Glad you liked it!

kzbin.info/www/bejne/gqPElZV-ibGJhrs

kzbin.info/www/bejne/ZpOlfqGOqr2ngtk

Good input! Just randomly came across this video and thought it would be a good refresher for me. A few questions that I didn't see answered in the video that maybe you can help. 1 - I was especially hoping to see more about the grounds. You mention to never connect dc side and ac grounds together. In the schematic shown in the video, the dc output has a floating ground reference. Couldn't this cause issues when connecting to devices that are earth referenced? What's the proper strategy around having an earth-referenced ground output on the dc side? 2 - Galvanic action due to two dissimilar metals being in contact with each other, correct? Is that really what it's protecting against? I've seen this mentioned before, and I have always wondered why it is actually called galvanic?

Hi, friend. Watch my video! kzbin.info/www/bejne/aILVZ32Zop2qmKM

Thank you. That confused me. I think it makes sense the way you explained it.

It IS alternating current at the transformer. It changes between 2 definite values, ramping up and down due to the time constant of the inductance of the transformer. It may be caused by the switching, but it is alternating current nonetheless. If it weren’t AC, the transformer wouldn’t be doing anything because there would be no change in the magnetic field.

A voltage that is changing periodically is AC. It doesn't really matter if it's a square or sine wave

@@michaelkeymont501 isn't it pulsating dc? A transformer only takes a change in electric field; it doesn't have to reverse. But the definition of AC means that it goes both positive and negative.

@@mschwage it’s chopped DC - when the DC gets chopped from full on to full off, it a voltage is induced in the coil and the result is a current that goes positive and negative about a virtual ground. “Negative” because the direction of current flow reverses when the DC is turned off, because the collapsing magnetic field is trying to oppose the instantaneous change. The current goes positive while DC is on and negative when it is off, hence alternating current. That’s also the reason that you need a snubber diode across the coil. If it weren’t there, that opposite polarity current would fry the switching circuit because it’s initially a very high voltage spike in the wrong direction. When I worked in failure analysis for a power supply company, we used to see that voltage spike get out of control - literally - if the adhesive in the potted transformers started to fail. As the air gap changed the characteristics of the transformer, they would get extremely hot and burn up from the voltage spikes blowing out the snubber diode and taking out the MOSFET in a magnificent puff of smoke.

kzbin.info/www/bejne/ZpOlfqGOqr2ngtk

Hi, friend. Watch my video! kzbin.info/www/bejne/aILVZ32Zop2qmKM

Hi, friend. Watch my video! kzbin.info/www/bejne/aILVZ32Zop2qmKM

The Y-cap is to isolate the primary from the secondary. Though, it has to connected such that one terminal to the Secondary GND and the other to the +ve primary.

And the name/topology of this type is "flyback".

Hi, friend. Watch my video! kzbin.info/www/bejne/aILVZ32Zop2qmKM

Hi, friend. Watch my video! kzbin.info/www/bejne/aILVZ32Zop2qmKM

requires very large transformer. switching supplies are smaller and more efficient.

@@IMSAIGuyWhy do you need a larger transformer to make 12V AC out of 120V AC than making 16V pulse modulated DC out of 164 V pulse modulated DC? Also, why is the output of the rectifier 164V DC, when the input is 120V AC? Im just beginning to learn electronics, so please excuse my dumb questions... 😊 Great video, by the way - love your channel! Keep up the great work!!

@@fo76 The line voltage is 60 Hz. In this switch mode design the DC is switched at more than 1000 times that. Transformers at low frequencies require a lot of iron which makes them big and heavy. Even 50 Hz transformers are significantly bigger and heavier than their 60 Hz equivalents. That is one reason why aircraft use 400 Hz AC rather than 50/60 Hz.

@@fo76 They certainly are not dumb questions. When no load is connected to a transformer the primary winding just looks like an inductor. With sinusoidal AC applied to the winding there will be magnetic field at the same frequency created. In an ideal inductor the voltage and current will be out of phase and the power will be zero, even if the current is high. But there is resistance in the primary winding, so you want to keep that current quite low so you don't waste power according to I²R in the resistance of the winding. That means you must make the inductive reactance quite large to make that "magnetizing current" quite small (the reactance of an inductor is 2 • pi • f • L, where f is the frequency in hertz and L is the inductance in henries and the reactance in ohms) At AC mains frequency (50 or 60 Hz, depending on where you live) that means you need quite a lot of inductance. That translates to lots of turns of wire and/or a large iron core. The inductance is proportional to the square of the number of turns. When the secondary winding is connected to a load, current that is in phase with the primary voltage begins to flow in both the primary and secondary winding. The current in the secondary "cancels" the current in the primary, so there is no change in that magnetizing current we had before. But the primary and secondary currents are now determined by the load connected to the secondary and the turns ratio of primary to secondary. We have to use wire that is large enough to carry the current without getting too hot. It's hard to get the heat of the winding of a transformer, so the wire is much bigger than we'd use if it were just a single conductor in free air for the same current. We already knew how many turns we'd need, so now we more or less multiply that by the cross sectional area of wire to get the total cross sectional area of each of the windings. We have to be able to fit that into the area available in the "window" of the core. If we need lots of turns of heavy wire, we need a big core with a big window to be able to fit the windings. The bigger core MAY change the inductance of the primary, so we may use an iterative approach to arrive at the best combination of core, wire size and turns. Usually we check some published tables that give us a good starting point, though. If you raise the frequency, you can get tolerable magnetizing current with far fewer turns of wire. That means you can use a smaller core.The core material must be different at high frequency because some energy is lost in the core material itself. "Hysteresis" and "eddy current" losses are the big players, but that's a topic unto itself. At line frequency "silicon steel" is the usual core material. For switch mode power supplies the usual core material is ferrite - a ceramic made mostly of iron oxide. There are many formulations of ferrites. Most companies that make ferrite cores will offer three or four that are suitable for switchers, each with somewhat different properties. As for 164volts - AC line voltage is specified as RMS - Root Mean Square. If you divide a whole AC cycle into tiny time increments, take the instantaneous voltage in each of those intervals, square it, calculate the mean (average) of all those squares and take the square root of the mean you get the RMS voltage. AC mains is a sinewave. The peak (from zero) of a sine wave is 1.414 (square root of 2) times the RMS value of the sinewave. So 120 VAC gives you 120 x 1.414 = 170 at the peak. When there is no load, the input filter capacitors charge up to the peak voltage. (RMS is used because heating (power) in a resistor is equal to the RMS voltage squared divide by the resistance, just as with DC the power is the voltage squared divided by the resistance).

