Hello friends
Please see the picture that is attached.
The load may be turned ON/OFF with a 100ms delay based on the controller's signal.
Instead of a mechanical relay, we used an NPN transistor.
It is now operating OK, however the bridgre rectifier temperature is occasionally rising when the load is switched ON
How can I fix the heating problem on the rectifier?
What is the rate at which the switch, NPN, is operated ?
What is the line input V to the bridge ? 110 or 220 Vac ?
You sure the 1N4007 is still working correctly ? Maybe post some
pics from oscilloscope measured across the bridge output. Be careful
and do differential measurements, follow this ap note so you do not
blow up your scope ::
A 1N4007 is not exactly a fast rectifier for motor back emf suppression applications.
You are using a Darlington for a switch, that creates a lot of power dissipation due
to its high Vcesat values. And it is a slow switch, its switching times also quite high.
Don´t want to be offensive, but your question is like from a newbie.
* R, L, C and D are most the most basic electronic devices. You should be aware of how they work.
* Also you should know some basic equations in electronics, like for power: P = V x I.
Thus you should know that you need to give some values for V and I ...
* Also your schematic is far from being complete. No input voltage, frequency, waveform. No MCU signal voltage and no information what is the common reference (GND).
* The description lacks of many infromations
This sentence leads to more questions than true information. "may", "delay", "based on"...
Since "heating" means temperature rise ... and temperature rise is delta_T = P_D * R_th..
So the answer is rather clear: o reduce the temperature rise you have to
* reduce P, by reducing V or I or both
* reduce R_th by installing a heatsink.
* you talk about relay and transistor ... but your final question does not even depend on whether you use the one or the other.
***
Nowadys we have the internet. It provides many many tutorials, especiall for the basic stuff. But also vor very advanced stuff. And we also have youtube for a most effective way of teaching things (compared to pure text).
To speed up your designs in the future, it could be rather effective to watch some youtube tutorials for basic electronic stuff. The earlier the better.
DC? Then, what is the rectifier for?
Please give clear informations: How long is the ON_time, how long is the OFF_time?
Diode:
* most important: V and I
* do you know what "fast recovery" means?
The "recovery" comes into play when
* there is current through a diode (supplied by the L)
* and - at the same time - the BJT becomes switched ON with high dI/dt.
--> thus there are two questions - your schematic and your text does not provide:
* what´s the expected dI/dt of your BJT.
* and how likely is it that - at the "ON-edge" of the BJT - the inductor still provides current for the diode to stay conductive?
Less load current, lower rectifier losses @ load, or better
heat removal.
A pure inductor load does not limit current except if you
control on-time. You might be interested in whether the
NPN / Darlington is turning off as quickly as you imagine
(or getting so cooked that its turnoff time blows way out,
and beware any Darlington that does not give you access
to the lower base / upper emitter, to enable adjusting that).
Hello buddy, your filter capacitor seems to be installed incorrectly. It does not store energy when the NPN transistor is not turned on. As for the bridge heating, it should be a reverse end recovery time issue. You can connect a high-speed rectifier tube in series at the positive pole of the rectifier bridge.