It’s a very capitalist way of thinking about the problem, but what “negative prices” actually means in this case is that the grid is over-energised. That’s a genuine engineering issue which would take considerable effort to deal with without exploding transformers or setting fire to power stations
Home owned windmills are almost a total waste. Its surprising how little electricity they generate especially given how much the cost to buy and install. Some real numbers. A 400w can cost almost $18k to buy and install. A 410w solar solar panel is about $250 + $3k of supporting electronics and parts. And that same $3k can support 10+ more panels. I looked into it myself really wanted it to be worth it for home, but it just isn’t. Now utility grade wind? Absolutely worth it. You need absolutely giant windmills with massive towers, but once you have those, you can make a LOT of electricity very cost effectively.
Solar panels worth it? Yes. Absolutely.
Batteries, not quite there yet for most folks. Batteries are really expensive, and don’t hold very much electricity $10k-$15k can get you a few hours of light or moderate home use capacity. For folks with really expensive electricity rates or very unreliable power this can be worth it financially, but for most every else. Cheaper chemistry batteries are finally starting to be produced (Sodium Ion), but we’re right at the beginning of these and there not really any consumer products for home made from these yet.
Yeah, right now end of life EV batteries are great for making your own power storage but that’s a level of diy beyond what 95% of people are willing or able to do
What’s infuriating is that we had electric cars before ICE powered cars. 1899. If we would’ve been investing money and effort into research for battery technology since then, we wouldn’t have this problem. Salt batteries, solid state batteries, and other promising tech is in it’s infancy because we just started to take this seriously as a society like 10 years ago.
Better late than never but it grinds my gears that the best argument against solar and wind is power storage requirements due to unpredictable power generation. Like this is an extremely solvable problem.
Yeah, right now end of life EV batteries are great for making your own power storage but that’s a level of diy beyond what 95% of people are willing or able to do
End of life EV batteries are great for grid-scale operators doing power storage, but I highly recommend against homeowners use them this way. Not just because they are complex DIY projects as you point out, but because the EV batteries that are aging out of car use are NMC chemistry. These are great for high density power storage, which you want in a car, but they are susceptible to thermal runaway if they get too hot. The original Tesla Powerwall and Powerwall 2 also used these same chemistry batteries. I wouldn’t want these in my house. However, in a utility grid scale? Sure, they won’t be anywhere near people so in the unlikely event they do catch fire its a property problem, not a lost human life problem.
I understand your concern, I totally agree that the volatility isn’t ideal, but putting it in a steel box outside your house isn’t that beyond the scope for a diy-er. Envision it the same way a generac sits outside and ties in to your house but with a safe enough enclosure.
As long as you check the cells you use when you deconstruct the car battery it should be fine. All the projects I watch online they don’t even need the liquid cooling system that it utilized when it was in the car because the discharge rate is so far below the C rating the battery that they don’t generate great like when they are in cars
I understand that cell could go bad though at any time, so the box is necessary imo
Sodium ion batteries are going to be the solution. 18650 packs are already out and perform economically. Since the molecules are so much bigger, energy density is only like 60% of lithium based solutions, but they have a very wide temperature range and are incredibly more inert and safe and density isn’t a problem for bulk energy storage.
The hurdle to overcome in inverters dealing with the very wide voltage span and bespoke charging ICs, but definitely possible and within 5 years will probably become a lithium iron phosphate competitor.
Ahh I get it now. You have no idea what you’re talking about. You have the smallest understanding of something and assume that is everything. You’re so very far away from understanding the practical applications and limits. You’re also clearly not interested in learning, so I’ll leave you to your impractical delusions.
Did you not look at the specs on that product? It only produces energy when winds are above 7mph and don’t actually hit the rated output unless the winds are almost 35mph.
Almost none of the country averages an amount of wind power per square meter equivalent to the rating on home turbines at 10 meters above ground level (yellow and red on this map):
Wait so the same people that can’t drop 500 USD for an emergency are expected to drop 300 USD for a wind turbine and provide the installation of it to boot is that right
“put the excess energy into batteries” is an idea, and is already pretty much what is done, but the large scale implementation still requires a lot of time, effort, and expense.
