I used to work at a very large manufacturing facility that was built in the late 1960s. This place was so big it had it's own power substation. They had incredible milling machines to create large parts for aircraft. At some point they were experiencing a large lagging power factor issue and the utility was going to require them to pay for a major upgrade to the power lines to the facility. One of their electrical engineers said hold on. He designed a system to use synchronous motors to create a leading power factor to correct the problem. He used these motors to power air compressors for the facility since they used a lot of compressed air. In 1980 we installed a 5000v 500 horsepower synchronous motor. It was the 3rd compressor in that building. Since that time a lot of the electrical loads have been changing. The lighting all changed from fluorescent to high pressure sodium in 1982. By 1990 we were replacing those with metal halide. Now those have been replaced with LEDs. The milling machines are all going to variable frequency drives. I retired in 2012 so I don't see what's going on there anymore.

PFCs are mandatory already! If your device is CE marked, it should have been tested to IEC 61000-3-2/-3-12. Exclusions for Harmonics are

Btw, you can change the backroom color of the schematic sheet in altium (in propierties around the same area of paper size) so when you print it you don't waste as much ink ;)

Its about time PFC was delt with. Harmonics are no joke. Im pleased to finally see this, given all the DC loads in our world now days.

Many good quality LED bulbs have PFC correction built in. It is mainly to allow them to work with existing dimmers, but at least keeps the harmonics on the mains down.

Around 8:36 you didn't have to remove that rectifying bridge unless voltage would be higher than what it can handle. It would work fine just dropping voltage slightly giving you protection against reverse polarity.

Nice! Funny detail that this video also really shows how distorted the mains voltage has become, because of this problem. It's very common for it to look just like in the video. The top of the sine wave get "clipped" (almost like an overdriven audio signal) because of voltage sag when all the AC to DC converters with smoothing capacitor and no PFC, draws current only in that part of the wave.

I remembered all this from engineering school. You explained it a lot better. I remember calculating all of it and not understanding where I'd ever use it. Funny enough I work at a large corporation now and use emails more than any engineering tools.

The fact that you have a relatively high number of subscribers gives me hope for the future.

Great video! Also, it only remains to add, that some power supplies use passive PFC in form of a huge coil on an iron core. The coil opposes the fast current rises of the capacitor without drawing too much real power.

I just want to say this: This gifted kind of man, is really needed in every university and tech institute.

HI, further to my previous post I have been told by the meter manufacturer that the sampling period for AC current is 100ms. If I understand correctly the cycle time for 50Hz is 20ms, therefore it looks like my meter measures my current use every 5 voltage cycles and assumes that the current waveform is sinusoidal. MY office uses many LED lights and other electronic devices and the current waveform is not sinusoidal, not symmetric and just a mass of spikes. It seems to me that there is almost zero chance that my electricity is being accurately metered.

Finally you made an explanation video about PFC. 🍓 I had been wondering how does PFC work.

Nice fart at 44s.

I’ve never heard of the foam to drink ratio analogy before until now. But it makes so much sense now. Thank you Great Scott !

Not only because of LEDs, but with the increasing number of inverters, as a company we are starting to install neutral cables with bigger sections (it usually is half the phases section). Harmonics are starting to get at concerning levels in some places.

This was a great topic. Thanks for a well+presented video.

It had not occurred to me to consider harmonics with respect to power let alone an active power factor compensation system. Very interesting video as usual!

The common household consists of lagging power factor due to at least there being a fridge, ceiling fans, exhaust fans or an AC all of which require reactive power to operate. The most simple way to deal with that is to connect a mains voltage rated capacitor of 1kvar or more as required parallel to the mains breaker. In most skyscraper/ big buildings it is mandatory to place an APFC Panel board to monitor and control power factor between -0.96 to +0.96

Glad to see you got sponsership from Mouser!! I love your channel.

It's also worth mentioning that the "apparent power" of a device with poor power factor is *not* the power you pay for in a residential situation; you pay _only_ for the real power component. Power factor is a consideration and concern at the grid level, but will not meaningfully impact your own power bill. I say this mostly because there's a lot of scam products out there that claim they can save you tons of money on your electrical bill by correcting your home's power factor simply by plugging them into an outlet. Even if these devices _did_ correct your power factor (most don't do anything), they still wouldn't save you any measurable money, and their little LED will probably consume more power than they'd otherwise save!

