Very well done, been using this circuit since around 1971, never fails to give a bit of safety.

This is a good presentation of a current limiting circuit. It applies well for circuits that have their current increased as they heat up, like Power LEDs. Without a current limiting circuit they would burn out. However, it is not an efficient solution for a short-circuit situation as you propose. During a short-circuit the current keeps flowing (even if limited) and all the unregulated power supply voltage gets dumped on the pass transistor Q1 to a maximum dissipation of 12W for a maximum voltage drop of 24V. Also, during a normal operation with a current limited to 500mA, the Q2 collector current would drive the operational amplifier current to a much higher value than the 3mA it was designed to carry so, if the Q1 transistor does not burn, the operational amplifier certainly will. A better solution would be an Electronic Circuit Breaker that shuts off the load. You might consider the design presented in this KZfaq video “Electronic Circuit Breaker Part 3” from Palomas Estate (link kzfaq.info/get/bejne/nruDm9mht9KtpHk.html). I have simulated the circuit with a 24V power supply, 12V output, and 500mA current limit. Without the current limiting circuit (Q2 and R4) and adding the circuit breaker, the maximum power dissipation is 7W when the current reaches 500mA and the circuit shuts off. Considering that at 500mA the power dissipation on the pass transistor is 6W (24V in - 12V out, times 500mA), the circuit breaker solution only dissipates 1W more when the current reaches 500mA, in a short-circuit situation. Thanks.

Thank you for another great video.

Fantastic explanations. Thanks

Very clear explanation paced very well with no time wasting. Like it!

In the case of a short circuit on the output, the action of R3 and Q2 does limit the current through Q1, but now the collector to emitter voltage across Q1 is much higher than it is in the normal operating case, leading to additional power dissipation in Q1. It is important to size Q1 and its heat sink to handle this power dissipation.

There is a great deal of information here, but your delivery is very quick and therefore hard to follow. But thank you for posting

Thank you, i can think of many applications.

Great video. Thanks👍

It would be great if you gave us specific transistors and opamps to make the circuit at home and try it! Thank you for these lessons!

it wouldnt act lik a switch tho it would find a stable equilibrium point and the voltage would drop while it continues to pass the load current

if you thermally connect both transistors, would this give you some over temperature protection, too? (the idea is that Vbe(on) drops with temperature)

Good old LM723.

ok you will save q1 for the live of an opamp. opamp do not like too much current in long term. my english is verry bad but.... you have to Design the circuit so that never ever the opamp reach füll current;). A lesson i get from repairing faulty power supplies.