How, exactly, does that solve anything? It’s not like we can add some kind of magic automatic residential cutoff system (that would just make it worse) and residential distribution is already the problem! Residential solar is awesome (tho home batteries are largely elon propaganda…) but they only contribute to the above issue, not solve it. There are ways of addressing it, but they’re complicated and unglamorous.
It’s not like we can add some kind of magic automatic residential cutoff system
Of course we can. They’re called Microgrid Interconnection Devices (MIDs).
that would just make it worse
Microgrids that can disconnect from the utility at appropriate times may in fact make it better. If homeowners responded to utility alerts of high demand and opted to disconnect from the grid during those times while still having power, that would just make grid operators and home owners happier.
residential distribution is already the problem!
Microgrids are the solution!
tho home batteries are largely elon propaganda…
While residential BESSs are largely Tesla based, they are absolutely key in the energy transition from fossil- to renewables-based power sources.
they only contribute to the above issue, not solve it.
How?
There are ways of addressing it, but they’re complicated and unglamorous.
MIDs are in fact one of the bigger ones! That said, all the ones I have worked with are promising but are as-yet still unreliable enough that municipal adoption has been mired in safety concerns and the usual nonsense. To be honest that’s been ever since they were first added to the NEC (admittedly most of this initially was based on speculative concerns), because of course. There are still warranted concerns with the implementation of microgrids, including things that are obviously bullshit like a lack of confidence in the reactivity of stations to the potential for the excessive peaking large residential adoption of home batteries might cause, but also much less bullshit things like the complicating risks of having very large lithium-based batteries present in a residential fire.
They are not insurmountable concerns, but they are ones that need answering and are not a small part of why I say that currently, home battery storage solutions just aren’t there yet. Local-grid facilities (what one of your sources calls a Mini-grid) are currently the best solution, which is why so many utilities are installing them. I’ve no doubt that the issues will be worked out, and although it will be some time before the technology matures to where the economies of scale present at the municipal level are no longer a driving consideration, it’ll probably get there.
very minor stuff
While residential BESSs are largely Tesla based, they are absolutely key in the energy transition from fossil- to renewables-based power sources.
Is this what you’d intended to link here, because while you’re factually accurate in their necessity and I’m not disputing your claims, as far as I can tell the source here is only discussing local-municipal (‘mini grid’) installs, not microgrid installs, nor does it touch on the value of home-scale BESS
After installation, a home owner has free electricity? I’m not trying to solve the issues for the power grid people, they have teams of people for that.
Spain and Portugal had almost complete blackouts today. You know who wouldn’t have had blackouts? The people with their own solar panels and windmills.
I acknowledge that there’s no real way to communicate sincerity online, but I’m gonna go ahead and promise I’m not trying to be a dick here when saying this:
a home owner has free electricity
I think you’re bonking up on the Dunning Kruger limit here, because that’s absolutely not how it works. Not only are the vast majority of homes not candidates for useful solar installs (you can pay someone to do it, but holy cow nearly every residential solar installer is a scam looking at you, Lumio International (how’s that RICO case going?)), but solar for home-use power generation is very much not the norm for a whole host of reasons (dead linemen one of the biggest ones) and the safety considerations for implementing it generally make it an onerous enough task to manage that it’s appeal is restricted largely to special interest users (homesteaders, preppers, S&R, power system enthusiasts, van life, etc ). There are ways this could be mitigated, but it would require a massive grid overhaul and additional constant upkeep beyond what any current grid already requires.
Not only are the vast majority of homes not candidates for useful solar installs
Australia is an edge case for everything solar and I’ll quite happily admit that! Yay Australia, well done. That said I’d be very willing to bet that the majority of those are not-above-50%-ideal installs (don’t take that bet, I’m cheating)
Hardly “only special interest groups”
Sorry, you’ve misunderstood, I was talking about direct home power generation being special interest, not residential solar in general. Aussies don’t have a higher rate for direct power generation than anywhere else because grids are, by and large, all suffering from the same fundamental design issues. I’m not at all attempting to argue that solar installs in general are special interest, and especially with the incredibly well thought out incentives the aus gvmt has been offering for both new construction and residential conversion/installation. 100% best handling of it in the world right now.
In no home outside of fringe uses are any lights 12vdc, with the exception of maybe led strip lights for undercabs. They’re all designed for 120vac. That lightbulb in the diagram is an e37/medium base for 120vac.
