Dear tooki,
Thank you for your comment and for pointing out the power calculation for the dummy load. You are correct that the 5W 75ohm resistor should be dissipating approximately 3W of power and therefore getting hot.
However, my concern is not with the power dissipation itself, but with the fact that the resistor is getting much hotter than expected. In my experience with other similar circuits, the dummy load typically only gets slightly warm to the touch, whereas in my circuit it is becoming too hot to touch.
So my question is not why the dummy load is dissipating 3W of power, but why it is getting so much hotter than expected with that power dissipation. I suspect there may be an issue with the circuit design or component selection that is causing this excessive heating, and I am hoping for some guidance in identifying and addressing the problem.
Thank you again for your input and any further insight you may have on this matter.
I think there's still a disconnect in your logic. You seem to think that 3W dissipation should have the resistor stay cool, and that the heat must be due to some other problem, thus causing higher dissipation. But you said that the circuit is working fine, so I assume that means the output is in fact 15V. (Please confirm.)
If the output is in fact 15V, and the resistor is in fact 75 ohms, then the dissipation
is 3W -- it
can't be anything else.
So the real question is: why do you think 3W of dissipation shouldn't get hot? Into a small resistor, that is a LOT of power. You haven't specified what kind of resistor it is, but many power resistors will have a temperature rise graph in the datasheet. For example, for the Vishay AC05 axial 5W resistor, at 3W, a temperature rise of about 180K is expected. So it'll be damned hot. A Yageo SPQ500 5W cement resistor (those little white blocks) "only" has a temperature rise of about 120K at 3W. (Why the difference? The cement resistor has a much larger surface area from which to dissipate heat.)
But you see that in either case, the amount of heating that is
expected is enough to make it too hot to touch. (Assuming 20C ambient, you're looking at the resistor reaching 140-200 degrees C!)
So it sounds to me like the problem here is that you don't have any feel for how much heat a particular amount of power dissipation should generate, so your "expected" temperature is completely unrealistic for the power dissipation you selected.
If the other designs you're comparing to have the dummy load resistors staying cool, then either:
- they're using physically larger resistors that can dissipate a lot more heat, or
- they're using heatsinks or cooling that can help dissipate more heat, or
- they're simply dissipating a lot less power to begin with
Look at those other designs and see what resistor value they used, and then run the math to see how much power they're dissipating. I suspect you'll find they're dissipating a
lot less power, either by using a much higher resistor value, or a much smaller output voltage. (For example, at 5V, a 75 ohm resistor dissipates just 1/3 of a watt, which would only produce about 25K of temperature rise in the cement block resistor above.)
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