> You'd have to go to a university library and dig for hours.
If it's not online it doesn't exist. /s We really need more of these obscure pieces of knowledge put online because people don't go to the library as much as they used to.
There's so much specialized knowledge out there, but often you'll only learn about it from someone else, or a highly technical book.
Like, say you want to frame and build your own house - there's bazzilions of YouTube videos about the beginning process. But very very few about the more advanced details you need to know.
>There's so much specialized knowledge out there, but often you'll only learn about it from someone else, or a highly technical book.
I remember my mind being blown by the Cal engineering library. Endless stacks and stacks of dense foundational knowledge from the 1950s-1990s you would never find on Google. Books are massively underrated these days.
Many large academic libraries have extensive digitisation efforts, though the results more often turn up on Hathi Trust (something of a waste of electrons in my view) than anywhere truly useful.
Hathi Trust itself grew out of Google's book-scanning initiative, and is shaped (and scarred) by copyright lawsuits.
That said, I hope some number of those works also find their way to Libgen and ZLibrary.
"Like, say you want to frame and build your own house - there's bazzilions of YouTube videos about the beginning process. But very very few about the more advanced details you need to know."
Advanced? All I need is some TooBa Fours and a Larry Haun book...
At some point someone is going to figure out how to feed every scientific paper into an AI, including all measurements and formulas, and I have to imagine that is going to really make some progress towards less-than-obvious connections in knowledge.
This does bring up the issue of actual legal protections, though.
If you are training an LLM on the open web, or things posted for everyone to view for free, than that is OK I guess when it comes to legal ramifications. (Definitely not a lawyer)
When you start using data that you really don't have the rights too...and somehow someone finds out that their protected data is included in the dataset...then what?
It might be protected if you are doing it yourself, for personal (non-commercial) use. Just like you can build any patent you want for fun, but the second you try to sell it, you need permission.
Even if it is online, it probably doesn't exist either - see today's threads about communities moving from Reddit to Discord. The "cozy web" is undoing a lot of progress of the past decades. Might be that we'll all need to go to the university libraries and dig for knowledge ourselves, hoping any of the more recent experiences and discoveries end up being published as books, instead of dying in private Whatsapp groups.
> Like, say you want to frame and build your own house - there's bazzilions of YouTube videos about the beginning process. But very very few about the more advanced details you need to know.
That's an interesting factor of online knowledge - the most readily available one is the one that masses are interested the most because the views give the budget for people to care. It's also weirdy trendly, like how pandemic spawned a lot of woodworking channels coz people cooped up in their homes found a new hobby.
To add to the point this [1] random video is an example, it does go into terminology and reasoning behind each element but won't tell you what kind of lumber to get, how climate would affect that decision, how to isolate the house and a bunch of other things. You might look for them and probably find some info but at some point just looking for a dedicated book might be the saner option.
And uh, if someone knows a good one covering how to build and isolate your own shed I wouldn't mind recommendation...
Undergraduate electrical engineers learn this fact. It’s technical but in the scheme of things not all that obscure. That’s some of the value of a formal education.
I've been lamenting for many years that the dream of an "information superhighway" has basically failed.
There is so much deep information available in any large university library that is simply not on the internet at all. If you're researching any historical topic, there are at least a few solid books (and possibly hundreds) that draw from primary sources, compared to a couple pages of text on Wikipedia and very little else. You mostly won't even find ebooks.
Somehow the best, most extensive free digital resource is a podcast like Age of Napoleon, which synthesizes information from many books.