Couldn’t solar farms just strategically disconnect some of their panels from the grid to avoid that? Solar panels are always collecting energy, but if you disconnect them that energy just goes into making them a bit warmer rather than overloading the grid.
The grid is always over energized. That’s not a problem. Large solar and wind farms connect to the grid with great specificity about the maximum amount of energy they will put on the lines. The problem would be not enough energy. Batteries are beginning to solve the dispatch energy issue with renewables. As long as republicans don’t get their way and ruin renewable energy with unfair fossil fuel mandates, the grid will continue to modernize in this way and we’ll be fairly independent of fossil fuels in the future for electricity.
This is some real “basic biology” level thinking here. Even if it were as simple as “Pull the lever Krunk!” then you’ve just turned all that solar infrastructure into junk for the majority of the time that we need power.
People use the vast majority of electricity in a day in the afternoon and at night - times that are noticeably after the peak solar production time. So you have all that energy going into the system with nowhere to go because battery technology and infrastructure isn’t there, and then no energy to fulfill the peak demand. This is an issue nuclear runs into as well because a nuclear plant is either on or off and isn’t capable of scaling its power to the current demand.
There are times where power companies have to pay industrial manufacturing facilities to run their most energy consuming machines just to bleed extra energy out of the grid to keep it from overloading and turning into a multi-million dollar disaster that could take years to get people back on the grid.
Not an engineer but I sometimes watch them on YouTube.
Could you not just set up a breakout point and have it arc to ground? If the power source is renewable then wasting a little when you have a full grid shouldn’t be a big issue. I’m thinking something along the lines of StyroPyro’s arcing plasma flamethrower should chew up plenty of excess power if you scale it up. As you ramp your total storage up toward 100% capacity I’d start shutting off inputs (disconnecting solars, etc) and then have what’s basically a big old Tesla coil to vent excess power over 95% capacity.
There’s obviously a lot of issues with that idea, but I’d like to throw my wholehearted support behind it anyways, just to see the expressions my FCC/Radio buddies would make when they realize someone’s running a MW-scale tesla coil as some kind of electrical blowoff valve. I can’t easily tell you the exact size of the area you’d utterly obliterate all radio communications in, but it’d be hilariously large.
Faraday cage should cover that no? Styro even mentions in the linked video that he needed to encapsulate his workshop in one in order to not get angry visits from the FCC. I’m sure for something scaled up like this you might want to nest a couple of them together.
Again, not an engineer, I could be (and likely am) wildly off base here. Not sure what makes it such a terrible idea though. I am pretty certain that a MW-scale Tesla coil probably wouldn’t blow out a larger area of communications than, say, nuclear testing would, and we do that all the time in the Midwest.
In fairness, capitalist expansion is predicated on generating and reinvesting profit. If you build an array of solar panels and generate a revenue less than the installation+maintenance cost of the panels, you don’t have any more money to buy new panels and expand the grid.
That is, under a privatized system, anyway. If you’re a public utility and your goal is to meet a demand quota rather than raise revenue for the next round of expansion, profit isn’t your concern. You’re looking for the lowest possible installation/maintenance/replacement cost over the lifetime of the system, not the high margins per unit installed.
Incidentally, this is why vertically integrated private firms that consider electricity an expense rather than a profit center have been aggressively rolling out their own privately managed solar/wind arrays. When the concern is minimizing cost rather than maximizing revenue, and you can adjust your rate of consumption to match the peak productive capacity of your grid, then solar/wind is incredibly efficient.
If you’re describing nearly free and unlimited electricity as a problem, you may want to reconsider some things.
It’s a very capitalist way of thinking about the problem, but what “negative prices” actually means in this case is that the grid is over-energised. That’s a genuine engineering issue which would take considerable effort to deal with without exploding transformers or setting fire to power stations
Home owned windmills, solar panels and battery storage solves that.
Edit: Look at this awesome diagram of how it’s done for a hybrid setup that’s about $400 on Amazon.
PIKASOLA Wind Turbine Generator 12V 400W with a 30A Hybrid Charge Controller. As Solar and Wind Charge Controller which can Add Max 500W Solar Panel for 12V Battery.