Thanks!!@@d614gakadoug9

This circuit is called a "flyback converter." The name comes from a sort of similar circuit that is used to sweep the electron beam across a CRT, like a TV screen. When the beam gets to the end of its sweep of one line it "flies back" to the other side. If you look at the voltage waverforms those in flyback switcher are kind of similar and the circuit is similar, though the CRT circuit is concerned with making magnetic or electrostatic fields rather than generating voltage (in a TV it actually does both - manages the magnetic field to sweep the beam and generate the high voltage required to make the beam). Anyway - with a flyback converter you aren't actually transforming voltage directly. Each cycle delivers a "packet" of energy. If the current requirement of the load increases and the packets are being delivered at a constant rate (frequency) then each packet must be made bigger to maintain the voltage across the load. The feedback circuit detects that the voltage at the output is not what it should be and commands the input side to adjust the size of the packets. If the voltage is too high, make the packets smaller. If it is too low, make them larger. This is "negative feedback." The are made larger or small by adjusting the amount of time the switch on the input side is ON - "pulse width modulation." Feedback circuits also make sure that things like power losses (inefficiency) in the circuit are corrected for. The feedback circuit doesn't need to know what is causing the disturbance, only that it is happening and a change must be made in the appropriate direction to correct for it. It's like controlling the speed of a car with the gas pedal. You don't really need to know if you are fighting a headwind, or going up hill, all you know is that you need to push the pedal down so your speed is maintained. Feedback also corrects for variation in the input voltage.

kzbin.info/www/bejne/ZpOlfqGOqr2ngtk

Thanks for the sub!

1. I explain that in the video, feedback is through opto-coupler 2. size is due to low current. old has high current in transformer, new has low current. by using a high voltage you only need low current for the same power.

no, it provides a high frequency path back to the other ground to kill emission spikes

@@IMSAIGuy ah, cool thanks

the 50khz would be generated by the controller IC. in this case DK1203

@@IMSAIGuy is there a need for a MOSFET?

@@IMSAIGuy lemme see if I got it right : First I need a rectifier bridge and a capacitor to convert 220 ac to DC then for the tapping work I need the DK1203 you've mentioned then I can connect to the primary ferrite core coil.

@@danielwhite5705 just buy one, it is cheaper, this was $7

this control chip has a built in FET, higher current designs need an external one.

not with the parts shown.

there are many types of supplies. I only show this very simple one

could be many things wrong. I can't help you. check the fuse

Thanks for reply. I checked the fuse and just replaced the rectifier bridge (it was GBP310 and i replaced with KBP410 (what i had at home). Also checked the input AC and it's OK. I don't know what is the problem. It may be a lose connection on the board or something like that.@@IMSAIGuy

only at high frequencies

@@IMSAIGuy Right, but what if the component short circuits? Wouldn't frequency no longer be an issue? After all, isolation was always about protecting against component failure, Right? Again, I am just curious.

well if the transformer shorted what would be bad news, if the capacitor shorts you just connect input ground to output ground and the output is low voltage DC anyway. so not too bad

the design would have be different to use a single supply, the -V allows the op-amp to operate correctly around zero

119 * sqrt(2) = 168 minus two diode drops

Vcc is very strange. it is pin 2. input via a capacitor. see the datasheet: radiolux.com.ua/files/pdf/DK1203.pdf

@@IMSAIGuy Well does that make sense? You are connecting the negative DC terminal (which means its zero/gnd/rtn) to the negative terminal of the capacitor but then connect the positive terminal to the VCC. But the capacitor is open in DC. So you are essentially floating the VCC terminal. How could this work? Am I missing something?

it gets the voltage by passing AC though the cap. it is not a DC Vcc. internal to the IC it converts this AC to whatever voltage it needs

@@IMSAIGuy ok now it makes sense. I didn't read the datasheet for DK1203 properly. In the datasheet in table 6 page 2 the absolute max supply voltage (VCC) is -0.3V - -8V. Now that doesn't make sense and that's where I got confused. Now in table 2 it clearly says the input power supply is 85V-265V AC. Isn't there a contradiction between table 2 and 6? Also, in the schematic in the datasheet it shows the VCC capacitor (EC2) as 22uF/10V but it won't be able to withstand AC peak voltage of 170V. Also, my understand was that polarized capacitors can only be used with DC voltages but here they are using them with AC voltages. Is that not correct?

The data sheet has a nice little blurb on designing the power transformer. I found it useful

Hi, friend. Watch my video! kzbin.info/www/bejne/aILVZ32Zop2qmKM

it is marked +12, it connects to the 12v

part 2

it would be awful. 35A needs better

That is awesome!

Hi, friend. Watch my video! kzbin.info/www/bejne/aILVZ32Zop2qmKM

computer supplies can be very complicated and explaining how one works is probably only valid for that one design.