I believe that books continue to hold immense importance in the realm of internet knowledge. While the internet offers a vast array of information, books provide depth, rigor, and expert insights that are often lacking online. They are the repositories of specialized knowledge, offering in-depth exploration of complex subjects. Books provide a tangible, reliable, and authoritative source that withstands the transient nature of the internet. They remain invaluable resources, ensuring a comprehensive understanding of subjects beyond what can be found online.In addition to the significance of books, it is important to acknowledge the value of the internet in knowledge acquisition. The internet provides unparalleled access to a vast amount of information from diverse sources. It enables rapid dissemination of knowledge, facilitates global collaboration, and offers interactive platforms for learning. The internet also offers convenience, allowing individuals to access information anytime, anywhere. Its dynamic nature allows for the dissemination of up-to-date research findings and fosters the exchange of ideas across disciplines. The internet complements books by expanding the accessibility and availability of knowledge in an unprecedented manner.
And one challenge (as is so often true in software) is knowing what to know. It's not particularly intuitive that grid balance is necessary if one's entire experience with electricity is "I plug in a machine and the power comes out of the wall."
It's actually a minor plot point in Stephen King's "The Stand" that after a viral apocalypse wipes out most of humanity, the survivors try to restart the electrical grid in a town.
The first attempt proves fatal because they haven't properly isolated the circuits throughout town, so when they connect the plant to the main grid the plant's generators explode from trying to support the load of every home where someone died spontaneously while running a hair dryer.
That book, well the most enjoyable parts for me of the 1000 pages or so besides the intro (king is great at starting plots) was the whole power station business. Otherwise 900 pages of fumbling with a plot. I should go reread it
The internet has made "random fact retrieval" much faster for sure. In fact, I notice movies seem... less dumb than they were a few decades ago, and I have a theory that that is why.
But to really know something, you have to have studied it, even in the modern era. I can read an instantly-available wikipedia article about power generation, but I'm only scraping the absolute surface.
You are forgetting museums. Before the internet was widely available I visited the Electricity Museum in Lisbon which is a repurposed power station. They had a simulator of a power station with operating instructions and, according to the staff, it was realistic. I spent quite a few hours trying to startup the damn thing but it was too complicated. It was a bit like a game but with very low tolerance and a long list of steps which gave me quite an insight into how complex that field is.
One question about the grid I've never wrapped my head around:
So the entire grid is in phase, by which I mean every generator, load, &c is operating on the same AC pulse (handwave-handwave ignoring smaller loads, transformations, etc.). But that phase isn't instantaneous; it's near-light, and the grid is long enough for that to matter in places.
So every point in the grid can't be perfectly in phase with every other point, right? Because we have both lightspeed delays and loops, so even if point A is receiving power from two substations in-phase, point B (with different lengths of wire to those two substations) should be receiving it out-of-phase, right? How do we balance that in the grid?
I wonder if the solution is similar to routing traces on PCBs where there's high-frequency stuff going on - you add and subtract length from the line pairs until the phases match up. Sometimes the dumb solutions are the best ones?
Weird how all the replies so far misunderstood your question.
There's a lot of high-frequency stuff going on, but the line length is so much that most of it irradiates away. You don't go adding more line to compensate anything, but you do add filters at some places.
In most cases where you do have more than one source (say datacenter for redundancy) you don't just tie them together directly, in simplest config you'd just switchovered from one to another if one failed.
Imagine you've got two cables coming into your factory. One is 500 meters longer than the other. That would mean that the sine waves are 0.01% out of sync.
I'm pretty sure for home electronics the phase difference doesn't even matter that much. Everything sensitive seems to be converted to DC anyway.
Maybe it matters in large industrial applications, I have no idea. But I also imagine in their situation it's probably pretty straightforward to clean up the power supply.
Would be fun to see this turn up as a case study for two identical assembly lines driven by motors. One on the “fast” frequency and the other on the slow.
In my imagination, the specialists are brought in only to learn that the RPMs in one motor were juiced because someone didn’t practice cable management
In reality, the phase difference is always small, and it ends up not mattering.
