3970107371 - ARTESYN EMBEDDED POWER

APA501

AMPSS

™

Astec Modular Power Supply System

Series Highlights

•Horizontal, Vertical and Low Profile fin options

•Full range of mounting accessories

Heatsinks for Power Modules

Technical Reference Manual

Series

Rev. 01 Jan 96

AMPSS

Reference Manual

Table of Contents

Contents

Heatsinks ............................................................................ 3

"60" Size Heatsink Dimensions & Characteristics............................................4

"80" Size Heatsink Dimensions & Characteristics............................................7

Thermal Design Process and Example .......................... 11

Rev. 01 Jan 96

AMPSS

Reference Manual

AMPSS

® Accessories

Heatsinks

Heatsinks for

AMPSS

modules are available in a

variety of sizes and fin orientation. Mounting kits

and thermal pads are also available. The table

below shows the options available for "80" and "60"

module sizes.

A heatsink mounting kit provides the most conven-

ient way to mount the heatsink to the module and

then mount the assembly onto a circuit board

AMPSS

modules may be retained by their input and

output pins only, or may be fixed to the board using

bolts screwed into the tapped studs which are

provided as part of the mounting kit. In both cases

the studs provide clearance between the module and

the circuit board to facilitate PCB cleaning opera-

tions.

Note: baseplate and heatsink must be connected to

protective earth

Description Model Number Dimensions Free air therma

inches mm resistance

Heatsink, "60" size, vertical fin. APA501-60-001 2.26x2.32x0.6 57.5x59x15 3.8˚C/W

Heatsink, "60" size, horizontal fin APA501-60-002 2.26x2.32x0.6 57.5x59x15 3.9˚C/W

Heatsink, "60" size, vertical fin. APA501-60-003 2.26x2.32x0.9 57.5x59x22.5 3.3˚C/W

Heatsink, "60" size, horizontal fin APA501-60-004 2.26x2.32x0.9 57.5x59x22.5 3.7˚C/W

Heatsink, "60" size, vertical fin. APA501-60-005 2.26x2.32x1.5 57.5x59x37 2.8˚C/W

Heatsink, "60" size, horizontal fin APA501-60-006 2.26x2.32x1.5 57.5x59x37 2.8˚C/W

Heatsink, "60" size, low profile APA501-60-007 2.25x3.50x0.5 57.2x89x12 3.6˚C/W

Heatsink, "80" size, vertical fin. APA501-80-001 4.53x2.32x0.6 115x59x15 2.7˚C/W

Heatsink, "80" size, horizontal fin APA501-80-002 4.53x2.32x0.6 115x59x15 2.4˚C/W

Heatsink, "80" size, vertical fin. APA501-80-003 4.53x2.32x0.9 115x59x22.5 2.2˚C/W

Heatsink, "80" size, horizontal fin APA501-80-004 4.53x2.32x0.9 115x59x22.5 2.0˚C/W

Heatsink, "80" size, vertical fin. APA501-80-005 4.53x2.32x1.5 115x59x37 2.0˚C/W

Heatsink, "80" size, horizontal fin APA501-80-006 4.53x2.32x1.5 115x59x37 1.7˚C/W

Heatsink, "80" size, low profile APA501-80-007 4.55x3.50x0.5 115.6x89x12 2.2˚C/W

Thermal Pad, "60" size APA502-60-001

Thermal Pad, "80" size APA502-80-001

Mounting Kit, Tapped Studs APA503-00-001

Mounting Kit, Solder Studs APA503-00-002

Mounting Kit, Tapped Studs APA503-00-007

for low profile heatsink

Mounting Kit, Solder Studs APA503-00-008

for low profile heatsink

Spring Sockets (20 cont. 15pwr) APA504-00-001

Rev. 01 Jan 96

AMPSS

Reference Manual

Heatsinks

APA501-60-002

APA501-60-003

57.50 (2.26)

59.00 (2.32)

24.0 (0.9)

50.80 (2.00)

4.0 (0.16) 12.0 (0.47)

48.26 (1.90)

ø 3.80 (0.15)

APA501-60-001

"60" Size Heatsink Dimensions & Characteristics

57.50 (2.26)

59.00 (2.32)

15.0 (0.6) 50.80 (2.00)

4.0 (0.16) 12.0 (0.47)

48.26 (1.90)

ø 3.80 (0.15)

57.50 (2.26)

59.00 (2.32)

15.0 (0.6) 50.80 (2.00)

4.0 (0.16) 12.0 (0.47)

48.26 (1.90)

ø 3.80 (0.15)

Forced Convection for APA501-60-001 at 100W Output

0.5

1.5

2.5

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Forced Convection for APA501-60-002 at 100W Output

0.5

1.5

2.5

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Forced Convection for APA501-60-003 at 100W Output

