Balcony solar panels can save 30% on a typical household’s electricity bill and, with vertical surface area in cities larger than roof space, the appeal is clear
Microgeneration makes way more sense to me. If you generate the power where it is used without pollution, we should. The unfortunate piece is we have to many landlords who’s interest are too divorced from their tenets to put up more microgeneration
Grids work on economies of scale. The bigger the better. Ask anyone who lives on an isolated island for their power bill. That’s why it was such a big deal when the Baltics switched from the Russian grid to the EU one.
Bigger grid = more intertia&redundancy = less likelihood of failure, more options, lower costs.
Electricity isn’t like chicken eggs. Transporting it is for all intents and purposes free. The network is expensive, but whether your house is pulling 1 A or 5 A is a non-difference to your utility. So to think local generation is “better” is a complete fallacy. Unless your house is fully disconnected from the network (not “net zero”, disconnected) then it’s not helping to generate power locally. Like someone else said, it’s actually way more expensive per kWh than grid-scale solar.
Now this would all be a “you” problem, except the big problem with microgeneration is that current tech is “dumb”. It’s either pushing power on the network, or sometimes tripping if the voltage goes above 250V or so. Which actually happens in rich neighborhoods on very sunny days where everyone is pushing power.
What this means for the operators is that on very sunny days, they cannot do anything but account for the extra residential solar power. Which might mean they have to very quickly spin up or down alternative power generators which were not meant for this. Or they might be dealing with complex issues with current flowing the other way than designed and large voltage fluctuations on specific parts of the network that don’t have the necessary infrastructure to “dump” that extra solar somewhere else.
The end result is that, counter-intuitively, microgeneration is one of the many failures of the neoliberal electricity market. It’s more expensive and more disruptive for society than if those solar cells had been put to use in grid-scale solar production. They only end up where they are through political mismanagement and misaligned incentives (e.g. net metering which does not account for negative externalities).
I am sorry, but your ideas about how these things work are ignoring a lot of issues.
First of all you have significant losses in the distribution grid. This is minimized the higher your voltage is, which is why longer range grids run on 110 kV and more. Then you have an intermediate level, typically 20 kV. Finally you get your local distribution with 220/230V. Also “current flowing the other way” does not exist in AC, because the “direction” changes 50x per second.
Then you only have a limited transportation capacity, so moving a lot of electricity from a central plant of course costs a lot of investment and maintenance. The idea that “Transporting it is for all intents and purposes free” is completely out of touch with the reality of the electrical grid.
But it gets worse. The more producers and consumers you have, the more you will need to balance fluctuations in production and consumption. This is why traditional grids were built around having a high baseload, with incentivizing high demand industries to connect, stabilizing demand. For renewables this is completely different, because renewabls will fluctuate. So the more energy you run through the centralized grid, the more short and medium term storages you will need to provide and the more investment and running costs you will have.
You mention this with there being too much production on the local grid and then in another place also needing to react to this. This is not a problem exclusive to local grids. It is a problem for any level of the grid with integrating renewables. Note how the article also mentions the limit of 800W without requiring a permit.
Finally in the long term we need to make the demand more flexible to production. So if the sun shines and the wind blows, household appliances should run, the fridge should cool a bit stronger, and the water heater heats up for the evening shower… Having a responsive demand with millions of agents can easily lead to overshooting, so that the demand spikes up far beyond supply, because every consumer reacts at the same time and it doesn’t temper out.
This problem is much smaller, if every household can directly see their own production and consumption and already limit how much excess goes into, or is demanded.
So microgeneration is part of the solution and not a problem like you make it out to be.
If you generate the power where it is used without pollution, we should.
Generators take space, require maintenance, and have a certain optimal capacity that isn’t necessarily hit on a given roof.
For wind energy in particular, the bigger the turbine, the more yield per $ spent. If you go out to Corpus Christi you’ll see these enormous turbines - $10M to $50M / ea - that generate on the order of $24 to $75 per MWh, or $.024-.075/kWh. Home wind/solar don’t get anywhere close to that.
Prime placement of units, distribution across a wide area, and a degree of storage capacity means you’re going to get better and more consistent yield.
But people will always be interested in generating their own, just like we don’t use communal bath houses, or community heating, or unfortunately mass transit. Yes, group services can be a lot more efficient and more reliable but they’re also out of your control and become an ongoing cost
Who is we? Lots of places do communal bath houses. Japan has an entire industry around it. Mass transit is also highly prevalent.
Yes there will always be some level of individual desire to do things or need in some cases but communal projects are useful and common I don’t get the dismissal of that for energy creation something we long ago figured out was better to be done at scale and distributed after.
This is neoliberalism and treating it like it’s the only way to exist. It’s a failure of consideration or imagination. Either way your take is not right for that.
Transformers, power lines, roads, trucks, and maintenance teams to move from large scale plants to houses also doesn’t grow on trees, but if maintenance in remote places doesn’t happen it can burn a lot of them.
Sometimes large scale plants make sense, but as the back up too microgeneration where the costs of infrastructure to move from unpopulated to populus areas make sense.
I am also a fan of less inverted power in microgeneration though. More and more of power usage is DC anyways. The need to convert to AC as much IMHO, but that is my far more radical take
The reduction of infrastructure and leveraging existing buildings without reducing their existing utility vs converting a new space to be a dedicated power plant plus the infrastructure to move power from less populus (normal case because the cost of populus land is high due to demand) to more populus space.
I also idealogically support it because it makes more controllable by people and less controlled by an outside entity (a corporation/state).
