QBE025A0B1 Datasheet, PDF(11/16 Page) Lineage Power Corporation – 42 - 53Vdc input; 12Vdc Output; 25A output current

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QBE025A0B1 Datasheet, PDF (11/16 Pages) Lineage Power Corporation – 42 - 53Vdc input; 12Vdc Output; 25A output current

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Data Sheet

March 27, 2008

QBE025A0B Series Power Modules, DC - DC Converters:

42 â 53Vdc input; 12Vdc Output; 25A output current

Thermal Considerations

The power modules operate in a variety of thermal

environments and sufficient cooling should be

provided to help ensure reliable operation.

Thermal considerations include ambient temperature,

airflow, module power dissipation, and the need for

increased reliability. A reduction in the operating

temperature of the module will result in an increase in

reliability. The thermal data presented here is based

on physical measurements taken in a wind tunnel.

Heat-dissipating components are mounted on the top

side of the module. Heat is removed by conduction,

convection and radiation to the surrounding

environment. Proper cooling can be verified by

measuring the thermal reference temperature (TH).

Peak temperature (TH) occurs at the position

indicated in Figure 13. For reliable operation this

temperature should not exceed the listed temperature

threshold.

Figure 31. Tref Temperature measurement

location.

The output power of the module should not exceed

the rated power for the module as listed in the

Ordering Information table.

Although the maximum TH temperature of the power

modules is 110 Â°C - 115 Â°C, you can limit this

temperature to a lower value for extremely high

reliability.

Heat Transfer via Convection

Increased airflow over the module enhances the heat

transfer via convection. The thermal derating figures

(14-17) show the maximum output current that can be

delivered by each module in the respective orientation

without exceeding the maximum TH temperature

versus local ambient temperature (TA) for air flows of

1 m/s (200 ft./min) and 2m/s (400 ft./min).

Note that the natural convection condition was

measured at 0.05 m/s to 0.1 m/s (10ft./min. to 20

ft./min.); however, systems in which these power

modules may be used typically generate natural

convection airflow rates of 0.3 m/s (60 ft./min.) due to

other heat dissipating components in the system. The

use of Figures 14 - 15 are shown in the following

example:

Example

What is the minimum airflow necessary for a

QBE025A0B operating at VI = 48 V, an output current

of 12A, and a maximum ambient temperature of 70 Â°C

in transverse orientation.

Solution:

Given: VI = 48V, Io = 12A, TA = 70 Â°C

Determine required airflow (V) (Use Figure 14):

V = T1 m/sec. ( 200 ft./min.) or greater.

3m/s (600LFM)

2m/s (400LFM)

1m/s (200LFM)

Natural Convection

100

LOCAL AMBIENT TEMPERATURE, TA (Â°C)

Figure 14. Output Current Derating for the

QBE025A0B in the Transverse Orientation with no

baseplate; Airflow Direction from Vin(+) to Vin(-); Vin

= 48V

30.0

25.0

20.0

15.0

10.0

5.0

0.0

3m/s (600LFM)

2m/s (400LFM)

1m/s (200LFM)

Natural Convection

100

LOCAL AMBIENT TEMPERATURE, TA (Â°C)

Figure 15. Output Current Derating for the

QBE025A0B (Vo = 12V) in the Transverse

Orientation with baseplate; Airflow Direction from

Vin(+) to Vin(-); Vin = 48V

LINEAGE POWER

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