help about DC-AC inverter

Thread Starter

the kid

Joined Jan 4, 2015
81
Hello everybody
I'm done making an inverter circuit to convert 12VDC to 220 VAC.
My project consists of two components are DC-DC and DC-AC. Below is a DC-DC circuit to convert voltage from 12VDC to 310 VDC. I made this diagram from an online project. But I do not understand the method to stabilize the output voltage for diagram no output filter inductor. Other people told me that, the output voltage is stabilized by the resistors R933, R833, R733 and R233. But in my opinion this is not a form of SMPS power supply because there is no filter chokes. anyone can help me explain the method 310 VDC voltage stability in output and not the role of the resistors R933, R833, R733 and R233 in schematic?
Thank you everyone
 

Roderick Young

Joined Feb 22, 2015
408
I am not sure I exactly understand your question, but will try to explain. R733, R833, and R933 can be thought of as one resistor. Most likely, the designer used three of them in order to dissipate the power, as there will be about 300 volts across them. Together with R233, the previously mentioned resistors form a voltage divider, so a fixed percentage of the output voltage appears on the left side of R133. For example, let's say that the percentage is 1%. Then if the output is 300V, there will be 3V on the left side of R133, and since the input draws hardly any current, there will be 3V on the right side, too, at the -IN of U27. Let's further say that VREF is also 3V, fed into +IN of U27.. Now, if the output voltage falls to 290V, then there will be 2.9V going into -IN, and U27 knows to generate longer pulses, and therefore more current, in driving T133. So the output voltage rises as T133 puts out more power. Now what if the output voltage goes to 301V? There will be 3.01V at the -IN, and 3V on the +IN of U27. The IC then knows to scale back the power output so that the voltage drops back into exactly 300V. The stability is achieved by this feedback mechanism, not by a filter capacitor or inductor.
 

Lestraveled

Joined May 19, 2014
1,946
It is most definitely a SMPS. The inductive element is the transformer (T133).

As Roderick said, the output (300V) is scaled down to a voltage that the Switch mode controller (U27) wants to see. U27 compares the scaled voltage to a voltage reference and the difference tells the controller to increase the pulse width or the decrease the pulse width. The resistors (R733, 833, 933 and 233) set the output voltage that the switch mode controller will regulate to.
 

Papabravo

Joined Feb 24, 2006
21,159
Is it fair to claim that this is a 12V to 310V DC-DC Converter when the center tap of the transformer shows +24V? Where exactly is this 24V supposed to come from?
 

Thread Starter

the kid

Joined Jan 4, 2015
81
as you said, T133 operate as inductive. Why?
ithink this schematic is push pull converter?
sory for my english
 

Papabravo

Joined Feb 24, 2006
21,159
sorry, I m missing that point
The design seems to require a +24V DC Power Supply to connect to the center tap of the transformer, and a +12V Power supply for the controller chip. Where do they come from?
In the title you imply that you have designed a 12V to 310V DC-DC converter THAT REQUIRES ANOTHER SUPPLY VOLTAGE. How can you be missing that point? Maybe you didn't do the design and are just in marketing, or maybe it is just a careless typographical error.
 

Thread Starter

the kid

Joined Jan 4, 2015
81
Thank you, but i dont see a inductor at output. How to filte dc voltage without inductor. What if i insert an inductior bettwen brige diodes and filter capacitor?
 

Thread Starter

the kid

Joined Jan 4, 2015
81
I m not sure, but i had researched about push pull SMPS. If there is not an inductor, formular
Vout =n* D* Vin
is not correrct.
in which : n is the ration bettwen secondary to primary.
D is duty cycle
Vin: Input voltage
 

Thread Starter

the kid

Joined Jan 4, 2015
81
Can anyone help me expplaining why not have the inductor that still regulate output voltage? Thank u everyone
 

Roderick Young

Joined Feb 22, 2015
408
Possibly you were looking at a forward converter, like this https://en.wikipedia.org/wiki/Forward_converter ? The formula is for maximum possible output voltage in that case.

The extra inductor after the transformer helps to maintain current flow, but even if you remove it, the output voltage will still be regulated. It all depends on the needs of your load. In some cases, it's not terribly important to have precise voltage regulation. If your ultimate goal is to make a DC-AC inverter, that may be one of those cases. Line voltage in the US could vary from 110 volts to 130 volts, and products are made to tolerate that. Where the nominal line voltage is 220, I suspect it's the same way.
 

neonstrobe

Joined May 15, 2009
190
I think you are confusing a switching converter (forward/flyback etc) which need an inductor with a simple push-pull converter. Many old type converters simply used a transformer as a transformer: A.C. in (in this case a square wave) gives A.C. out which can be at a higher or lower voltage. I would not class this as an SMPS in the sense that it does not fall into the general SMPS class (forward/flyback/resonant etc etc). The output voltage can be controlled only by controlling the input voltage (perhaps the 24V but there is no indication of a controlled input) or the run-time. NOrmally, transformers will output the voltage that their turns ratio is designed for. BUt in square wave switching, flyback voltages can create high spikes, so the output voltage could rise if lightly loaded. It might be that the control system simply shuts down operation until the voltage falls again: just on-off, basically.
 

tcmtech

Joined Nov 4, 2013
2,867
Now to really make you head spin you can modulate your PWM signals to each of the two switching device banks in a way to make the output of the HF transformer so that once it goes through a simple LC filter it appears to be a nice standard 50 - 60 Hz sine wave and eliminate the second DC to AC part of the circuit altogether. :cool:
 

Thread Starter

the kid

Joined Jan 4, 2015
81
Possibly you were looking at a forward converter, like this https://en.wikipedia.org/wiki/Forward_converter ? The formula is for maximum possible output voltage in that case.

The extra inductor after the transformer helps to maintain current flow, but even if you remove it, the output voltage will still be regulated. It all depends on the needs of your load. In some cases, it's not terribly important to have precise voltage regulation. If your ultimate goal is to make a DC-AC inverter, that may be one of those cases. Line voltage in the US could vary from 110 volts to 130 volts, and products are made to tolerate that. Where the nominal line voltage is 220, I suspect it's the same way.
thank you very much. but I have a question that is if the R233 is 47 K, the output voltage can be changed to other values?
 
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