board mount.

A basic measure of a device’s thermal performance

is the junction-to-case thermal resistance, R_thJC, or the

junction-to-foot thermal resistance, R_thJFThis parameter is

measured for the device mounted to an infinite heat sink and

is therefore a characterization of the device only, in other

words, independent of the properties of the object to which

the device is mounted. Table 1 shows a comparison of

the DPAK, PowerPAK SO-8, and standard SO-8. The

PowerPAK has thermal performance equivalent to the

DPAK, while having an order of magnitude better thermal

performance over the SO-8.

The only concern when mounting a PowerPAK on a

standard SO-8 pad pattern is that there should be no traces

running between the body of the MOSFET. Where the

standard SO-8 body is spaced away from the pc board,

allowing traces to run underneath, the PowerPAK sits

directly on the pc board.

Thermal Performance - Spreading Copper

Designers may add additional copper, spreading copper, to

the drain pad to aid in conducting heat from a device. It is

helpful to have some information about the thermal

performance for a given area of spreading copper.

TABLE 1 - DPAK AND POWERPAK SO-8

EQUIVALENT STEADY STATE

PERFORMANCE

Figure 6 shows the thermal resistance of a PowerPAK SO-8

device mounted on a 2-in. 2-in., four-layer FR-4 PC board.

The two internal layers and the backside layer are solid

copper. The internal layers were chosen as solid copper to

model the large power and ground planes common in many

applications. The top layer was cut back to a smaller area

and at each step junction-to-ambient thermal resistance

measurements were taken. The results indicate that an area

above 0.3 to 0.4 square inches of spreading copper gives no

PowerPAK

SO-8

Standard

SO-8

DPAK

Thermal

Resistance R_thJC

1.2 °C/W

1 °C/W

16 °C/W

Thermal Performance on Standard SO-8 Pad Pattern

Because of the common footprint, a PowerPAK SO-8

can be mounted on an existing standard SO-8 pad pattern.

The question then arises as to the thermal performance

of the PowerPAK device under these conditions. A

characterization was made comparing a standard SO-8 and

a PowerPAK device on a board with a trough cut out

underneath the PowerPAK drain pad. This configuration

restricted the heat flow to the SO-8 land pads. The results

are shown in figure 5.

additional

thermal

performance

improvement.

A

subsequent experiment was run where the copper on the

back-side was reduced, first to 50 % in stripes to mimic

circuit traces, and then totally removed. No significant effect

was observed.

R

th

vs. Spreading Copper

(0 %, 50 %, 100 % Back Copper)

56

51

46

41

36

Si4874DY vs. Si7446DP PPAK on a 4-Layer Board

SO-8 Pattern, Trough Under Drain

60

50

40

Si4874DY

30

100 %

Si7446DP

0 %

20

50 %

10

0.00 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00

Spreading Copper (sq in)

0

Fig. 6 Spreading Copper Junction-to-Ambient Performance

0.0001

0.01

1

10000

100

Pulse Duration (sec)

Fig. 5 PowerPAK SO-8 and Standard SO-0 Land Pad Thermal

Path

Revision: 16-Mai-13

Document Number: 71622

3

For technical questions, contact: powermosfettechsupport@vishay.com

THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT

ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

Application Note AN821

www.vishay.com

Vishay Siliconix

PowerPAK^®SO-8 Mounting and Thermal Considerations

Suppose each device is dissipating 2.7 W. Using the

SYSTEM AND ELECTRICAL IMPACT OF

PowerPAK SO-8

junction-to-foot thermal resistance characteristics of the

PowerPAK SO-8 and the standard SO-8, the die

temperature is determined to be 107 °C for the PowerPAK

(and for DPAK) and 148 °C for the standard SO-8. This is a

2 °C rise above the board temperature for the PowerPAK

and a 43 °C rise for the standard SO-8. Referring to figure 7,

a 2 °C difference has minimal effect on R_DS(on)whereas a

In any design, one must take into account the change in

MOSFET R_DS(on)with temperature (figure 7).

On-Resistance vs. Junction Temperature

1.8

43 °C difference has a significant effect on R_DS(on)

.

V

= 10 V

= 23 A

GS

1.6

1.4

1.2

1.0

0.8

0.6

I

D

Minimizing the thermal rise above the board temperature by

using PowerPAK has not only eased the thermal design but

it has allowed the device to run cooler, keep r_DS(on)low, and

permits the device to handle more current than the same

MOSFET die in the standard SO-8 package.

CONCLUSIONS

PowerPAK SO-8 has been shown to have the same thermal

performance as the DPAK package while having the same

footprint as the standard SO-8 package. The PowerPAK

SO-8 can hold larger die approximately equal in size to the

maximum that the DPAK can accommodate implying no

sacrifice in performance because of package limitations.

-50

-25

0

25

50

75

100 125 150

T

J

- Junction Temperature (°C)

Recommended PowerPAK SO-8 land patterns are provided

to aid in PC board layout for designs using this new

package.

Fig. 7 MOSFET R_DS(on)vs. Temperature

A MOSFET generates internal heat due to the current

passing through the channel. This self-heating raises the

junction temperature of the device above that of the PC

board to which it is mounted, causing increased power

dissipation in the device. A major source of this problem lies

in the large values of the junction-to-foot thermal resistance

of the SO-8 package.

Thermal considerations have indicated that significant

advantages can be gained by using PowerPAK SO-8

devices in designs where the PC board was laid out for

the standard SO-8. Applications experimental data gave

thermal performance data showing minimum and

typical thermal performance in a SO-8 environment, plus

information on the optimum thermal performance

obtainable including spreading copper. This further

emphasized the DPAK equivalency.

PowerPAK SO-8 minimizes the junction-to-board thermal

resistance to where the MOSFET die temperature is very

close to the temperature of the PC board. Consider two

devices mounted on a PC board heated to 105 °C by other

components on the board (figure 8).

PowerPAK SO-8 therefore has the desired small size

characteristics of the SO-8 combined with the attractive

thermal characteristics of the DPAK package.

PowerPAK SO-8

Standard SO-8

107 °C

148 °C

0.8 °C/W

PC Board at 105 °C

16 C/W

Fig. 8 Temperature of Devices on a PC Board

Revision: 16-Mai-13

Document Number: 71622

4

For technical questions, contact: powermosfettechsupport@vishay.com

THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT

ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

Application Note 826

Vishay Siliconix

RECOMMENDED MINIMUM PADS FOR PowerPAK^®SO-8 Single

0.260

(6.61)

0.150

(3.81)

0.024

(0.61)

0.026

(0.66)

0.050

(1.27)

0.032

(0.82)

0.040

(1.02)

Recommended Minimum Pads

Dimensions in Inches/(mm)

Return to Index

Document Number: 72599

Revision: 21-Jan-08

www.vishay.com

15

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Vishay

Disclaimer



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Revision: 08-Feb-17

Document Number: 91000

1


型号：	SI7136DP-T1-GE3
厂家：	VISHAY
描述：	N-CHANNEL 20-V (D-S) MOSFET - Tape and Reel 开关脉冲晶体管
文件：	总13页 (文件大小：319K)
中文：	中文翻译
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