Microgeneration makes way more sense to me. If you generate the power where it is used without pollution, we should. The unfortunate piece is we have to many landlords who’s interest are too divorced from their tenets to put up more microgeneration
Grids work on economies of scale. The bigger the better. Ask anyone who lives on an isolated island for their power bill. That’s why it was such a big deal when the Baltics switched from the Russian grid to the EU one.
Bigger grid = more intertia&redundancy = less likelihood of failure, more options, lower costs.
Electricity isn’t like chicken eggs. Transporting it is for all intents and purposes free. The network is expensive, but whether your house is pulling 1 A or 5 A is a non-difference to your utility. So to think local generation is “better” is a complete fallacy. Unless your house is fully disconnected from the network (not “net zero”, disconnected) then it’s not helping to generate power locally. Like someone else said, it’s actually way more expensive per kWh than grid-scale solar.
Now this would all be a “you” problem, except the big problem with microgeneration is that current tech is “dumb”. It’s either pushing power on the network, or sometimes tripping if the voltage goes above 250V or so. Which actually happens in rich neighborhoods on very sunny days where everyone is pushing power.
What this means for the operators is that on very sunny days, they cannot do anything but account for the extra residential solar power. Which might mean they have to very quickly spin up or down alternative power generators which were not meant for this. Or they might be dealing with complex issues with current flowing the other way than designed and large voltage fluctuations on specific parts of the network that don’t have the necessary infrastructure to “dump” that extra solar somewhere else.
The end result is that, counter-intuitively, microgeneration is one of the many failures of the neoliberal electricity market. It’s more expensive and more disruptive for society than if those solar cells had been put to use in grid-scale solar production. They only end up where they are through political mismanagement and misaligned incentives (e.g. net metering which does not account for negative externalities).
I am sorry, but your ideas about how these things work are ignoring a lot of issues.
First of all you have significant losses in the distribution grid. This is minimized the higher your voltage is, which is why longer range grids run on 110 kV and more. Then you have an intermediate level, typically 20 kV. Finally you get your local distribution with 220/230V. Also “current flowing the other way” does not exist in AC, because the “direction” changes 50x per second.
Then you only have a limited transportation capacity, so moving a lot of electricity from a central plant of course costs a lot of investment and maintenance. The idea that “Transporting it is for all intents and purposes free” is completely out of touch with the reality of the electrical grid.
But it gets worse. The more producers and consumers you have, the more you will need to balance fluctuations in production and consumption. This is why traditional grids were built around having a high baseload, with incentivizing high demand industries to connect, stabilizing demand. For renewables this is completely different, because renewabls will fluctuate. So the more energy you run through the centralized grid, the more short and medium term storages you will need to provide and the more investment and running costs you will have.
You mention this with there being too much production on the local grid and then in another place also needing to react to this. This is not a problem exclusive to local grids. It is a problem for any level of the grid with integrating renewables. Note how the article also mentions the limit of 800W without requiring a permit.
Finally in the long term we need to make the demand more flexible to production. So if the sun shines and the wind blows, household appliances should run, the fridge should cool a bit stronger, and the water heater heats up for the evening shower… Having a responsive demand with millions of agents can easily lead to overshooting, so that the demand spikes up far beyond supply, because every consumer reacts at the same time and it doesn’t temper out.
This problem is much smaller, if every household can directly see their own production and consumption and already limit how much excess goes into, or is demanded.
So microgeneration is part of the solution and not a problem like you make it out to be.
Generators take space, require maintenance, and have a certain optimal capacity that isn’t necessarily hit on a given roof.
For wind energy in particular, the bigger the turbine, the more yield per $ spent. If you go out to Corpus Christi you’ll see these enormous turbines - $10M to $50M / ea - that generate on the order of $24 to $75 per MWh, or $.024-.075/kWh. Home wind/solar don’t get anywhere close to that.
Prime placement of units, distribution across a wide area, and a degree of storage capacity means you’re going to get better and more consistent yield.
But people will always be interested in generating their own, just like we don’t use communal bath houses, or community heating, or unfortunately mass transit. Yes, group services can be a lot more efficient and more reliable but they’re also out of your control and become an ongoing cost
Who is we? Lots of places do communal bath houses. Japan has an entire industry around it. Mass transit is also highly prevalent.
Yes there will always be some level of individual desire to do things or need in some cases but communal projects are useful and common I don’t get the dismissal of that for energy creation something we long ago figured out was better to be done at scale and distributed after.
This is neoliberalism and treating it like it’s the only way to exist. It’s a failure of consideration or imagination. Either way your take is not right for that.
Spas and apartments and buses/trains do absolutely exist. Only the former is considered “luxury” in the US, though.
Wasn’t Solar City’s whole gambit to effectively buy everyone’s roofs and lease them back for a fraction of their real market value?
I don’t think you escape “Own nothing and be happy” just by throwing up a few hundred watts of solar on an extension cord.
welcome to the land of windmills
These microinverters aren’t made of fairy dust. Doing this stuff at utility scale uses a lot less nasty minerals and chemicals.
Transformers, power lines, roads, trucks, and maintenance teams to move from large scale plants to houses also doesn’t grow on trees, but if maintenance in remote places doesn’t happen it can burn a lot of them.
Sometimes large scale plants make sense, but as the back up too microgeneration where the costs of infrastructure to move from unpopulated to populus areas make sense.
I am also a fan of less inverted power in microgeneration though. More and more of power usage is DC anyways. The need to convert to AC as much IMHO, but that is my far more radical take
Makes sense mathematically or you think makes sense?
Both.
The reduction of infrastructure and leveraging existing buildings without reducing their existing utility vs converting a new space to be a dedicated power plant plus the infrastructure to move power from less populus (normal case because the cost of populus land is high due to demand) to more populus space.
I also idealogically support it because it makes more controllable by people and less controlled by an outside entity (a corporation/state).