0.2

0.4

0.6

0.8

1.2

1.4

1.6

1.8

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Rev. 01 Jan 96

AMPSS

Reference Manual

AMPSS

® Accessories

APA501-60-004

57.50 (2.26)

59.00 (2.32)

37.0 (1.5)

50.80 (2.00)

4.0 (0.16) 12.0 (0.47)

48.26 (1.90)

ø 3.80 (0.15)

APA501-60-005

APA501-60-006

57.50 (2.26)

59.00 (2.32)

24.0 (0.9)

50.80 (2.00)

4.0 (0.16) 12.0 (0.47)

48.26 (1.90)

ø 3.80 (0.15)

57.50 (2.26)

59.00 (2.32)

37.0 (1.5)

50.80 (2.00)

4.0 (0.16) 12.0 (0.47)

48.26 (1.90)

ø 3.80 (0.15)

Forced Convection for APA501-60-005 at 100W Output

0.2

0.4

0.6

0.8

1.2

1.4

1.6

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Forced Convection for APA501-60-006 at 100W Output

0.2

0.4

0.6

0.8

1.2

1.4

1.6

1.8

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Forced Convection for APA501-60-004 at 100W Output

0.5

1.5

2.5

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Rev. 01 Jan 96

AMPSS

Reference Manual

Heatsinks

50.80 (2.00) 19.10 (0.75)

4.47(0.18)

48.26 (1.90)

57.2 (2.25)

45°

63.0 (2.48)

89.0 (3.50)

ø7.5 (0.30) (4X)

ø3.8 (0.15) (4X)

ø4.2 (0.17) (4X)

4.0 (0.16) ± 0.1

12.0 

(0.47) 4.2 (0.17)



3.5 (0.14)

Section A-A



APA501-60-007

Forced Convection for APA501-80-007 at 200W Output

0.5

1.5

2.5

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Rev. 01 Jan 96

AMPSS

Reference Manual

AMPSS

® Accessories

"80" Size Heatsink Dimensions & Characteristics

115.0 (4.53)

59.0 (2.32)

15.0

(0.6)

50.80(2.00)

4.0 (0.16) 12.0 (0.47)

106.68 (4.20)

ø 3.80 (0.15)

115.0 (4.53)

59.0 (2.32)

15.0

(0.6)

50.80(2.00)

4.0 (0.16) 12.0 (0.47)

106.68 (4.20)

ø 3.80 (0.15)

Forced Convection for APA501-80-001 at 200W Output

0.2

0.4

0.6

0.8

1.2

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Forced Convection for APA501-80-002 at 200W Output

0.2

0.4

0.6

0.8

1.2

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

APA501-80-001

APA501-80-002

Rev. 01 Jan 96

AMPSS

Reference Manual

Heatsinks

APA501-80-003

APA501-80-004

Forced Convection for APA501-80-003 at 200W Output

0.2

0.4

0.6

0.8

1.2

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Forced Convection for APA501-80-004 at 200W Output

0.2

0.4

0.6

0.8

1.2

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

115.0 (4.53)

59.0 (2.32)

22.5 

(0.89)

50.80(2.00)

4.0 (0.16) 12.0 (0.47)

106.68 (4.20)

ø 3.80 (0.15)

115.0 (4.53)

59.0 (2.32)

22.5

(0.89)

50.80(2.00)

4.0 (0.16) 12.0 (0.47)

106.68 (4.20)

ø 3.80 (0.15)

Rev. 01 Jan 96

AMPSS

Reference Manual

AMPSS

® Accessories

Forced Convection for APA501-80-005 at 200W Output

0.2

0.4

0.6

0.8

1.2

1.4

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Forced Convection for APA501-80-006 at 200W Output

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

APA501-80-005

APA501-80-006

115.0 (4.53)

59.0(2.32)

37.0 (1.5) 50.80(2.00)

4.0 (0.16) 12.0 (0.47)

106.68 (4.20)

ø 3.80 (0.15)

115.0 (4.53)

59.0(2.32)

37.0 (1.5) 50.80(2.00)

4.0 (0.16) 12.0 (0.47)

106.68 (4.20)

ø 3.80 (0.15)

Rev. 01 Jan 96

AMPSS

Reference Manual

Heatsinks

APA501-80-007

50.8 (2.00) 19.1 (0.75)

4.47 (0.18)

106.68 (4.20)

115.6 (4.55) ±0.2

45°

Section A-A

63.0 (2.48)

89.0 (3.50)

ø7.5 (0.30) (4X)

ø3.8 (0.15) (4X)

ø4.2 (0.17) (4X)

4.0 (0.16) ± 0.1

12.0 

(0.47) 4.2 (0.17)



3.5 (0.14)

