In the case of PG&E, they have to pay for killing a bunch of people and burning down some towns, so they’re passing the expenses onto everyone else. Privatize the gains and socialize the losses baybeee. Gotta love state sanctioned monopolies.

Nah fam, here in Cali, you get charged extra for solar.

You’re charged a monthly fee to be able to sell your excess energy back to the grid. But you can’t opt out and disconnect from the grid, because CA regulations require all homes to be connected to the grid (probably for emergencies).

And pay pennies on the dollar for your excess energy.

I’ve heard that in fees alone, you still end up paying around $100/mo even if you’re breaking even on energy (excess sold during the day >= grid consumption at night).

Ohh, and it’s $0.53 / KwH during peak hours. Off-peak is $0.50, saving you a whopping 3 cents per kwh!

And then there’s super off peak at around $0.22 which is like 10pm-5am (might be off by an hour or two), which is only good to do like one load of laundry before bed, and charge an EV over night.

Except people are going to cheat like they always do

Id like to visit, I love long nights and the cold.

If supply is higher than demand, then getting rid of that excess supply costs money, and the producer might have to pay someone to take it away

That is all absolutely correct, and that is all completely irrelevant. That scenario only exists after shaping efforts have failed to match supply and demand.

The purpose and intent is to sell power at a profit. Where demand cannot be increased enough for rates to remain profitable, demand shaping has not achieved its intended purpose. Negative rates are not an example of demand shaping. Negative rates are an indication that demand shaping has failed.

It applies to grocery stores that over order inventory of perishable goods

The dumpster behind the grocery store is “disposal”, not “demand”. The solution to negative rates is not for the power companies to find a dumpster in which to dispose of their excess power.

The supply shaping solution to this problem is reduced solar and wind production, augmented by flexible peaker plants, and drawing on previously stored grid power.

The demand shaping solution to this problem is flexible loads that can be added or removed from the grid as needed, and storing grid power for future use.

The “places with different weather conditions” are across the equator. Everyone in the northern hemisphere has summer at the same time. The best we can do with interconnects up here is shift the problem around by a couple hours.

Now, if we convert that excess power into cryogenic hydrogen, load it aboard a tanker, and drive that tanker to the end of the earth currently experiencing winter, they can then burn it in gas turbine generators.

Hell, we can put such generators on ships and move them back and forth every 6 months.

Sure, not to mention they should probably cut out all the electric stuff that eats up like 80-90% of the suns efficiency and use mirrors directly. I mean if you gave the “battery” close.

Nuclear isn’t particularly good for leveling the daily demand curve, no.

But, it can be very useful for leveling the seasonal variation. Slowly ramping up nuclear production to make up for the short winter days of December, January, February. Slowly rolling it back for the long summer days of June, July, August.

Nuclear is also an excellent option for meeting overnight demand.

But you’re right: it is terrible for making up for inclement weather, and other short-term variation. We will continue to require short- and medium-term storage. We will continue to need peaker plants, although we will hopefully be able to fire them with hydrogen instead of carbon-based fuels.

ok so, solar, naturally produces the most power during the daytime, when the sun is up, which in places where it’s warm is when you get the most significant energy bump due to AC and what not. There is also a bit of a trailing period in the evening where people get back from work and cook dinner/relax and whatever. But that’s not super far off from noon peaking in the grand scheme.

Nuclear plants are baseload, so they produce 100% power output for 100% of the time they exist (at least in an ideal world) usually they have a capacity factor of about 80-90% though i’ve seen plants go past 100% before. This load is super useful for leveling out the power demand overnight, as well as shortening the day time peak loading a little bit. As well as providing a very consistent and regular source of power than can be used for things like hydro storage, and battery charging for example. So paired with a large thermal battery a nuclear plant might even be able to adapt to the midday loading cycle pretty functionally, as it can recoup most of it’s lost energy over the night, through the baseload averaging out.

Nuclear plants are actually really well suited to be used with a thermal battery solution (given that they output thermal power, obviously) It’s more common for modern plant designs to integrate thermal battery technology to some degree, but those are all gen IV designs, so they don’t exist yet.

As for wind, i’m not sure what the effects on it during the day/night cycle is, but i imagine during the day they generally produce more power, though they will also produce some power over night. So those are a relatively low yield but high regularity power source, similar to nuclear, however you have much greater control over them as you can change the blade pitch during rotation in order to increase/decrease output as needed. Though ideally you would always be outputting, as often as possible.