Best explanation I heard about PFC my entire life.. I finally understand what it is!

Many of these power packs will run on 385-400v DC if you know what you are doing and test carefully. Internally they already rectify to that voltage. Caveat: The rectifier in the power pack will only be using half of it's diodes and can possibly exceed it's rating specifications. Our farter, who art in evven.

PF of 0.58 (what that LED strip comes out to at 21W vs 36VA) is actually not _too_ bad compared to most small switch mode power supplies. I frequently see 0.4-0.5, which is more the norm for small power supplies. My secondary computer monitor as an example is 0.38 PF (my primary monitor has dual USB-C with PD on both, so its 340W power supply exceeds the required load rating to require PFC by law, so it comes in at 0.97 since it has aPFC).

Highly recommend to use ATX power supplies for larger applications. They're tested, rated and certified for all the good stuff one needs/wants in a PSU.

There are also PFCs that act more like filters. The input is AC mains voltage, the output is also AC mains voltage, but even if you hook up a dirty consumer with an abysmal power factor to its output, you still see a perfect power factor at the input.

Yes, the PFC circuit does reduce those harmonics for the device it is correcting, BUT due to all that PWM activity of the mosfet in the boost converter it could well be adding tons of harmonics back onto the AC mains. (Do a 'before and during' test with a spectrum analyser.) While this is not a reactive power issue this 'dirty' electricity has been shown to add to the EMF smog in the house and beyond.

Hey! Nice content! If you testing and not sure about a device, just use a bulb lamp connected in series with it. It will prevent circuit from explosion.

Given the amount of DC devices these days maybe homes should include PFC'ed DC sockets as well as AC and have the bulky PFC circuit in the wall/at the fuse box? Then DC devices plug into DC sockets? How small can active PFC get? Is it acceptable to expect it with all DC devices in the future?

Oh yeah, I remember when learning about the "power triangle" (apparent power is a vector made from real and reactive power) when working with 3 phase AC. When you want to compensate for inductive loads generating unwanted reactive power, we simply put a calculated capacitor in parallel to it. But I didn't know it was such a huge deal with DC appliances. I actually never thought chargers weren't SMPSs for the most part and were MUCH more rudimentary.

Memory aid from the old days: "ELI the ICE man." (An 'ice man' is someone that delivers blocks of ice back in the pre-refrigeration days, not intended to be a prehistoric human.) ELI means Voltage (E) on an Inductor (L) comes before the Current (I) which builds up more slowly. ICE means Current (I) through a Capacitor (C) comes before the Voltage (E) which builds up more slowly. These are not really needed if you know how these components work, but it can help bridge the gap until trained-instinct takes over. It's a tiny bit interesting (very tiny) that only one symbol/letter out of four ('C') matches its word's first letter ('Capacitor').

Guess I'm glad that when building my 3D printer back then, I sprang some extra money for an active PFC power supply. I'm sure the various PWM driven loads create some kind of havoc power factor wise.

I always enjoy your videos and often learn new things. Thank you for the effort you put into creating these videos.

Amazing content as always!! Can we have a tutorial vedio that shows the basics of using multimeters to reverse engineering circuits like you do? That would be great!!

I always felt that resistors contribute to wasted power. You're effectively burning off energy in the form of heat, just to reduce the voltage.

Good news is that most higher power AC/DC power supplies like those in your PC include PFC circuits.

From what I've read the real problem with uncorrected electronic power supplies is the amount of third harmonic current drawn, as in a three phase system the neutral current is supposed to cancel but the 3rd harmonics add. One possible unfortunate unintended consequence is that with the power supply industry bragging about 0.98+ power factors in single phase equipment and crazy low harmonics it has caused a problem for the designers of multi-kilowatt systems. It is easy to get a simple three phase rectifier to about 0.85, maybe 0.9 I can't remember the exact figure by just levelling the current drawn and sometimes an inductor is enough, but getting above that to the levels claimed for single phase designs is significantly more complicated. As a result installations that should be three-phase input end up using multiple single phase modules instead. Hopefully they are properly spread across phases.

I've always known PFC as "that thing that makes your devices work at both 120 and 240v without them blowing up". Very good video. Definitely learned something.

No two ways about it my young buddy, you are super human, so good to see you analyse these components and shed light on all things electronic.

