• Skip to main content
  • Skip to primary sidebar

Homemade Circuit Projects

Need circuit help? Post them in the comments! I've answered over 50,000!

Blog | Categories | About | Hire Me | Contact | Calculators-online
You are here: Home / Power Supply Circuits / 12V DC to 220V DC Boost Converter Circuit

12V DC to 220V DC Boost Converter Circuit

Last Updated on March 17, 2026 by Swagatam 126 Comments

In this article I have explained a very simple method of acquiring 220V DC from a 12V DC source. The idea utilizes inductor/oscillator based boost topology with the help of the IC 555.

Table of Contents
  • Circuit Operation
    • 555 IC Astable Frequency Generator
    • MOSFET Switching
    • L1 is the Main Boosting Component
    • Automatic Output Voltage Control
    • Automatic Output Overload Protection
    • This is Only a Low Watt Converter
    • Caution
    • Circuit Diagram
    • Audio/Video Representation
  • How to Calculate all the Parts (For 1 Amp 220V Output)

Circuit Operation

Now let us learn more about this simple 12V to 220V DC boost converter circuit, which is built around IC 555, one IRF840 MOSFET, one inductor, and then a few transistor parts for feedback side.

It is made to boost a low 12V DC input into a much higher DC output, somewhere near 220V DC, by fast inductive switching...

555 IC Astable Frequency Generator

If you look at the circuit diagram on the screen, then the left side starts with IC 555 working as an astable oscillator. In that area, R1, R2, C1 decide the switching frequency of the integrated circuit.

IC 555 keeps sending rectangular pulses from pin 3, and that pulse becomes the switching drive for the mosfet.

Pin 8 and pin 4 go to the +12V line, while pin 1 goes to ground. Pin 5 is connected to ground through a 10nF, which helps keep the integrated circuit quiet from switching noise, so it stays stable.

The pulse coming from pin 3 passes through 1k resistor before reaching the gate of IRF840. That resistor limits gate charging current and also saves the output side of IC 555.

1N4148 diode is placed around that gate path, so when the pulse goes low then the gate can discharge faster. Because of that the mosfet turns off quicker and switching loss stays lower.

MOSFET Switching

Now IRF840 is the main switching part here. It turns on and off again and again following the pulse from IC 555. When it turns on, then current starts moving from twelve volt supply through L one and then through the mosfet to ground. During that small on time, L1 stores energy inside its magnetic field.

When the mosfet turns off, then that magnetic field inside L1 collapses and throws a high-voltage reverse pulse.

That pulse appears at the drain side of the mosfet and then goes through the 5 ampere Schottky diode into the output capacitor.

Because this keeps repeating, the capacitor slowly charges and reaches high direct current voltage near two hundred twenty volts.

L1 is the Main Boosting Component

L1 is actually the part doing the voltage BOOSTING work, so its quality matters a lot. A ferrite core inductor works better here. A practical winding can be around forty to forty-five turns of one millimeter copper wire on ferrite rod or ferrite toroid core, which usually gives proper response.

The capacitor here is 100 microfarad rated at 400 volts, and it stores that boosted energy while also smoothing the output side.

Automatic Output Voltage Control

Now let us see the automatic voltage control side also.

At the output, 180K resistor and 10K resistor make a voltage divider. That divided voltage goes to the base of the shown BC547 transistor. This transistor keeps watching output voltage.

If output rises above the set level, then the left BC547 transistor turns on and grounds pin 5 of IC 555, executing PWM control, which limits further voltage rise. The 4.7k preset is there so you can adjust carefully and bring output near two hundred twenty volts.

Automatic Output Overload Protection

Now if we want overload control also, then one current sensing resistor marked RS can be added as shown. When output current increases, then voltage develops across RS and switches the right side BC547 transistor on, which grounds the MOSFET gate.

So now current limiting starts and mosfet gets protection during overload. 100 ohm resistor and 0.1uF capacitor there help steady the sensing action and reduce switching spikes.

We can also see one snubber network across drain and source of the mosfet, made using one 100 ohm and 0.1uF high-voltage capacitor. That part absorbs sharp spikes, so mosfet reliability improves.

This is Only a Low Watt Converter

In practical use, this circuit is only for small high-voltage jobs. Output power usually stays around five watts to fifteen watts, depending on inductor quality, switching frequency, and how strong the input supply is.