Home owned windmills are almost a total waste. Its surprising how little electricity they generate especially given how much the cost to buy and install. Some real numbers. A 400w can cost almost $18k to buy and install. A 410w solar solar panel is about $250 + $3k of supporting electronics and parts. And that same $3k can support 10+ more panels. I looked into it myself really wanted it to be worth it for home, but it just isn’t. Now utility grade wind? Absolutely worth it. You need absolutely giant windmills with massive towers, but once you have those, you can make a LOT of electricity very cost effectively.
Solar panels worth it? Yes. Absolutely.
Batteries, not quite there yet for most folks. Batteries are really expensive, and don’t hold very much electricity $10k-$15k can get you a few hours of light or moderate home use capacity. For folks with really expensive electricity rates or very unreliable power this can be worth it financially, but for most every else. Cheaper chemistry batteries are finally starting to be produced (Sodium Ion), but we’re right at the beginning of these and there not really any consumer products for home made from these yet.
Yeah, right now end of life EV batteries are great for making your own power storage but that’s a level of diy beyond what 95% of people are willing or able to do
What’s infuriating is that we had electric cars before ICE powered cars. 1899. If we would’ve been investing money and effort into research for battery technology since then, we wouldn’t have this problem. Salt batteries, solid state batteries, and other promising tech is in it’s infancy because we just started to take this seriously as a society like 10 years ago.
Better late than never but it grinds my gears that the best argument against solar and wind is power storage requirements due to unpredictable power generation. Like this is an extremely solvable problem.
End of life EV batteries are great for grid-scale operators doing power storage, but I highly recommend against homeowners use them this way. Not just because they are complex DIY projects as you point out, but because the EV batteries that are aging out of car use are NMC chemistry. These are great for high density power storage, which you want in a car, but they are susceptible to thermal runaway if they get too hot. The original Tesla Powerwall and Powerwall 2 also used these same chemistry batteries. I wouldn’t want these in my house. However, in a utility grid scale? Sure, they won’t be anywhere near people so in the unlikely event they do catch fire its a property problem, not a lost human life problem.
I understand your concern, I totally agree that the volatility isn’t ideal, but putting it in a steel box outside your house isn’t that beyond the scope for a diy-er. Envision it the same way a generac sits outside and ties in to your house but with a safe enough enclosure.
As long as you check the cells you use when you deconstruct the car battery it should be fine. All the projects I watch online they don’t even need the liquid cooling system that it utilized when it was in the car because the discharge rate is so far below the C rating the battery that they don’t generate great like when they are in cars
I understand that cell could go bad though at any time, so the box is necessary imo
Sodium ion batteries are going to be the solution. 18650 packs are already out and perform economically. Since the molecules are so much bigger, energy density is only like 60% of lithium based solutions, but they have a very wide temperature range and are incredibly more inert and safe and density isn’t a problem for bulk energy storage.
The hurdle to overcome in inverters dealing with the very wide voltage span and bespoke charging ICs, but definitely possible and within 5 years will probably become a lithium iron phosphate competitor.
Oh yeah, super expensive. /s
https://www.amazon.com/dp/B087BY2YV7/?
The first link that came up: https://www.bobvila.com/articles/best-home-wind-turbines/
Ahh I get it now. You have no idea what you’re talking about. You have the smallest understanding of something and assume that is everything. You’re so very far away from understanding the practical applications and limits. You’re also clearly not interested in learning, so I’ll leave you to your impractical delusions.
Oh I’m willing to learn. Explain it to me.
https://youtu.be/oiB1Sm_f48w
Did you not look at the specs on that product? It only produces energy when winds are above 7mph and don’t actually hit the rated output unless the winds are almost 35mph.
Almost none of the country averages an amount of wind power per square meter equivalent to the rating on home turbines at 10 meters above ground level (yellow and red on this map):
Compare to this map of average insolation:
It’s a hybrid solar and wind. Also, that’s why you have batteries for storage.
Why not skip the middleman and go straight solar, then?
For places like Seattle.
Wait so the same people that can’t drop 500 USD for an emergency are expected to drop 300 USD for a wind turbine and provide the installation of it to boot is that right
“put the excess energy into batteries” is an idea, and is already pretty much what is done, but the large scale implementation still requires a lot of time, effort, and expense.