Couldn't you just feed the HVDC directly into the device and just let the internal rectifier flow through? Sure only half of the rectifier would be in use, which half would be dependent upon polarity, meaning polarity would not matter.

Brillient stuff. Learning curve. Thks for putting it out

I love your analogy of foam/drink ratio in a cup to explain Apparent power/ real power. Im gonna call it gretscotts analogy when explaining it to my interns & students.

Nice video. I can only note at 8:00 professionals don't put PCBs with grid voltage traces on a bare table. Professionals use distance bolts.

In the EU it is already mandatory for commercial devices that use more then X W But if it is a china import it may be avoided for better or worse. Well for super small loads like that LED lamp adding PFC would cost a ton and to make it worth it you need to increase to lot the life time of that LED so costs simply balloon.

Fascinating stuff indeed! Thanks, dude! 😃 And yeah, I'm going to need a power supply pretty soon! Stay safe there with your family! 🖖😊

Great video! PF is something I rarely think of but it definitely can impact our modern systems in a big way.

Nice. Active PFC has been on the market for good PC power supplies since quite some years, but I guess it has to be everywhere. Chargers, LED light, everything that does not is an ohm resistive load.

What I'm currently learning in class is that power factor correction occurs near powerlines. That is, the sum of the loads in a particular building are balanced adding shunt capacitors on power lines. Could anyone comment on this in relation to the video topic?

It's always nice when components work and don't blow up😁. Listening to you talk about these electrical circuits and how they function is like trying to understand someone that speaks another language. I get some if it but you have such a good understanding of it it's just second nature to you. It's the same way when I try and listen to a MD talk about medicine and the more advanced science involved with treating patients when they talk to another doctor.

At first I thought it was weird that music and electronics have so much in common with graphs and hz and harmonics and stuff. But it’s not really that weird when you actually think about it. Also. Music will only get recorded thanks to electronics these days so oscilloscope graphs looking like audio waveforms makes quite a lot of sense. What is weird is that I am not the only audio engineer I know that has a moderate understanding of electronics. Maybe there’s a whole bunch of us that just know how to translate different graphs to different things.

Didn't really "get" Power Factor (PF) until this video. Thanks for this!

Love the videos! Wanted to ask if you were familiar on making PCB Antennas for custom Pcbs without needing to use external pre made modules like you have done before. I tried doing research on my own to help but nothing really helped me. A video from you would be very easy and informative to understand 👍

A very good explanation of the efficiency of the used electrical energy. The problem that arises is with dirty input energy. Where various devices connected to the network leave traces in the form of high-frequency harmonic oscillation. These phenomena are best observed in high-rise buildings with several apartments, which are connected to a single transformer station! Another point that you can show is at what DC input voltage the device starts working normally and if the components can withstand the DC stress. Capacitors are not the best friends with direct current because it fills them up and doesn't let them breathe, causing them to burn out. And manufacturers use these stress statistics to make products with an approximate lifespan of around 5 years of constant use. However, coils have an enemy in high-frequency pulses, because their property is inductive in nature, they create counter currents and amplification of the electromagnetic field from the surroundings into the very circuit that we use. So that in a society with more and more devices that use wireless technology, it is necessary to protect the coils from the signal-filled environment. It would be nice to have an efficiency coefficient close to 1, but until this is put into law and forces manufacturers to comply, I don't see why they would do it by themselves and guarantee a long working life of the devices. Just looking at smartphones and computers, even if the device itself is still working after 5 years, we now have to throw it in the trash because there is no software support, and spare parts stop being produced after 3 years of the product release! And let's not forget that just one such device usually costs at least two salaries of an average working person. And everything that is cheaper no longer has service or software support!

And how many watts does the PFC consume? I see a large heatsink...

I can listen this guy for years....his so funny.....and EXPERT

Excellent video! One of the most apparent circumstances where a poor power factor can be an issue is when using backup inverters. Your 1500VA backup inverter is only going to reach 1500W if you've got a perfect load on it. If you've got a poor power factor, you'll have to derate the power rating!