Even in the event that you have a total grid blackout, nuclear plants are a potential source of blackstart power sources, though presumably it’s not nearly as big of a deal in a solar plant for example. It’s unclear how much those rely on being secondary producers, or how well they can function as primary producers to me. Presumably it will be dealt with at some point if it hasn’t been already.

yeah, but if you’re not doing it in a complicated manner you could just stick an IBC tote full of water in the middle of your home and it would provide a similar effect.

Personally i would probably just install a ground loop, and then use that to provide a source for heating and cooling, it’s also very consistent year round, though if you live in an area of deep frost lines, or permafrost, it’s probably going to be more exciting.

The first will almost certainly happen in the next few years. Batteries have been improving kwh/kg at 5-8% per year. There are still enough lab research projects making their way into actual manufactured batteries that we expect this to continue for a while longer. It’s been at the higher end of the range for the last few years. That growth compounds every year; at 8%, you’ve more than doubled capacity in 10 years. Which is about where trucks would need to be.

we’re also moving away from wet lithium cell tech and into solid state tech, as well as other non rare metals based technologies, though those are all in the very super alpha states (except for solid state lithium cells)

nickel hydrogen might become something interesting if a company picks it up. Cheap and relatively reliable, though unconventional.

also flywheel energy storage is almost exclusively used for frequency stabilization of the grids, as opposed to actually storing energy. It mechanically couples a source of inertia to the frequency, which in an all renewable grid, is required to some degree.

I agree: transportation will probably favor hydrogen over batteries.

That being said, to pile on hydrogen, I’m not sure if I like the water demand part of it either. Coastal hydrogen production might make sense if sea water is the feedstock and corrosion/discharge can be released to the source in a manner that doesn’t lead to biodiversity death.

Then again, fossil fuel and mineral based (thermal) energy sources like coal, nat gas, oil, and nuclear all require cold water for cooling purposes. If we transition those sources to hydrogen production (and maybe use in the case of 100% hydrogen fired CCGTs that GE, Siemens, andbMitsubishi are making), there might actually be increased water demand since you have hydrogen + cooling.

It’ll have it’s niche, that’s for sure. But I wouldn’t count it out.

And on the topic of better solutions, I’d love to see vertical underground pumped hydro storage pick up steam (buh dum tss). I don’t see how underground pumped hydro isn’t feasible since we already do geothermal in the same way.

There aren’t many other options for long-term storage. Massive, cryogenic storage facilities could hold summer-produced hydrogen for winter generation, or allow grid-scale energy transport across the equator.

Hydrogen reaction to oxygen in a fuel cell turns it back into water

once you burn it

You missed the point entirely. Finland has little to none solar energy. They have only wind and water energy. Same with most Nordic, Baltic and northern Poland. There is not enough solar energy provided by sun to make it affordable ( whole life cycle including utilization costs )

If you don’t know what energy output per meter is, total output and total cost of solar panel ownership, how it varies across geography in relation to equator, the fact there is no cheap way to store it (or you have to use it somehow in that very moment), it means it’s pointless to talk any further. Simple physics. It doesn’t matter though whether if it is solar, wind or water

I heard only shale gas but good to know about oil. As far as I know, USA is not one of the main oil exporters, mostly middle east countries, especially of Arab peninsula. Venezuela, Iran, too but they are under sanctions. American oil / gas, please, correct me if I am wrong serves mostly as strategic reserves so it may be that USA that it’s better for Texas to use solar energy. However, most of calculations don’t track the whole lifecycle of solar panels and their environment conditions - I mean whole energy produced for the solar panels lifespan (15 - 25 years) minus the costs of production and utilization. The analysis needs to be done per each case not mandated for all because it doesn’t make sense with the total costs adjusted like in Poland. I know many owners of solar panels in Poland and it’s not that ‘rosy’ with the solar energy savings

In Finland they’ve been developing small scale reactors about the size of a shipping container but they’re not intented to produce electricity but instead just heat water and then push it into the district heating grid. This way the powerplant would also be much simplier to produce and maintain as well as safer due to the lower pressures and temperatures it operates at. Basically a nuclear powered kettle.

SMRs (or small-scale nuclear plants in general) solve some problems with nuclear power. If you were to build a single design very often, the principles of economies at scale would apply and drive down costs.