Ideally one 7 ampere-hour 12 volt battery or more works better, because weak adapters often fail when sudden current pulses are demanded by L one.

Caution

Please remember, although input is only twelve volts, output reaches dangerous high-voltage direct current. High-voltage direct current can be more dangerous than alternating current, because it does not naturally cross zero, so before touching the circuit always discharge the output capacitor.

Circuit Diagram

WARNING: THIS CIRCUIT INVOLVES HIGH VOLTAGE, EXTREME CAUTION IS ADVISED WHILE HANDLING THIS CIRCUIT.

IC 555 Pinout Details

IC 555

Audio/Video Representation

How to Calculate all the Parts (For 1 Amp 220V Output)

Let's assume the maximum output current required is 1 Amps.

So 220V * 1A = 220W output.
From 12V battery, ohh so now we see the problem already.

Even if we assume 85% efficiency, which is optimistic, yep a little hopeful.

Pin ≈ 220 / 0.85
≈ 259W

Input current then becomes:

Iin ≈ 259 / 12
≈ 21.5A

So now our inductor L1 and MOSFET must survive that, and if current rises then it must not panic.

Around 25A peak current...
Around 220V drain voltage..

This is not small but maybe possible if parts are seriously selected.

Now duty cycle, which is the main issue here.

For boosting:

D = 1 − (Vin / Vout)
= 1 − (12 / 220)
= 0.945

So now 94.5% duty cycle, which means if duty goes that high then stress also goes high, that is the real heat generation issue here, on the MOSFET.

Now 5555 astable working with 50kHz, let us see.

Formula:

f = 1.44 / ((R1 + 2R2) * C1)

Choose C1 = 1nF.

50000 = 1.44 / ((R1 + 2R2) * 1e-9)

Then:

(R1 + 2R2) ≈ 28.8k

So we take:

R1 = 4.7k
R2 = 12k

Check:

R1 + 2R2 = 4.7k + 24k
= 28.7k

Close enough right... so frequency comes near 50kHz, that looks fine...

Now inductor, which is hugely critical, so lets pay attention here.

Input current ≈ 21.5A.
If ripple is 20%, then ΔI ≈ 4A.

Boost formula:

L = (Vin × D) / (ΔI × f)

L = (12 × 0.945) / (4 × 50000)
L ≈ 56 µH

So L1 equal around 56 µH.
Current rating must be 30A or more.
Use good Ferrite core only, since if core is weak then saturation quickly happens, killing the MOSFET.
DCR very low, below 10 milliohm if possible.

If inductor saturates then MOSFET dies instantly, without warning...

Now MOSFET side.

Ipeak ≈ 21.5 + 2
≈ 23.5A

But if spikes come then you can design for 30A minimum.
Voltage rating should be at least 500V.

IRF840, which does not look good here.
Rds(on) ≈ 0.85Ω.

Loss:

P ≈ I²R
≈ 20² × 0.85
≈ 340W during ON time

Even if duty scaling reduces average, still too much heat, it will overheat badly.

So we need:

500V 30 Amp MOSFET
Rds(on) below 0.3Ω ideally
Big heatsink, not small toy one

If one device struggles then parallel two, but layout must be tight, otherwise sharing goes wrong.

Please Use FQD20N60 or FCPF20N60 for the MOSFET.

Now about the diode.

It must handle 1A average output, but peak pulses go 20–25A.
Reverse rating at least 400V, but safer is 600V.

Ultra-fast diode is mandatory, since if recovery is slow then losses rise.

Schottky diode ultra-fast 600V diode is practical choice.

Now let's check real world situation..

220W from 12V boost is possible, but stressful.
Efficiency maybe 75–85% best case.
Copper tracks must be thick, since if tracks are thin then heating happens.
Cooling must be serious.

Note: This is not a small hobby circuit, it becomes power hardware.

Now Even at 1A output, frequency is not main issue.

The real issue is 94.5% duty cycle.

Only 5.5% OFF time exists, and if energy must transfer in that small window then current spikes grow huge, That can creates high peak currents and heavy switching stress.

That is why industrial designs do not boost 12V straight to 220V in one stage at high power.
They use transformer-based topology, since then stress spreads better.

So now safe recommendation.