But... If you had a worldwide electricity grid running at 60Hz, it would start to matter, and you would make sure to use local capacitors/inductors to make phase shifts to make sure that you didn't have big circulating currents in loops (they just are wasting energy)
you would have to be in a location to straddle synchronous grid. There may be some places that allow that. Otherwise, the two sources are already in approximately in phase anyways. To put it simply though, you put some devices on one feed and some devices on another feed. So it is a non-issue.
If you have local generation you want to combine with grid power you usually just sync your local generation to the grid. If you don't want to do that you can just use a DC intertie that is local. Basically you'd have two AC -> DC converters and a single DC -> AC converter.
An airport or hospital might be fed from two different nearby substations.
The substations are probably fed from the same transmission lines with parallel circuits.
The substations will have transformers with the same winding configuration for a consistent phase shift from transmission to distribution level voltages.
The airport or hospital will procure transformers that have the same winding configuration and impedance so the phase shift and voltage drop across them will also be the same.
The low voltage windings of the transformers at the hospital can be paralleled so they both feed the load. Reverse power protection would be implemented so the hospital can’t back feed the distribution line.
What phase difference do you expect in this case? What effect would it have?
I think it's more like doing the wave at a large sports stadium.
Everyone isn't always in phase with every other station's phase at that exact moment in time. They're just in phase with their local part of the grid's phase. Though amount that is different is milliseconds, not seconds as in the stadium wave example.
You can think of electrical phases like any other kind of wave: maybe like shaking a slinky. The power plant sends the phases downstream to consumers, and once it leaves the factory it doesn't know what consumers do with it (beyond detecting voltage drops, etc.).
So the grid doesn't need to balance it, no.
And from the receiving end's perspective, power will be exactly one phase out of sync if the cables differ in length by 5000 km. I'm assuming that isn't really a problem people have to worry about, but my background is in physics and not engineering (i.e. maybe there's some industrial applications that I'm not thinking of).
50Hz wave length is at ~6000 km so it frankly isn't a problem.
You'd have to have 2 different routes from same power source that differed in hundreds of kilometers in length and that just doesn't really happen. And small phase difference would just cause uneven loading
Also that power would be "used up" closer to the power source and you'd be sucking off power from closer sources.
Others answered your question. A related, but different problem is “how do you make sure a new power source you add to the grid is in sync with the grid the moment you connect it?”.
Firstly, you design your generator to have the same wave form and phase sequence as the grid.
Then, you power up your generator and make sure the voltage, frequency and phase angle of the electricity it generates matches that of the grid.
The moment that’s (more or less) the case, you connect the grids, preferably on a zero crossing. That Wikipedia page describes a setup with incandescent bulbs that can be used to manually detect that moment, but nowadays, it’s done using electronics.
> So every point in the grid can't be perfectly in phase with every other point, right?
not in phase as such, but in sync.
because you only have to match your 60hz(or 50hz) to what you receive locally, so long as the waveform is reasonably stable its not that much of an issue.
Because everything is effectively a bunch of elastically linked pendulums, you tend to reach equilibrium, so long as the load doesn't act too much as a dampener
I looked this up once, and the answer is: They basically just ignore it.
If everything is in a line, you just sync to your local phase, but if you have wires in a triangle that's impossible, and they basically just ignore it, in practice it doesn't happen often enough to cause any problems.
> So every point in the grid can't be perfectly in phase with every other point, right? Because we have both lightspeed delays and loops, so even if point A is receiving power from two substations in-phase, point B (with different lengths of wire to those two substations) should be receiving it out-of-phase, right? How do we balance that in the grid?
As far as I know, in your example, one of the two circuits will be transmitting more power from the substations to point B than the other. There's a device called a phase-shifting transformer (https://en.wikipedia.org/wiki/Phase-shifting_transformer) which can be used to adjust the phase angle of the circuits, and that way, adjust how much of the power is carried by each circuit.
(The following sentence from that article probably goes to the core of the answer for your question: "For an alternating current transmission line, power flow through the line is proportional to the sine of the difference in the phase angle of the voltage between the transmitting end and the receiving end of the line.[1]")
Ew, you mean they have to talk to a human on the telephone?
