That setup is a dream for a lot of people, but it's not always easy to make happen depending on state regulations (and how powerful the utilities there are)...
Since the local power company here is only paying 10 cents per kw for solar power (which they resell at greater profit), I decided to run a small crypo miner and I still have excess power on a 22kw system.
I don't know of anywhere where its not legal to be solar powered but there were several thousand in costs associated with engineer plans and permits.
I think this is a common reason for disappointment in solar incentives. At least half of your power bill pays for transmission, and the half that pays for generation needs to be constructed such that the overall supply must meet the demand at all times, rather than simply supplying a number of kWh per day regardless of instantaneous demand. You can’t consider the “price” per kWh that you pay commercially to be the value of supplying a kWh to the grid, it’s much more likely that the utility is making a (subsidized) loss paying you 10c per solar kWh.
Electricity on the local distribution node has a value equal to the cost of generation plus the distribution. That's the value of it, what we pay. So by supplying the kWh locally to neighbors, the grid costs have been avoided. But the value is still the same.
Now, the T&D infrastructure has already been built, and the utility wants to get paid no matter what, but if they were a private company and not a monopoly, they wouldn't have a right to get compensated for their investment no matter what, because every company buys capital at risk. And that's for the good of the economy.
There needs to be some sort of forcing function to incentivize this cheaper form of power delivery, that avoids a lot of transmission and distribution costs. And that forcing function is the price that we pay those who generate the electricity.
The utility of course loses on every kWh they don't generate, because they want to sell more electricity. However, since they have a monopoly, we need other regulation to ensure that innovation that results in lower overall costs actually results in lower prices for consumers.
So far, the utilities have snowed the public and the PUCs such that they get away with murder on this transition. We need a grid, but we do not need the utility. And if the utility can not come up with a business model that works as a regulated monopoly when we have local generation, then we need to change the regulatory model, most likely eliminating the monopoly.
There's a lot to learn from Texas here for the rest of the country.
The infrastructure has not “already been built” - it is constantly under expansion and maintenance, and the bonds used to fund construction also need to be repaid.
I think your mind frame is that the reason the grid is not smart enough to pay you what you think your excess unreliable power is worth (which you stated to be the entire retail cost of power, including transmission and distribution) is because of incompetence and corruption of the utility monopolies. I think that is a pretty uncharitable take. It’s a hard problem and people generally want reliable and cheap. You can’t make microgrids reliable and plentiful without a ton of diverse generation (which already exists on the macro-grid) OR a ton of storage, both of which are very expensive. It is a problem worth solving but it needs to be considered with a realistic view on what people are actually paying for when they pay their power bill.
Grids are sized for peak, and without solar that peak is midday in most places, meaning that distributed behind-the-meter solar makes the grid cheaper.
Utilities, when they argue that solar is worth less, are not arguing on the merits of the issue but only selectively advancing arguments that benefit them. They will never present the totality of the issue.
It is up to others to push back against utilities' narrow views with a more complete view of the picture and what's possible.
The United States electric grid data is freely available and pretty neat: https://www.eia.gov/electricity/gridmonitor/dashboard/electr... Choose a grid or a state to get regional time and you can see that region's peak will usually be 4-7pm. You can even see that weekend peaks are a bit lower, and that there's a second peak at ~10am when people get to work.
https://www.caiso.com/Documents/CaliforniaISOPeakLoadHistory...
(Note also in your visualisation that all times are Eastern and should be adjusted for different localities. And if you go to a summer week rather than a winter week, you'll find the true peak, which is much higher, and which has a pretty standard curve with a peak that overlaps sunlight hours.)
They have this summer's data too, though no way to link directly, and it still peaks at ~7pm: https://i.imgur.com/16mssuH.png . Using the 16th as an example, a peak demand of 44,008 megawatthours @ 20H PDT. Comparing that to their generation graphs, which you can separate into sources, like solar. On the 16th, peak solar generation is at 11 @ 13,201 megawatthours. By 6PM, it's down to 853 megawatthours. By peak time, it's nothing. My own residential solar matches that curve on that date.