Forced Convection for APA501-80-007 at 200W Output

0.2

0.4

0.6

0.8

1.2

1.4

0 200 400 600 800 1000

V air (LFM)

Thermal Resistance Baseplate to Ambient (˚C/W)

Rev. 01 Jan 96

AMPSS

Reference Manual

AMPSS

® Accessories

Thermal Design Process and Example

Temperature & MTBF

APMSS

modules are designed to be able to run at

baseplate temperatures of 100°C in the case of the

AM80 series and 85°C for other series. However, for

normal operation the modules should not be run at

the maximum allowable temperature since the Mean

Time Between Failures (MTBF) will reduce sharply

as temperature increases. For example, an

AM80-300L-050F40 operating at 5V@40A output,

with a baseplate temperature of 50°C, has an MTBF

of over one million hours. If the temperature is

doubled to 100°C this figure drops to 155,000 hours.

The following rules should be followed to ensure

reliable operation -

• At the maximum system ambient tempera-

ture the APMSS

baseplate temperature

rating should not be exceeded.

• At the normal system ambient operating

temperature the APMSS

baseplate tem-

perature must be low enough to meet MTBF

requirements.

The Thermal Design Process

1. Determine heat generated by module from its

losses. The minimum efficiency at relevant line

and load conditions should be used in calculat-

ing the losses.

2. Determine maximum baseplate temperature

rise to stay within module temperature rating

at maximum system ambient.

3. Define maximum system baseplate tempera-

ture to meet MTBF in normal system operating

conditions or at the temperature at which the

MTBF is specified.

4. Select/design heatsink and airflow require-

ment.

5. Test using the

APMSS

imbedded TEMP-MON

feature which allows direct and convenient

monitoring of baseplate temperature. (BM/AM/

AL/AK Series)

Thermal Design Example

This example is for the following parameters:

• Single 5V AM80 module used in a distributed

power system.

• Average load 30A (150 Watts)

• Normal operating ambient temperature 25°C

• Maximum ambient temperature 60°C

• MTBF required - 800,000 hours (from system

requirements)

• Efficiency measured at 83% (Efficiency =

Output power/ Input power)

1. Heat generated = Power Out x [(1/Efficiency)-1]

= 150 x [(1/0.83)-1]

= 31 Watt

2. Maximum baseplate temperature 100°C (from

AM80 specifications).

⇒ At 60 °C (max. ambient temp.) the maximum

baseplate temperature rise is 40°C.

3. To achieve 800,000 hours MTBF, baseplate

temperature must not exceed 61°C.

⇒ Maximum baseplate temperature rise (from 25°C

operating ambient) is 36°C.

4. Choose the lowest temperature rise of ➁ or ➂ i.e.

36°C.

The cooling system must dissipate 31 Watts with a

maximum baseplate temperature rise of 36°C.

⇒ Thermal resistance = 36/31 = 1.16°C/Watt.

To ensure good thermal contact Astec recommends

the use of Thermstrate® thermal mounting pads.

Thermal resistance of the Thermstrate® interface

between baseplate and heatsink is 0.1°C/W.

For this example (overall thermal resistance 1.16 °C/

W) the heatsink thermal resistance should be a

maximum of 1.06°C/W. A 10% safety margin is

desirable so a heatsink achieving 0.95°C/W is

chosen.

To achieve this level of cooling using natural convec-

tion would require an very large heatsink. It would

therefore be better to employ forced air cooling. A

thermal resistance vs air flow characteristic should

be referenced to determine the required airflow for

the heatsink you are using.

Rev. 01 Jan 96

AMPSS

Reference Manual

Heatsinks

Tips on installation of

AMPSS

modules

1.Ensure that the module/heatsink interface

smooth, flat and free of debris. Always use either

thermal grease or APMSS thermal pads.

2. Fit modules and other heat generating devices at

the top of the cabinet where possible.

3. Stagger modules to improve cooling and facili-

tate even heat distribution between modules.

4. Avoid blocking the airflow to the modules with

other components.

5. Use a heatsink with fins running vertically for

natural convection cooling.

✖

✓

AIRFLOW AIRFLOW

AIRFLOWAIRFLOW

EUROPE

ASTEC EUROPE LTD.

Astec House, Waterfront Bus. Park

Merry Hill, Dudley

West Midlands

DY5 1LX

U.K.

Tel : 44-1384-842211

Fax : 44-1384-843355

NORTH AMERICA

ASTEC AMERICA, INC.

5810 Van Allen Way

Carlsbad, CA 92008

USA

Tel : 760-930-4600

Fax : 760-930-4700

For further information contact :

ASIA

ASTEC ASIA

6F., China Dyeing Works Building

382-392 Castle Peak Road

Tsuen Wan

N.T.

Hong Kong

Tel : 852-2437-9662

Fax : 852-2402-4426

APA701-VRM Rev. 04 May 97