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We built a whole application to manage a certain workflow between multiple systems, and our users kept using email instead, because it turns out that the users on the other end don't check the system, but they do check their email.
For critical stuff that is not instantaneous, it's good to have both automated and human communication/confirmation. In this case, the automation is equipment throughout the grid that can disconnect a line if it falls too far out of compliance (for example, frequency drops too low, due to a sudden increase in load). As mentioned elsewhere, huge consumers get their own substation, and such equipment can be placed there.
You also have people who are drilled in following procedures, especially when failures in process become very public.
As a concrete example, if you look at an electric grid map of South Korea (here is one: https://www.e2news.com/news/articleView.html?idxno=236289), you will find that POSCO, Hyundai Steel, and Samsung Electronics have their own substations.
New Zealand had to build an aluminum plant in the 1960s and figured out it would be more efficient to bore miles underground, build turbines, install a huge power station, and wire it tens of miles to the smelting plant. It relies on a vertical drop between Lake Manapōuri and the open ocean to create the gravitational potential to turn the turbines. When the smelting station doesn't use the full capacity the power station has to immediately reduce output, otherwise it can overload the transmission lines to the rest of the grid.
This comment reminded me of a cute tool I used to have installed back in the WinXP days called "Screen Calipers". It was a super sweet tool. 100% skeumorphic :D
What percentage of a non-negligible amount of fresh water pumped/dumped into the ocean is returned to the freshwater ecosystem/loop given, say, 10 years?
Plenty of places can do this with essentially zero environmental impact. If it rains a lot and the rain came from ocean evaporation and the natural water route was a big river quickly back to the ocean, you can pretty harmlessly divert a portion through hydroelectric.
Not everywhere is the American west where it doesn’t rain a lot and water sources are being used way past their capacity.
The lake is in a reasonably remote part of the country, in an area with exceptional high rainfall. Plenty of other sources of water. Most of that fresh water was going to flow out into the ocean anyway, this just sends it via a more direct route.
The longer route (which actually flows next to the farm my mum grew up on) doesn't even go near a major population centre. The largest town (Tuatapere) has a population of 500 people.
A slight aside, Tiwai is now now owned by Rio Tinto. Every few years Rio Tinto claims the power is too expensive and they may have to closed down. Then they get a discount and carry on.
They are at it now. That place closing down would lose 1000+ jobs if n a region that doesn’t have a ton of options, the world would lose a greenish supply of aluminium and I would potentially get a discount on my power bill when I stop subsidising that massive company (that smelter uses a bit over 10% of NZs electricity).
Oh, and Rio Tinto have dumped toxic waste in various places too.
Rio Tinto is always extorting the Québec government for preferential rates on power to make aluminum. I don't understand why governments let companies hardball them like that. The c-suite and the trademarks can leave, the factory, the expertise and the market will still mostly be there, governments could invest and rebuild something they/the people actually have ownership of.
I don't understand why governments let companies hardball them like that
Moral hazard [1]. Government officials make these decisions because they can win political points by doing so. Usually, they get to take credit for being “job creators.” Opposition politicians who try to raise the issue of risks, potential debts, environmental degradation, etc. can be quickly branded as anti-jobs and their valid criticisms dismissed.
Down the road, when the chickens come home to roost, the politicians who approved the deal are nowhere to be found. Since there’s no law allowing the public to hold those politicians financially accountable for their past decisions the effect of moral hazard has run its full course, leaving the public holding the bag.
As for why (even new generations of) politicians would continue to cave to these companies’ demands: no one wants to be left taking the blame for job losses.
If they actually throttle them during peak usage aluminum plants should get a discount. Because much of the electrical part is more or less the equivalent of charging a shitty battery, it can be throttled really easily and being able to eat up extra capacity during low electrical usage is really environmentally friendly, as is aluminum as a material for making stuff being infinitely recyclable.
