Green Energy

Small wind is horrible, the efficiency of wind is entirely based on the swept area of the blades. At scale it's great, but at household sizes it's just not worth the cost. Turbines and windmills are a 'Go big, or go home' situation as far as being cost effective. Solar, even with batteries, is more cost effective for household or mobile sizes.

It's important to note that Europe has 220/240v by default so most household wiring is robust to higher wattages at lower amps.

Back feeding power is always problematic. A proper system should detect and match the mains before providing power. Once they become normalised then lower quality kit will start hitting the market.

The problem comes when they have to do line work etc. The power is intended to only flow 1 way, so turning it off, and making it safe is easy. It only takes 1 dodgy plug in solar to deliver a lethal shock to someone working on the line. Even worse, it could suddenly appear either by being plugged in, or the sun coming out, so a tested safe line can suddenly become hot.

It's worth noting that fixed solar can also have this issue. However, it's a lot easier to regulate and enforce with fixed installs.

There are a lot of older homes with really messed up wiring.

How do it plug in? How easy is it to do it. Do you need an electrician or can you do it yourself? How is the risks from fires?

We're also late on implementing good public transport, having universal healthcare, 30 days off from work per year, and more! :D

It sucks.

The problem isn't when it's done correctly, it's when it gets half arsed by cheap Chinese suppliers. A lot of the corner cuts are not easily detectable to layman consumers.

The biggest is matching protection. The solar needs to shut down within ms of an RCD going (RCDs take 30ms). Otherwise it could continue to shock a victim, or risk a fire.

The most insidious would be to stop any with an "Off grid" mode. Grid workers already fear generators being backfed during a power cut. It turns cold lines live, with no warning. Having a switch to get your lights and TV working again would be far too tempting to too many people.

Speaking of the grid. One of the biggest issues is grid instability. Solar can do offline VERY quickly. Micro solar is even worse for this. Without major upgrades on the grid, it's akin to having a small child "helping" you move heavy furniture up some stairs. In theory you're better off. In practice you spend more resources countering the chaos than you save.

My personal view is that all new homes should have power feed in capabilities baked in at the mains entry point. It can then have proper cutoff/cutover capabilities, from fully approved parts. No chance of Chinese cheap crap killing people. It also puts the breakers back inline with the power. Home solar (balcony or rooftop), battery backup, generators all can be fed in via a known safe method.

The plug in systems aren't meant to provide power on their own, they're meant to supplement grid power and reduce energy costs for the purchaser. They don't provide electricity unless some is already detected on the line, for the exact reason you ask

In Germany, where these "balcony solar" devices have been approved for years and seem to be the most popular out of any country, the panels have all kinds of safety mechanisms. One of them is a mechanism that shuts of the power coming from the panel if it detects that line power has been lost. It seems that this is what would prevent it from shocking electricians working on lines that they think are unpowered. This article goes into details about the various safety mechanisms on these: https://balkon.solar/news/2025/03/17/how-does-plug-in-pv-in-germany-work/

I assume unplug the solar? If the whole point is that it plugs into an outlet

As an electrical engineer in renewable energy, it's a lot more complicated than that unfortunately. To trot out the often-used water analogy, net metering is a bit like pumping water back into your water main and then billing your water utility for it. The grid isn't really designed to allow power to flow backwards and it causes all kinds of problems when it does. Distributed generation CAN work, but because of its challenges net metering isn't realistic. Even wholesale power prices aren't realistic, because utilities would much rather buy that power from conventional power plants. Requiring net metering or the market rate for rooftop solar is fine to promote solar, but it's a market distortion and at that point I would rather they just have a conventional subsidy.

I live in SE MI. There are two things working against residential solar here.

First, in terms of peek sun hours it's just not a great proposition. Yay cloud cover and short winter days

More importantly, we no longer have net metering. If you generate surplus energy you can still sell it, but you sell it for below what you would have to pay it for.

In Germany, it's limited to more like 800 watts (and I think some other safety regulations). As I understand it, it's generally worked without this being much of an issue despite millions of plug in solar installs (primarily for balcony solar)

I'm not sure why all the downvotes, but overloading is true, see here how to avoid it:
https://balkon.solar/news/2025/03/17/how-does-plug-in-pv-in-germany-work/

Preventing Circuit Overload (Source + Load on One Circuit)

The key safety concern is that a plug-in solar inverter feeds into a final sub-circuit “downstream” of the main breaker. Normally, a circuit breaker senses all current on its circuit and trips if the load is too high. But with a PV source injecting current at a wall socket, part of the load is supplied locally. The breaker only “sees” the net current from the grid – not the portion supplied by the solar module . This means the wiring could carry more amps than the breaker’s rating without tripping. For example, on a 16 A circuit a 600 W micro-inverter (≈2.6 A) plus a 16 A appliance could theoretically pull ~18.6 A through the wires while the breaker sees only ~16 A . Over time, such an unseen overload can overheat cables, especially in old or unfavorable installations.

The 800 W limit (specified as 800 VA) was chosen as a conservative safe value so that typical 1.5 mm² house wiring can handle the extra current margin. Even under full sun, a 800 W unit rarely sustains peak output (often max ~500–550 W ≈ 2.4 A), and most circuits can tolerate that small extra current. The limit is rising to 800 W (≈3.5 A) as EU regulations consider <800 W “not significant” generation. At 800 W, German guidance still deems the slight increase manageable, but extra safety margins are advised. For example, in older homes with uncertain wiring, it’s recommended to replace the 16 A breaker with a 13 A one. A 13 A MCB will trip sooner, ensuring that the sum of grid + solar current can’t overheat the cables (13 A from grid + ~3 A PV ≈ 16 A total). Another strategy is having an electrician connect the balcony PV on a dedicated circuit with its own breaker, so it doesn’t combine with heavy appliance loads on the same line. Then even larger system would be possible.

In practice, users are advised to avoid overloading scenarios proactively: connect the mini-PV to a circuit that isn’t already near capacity, and never daisy-chain multiple PV units or plug them into extension strips . Only one unit per outlet/circuit is allowed, which prevents additive overcurrent from two inverters. By following these limits and using the existing circuit protection, Germany keeps wiring stress “within tolerance” . Notably, tests have shown that issues (excessive heating) would only start to appear above roughly 700 W sustained feed-in combined with a fully loaded 16 A circuit in worst conditions.

The solar panel would be providing some of that electricity though. You're not accounting for that.

Dude... the way you got piled on with stupid replies. Sometimes comment sections just go the wrong way even if you are completely right. My sympathies.

Of course I will need to be in a disposable income situation to get one of these.

The prices I’ve seen for the simple plug-in PVs are terrible. I can only imagine it making sense on frequent road trips or camping, or perhaps in situations where you live in an apartment and have no rooftop real estate for proper panels.