How, exactly, does that solve anything? It’s not like we can add some kind of magic automatic residential cutoff system (that would just make it worse) and residential distribution is already the problem! Residential solar is awesome (tho home batteries are largely elon propaganda…) but they only contribute to the above issue, not solve it. There are ways of addressing it, but they’re complicated and unglamorous.
Of course we can. They’re called Microgrid Interconnection Devices (MIDs).
Microgrids that can disconnect from the utility at appropriate times may in fact make it better. If homeowners responded to utility alerts of high demand and opted to disconnect from the grid during those times while still having power, that would just make grid operators and home owners happier.
Microgrids are the solution!
While residential BESSs are largely Tesla based, they are absolutely key in the energy transition from fossil- to renewables-based power sources.
How?
Which ways?
MIDs are in fact one of the bigger ones! That said, all the ones I have worked with are promising but are as-yet still unreliable enough that municipal adoption has been mired in safety concerns and the usual nonsense. To be honest that’s been ever since they were first added to the NEC (admittedly most of this initially was based on speculative concerns), because of course. There are still warranted concerns with the implementation of microgrids, including things that are obviously bullshit like a lack of confidence in the reactivity of stations to the potential for the excessive peaking large residential adoption of home batteries might cause, but also much less bullshit things like the complicating risks of having very large lithium-based batteries present in a residential fire.
They are not insurmountable concerns, but they are ones that need answering and are not a small part of why I say that currently, home battery storage solutions just aren’t there yet. Local-grid facilities (what one of your sources calls a Mini-grid) are currently the best solution, which is why so many utilities are installing them. I’ve no doubt that the issues will be worked out, and although it will be some time before the technology matures to where the economies of scale present at the municipal level are no longer a driving consideration, it’ll probably get there.
very minor stuff
Is this what you’d intended to link here, because while you’re factually accurate in their necessity and I’m not disputing your claims, as far as I can tell the source here is only discussing local-municipal (‘mini grid’) installs, not microgrid installs, nor does it touch on the value of home-scale BESS
(edit: fixed some typos)
After installation, a home owner has free electricity? I’m not trying to solve the issues for the power grid people, they have teams of people for that.
Spain and Portugal had almost complete blackouts today. You know who wouldn’t have had blackouts? The people with their own solar panels and windmills.
I acknowledge that there’s no real way to communicate sincerity online, but I’m gonna go ahead and promise I’m not trying to be a dick here when saying this:
I think you’re bonking up on the Dunning Kruger limit here, because that’s absolutely not how it works. Not only are the vast majority of homes not candidates for useful solar installs (you can pay someone to do it, but holy cow nearly every residential solar installer is a scam looking at you, Lumio International (how’s that RICO case going?)), but solar for home-use power generation is very much not the norm for a whole host of reasons (dead linemen one of the biggest ones) and the safety considerations for implementing it generally make it an onerous enough task to manage that it’s appeal is restricted largely to special interest users (homesteaders, preppers, S&R, power system enthusiasts, van life, etc ). There are ways this could be mitigated, but it would require a massive grid overhaul and additional constant upkeep beyond what any current grid already requires.
Here in Australia 37% of households have rooftop solar. Hardly “only special interest groups”.
Australia is an edge case for everything solar and I’ll quite happily admit that! Yay Australia, well done. That said I’d be very willing to bet that the majority of those are not-above-50%-ideal installs (don’t take that bet, I’m cheating)
Sorry, you’ve misunderstood, I was talking about direct home power generation being special interest, not residential solar in general. Aussies don’t have a higher rate for direct power generation than anywhere else because grids are, by and large, all suffering from the same fundamental design issues. I’m not at all attempting to argue that solar installs in general are special interest, and especially with the incredibly well thought out incentives the aus gvmt has been offering for both new construction and residential conversion/installation. 100% best handling of it in the world right now.
In no home outside of fringe uses are any lights 12vdc, with the exception of maybe led strip lights for undercabs. They’re all designed for 120vac. That lightbulb in the diagram is an e37/medium base for 120vac.
Couldn’t solar farms just strategically disconnect some of their panels from the grid to avoid that? Solar panels are always collecting energy, but if you disconnect them that energy just goes into making them a bit warmer rather than overloading the grid.
You can have your own batteries as well. If those then get overloaded, disconnect.