Efficient use of capital and resources. Idle power plants waste resources and make things more expensive.
Consider every dollar spent as an interest baring loan. Spending money on a power plant not used wastes it and making everything more expensive.
Scalable loads makes the return on investment for variable load renewables and constant load nuclear much better. The most expensive power are the peaker plants that have to run only a handful of hours per day.
More scalable grid connected loads like aluminum processing makes building capacity and especially renewable capacity cheaper.
In the example here, the power plant was made to supply the smelter. The taxpayer built the plant for the smelter and now Rio Tinto are dictating the power price.
The power plant can’t easily supply the National grid, as the lines aren’t there with sufficient capacity. The lines are being built but Rio Tinto have used these facts to get to a position where they are subsidised by the rest of the country.
The power plant also has a finite life, and it’s passed its midpoint.
Additionally, that smelter has also had government subsidies to stay open. I see no great loss in letting it die.
Oh Cool, there's a very similar setup in northern BC. The Nechako reservoir drains through tunnels drilled under the Coast Range and generates powers in Kemano. Most of the power goes to a smelter in Kitimat.
Thank you for sharing, I grew up next to a hydroelectric dam and the time I spent on top of it for general tours and special tours with our scout group is something I will always remember.
My brain however has in the past created incredible nightmares based on the scale of what I experienced there. I just _had_ to see what the tailrace output looked like and was not disappointed by this nightmare fuel: https://www.youtube.com/watch?v=qlhSzs4JXE0
Why is the video nightmare fuel? I have zero context, but I assume it's nightmare fuel because they could suddenly let out a crap-load of water through there and you'd get smashed to smitherines?
Yeah basically. I guess it’s mostly me on personal nightmare fuel… The turbine output chute of the dam I grew up with was so rapid and voluminous that standing next to it was like being caught in a tsunami and the white water extended hundreds of meters from the dam. I spent a lot of time in the river in boats and jetskis and there were a number of signs and buoys ominously warning of certain death.
The scale of it all was quite terrifying to my young mind as I imagined all the unseeable hazards beneath the water’s surface, on which it capitalized during my sleeping moments.
X( These are pretty abundant in the Jordan River (for feeding canals in Utah where I live now) and have sadly claimed a number of lives. Indeed, I do not like them at all.
Many years ago, before I was twenty, I hitched a ride on a pearling boat with a sea kayak to shoot the horizontal falls in the Kimberley (Western Australia) which was then (~1980) unvisited and well off even the remote adventure tourism tracks although much better known now [1][2].
It remains today as both one of the most exhilarating and the stupidist things I've done.
Equatorial tide changes through a narrow gorge are insane enough before adding in salt water crocodiles on one side and sharks on the other (well, both on both sides to be honest).
Woa cool! I'm really glad there are other nerds out there wanting to know the same things as me (and having the stones to do it). I'm glad he got out alive.
Iceland did something similar in the highlands in 2002-2008, for an Alcoa smelter.
Several dams in the highlands create multiple reservoirs, the water is then fed through kilometres of tunnels before it reaches a ~400m vertical penstock to the Fljótsdalur underground power station (the power station is about 40km / 25mi inland, while the smelter is on the coast)
Relevant story: back in grad school, I did a few experiments in the (old) MIT wind tunnel, now torn down.
Before starting up the fans, the guy running the control booth picked up the phone and had a short conversation, roughly
"Hi, this is [name] at the wind tunnel; can we turn it on?"
[someone on the other end replies]
"Great, thanks."
I asked who he was calling, and he explained that he had to check with the power company before powering it on. This was mid-winter, so grid demand was low; apparently during the summer (when everyone has ACs on), the start-up load could cause brownouts!
I was touring a datacenter and they got the reverse call; California was experiencing some power issues so the local electric company would call them and say "switch to the back up gens, we need to cut you off".
