Presentation is loading. Please wait.

Presentation is loading. Please wait.

Thermal Equivalent Circuit for a Transistor. Junction Temperature Case TemperatureHeat Sink Temperature Ambient Temperature.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Thermal Equivalent Circuit for a Transistor. Junction Temperature Case TemperatureHeat Sink Temperature Ambient Temperature."— Presentation transcript:

1 Thermal Equivalent Circuit for a Transistor

2 Junction Temperature Case TemperatureHeat Sink Temperature Ambient Temperature

3 Thermal Resistance from Junction to Case Thermal Resistance from Case to Heat Sink Thermal Resistance from Heat Sink to Ambient Total Average Power Loss

4

5 Motorola MS-10 Heat Sink

6 Performance Under Forced Air Flow

7 Thermal Characteristic in Free Air

8 Top View of MS-10 Heat Sink

9 Hole Pattern for a TO-3 Case

10 Mica Insulator

11 Thermal Resistances for Mica Insulators

12

13 Clip-On Heat Sinks

14 Thermal Performance

15 Thermal Resistance for Clip-On

16 Bond-On Extrusions for DIP Packages

17 Thermal Performance

18 Thermal Resistances for Bond-On

19 Example TO-220 case style dissipating 5 watts R JC = 3.0  C / Watt (from device spec) T Jmax = 150  C T Amax = 50  C Find the proper heat sink to keep the junction temperature from exceeding 150  C in natural convection.

20 Need to determine a value for R CS – depends on the mounting technique. If the device is mounted without an insulator, but only with Thermalcote, (silicone grease), check page 57, Figure 9 for TO -220 case style.

21 R CS = 1  C/W No Insulator Use Thermalcote

22

23 Thermalloy P/N 6030 Temperature rise above ambient@ 5 Watts Power Dissipation = 66  C

24 Thermal Resistance R SA As long as R SA is less than 16  C/W, the requirement is met.

25 Thermalloy P/N 6030

Download ppt "Thermal Equivalent Circuit for a Transistor. Junction Temperature Case TemperatureHeat Sink Temperature Ambient Temperature."

Similar presentations

ECE 442 Power Electronics1 Two Devices on a Common Heat Sink Thermal Model.

ECE 442 Power Electronics1 Two Devices on a Common Heat Sink Thermal Model.
MOSFET SELECTION FOR A THREE PHASE INVERTER Team 9 JR Alvarez, Matt Myers Chris Sommer, Scott OConnor.

MOSFET SELECTION FOR A THREE PHASE INVERTER Team 9 JR Alvarez, Matt Myers Chris Sommer, Scott OConnor.
Lecture-6 Thermal Design-2 Dr. Tahir Izhar

Lecture-6 Thermal Design-2 Dr. Tahir Izhar
Heat.

Heat.
The nonlinear compact thermal model of power MOS transistors

The nonlinear compact thermal model of power MOS transistors
Extended Surfaces Chapter Three Section 3.6.

Extended Surfaces Chapter Three Section 3.6.
Breakdown in Solid Dielectrics

Breakdown in Solid Dielectrics
Power Device Characteristics Voltage Rating: Off state blocking voltage – exceed and destroy! Current Rating: On (saturation) state maximum – exhibits.

Power Device Characteristics Voltage Rating: Off state blocking voltage – exceed and destroy! Current Rating: On (saturation) state maximum – exhibits.
Home Insulation By: Jeff Krise. Introduction Analyze the rate of heat transfer from the attic to the interior of the home. Based on summer average temperatures.

Home Insulation By: Jeff Krise. Introduction Analyze the rate of heat transfer from the attic to the interior of the home. Based on summer average temperatures.
Jed Goodell Jesse Williams. Introduction Problem How much heat does a particular heat sink dissipate How many fins are needed to dissipate a specific.

Jed Goodell Jesse Williams. Introduction Problem How much heat does a particular heat sink dissipate How many fins are needed to dissipate a specific.
Thermal Design And Analysis of High Power Electronic Boards J. Collado CHT, April 13, 2000.

Thermal Design And Analysis of High Power Electronic Boards J. Collado CHT, April 13, 2000.
Output Stages and Power Amplifiers

Output Stages and Power Amplifiers
Electronics Cooling Mechanical Power Engineering Dept.

Electronics Cooling Mechanical Power Engineering Dept.
Output Transistors Current gain / input impedance is a vital parameter of a power amplifier. In the class A analysis, the load impedance is scaled by a.

Output Transistors Current gain / input impedance is a vital parameter of a power amplifier. In the class A analysis, the load impedance is scaled by a.
CHE/ME 109 Heat Transfer in Electronics

CHE/ME 109 Heat Transfer in Electronics
1 Figure 14.11 Class AB output stage. A bias voltage V BB is applied between the bases of Q N and Q P, giving rise to a bias current I Q given by Eq. (14.23).

1 Figure Class AB output stage. A bias voltage V BB is applied between the bases of Q N and Q P, giving rise to a bias current I Q given by Eq. (14.23).
Output Transistors Current gain / input impedance is a vital parameter of a power amplifier. In the class A analysis, the load impedance is scaled by a.

Output Transistors Current gain / input impedance is a vital parameter of a power amplifier. In the class A analysis, the load impedance is scaled by a.
POWER TRANSISTOR – MOSFET Parameter 2N6757 2N6792 VDS(max) (V)

POWER TRANSISTOR – MOSFET Parameter 2N6757 2N6792 VDS(max) (V)
VOLTAGE REGULATORS. Types of Voltage Regulators Zener Diode Regulators Series Transistor Regulators Low Dropout (LDO) Regulators Packaged Regulators.

VOLTAGE REGULATORS. Types of Voltage Regulators Zener Diode Regulators Series Transistor Regulators Low Dropout (LDO) Regulators Packaged Regulators.
Power Electronic Devices Semester 1 Lecturer: Javier Sebastián Electrical Energy Conversion and Power Systems Universidad de Oviedo Power Supply Systems.

Power Electronic Devices Semester 1 Lecturer: Javier Sebastián Electrical Energy Conversion and Power Systems Universidad de Oviedo Power Supply Systems.

Similar presentations

Ads by Google