The grid is always over energized. That’s not a problem. Large solar and wind farms connect to the grid with great specificity about the maximum amount of energy they will put on the lines. The problem would be not enough energy. Batteries are beginning to solve the dispatch energy issue with renewables. As long as republicans don’t get their way and ruin renewable energy with unfair fossil fuel mandates, the grid will continue to modernize in this way and we’ll be fairly independent of fossil fuels in the future for electricity.
deleted by creator
Nothing an open/close gate couldn’t fix. The real problem is how overly complicated we feel we need to make things.
This is some real “basic biology” level thinking here. Even if it were as simple as “Pull the lever Krunk!” then you’ve just turned all that solar infrastructure into junk for the majority of the time that we need power.
People use the vast majority of electricity in a day in the afternoon and at night - times that are noticeably after the peak solar production time. So you have all that energy going into the system with nowhere to go because battery technology and infrastructure isn’t there, and then no energy to fulfill the peak demand. This is an issue nuclear runs into as well because a nuclear plant is either on or off and isn’t capable of scaling its power to the current demand.
There are times where power companies have to pay industrial manufacturing facilities to run their most energy consuming machines just to bleed extra energy out of the grid to keep it from overloading and turning into a multi-million dollar disaster that could take years to get people back on the grid.
Sorry for the naive question, but is it not possible to send the excess electricity to the ground (in the electrical sense)?
It would definitely need to be ground in a literal sense.
And even the earth has its limits. Soil is only so conductive, pump enough energy into it and you’ll turn it to glass (which won’t conduct anymore).
Not an engineer but I sometimes watch them on YouTube.
Could you not just set up a breakout point and have it arc to ground? If the power source is renewable then wasting a little when you have a full grid shouldn’t be a big issue. I’m thinking something along the lines of StyroPyro’s arcing plasma flamethrower should chew up plenty of excess power if you scale it up. As you ramp your total storage up toward 100% capacity I’d start shutting off inputs (disconnecting solars, etc) and then have what’s basically a big old Tesla coil to vent excess power over 95% capacity.
There’s obviously a lot of issues with that idea, but I’d like to throw my wholehearted support behind it anyways, just to see the expressions my FCC/Radio buddies would make when they realize someone’s running a MW-scale tesla coil as some kind of electrical blowoff valve. I can’t easily tell you the exact size of the area you’d utterly obliterate all radio communications in, but it’d be hilariously large.
Faraday cage should cover that no? Styro even mentions in the linked video that he needed to encapsulate his workshop in one in order to not get angry visits from the FCC. I’m sure for something scaled up like this you might want to nest a couple of them together.
Again, not an engineer, I could be (and likely am) wildly off base here. Not sure what makes it such a terrible idea though. I am pretty certain that a MW-scale Tesla coil probably wouldn’t blow out a larger area of communications than, say, nuclear testing would, and we do that all the time in the Midwest.
Mmmmm no, a bit of napkin math here but the RF this thing would throw off would just melt any faraday cage smaller than a midsized town.
Also no, there are not nuclear tests all the time in the midwest.
Oh, look! A challenge. And a business opportunity! Just get a mortgage, buy some land in the middle of nowhere and make a reverse hydro plant.
Oh, I forgot. Banks don’t loan money for stuff not already existing or net-harmful hyped-up bullshit like AI and crypto.
In fairness, capitalist expansion is predicated on generating and reinvesting profit. If you build an array of solar panels and generate a revenue less than the installation+maintenance cost of the panels, you don’t have any more money to buy new panels and expand the grid.
That is, under a privatized system, anyway. If you’re a public utility and your goal is to meet a demand quota rather than raise revenue for the next round of expansion, profit isn’t your concern. You’re looking for the lowest possible installation/maintenance/replacement cost over the lifetime of the system, not the high margins per unit installed.
Incidentally, this is why vertically integrated private firms that consider electricity an expense rather than a profit center have been aggressively rolling out their own privately managed solar/wind arrays. When the concern is minimizing cost rather than maximizing revenue, and you can adjust your rate of consumption to match the peak productive capacity of your grid, then solar/wind is incredibly efficient.
thats why Westinghouse had to crush Nikolai Tesla. you can’t meter wireless power.
It’s how capitalists think about land, water, air, etc.
… And violently attacking people by depriving them of these needs.