I believe this is a somewhat common arrangement for industrial users. The power company gives a discount if you agree to be first in line to be cut when reserves are at a minimum.
Whoa, ever since learning about this, I randomly tell people about this. Noone ever seems to understand my fascination with this distributed grid of spinny things interacting.
Before quartz oscillators, clocks would use the grid as their time reference. It can be done mechanically via a small synchronous motor and some gears. I'm not sure if it's still the case today, but the grid frequency used to be managed through the night so those clocks were most accurate in the morning (for peoples' alarm clocks)
Some systems still use grid frequency for timekeeping.
If you own a mechanical rotary timeswitch, it's got a synchronous motor spinning 50 or 60 times a second, then a series of gears, gearing it down to 1 rotation per day.
Yeah. Some years back there was a structural underfreq event for a couple of weeks on the European grid. My microwave phased out of time by several minutes, and then phased back. Was fun to observe.
Interestingly, my country (Brazil) doesn't seem to regulate the grid frequency for use as a time reference, at least as far as I could find. So if this happened here, and if the microwave used the grid frequency for its clock, the clock would stay wrong.
A switch such as would be present in an older clothes dryer or washing machine. The newer ones use electronically controlled relays but I could see the designers skipping the quartz oscillator because the time difference comes out in the wash.
This isn't just a "before quartz oscillators" thing; it's still in extremely widespread use today since quartz oscillators still cost some fraction more than $0. And, it's not always mechanical, there are a lot of all-in-one timekeeping/clock chips that use AC as the reference frequency for their internal oscillator/PLL.
Almost all cheap / "simple" consumer mains appliances, including non-"smart" microwaves, ovens, alarm clocks, etc. still use mains frequency as their time reference.
Due to the growing complexity of power grids and in Europe, international power-grid politics and infighting, the grid frequency is becoming less stable and you see these devices fluctuate badly more often than they used to. https://hackaday.com/2018/03/09/europe-loses-six-minutes-due...
> Almost all cheap / "simple" consumer mains appliances, including non-"smart" microwaves, ovens, alarm clocks, etc. still use mains frequency as their time reference.
I find this incredibly hard to believe. Crystals are incredibly cheap and waaaaaay more accurate than anything that the grid does.
If you're not an actual motor, sensing the grid is both an engineering challenge and a non-trivial expense.
To my understanding, the grid is managed to have a fixed number of cycles per day, which would make it perfectly accurate. A cheap crystal can easily lose a few seconds per day. And given how hard it is to keep 60 Hz noise out of circuits, I can’t imagine the sensing would be difficult.
The trick is that so many devices use DC power bricks now, because it outsources the UL-or-whatever compliance, and makes FCC easier too. It's much harder to sense 60Hz downstream of that.
The grid is managed to an exact _average_ frequency. In this way, it essentially acts as a very slow transfer standard for GPS. I own a clock with a 60Hz motor, and while it can vary by anywhere from 5 to 30 seconds throughout a day, this error never accumulates and it recovers back towards zero after any excursions within a day or two.
I have one of those little “binary clocks” (it technically displays in BCD, but it’s still “binary”, right?). When I first set it up, it was running really fast —- like it was gaining hours over the course of a day.
Turns out it had a button combo for “switch between 50Hz and 60Hz mode” that was similar to its combo for (what I thought I was setting) “switch between 12- and 24-hour mode”. (I think the 12/24 switch was “hold the hour button down while plugging in” and the 50/60 switch was “hold both buttons down while plugging in”.)
I studied electrical engineering, but power engineering isn't a course that I took. The most enlightening quote I've heard about this was a response to a question:
"What happens when I turn on an electric device in my house?"
"A turbine in a power plant spins more slowly for just a moment."
Heh, it's easy to model when you have a few generators, especially when one is much bigger than the others on the grid. But what's fun these days is you can have an absolutely huge number of generators. Keeping things in phase just seems insane to me.