I like the theory. But in practice there’s a couple problems that so far I’ve not seen addressed very often. First is the issue that not all costs of building a nuclear power plant can be brought down by simply having more of them. Particularly infrastructure costs can rise significantly, because instead of building one large plant with a connection to the grid, necessary buildings for operational control, infrastructure for the coolant water, roads, security etc… you have to build several instead, which multiplies the costs of these.

Then there’s the issue of personnel. You need people to operate and maintain the plant, security, management, etc… Per reactor you may need less people, but because you have so many reactors you end up needing more people overall. Most countries have a hard enough time as it is to get enough qualified staff, you’d also need to heavily invest in education for the next generation of nuclear engineers.

You also have these container-sized reactor concepts that basically promise to run themselves, requiring almost no maintenance other than the occasional refueling. But those are very much still in the concept-stage and also need to address the security issue. An unmanned container with nuclear fuel and expensive equipment inside could very well make a worthwhile target for criminals.

I like the utopian vision that nuclear promises but I worry the path to get there is full of pitfalls. I also don’t see the cost of nuclear coming down any time soon, and if we want to remain competitive in manufacturing for example, cheap energy is absolutely key.

Personally, I prefer investments in renewables and battery tech. Particularly battery tech I’m hopeful about. In theory there’s so much to gain still on that front, and it has the potential to improve so much other technology, from phones to drones to pacemakers to reliable, decentralised power. Nuclear tech is cool, but it only really promises to result in more nuclear power, rather than improvements in other areas as well. Fusion is interesting (and almost worth investing in just for the cool “it can be done”-factor) but at the same time still so far away. Too risky to rely on for now.

Especially since a lot of states turn the land surrounding the power plant into wildlife sanctuaries since nothing can be built in the safety zone anyway.

It’s like bird watching heaven at the power plant near me. I guess I just really like the idea of a power source that also incidentally protects forested areas.

Haha, I can see why that makes you more inclined to support nuclear! Though it does make me a little sad that in order to protect our forests and wildlife we first need to build a nuclear reactor next to it. Can’t we just designate them wildlife sanctuaries regardless of that power plant being there or not?

You don’t need to install X-amount of global demand. Battery/hydrogen storage can solve the issue as has been demonstrated repeatedly in various research. And with home battery solutions you can even fully decentralise it.

I don’t understand your centralisation argument, nuclear is about the most centralised power source there is. And it can be threatened, as seen in the current Ukraine-Russia war.

Solar and wind can scale up to the demand. Nuclear actually has a much harder time doing that, as materials are far more rare and expensive, and it takes much longer to build. If anything, the time argument works against nuclear, not in favour of it.

Most nuclear waste issues are vastly over-exaggerated. Most of the nuclear waste is not long term waste. It’s not things like spent fuel rods, it’s things like safety equipment and gear. Those aren’t highly contaminated, and much of it can almost be thrown away in regular landfills. The middle range of materials are almost always kept on site through the entire life of the nuclear plant. Through the lifetime of the plant that material will naturally decay away and by the time the plant is decommissioned only a fraction will be left to handle storage for a while longer from the most recent years.

Nuclear waste can be divided into four different types:

1. Very low-level waste: Waste suitable for near-surface landfills, requiring lower containment and isolation.
2. Low-level waste: Waste needing robust containment for up to a few hundred years, suitable for disposal in engineered near-surface facilities.
3. Intermediate-level waste: Waste that requires a greater degree of containment and isolation than that provided by near-surface disposal.
4. High-level waste: Waste is disposed of in deep, stable geological formations, typically several hundred meters below the surface.

Despite safety concerns, high-level radioactive waste constitutes less than 0.25% of total radioactive waste reported to the IAEA.
These numbers are worldwide for the last 4 years:

Your entire argument is a fallacy of saying it is either nuclear or coal, when in reality it is either renewables or coal+nuclear.

It is the same companies that want to continue both coal and nuclear, because it requires similar components in the power plants and similar equipment for mining.

Also the same government in Germany that expanded the nuclear power slashed the build up of renewables, resulting in the long time for coal in the first place.

Stop being a fossil shill. If you shill for nuclear you shill for coal too.

If you look at the actual stats it isn’t really closed nuclear plants being replaced by coal, they got replaced by other renewables, while coal still kept going at about the same rate as while the nuclear plants were active.

I. Germany we haven’t found this sufficient deep hole since 30 years.

Not only doesn’t it follow their FUD, but their existing business cannot easily transition to it since the entire process is completely different. Oil, coal, and natural gas are all fairly similar from their perspective.