With 555 boost style:

220V at 200mA–300mA, around 50W–60W, comfortable zone.
1A, which is 220W, possible but becomes aggressive, so make sure parts must be strong.
Above all that, 1 amp at 220V might not be practical, you will fight MOSFET heating and failure, sorry that is reality.

You'll also like:

  • power supplyLM324 Variable Power Supply Circuit
  • DIODE 1How to Make a Bridge Rectifier
  • 0 to 50V, 0 to 10amp Variable Dual Power Supply Circuit
  • How Buck-Boost Circuits Work

Filed Under: Power Supply Circuits Tagged With: 12V, 220V, Boost, Converter, DC

About Swagatam

I am an electronics engineer and doing practical hands-on work from more than 15 years now. Building real circuits, testing them and also making PCB layouts by myself. I really love doing all these things like inventing something new, designing electronics and also helping other people like hobby guys who want to make their own cool circuits at home.

And that is the main reason why I started this website homemade-circuits.com, to share different types of circuit ideas..

If you are having any kind of doubt or question related to circuits then just write down your question in the comment box below, I am like always checking, so I guarantee I will reply you for sure!



Previous Post: « LM567 Tone Decoder IC Features, Datasheet and Applications
Next Post: How to Design an Inverter – Theory and Tutorial »

Reader Interactions

Questions & Answers

Total Posts: 126
Newest Oldest
Carlos
April 19, 2026 • 3 months ago #205366

Hello, good afternoon, Mr. Swagatam. I like the circuit, but I’d like to know what function the 1N4148 diode serves when placed at the MOSFET’s gate. Thank you in advance.

Reply
SwagatamAdmin
April 19, 2026 • 3 months ago #205379

Good Morning Carlos,
As we know, a MOSFET can run cooler if its gate capacitance is allowed to discharge rapidly and fully, before the next ON period. So the diode allows the gate to be quickly grounded through the IC output pin, during its OFF periods, which allows an instant discharging of the gate capacitance of the MOSFET, enabling the MOSFET to work more efficiently.

Reply
NgPark
March 4, 2026 • 4 months ago #202140

Sir, could you please provide us with the same project, but this time using a ATmega328P ?

PLEASE SIR.

Or can you send me the complete code that will allow me to generate the appropriate pulses, taking into account when the potentiometer is varied

Reply
SwagatamAdmin
March 5, 2026 • 4 months ago #202172

Hi NgPark, let me check, I will try to figure it out soon…

Reply
NgPark
March 16, 2026 • 4 months ago #202841

Could you please try to explain in more detail the operating principle and the main function of each component?

please ing.

Reply
SwagatamAdmin
March 17, 2026 • 4 months ago #202878

Sure, I have updated the full explanation for the above 12V to 220V DC to DC converter circuit…you can check it out…

Reply
Duan
December 1, 2025 • 8 months ago #193044

Hi,sorry for the inconvenient but is there a way to change the output from 220V to only 45V

Reply
SwagatamAdmin
December 1, 2025 • 7 months ago #193058

Yes, you can build a custom design by using the following details:
https://www.homemade-circuits.com/ic-555-boost-converter-calculator/

Reply
Ronaldo Ngueadia
March 4, 2026 • 4 months ago #202148

Why use a Fast Recovery diode?
Because we know that, with each switching cycle (300,000 times per second at 300 kHz), the diode doesn’t turn off instantly.

And for a few nanoseconds, it will almost certainly create a near short circuit with the transistor. This repeated short circuit will heat the MOSFET much more than the load itself. The efficiency of the Boost chopper will plummet.

Reply
SwagatamAdmin
March 5, 2026 • 4 months ago #202171

Thanks for your valuable feedback!

Reply
umar Ashru
October 30, 2024 • 2 years ago #164633

what are the nmber of turns and size of wire

Reply
SwagatamAdmin
October 30, 2024 • 2 years ago #164655

The number of turns will depend on the 40uH value, make the winding until the 40uH is achieved. The wire thickness will depend on the load current, for this project a 1mm copper should be quite enough for delivering 220V, 200 mA current output.

