Looks expensive. The grey ones are the broken ones.
Utility scale photovoltaics just seems like a bad idea.
Utility scale coal and NG plants seem like a worse idea.
Certainly, but PV isn’t the thing to replace those.
If you agree that Coal is worse then PV, then you agree that PV should replace Coal.
Sure, but I don’t think that’s effectively possible. For example, Germany has had to restart coal fired plants even though they were deploying PV like crazy. However, nuclear power actually can replace coal. Incidentally, the good Germans have been falling for fossil fuel interests and getting rid of their nuclear plants.
Depends on how much there is, what level of the grid it’s connected to, and what the overall supply mix is. Without adequate energy storage yet, a lot of times it’s fossil fuels filling the gap between renewable output and peak demand.
That’s a huge caveat and the fossil fuel industry is happy to exploit it and prolong our dependence on them. The grids are already set up for thermal power generation, so nuclear is the way to go to really knock out fossil fuels.
Nuclear vs fossil gets in to why you don’t/can’t run all nuclear, else things would be very easy. Nuclear’s capabilities are best suited to supplying the base load/minimum demand but they can’t be ramped or dispatched, reactors basically run most efficiently at their designed output levels, so you can’t use them to balance supply and demand. The use of fossils for base load is more a thing in countries with lower regulations, usually because of things like a growing manufacturing economy (ie “global south”), but also in some extraordinary regulatory circumstances (Germany) or just because of when fossil was brought online/refurbished. Fossil’s capabilities are like the opposite and they are most efficient and economical used for load-following, which is even more important with renewables you can’t dispatch.
So fossil is still the main control lever for reliability, and that’s the crux of why a suitable replacement technology isn’t available yet. If it was simply a matter of output level then we’d have no problem. Mitigations to reduce use of fossils when demand is high can even be things like a demand response/dr program for transmission-connected facilities, where they are incentivized to reduce their use during times of high demand. Basically instead of having a higher energy price and all this generation online, you take a bit of what that price would be and use it to incentivize consumers to reduce their demand. Smart stuff but fossils are still a thing with that and if storage could replace them we could easily just have nuclear+storage, even smaller nuclear like those SMRs/small modular reactors.
Another massive consideration with all of this is the logical location of each type of generation at the transmission level. In the event you might have to bring the grid back from 0, or even just handle expected equipment failure, the specific location in the logical grid where types of generation is attached has to consider the capabilities of each type of generation. For example in a blackout situation you can’t just start a nuclear generator when the demand is effectively 0, you have to bring generation and loads online from scratch in very increments initially. During the 2003 northeast blackout there were opinion articles complaining about how the casinos were online before neighborhoods, ignorant to the fact those casinos were instrumental in providing an initial load on the transmission grid.
What are you saying, that fossil fuel power plants, presumably quick responding natural gas fired ones, will always have to be incorporated into a power supply mix? If it is just for emergencies, that seems like a reasonable compromise. Would it even be considered part of the mix in that case? Still, I’m not convinced that that would really be necessary. Couldn’t a properly sized variable load be sited at each nuclear power plant to the same effect? Couldn’t it be as simple as sending a little bit of steam to small turbines that are just for grid start up and then venting the rest?
Not that fossils/natural gas are required per se but their capabilities. Some places like Norway and Quebec are geographically blessed with distributed hydro that can fill a lot of that need. The variable load for a nuclear in that case could be many times larger than the generator itself but I’m not aware of any studies on that. Kinetic storage with massive flywheels is maybe the closest thing to that, or even batteries. You can ramp nukes by venting steam but that heat can cause environmental issues. Similar to hydro how their capabilites are reduced based on environmental factors like handling spring runoff.
There are some very recent reports out of the Ontario regulator who are dealing with this exact issue right now. Long term demand increasing for the first time vs carbon legislation, and the mandate to have a reliable grid.
That’s a really interesting engineering challenge. If you have any links handy to articles explaining the situation in Ontario please share them.
Why do you say so?
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That’s a solid negative. Sorry you’re being downvoted to hell. You might have some points we could all talk about.
Thanks. I do not take it personally at all.
PV isn’t super efficient. It’s great on a rooftop because the space isn’t being used for anything else, but for grind-scale there are other solar options, such as concentrated solar thermal arrays that drive heat engines.
Solar thermal systems can also store and retrieve excess energy using molten salt, allowing load balancing without needing batteries.
This. mirrors focused on a boiler work best, but then you get random fried birds…
Why
Too much surface area and too far away from where people live and work.
I imagine it’s one of those case by case things. Plenty of rural areas can use modest setups to power several properties. There are all kinds of communities out there where different solutions work better than others.
For sure. I think photovoltaics make sense for small scale installations close by to (or on top of) where people live and work. Also, spreading out photovoltaics helps to mitigate the effects of cloudy or destructive weather.