Practical engineering has a great video about power black starts that give some insight into this complicated machine.
It's a bit like they are all connected together by gears. All the generators are in phase.
The most difficult bit for an operator is to make sure the generator is synchronized before they actually connect it. Only after it's synchronized can they start actually feeding power in.
You can't just turn these things on and off at will like a regular motor. To extend the gears analogy, gears need to be synchronised before they can engage - just like synchronous AC generators.
It's not hard to keep it in phase. Once it's synchronized it is actually rather hard to not keep it in phase.
Generator spins at 50hz
Motor spins at 50hz
Add load to the motor, it starts slowing down both itself and the generator. Generator governor increases input energy, frequency goes up. Both are in phase all the time.
Remove load, both start spinning faster. Reduce governor to regulate it to 50hz again.
It's a bit harder with inverters but the idea is similar, you follow the grid phase and if you want to send energy to the grid you will be slightly early to the grid phase and if you want to take energy from the grid your phase will slightly lag.
As another commenter says, it's actually easier the more generators you have because the rotational inertia of all the spinning masses is larger. This (and the storage problem) is one of the reasons that wind and solar destabalise grids - they are interfaced to the rest of the grid by converters that create ac sources - but there's no real rotating mass there, so the inertia is tiny. The result is that as we add more renewable power to the network, it becomes less able to 'roll with the punches' of loads coming on and off line.
PS One of the answers in the SO thread mentions JET in the UK. I spent a few summers there as an electrical engineering student (it's home to the MAST and JET fusion reactors). When the JET tokamak ignites a plasma, it can't sustain it for very long (we are not yet at the point of extracting enough energy to sustain the reaction). As a result they need to ignite the plasma and keep it hot. They can't do it for more than 1-10 seconds. During that time, they draw massive amounts of power - they're permitted to draw up to 1% of the UK's capacity for a short period, whilst they simultaneously dump all the energy stored in two gigantic flywheel generators housed in a nearby building. I've never been there when the flywheels are running but I've climbed around beneath them. There's nothing quite like massive engineering :)
> This (and the storage problem) is one of the reasons that wind and solar destabalise grids - they are interfaced to the rest of the grid by converters that create ac sources - but there's no real rotating mass there, so the inertia is tiny. The result is that as we add more renewable power to the network, it becomes less able to 'roll with the punches' of loads coming on and off line.
Other problem is that for renewables to be profitable you want to push all the energy out all the time, especially in peak. Even now solar installation users have problem with that when there is too many small solar installations installed on same street the voltage goes too high and the inverters just trip and stop pushing the power to the grid, losing owner money.
We just need to have more cheaper storage solutions. Technically utilities could just put a bunch of batteries near concentration of residential solar and just basically sell the service of "storing the kilowatts" to them (say "you can receive 80% of what you put into it in next 48 hours"), all while having the capacity to use that stored joules in case a peak needs to be handled
If the inertia of turbines helps cover small loads, couldn't that be scaled up with a bunch of flywheels connected to motor/generators? Seems like it would be better able to handle sudden changes in the network than batteries+inverters.
Yes - this is precisely what was trialled in the UK a few years ago. You can basically take old decommissioned generators and just take power to spin them up - thus, you've just (re)created rotational inertia on your grid. It's a bit absurd, but it does work!
During the Texas blizzard power outages, the state was supposedly minutes away from a black start scenario[0]. Estimates are that it would have taken weeks to restore power to the state owing to the complexity of syncing everything back together.
> Heh, it's easy to model when you have a few generators, especially when one is much bigger than the others on the grid. But what's fun these days is you can have an absolutely huge number of generators. Keeping things in phase just seems insane to me.