Reply
Andrew
August 7, 2024 • 2 years ago #157383

I can’t see the AC side of this circuit… looks like a boost converter can you explain how the ac signal is generated and captured? I’m really interested in what I’m missing here. Boost yes. Using the mosfet to switch short the inductor and capture the EMF. The BC547 regulates as described but maybe I’m misunderstanding something. Can you explain in detail? Thanks a lot Andrew

Reply
SwagatamAdmin
August 7, 2024 • 2 years ago #157436

Sorry about the confusion, you are correct!
It is actually a 12V DC to 220V DC boost converter circuit.
I have now changed the article content and the title accordingly.

Reply
amfarina
July 12, 2024 • 2 years ago #154415

Hi
In order to work the mosfet have to be rated for Vdrain = Vout+Vf(diode). So IRF540 doesn’t fit for this application because his Vd max is 100V

Reply
SwagatamAdmin
October 30, 2024 • 2 years ago #164656

Sorry, you are absolutely correct, please change the MOSFET to IRF840…

Reply
Andrew
August 7, 2024 • 2 years ago #157384

Agree

Reply
SwagatamAdmin
July 12, 2024 • 2 years ago #154430

You are absolutely right, please upgrade the MOSFET to IRF840.

Reply
OYO MARK
October 25, 2023 • 3 years ago #146461

How is the above inductor wounded and using which wire

Reply
SwagatamAdmin
October 25, 2023 • 3 years ago #146466

You can wind a 1mm thick super enameled copper wire over a ferrire rod. Create number of turns which produces 40 uH value

Reply
Aref
March 30, 2023 • 3 years ago #141485

Excellent…
thank you

Reply
William H. Blair
March 22, 2023 • 3 years ago #141256

i want to use a 12v dc motor mechanically coupled at the shaft to another motor shaft of a 220v ac motor– the idea is to get 220v from the driving force of the 12vdc motor. am currently doing this with a hydro generator. again the idea is to have the 12v motor make the 220v ac motor supply power to feed itself with the proper invertors in line . can this work.

Reply
SwagatamAdmin
March 22, 2023 • 3 years ago #141257

That is definitely possible, however the output power of the 220V motor will be just 70 or 80% of the 12V motor power.

Reply
Wai Phyo
March 11, 2023 • 3 years ago #140926

How much time can I use from DC 12v 45 AH to AC 220v 65W?

Reply
Pierre Leo Besaans
December 11, 2022 • 4 years ago #137255

Hi, I need to build a transformer to be used as a inverter. 12vdc input to 220vac output at 50 hertz.
The total load the transformer must be able to take is 4 KW. I would very much like to know the wire size in mm for the 220vac side, the thickness of the wire and the number of turns.
The same applies to the 12vdc side having a center tap.
If you have a schematic, using normal components for the low voltage side to create the 50 hertz, using Mosfets. I would need a pure sine wave and not a square wave.
I would really appreciate your help.

Reply
SwagatamAdmin
December 11, 2022 • 4 years ago #137268

Hi, I do not have the details of the wire size for the transformer, it will need to be selected from a chart or a table maybe.
You can probably refer to the following article for any details:
https://www.homemade-circuits.com/how-to-make-transformers/
For the sine wave inveretr you can try the following concept:
Arduino Pure Sine Wave Inverter Circuit with Full Program Code

Reply
Ronc
September 18, 2022 • 4 years ago #133314

Thank you very much for your helpful circuits

Reply
sunil
June 20, 2022 • 4 years ago #128058

fish shocker circui

Reply
SwagatamAdmin
June 20, 2022 • 4 years ago #128080

Can you explain more.

Reply
Željko Kiš
April 23, 2020 • 6 years ago #78109

Coil about 40 mikrohenry-how many turns on what(Ferrite ring,ferrite EE trafo or)Which diameter off wire?How many ampers in outside,outside power?

Reply
Krish
May 5, 2019 • 7 years ago #66850

Can I run a1or 2 hp water pump ? Thank you very much.

Reply
SwagatamAdmin
May 6, 2019 • 7 years ago #66859

No, you cannot run 2 hp load with this circuit

Reply
Krish
May 6, 2019 • 7 years ago #66869

Then what I’ll do if I want to do this?I mean Is there any circuit or electonic devices you know to run 1hp load with DC? Thanks a lot….

