Low Frequency Vs. High Frequency Inverters

Yeah, but no. I have designed AC power conditioning and regulating products, and the transformer in "Low Frequency" inverters is NOT what gives them the ability to handle surges.
In general, low frequency inverters do handle surges better, but the reason is because the number and ratings of the FETs driving the big transformer. I don't know WHY the designers of high frequency inverters skimp in that area, but if they didn't, it would be totally practical to make one that had just as much surge cpapacity as a low frequency inverter.

Any high frequency inverter that self destruct when overloaded was poorly designed. A low frequency inverter will equally be damaged if the power switch rating is exceeded. Sturdier designs always have current limiting circuits.

@@xtneuron Thanks for the info! Yes, makes sense. I figured a low freq inverter would have fewer parts to fail, but I guess not. I agree that just about all budget Chinese hi freq inverters are designed to just barely hit specs but cheaply. They allow no room for any overloading. They also have piss poor isolation and RFI suppression. Some are so bad that even the neutral leg is floating and if it is bonded to ground...POOF!

Indeed, I didn't put this in the video because people would fall asleep 😀. The term "low frequency" in inverters can indeed be misleading. While low frequency inverters do use FETs that switch at high frequencies, the key difference lies in how they convert and manage power.

@@cleversolarpower Low frequency inverters also have another capability that most high frequency inverters lack: They can absorb AC power on the output side, and feed that power backwards through all the inverter circuits and charge the battery. This means that a low frequncy inverter can act like the grid. If you have an existing solar system that is grid connected, and is has only AC output, perhaps because it is built with microinverters under each panel, it will shut down when the grid fails. If you add a battery and a high frequency inverter to such a site, the solar panels are still useless. They can't charge your battery. But if you add a battery and low frequncy inverter, the AC power from your solar system can flow backwards through the inverter and charge your battery. For anyone who dove this deep into the comments - look up "AC coupled solar backup" for the details.
For me, this feature of low frequency inverters was the key factor that made that type mandatory for my situation. I had a large grid-tied solar system at my house, and wanted to add a backup system that would enable that system to work even when the grid was down. So I added a 5 kW low frequency inverter, and it does exactly that. The solar system "sees" it as a grid, and fires back up, and pushes its output to the inverter, which accepts it, just like the real grid would.

My pleasure!

Thanks for watching!

No because the inverters in the devices that you mentioned are inductive loads.

​@@Madsci-zy8wmSo are you saying that it is inconsequential despite the fact these devices are of inverter type as opposed to the traditional type?
Did you understand what I meant by inverter devices, which is clearly how they are branded by their manufacturers and quite rightly so?

you're right, also my power tools without inverter has soft start (but what about soft end :)), I think it also helps
but...I choose low-frequency :)

Good to know, thanks for sharing!

If your loads are low compared to the power rating of the inverter, then that will also extend the lifespan. Maybe thats happening in your case. They can last up to 10 years as well.

The MOSFETs switch very fast to create a sine wave. That's why it's called high frequency. Imagine a modified sine wave with the visible steps in between. MOSFETs in a pure sine wave high frequency recreate a sine wave by switching very fast.

@@cleversolarpower Thank you

No, but I'm a fan of their equipment. High quality, many options, good customization,...

Longevity is never a priority for any electronic device made today. They want it to break so you have to buy another one.

Grid tie is low frequency. They should last you about 10years. That's the standard warranty period in Belgium. The reason they last so long is that they don't have to supply surge power because the grid takes the surge demand. Off grid is less forgiving. Imagine you are on a boat and your inverter fails. Dependability becomes more of a factor then.

For fish farming you need 365/24/7 availability air supply.

Shipping weight rules! Shipping from China is always priced according to the weight of the container.

@@seymourpro6097 I beg to differ. In shipping, volume is more important of a greater concern than weight. Shipping weight also doesn't explain why even US based manufacturers like midnight solar are gravitating towards HF inverters.

Yeah, it's reliable.

Other than my chicom inverter handles my microwave, space heater, coffee pot
, vacuum cleaner, grinders, saws, fridge, freezer, window ac ect ect ect.... where as the double the price victron phoenix 1200....... not a chance. Charge controllers seem to be great though, super flexible/programmable.... have 6 of them 😂

Most likely, the big heavy power transformer has inherent loss compared to a hi freq unit.

The large, heavy 50/60 Hz transformer has an iron core. The direction of the magnetic field in the core has to alternate at the mains frequency. That alternation induces losses in the iron - think of it as being something like friction in the alternation if the magnetic domains in the iron. These losses are directly proportional to the amount of iron, and are typically 4 watts per pound of iron. Core loss is independent of the load on the inverter.

@@jimmurphy5355 thank you for the this response. Probably the best answer to this question so far. Forgive me for asking further questions out of this answer. How's is Victron managing to keep idle consumption low, even better than many low end HF inverters? Are they somehow reinjecting the (potentially) wasted power in the iron core back into the system. I apologise if these questions sound naive but I'm really curious.

@@adon8672 I honestly don't know. The core losses can't be recovered - they heat the core, and they are gone. My best guess - and it is just a guess - they don't power the low frequency unless the load is demanding power. Some "low frequency" inverters have a power save mode that does that. Or maybe they use (expensive) ultra low loss grade iron in the core, and/or run the core at relatively low flux levels (also expensive because then you need a bigger core.)
The true but not very infomative answer: better engineering and better quality components.

@@jimmurphy5355 thank you for the prompt and wonderful response. There's a lot of sense in your guesses and they are good enough for a lay person like me.

Indeed, like i said in the video it depends on the manufacturer.

Maybe there is a high import tariff going on?

@@cleversolarpower yes but i think its also due to lots of indian companies manufacture low frequency inverters and they are not importing it nor they are making them ( maybe because they have to set up new plant for it also they have to discontinue their existing plants which will be not be good for business) and the one who are importing them are charging premium

It could also be that it ran inductive loads which puts stress on the MOSFETs. 35 degrees Celcius is not that high for electronics when it's well ventilated.

​@@cleversolarpowerYou are right.In summer we regularly hit 45 degrees.And my 3kw /24v inverter keeps running.With hosehold items like fans,fridge,freezer,tv.And 600w water pump.Reaching 1000w all together.Most likely problem for breakdown is when you utilize over 2kw all the time.

2 years is nothing though. Heating water is a resistive load, so no surge power is required.