Now I understand why Nikola Tesla won the fight against Edison 😀 thanks for this information 🤓. From now I won't plug my power supply for 24/7

Love your videos Brother. I am an Electrical and Electronics Engineerand each of your video makes me correlate to the theory that I encountered during my graduation. I always liked to experiment around with all these stuff but to set up a testing and experimentation station is costly. And, the university didn't use to provide time and resources for undergoing such experiments to graduates. However, seeing your videos make my dream of testing and analysing electronic projects come true. Thanks again man. I Love your content. Love from India. Keep on blessing us with knowledge. 😊

How do i determine whether or not a PSU has a PFC when i can only look at it from the outside of the enclosure it's in?

Grid operators have big synchronous compensators (also called synchronous condensers), that are basically free spinning synchronous motors, to actively adjust conditions in the transmission grid. They are a more flexible alternative to capacitor banks. They were introduced in the 1930's and have been in widespread use since 1950's. They are still needed, especially due to wind and solar farms. In my opinion there should be requirements for PFC also in consumer equipment. There is so much crap out there.

0:43 who farted?

You showed us a board and a IC, but didn't talk more of the details. I don't know what makes a good active PFC board or nothing really to identify what might be a bad PFC board design to avoid. This is an interesting topic that I'd like to hear more info on.

Welcome to the farting teacher's channel!

I always learn so much from your videos, I usually have to watch them a couple times just so I can get a good grasp on what you’re teaching, lol.

0:44 fart 💩

Thanks for the video! Your explanations are so thoroughly clear!

Recently I salvaged APFC circuit part from 350W PC powersupply, now I use it to power my 24V DC powersupply. Ofcourse I worked carefully, because it gave 385V on main filter capacitor.

Excellent video! We all need one, just like you said! Thanks!

I learn the most important stuff from this channel. Real practical electrical knowledge, explained in a way I can understand.

PFC were mandated in the EU for all PC power supplies in the late 1990s. Worked at a large electronics OEM manufacturing company and was directly involved in implementation of these changes, we produced power supply's for customers like IBM, Compaq, Apple, Olivetti and others. It amazes me that they have not been more widely adopted in other countries.

Great! And my own handwriting looks like old Egyptian, while yours is very neat and clear. I am jealous! Thanks for the explanation in apparent and real power. Splendid!

Excellent, great job with the video! Perfect explanations !❤

I see more future for my business thanks to you.

thank you scott. i have a project and went straight to mouser.

Power factor and reactive power can be seen pushing a playground swing. If you push at exactly the right moment, you can use only a couple fingers to lift a toddler over your head. But if you're not in phase with the motion of the swing you'll be fighting your own kinetic energy or maybe even break your wrist.

oh, whow, big thanks! I'm a small-tier electronics and mc hobbyist, but I was totally unaware of it, I only knew it from small power supplies, but never researched what that exactly means

Very helpful and clear explanation of PFC. Thank you!

More important thing is, are you going too work out on making it cheaper, bypassing the extortioners, in any further videos?

A very interesting video thank you! Something that most people will never consider due to displayed wattages on products and the accompanying assumptions that this is the only figure of concern. Well done GreatScott! :)

This is just on time. I was learning about computer PSUs and you just showed up with the perfect video. Thanks

I work in a power installation that draws about 400A, supplying thousands of LED lights. Power Factor has not been the concern but harmonics and large neutral currents.

I believe one advantage of passive PFC is it can directly installed on AC loads. I'm not sure if this can be applicable in AC too(?). I wonder what these circuits before but after researching one of those chips I found out what their functions really are. Found these in some LCD TVs psu and one in Behringer powered console psu.

And of course the demo circuit device for this is twice as big as the already big power brick it's being used with. Hopefully they've got some of these things packaged in a much tidier form factor.

A power factor correction is only needed if your loads are inductive and most importantly if in large amount like large motors. Small devices such as LED lights consume the least amount of power. Then most of these device are fed with lower voltage thus making it more efficient. And the power supply of these LED devices are a switch mode type which play a big role in power consumption. a switch mode supplies nowadays have an efficiency greater than 95 percent. And looking at the oscilloscope display where the led devices are used, the trace almost correspond to almost unity power factor meaning that the load is resistive like your heat gun( neglecting the motor blower inside the heatgun). Another thing is, Refrigerators and air conditioning equipment today have inverters or variable frequency drives built-in to minimize the consumption of the equipment. Variable speed drives will have almost unity power factor since the line side of the device as seen from the power source is resistive. So installing such power factor correction is useless when your total load is low and only LED lights to consider.

