Nagi Elabbasi
Facebook Reality Labs
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Posted:
1 decade ago
13 nov. 2012, 09:57 UTC−5
Hi Juan,
There are different ways to model this LED-plate heating problem with varying complexity. The heat transfer from the LEDs to the Aluminum plate will be through conduction, convection and radiation with the relative contribution of each dependent on the geometries and temperatures involved.
You will have to decide whether to explicitly model convection through the air or use appropriate convection boundary conditions instead. Similarly, regarding radiation you will have to choose between modeling surface-to-surface radiation between the LEDs and plate, or using approximate expressions instead.
I would start by modeling one “distributed” LED heat source that covers the 7x7 area instead of the individual LEDs.
Nagi Elabbasi
Veryst Engineering
Hi Juan,
There are different ways to model this LED-plate heating problem with varying complexity. The heat transfer from the LEDs to the Aluminum plate will be through conduction, convection and radiation with the relative contribution of each dependent on the geometries and temperatures involved.
You will have to decide whether to explicitly model convection through the air or use appropriate convection boundary conditions instead. Similarly, regarding radiation you will have to choose between modeling surface-to-surface radiation between the LEDs and plate, or using approximate expressions instead.
I would start by modeling one “distributed” LED heat source that covers the 7x7 area instead of the individual LEDs.
Nagi Elabbasi
Veryst Engineering
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
15 nov. 2012, 06:26 UTC−5
Hi Juan,
There are different ways to model this LED-plate heating problem with varying complexity. The heat transfer from the LEDs to the Aluminum plate will be through conduction, convection and radiation with the relative contribution of each dependent on the geometries and temperatures involved.
You will have to decide whether to explicitly model convection through the air or use appropriate convection boundary conditions instead. Similarly, regarding radiation you will have to choose between modeling surface-to-surface radiation between the LEDs and plate, or using approximate expressions instead.
I would start by modeling one “distributed” LED heat source that covers the 7x7 area instead of the individual LEDs.
Nagi Elabbasi
Veryst Engineering
Hi, Nagi.
Thank you so much for your answer.
I have more doubts about this model.
Do I need to draw the lamp and setting all paremeters (geometry, materials,...) or I can "say" that the aluminum plate is heated by a lamp of 49 watts (for example) like one of the physics?
I am graduate in chemistry and not engineer. This is the reason why I ask lot of things.
Thanks again.
Regards.
[QUOTE]
Hi Juan,
There are different ways to model this LED-plate heating problem with varying complexity. The heat transfer from the LEDs to the Aluminum plate will be through conduction, convection and radiation with the relative contribution of each dependent on the geometries and temperatures involved.
You will have to decide whether to explicitly model convection through the air or use appropriate convection boundary conditions instead. Similarly, regarding radiation you will have to choose between modeling surface-to-surface radiation between the LEDs and plate, or using approximate expressions instead.
I would start by modeling one “distributed” LED heat source that covers the 7x7 area instead of the individual LEDs.
Nagi Elabbasi
Veryst Engineering
[/QUOTE]
Hi, Nagi.
Thank you so much for your answer.
I have more doubts about this model.
Do I need to draw the lamp and setting all paremeters (geometry, materials,...) or I can "say" that the aluminum plate is heated by a lamp of 49 watts (for example) like one of the physics?
I am graduate in chemistry and not engineer. This is the reason why I ask lot of things.
Thanks again.
Regards.
Nagi Elabbasi
Facebook Reality Labs
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
15 nov. 2012, 13:03 UTC−5
Hi Juan,
I didn’t mean to give you doubts about the model. It is certainly doable but not trivial. You need more than just the amount of power generated at the lamps. You need the outer surface temperature of the lamps. If you have that measured then you will not need to model the lamp geometry in details.
As I mentioned earlier, depending on the geometry and temperatures you may find that one heat transfer mode dominates. If, for example, radiation is the dominant source then you can develop a model that only captures radiation, etc. When it comes to the plate you need proper boundary conditions that capture how the heat will escape from there.
Nagi Elabbasi
Veryst Engineering
Hi Juan,
I didn’t mean to give you doubts about the model. It is certainly doable but not trivial. You need more than just the amount of power generated at the lamps. You need the outer surface temperature of the lamps. If you have that measured then you will not need to model the lamp geometry in details.
As I mentioned earlier, depending on the geometry and temperatures you may find that one heat transfer mode dominates. If, for example, radiation is the dominant source then you can develop a model that only captures radiation, etc. When it comes to the plate you need proper boundary conditions that capture how the heat will escape from there.
Nagi Elabbasi
Veryst Engineering