4 thermal considerations – OSRAM PrevaLED Core Z3 User Manual

14

PrevaLED

®

Core Z3 LED modules

|

Thermal considerations

Defi ne boundary

conditions

Estimate heat sink

thermal resistance on

LED module level

Select heat sink

thermal resistance

Total power dissipation of the
LED module, max. ambient
temperature t

a

, max. reference

temperature t

r

according to life-

time requirements

Use the estimated R

th

as a tar-

get for a possible heat sink
profi le and examine the perfor-
mance curve in the heat sink
manufacturer’s catalog.

R

th

=

t

r

- t

a

P

th

t

r

measured at the t

c

point

4 Thermal considerations

The proper thermal design of an LED luminaire is critical for
achieving the best performance and ensuring the longest
lifetime of all components. Due to the high effi cacy of Pre-
vaLED

®

Core Z3 LED modules, only a partial amount of the

introduced electrical power has to be dissipated through the
back of the LED module. The thermal power that has to be
dissipated for PrevaLED

®

Core Z3 LED modules is given

below.

4.1 Thermal power values

4.2 TIM and other accessories

When mounting a PrevaLED

®

Core Z3 LED module within a

luminaire, it is recommended to use thermal interface
material (TIM) between the back of the LED module and the
luminaire housing or heat sink. It is recommended to use
thermal paste, but thermal foil can also be used. In order to
balance possible unevenness, the material should be
applied as thinly as possible, but as thickly as necessary.
In this way, air inclusions, which may otherwise occur, are
replaced by TIM and the required heat conduction between
the back of the LED module and the contact surfaces of the
luminaire housing is achieved. For this purpose, the planarity
and smoothness of the surface should be optimized.

The list below is a selection of suppliers of thermal interface
materials. Additional suppliers for thermal management
support can also be found via OSRAM’s LED Light for your
network:

www.ledlightforyou.com

.

4.3 Cooling system and heat sinks

For the selection of a suitable heat sink, several points
regarding thermal resistance have to be considered.
The selection is usually done through the following
necessary steps.

To achieve the best possible lifetime of the module and to
save it from damage by overheating, a thermal protection
feature is added. This feature is only usable when operating
the module with an OSRAM OTi control gear.

The characteristics of the thermal protection are shown in
the following diagram:

Product

Typ. thermal

power [W]

1)

Max. thermal

power [W] at

nominal current

1)

Max. allowable

thermal resis-

tance R

th

[K/W]

2)

PL-CORE-1100-830-Z3

7.7

8.2

4.91

PL-CORE-1100-840-Z3

6.9

7.3

5.48

PL-CORE-2000-830-Z3

11.2

12.4

3.23

PL-CORE-2000-930-Z3

14.4

15.6

2.56

PL-CORE-2000-840-Z3

10.1

11.0

3.63

PL-CORE-3000-830-Z3

15.9

17.4

2.30

PL-CORE-3000-930-Z3

21.2

23.3

1.72

PL-CORE-3000-840-Z3

15.1

16.6

2.41

PL-CORE-5000-830-Z3

28.6

31.3

1.28

PL-CORE-5000-930-Z3

33.7

36.8

1.09

PL-CORE-5000-840-Z3

25.1

27.4

1.46

Thermal interface materials

Alfatec

www.alfatec.de

Kerafol

www.kerafol.de

Laird

www.lairdtech.com

Bergquist

www.bergquistcompany.com

Arctic Silver

www.arcticsilver.com

Wakefield

www.wakefield.com

1) Value measured at the t

c

point at a reference temperature (t

r

) of 65 °C.

2) Value measured at the rear of the luminaire at an ambient temperature

of 25 °C.

Selection of a heat sink

The behaviour below 50 % of the system current depends on the

nominal system current and the applied ECG.

t

c

[°C]

75

105

Current [% of minimal ECG current]

0

100

50