Thank you once again for your clear, easy -to-understand explanation. Love your videos

...and now I know what power factor means....thank you!!😀

Very interesting! I learned a great deal. Thanks for sharing your knowledge with us!

Fyi, the quick way to spot a power supply with active PFC is to look at the rated input voltage and frequency. If the converter supports all the common AC voltages and frequencies it has an active PFC front end. I.e. ratings like 90-270Vac and 50-60Hz. Another fun side effect of active PFC is that the power supply will often work fine on high voltage DC or 400Hz aircraft power. Some manufacturers will even provide ratings for DC and 400Hz use so you are still in spec.

I have lived off grid for 15 years, I have a lithium solar battery array which I've had for 5 years. The inverse of your argument is true for me. I love my direct DC LED lights and appliances. Heat-produced appliances running off my inverter like my rice cooker and heat gun are losing about 30% efficiency.

Cool. As a layman though I only understood, maybe a 25%, of what you talked about over the whole video?

My utility provider only charges for KWh, not KVA, so actually having a bad power factor doesn’t cost me any extra. However, when I run my devices from my offgrid solar inverter I notice the extra current which bad power factor causes, so the power factor correct stuff will be quite useful in this scenario. Thanks for the video 👍

What matters most is the sum of all loads, which can be complex when dealing with devices like motors that run intermittently. In the past residential power factor consumption has been close to balanced, with the relatively small inductive loads of motors washed out by much bigger resistive loads. I'd be interested to see if the balance is tipped by the capacitive load of LED lights, but more likely the effect is so small it is still negligible. Perhaps in an ideal world the capacitive LED's will balance inductive motors! In any case, even if PF balance is off, the technology for distribution line adjustment is pretty simple.

Just experiencing PFC in practice with a portable PowerStation and a compressor ice maker. Plugin power meter shows ~80W, with a PF of 0.5. The power station seems to draw 150-170W from the Battery as far as I can tell, and with that the *battery drains much faster than expected.* Now I will watch the Video and see if there is a "plugin-between" solution between ice maker and inverter.

I have a couple of those 5v power bricks, but I do not use them at the moment. Currently I run my circuits (typically an esp32 with 50 leds) from a USB phone charger. I don't run the led string at 100% intensity and not all are on at the same time. Sure this doesn't do anything for PFC but power consumption reduction is always a plus.

I run most of my interior lighting on DC. No power factor or harmonic distortion issues, and no flicker (to which a family member is sensitive). But then I'm off-grid so there's a handy source of DC here... I learned about PFC when I was involved with a tech start-up in the late 80's that figured they were going to take the world by storm with a sine-modulated UPS. I had just come out of technical college having gone back to school as an adult. I thought they seemed a bit naive but it was more interesting than what I was doing so I signed on. I had more practical experience as a hobbyist than the PhD who was in charge of design. PFC was just one of the critical factors that he should've known about but didn't. Oh well, I had a fun couple of years laying out circuit boards for prototypes and watching them blow up on the workbench. Later I got to contribute to the design of an ASIC-based inverter controller IC. That was fascinating. After we parted ways with the PhD we managed to get the major operational bugs worked out of the prototype, but when an opportunity came up to jump ship, I took it. No regrets.

Active PFC, such as used in computer power supplies also tends to short and explode when the big high voltage capacitor fails. I ave seen a few of such failed power supplies and managed to repair them. Still, when it fails, it not only turns off the load, but also trips the breaker, which means other stuff turns off as well. I can just use a bigger cable and avoid this problem. Even if it is not frequent, it is very annoying when it happens. The power grid sees constant 0.8 power factor from me though, because that's how the input for my big UPS works.

Awesome! You explained so nicely. That's why I love your channel. Keep it up. 👌

Cheap LED drivers often achieve power factor correction with a single stage topology. Mostly a flyback one. But the output has a lot of voltage ripple. Almost like a 50hz rectified voltage. Thats why you can see the LEDs flickering. Specially one cameras.

Turn the heat down on that heat gun and get back to us about "mostly looks like a sinewave" and has a current in phase. You can tell by the short delay at the zero crossing that the heat gun heating element is phase controlled. At lower heat settings, there will be significant distortion to the waveform along with a bad displacement power factor.

I would like to see a deep dive on transformer design if you are looking for ideas. To better understand saturation and how to design for higher frequency and it's affect on the size of the transformer.