Reply
SwagatamAdmin
May 7, 2019 • 7 years ago #66874

you will need a 24V to 220V inverter 1 kva

Reply
Shigida
May 6, 2018 • 8 years ago #60293

Hello Swagatam!
Can this circuit be used to power the “Cell Phone Battery Charger Station in Villages “(www.www.homemade-circuits.com/installing-solar-universal-cell-phone/)

Reply
SwagatamAdmin
May 7, 2018 • 8 years ago #60306

Hi Shigida, yes it can be used after proper adjustments

Reply
Shigida
May 7, 2018 • 8 years ago #60338

Swagatam,Thanks a lot.
would you mind telling me which part and how to adjust the ckt in order to get posibilly more watt out of it?

Reply
SwagatamAdmin
May 8, 2018 • 8 years ago #60349

Shigida, you will have to manually experiment with trial and error, and find out which frequency produces the maximum voltage output, once this is fixed then you can replace the coil with a thicker wire coil for upgrading the current capacity of the coil.

Reply
Abhinaya
May 13, 2017 • 9 years ago #50467

If I convert a 12 or 15 or 50v to 230v can I connect this to home appliances if it is possible means please explain it in detail and if not means give the solution to implement the home appliances to it.

Reply
SwagatamAdmin
May 14, 2017 • 9 years ago #50485

you can connect appliances which are SMPS based for exmple TV sets, LED lamps, amplifiers but not that require AC sinewave inputs like refrigerators, mixers, fans etc.

Reply
Ainsworth Lynch
February 17, 2017 • 9 years ago #49030

I can fool around with the RC timing parts of the ic to get the frequency but can you assist me with the coil, how man turns do you think I would need to get such high voltage.

Reply
SwagatamAdmin
February 17, 2017 • 9 years ago #49044

you can try 100 turns initially, for more info you can refer to the following article

https://www.homemade-circuits.com/2015/10/calculating-inductor-value-in-smps.html

Reply
View Older Comments

Need Help? Please Leave a Comment! We value your input—Kindly keep it relevant to the above topic! Cancel reply

Your email address will not be published. Required fields are marked *

Primary Sidebar



My Youtube Channel

Circuit Simulator

circuit simulator image



Subscribe to get New Circuits in your Email



Categories

  • Arduino Projects (95)
  • Audio and Amplifier Projects (134)
  • Automation Projects (18)
  • Automobile Electronics (103)
  • Battery Charger Circuits (88)
  • Datasheets and Components (109)
  • Electronics Theory (149)
  • Energy from Magnets and Earth (40)
  • Games and Sports Projects (11)
  • Grid and 3-Phase (20)
  • Health related Projects (27)
  • Home Electrical Circuits (13)
  • Indicator Circuits (16)
  • Inverter Circuits (99)
  • Lamps and Lights (162)
  • Meters and Testers (72)
  • Mini Projects (28)
  • Motor Controller (68)
  • Oscillator Circuits (28)
  • Pets and Pests (15)
  • Power Supply Circuits (91)
  • Remote Control Circuits (50)
  • Security and Alarm (65)
  • Sensors and Detectors (107)
  • SMPS and Converters (45)
  • Solar Controller Circuits (60)
  • Temperature Controllers (43)
  • Timer and Delay Relay (50)
  • Voltage Control and Protection (44)
  • Water Controller (37)
  • Wireless Circuits (31)



Other Links

  • Privacy Policy
  • Cookie Policy
  • Disclaimer
  • Copyright
  • Videos
  • Sitemap

People also Search

555 Circuits | 741 Circuits | LM324 Circuits | LM338 Circuits | 4017 Circuits | Ultrasonic Projects | SMPS Projects | Christmas Projects | MOSFETs | Radio Circuits | Laser Circuits | PIR Projects |



Recent Comments

  • Swagatam on IC LM393 Complete Datasheet with Circuit Diagram
  • Norman D Kelley on IC LM393 Complete Datasheet with Circuit Diagram
  • Swagatam on Simple Capacitive Discharge Ignition (CDI) Circuit
  • Hugo Mercurio Nicolucci on Simple Capacitive Discharge Ignition (CDI) Circuit
  • Swagatam on True MPPT Solar Controller Circuit using IC 555

Social Profiles

  • Twitter
  • YouTube
  • Instagram
  • Pinterest
  • My Facebook-Page
  • Stack Exchange
  • Linkedin

© 2026 · Swagatam Innovations