The difficulty is not "keeping them in phase", that just happens (aside from initial connection), it's the whole load prediction and handling, when to tell which plant to start producing more or less energy, with variety of plants having shorter or longer ramp-up/down periods
I do this at home - I’m off-grid, but have a picogrid here as we’re distributed over a fairly large area and have a few structures separated by up to a kilometre, and we’ve multiple PV arrays, a hydro generator to be installed later this summer when the river is low, and a few wind turbines.
By far and away the easiest way to control production - i.e. brake/feather turbines or dump PV, is frequency shifting, as I’ve batteries and inverters in several locations and while networking them would be possible, it’s unnecessary. It’s typically intended for grid-tie operations, but here I use it to control our tiny isolated grid.
It’s a pretty small range (50.2-53hz) over which they shift, but it’s more than enough.
Indeed. All the wallclocks I have here are old electromechanical beasties, 15 years off a single D cell type affairs with a traditional spring mechanism and a solenoid that winds it periodically.
I also discovered that some cheaper LED drivers are extremely sensitive to frequency shifts, and bulbs just flat out flat out die within weeks.
I’ve got the dead buggers sat in a box for later depotting and examination, as I’m also confused as to how a relatively small shift in frequency would kill them - can’t be voltage as I monitor that and it’s more stable than the public grid, and it was only after I started using frequency shifting that they all started flickering and ultimately died. I’d have assumed they’d just be using a boring bridge rectifier or something, and that they’d be expected to work at 60hz too - so yeah, agreed it’s bizarre. I can only think resonance might be at play, as in the evenings it sits at a pretty consistent 52.8 hz.
These days with batteries, a lot of that demand can be served very rapidly. Batteries act as buffers and increasingly replace traditional back up generation (stand by coal/gas plants). A lot of these load spikes are short lived. There are all sorts of weird spikes related to people turning on their tea kettles in the morning or turning on their stoves around 6 pm, etc.
Battery production is currently shifting from hundreds of gwh per year to twh per year worth of production. They last quite long too. If you cycle 1 twh of battery every day, it would run out in about a decade (assuming 3000 cycles or so). And if you do that, that amounts to absorbing and serving about 365 twh.
The worlds entire electricity production is measured in peta watt hour (pwh). About 25 phw. or 25000 twh. So, with battery production scaling int he tens of twh per year, there may soon be enough battery to absorb and produce that kind of volume. Doesn't mean it will be used exclusively for that. But it drives the point home that we are talking some very non trivial levels of standby power. That's car batteries, home batteries, grid batteries, etc. connected to the grid. Mostly neither charging or discharging most of the time.
Tesla and a few others are starting to experiment with virtual energy providers. That might go from a few GW to having in the order of TW of power available on demand very shortly. There are about half a million tesla home batteries out there apparently. Even a few thousand of those already add up to quite a bit of collective power. Imagine that scaling to millions of connected batteries. They'd be the largest power supplier, by far, in most markets.
That won't run the grid for hours/days obviously. But it does eliminate a lot stand by capacity that is expensive and poorly utilized.
That's also the future for energy intensive industries. They'll want to generate most of their power locally (because that's cheaper) and use batteries to buffer it and fall back to the grid only when that runs out and export to the grid whenever there's a surplus locally. So, that reduces load on the grid and evens out a lot of the load spikes. And a lot of the time they'll be feeding energy into the grid. Anything energy intensive is going to compete on cost. And that means investing in local production and batteries.
Another anecdote to share: at my dad's office, while doing a disaster recovery exercise, they realized that their startup power requirements exceeded what their electrical system could supply.
Systems had been slowly added over the years, but because the power system is pretty reliable around here, they'd never had to start things up from a complete power failure.
that's a common issue in high power applications, be it in a factory or a train.
You need to add special breaker which allow a long current peak and switch on loads in a sequence
This is no powerplant-level story, but sometimes there are high startup currents were you didn't expect them:
On one of my first IT jobs at a big manufacturing company my team was tasked to find out why there are regular power outages in some printer rooms (there were rooms with shared printers on each floor of the office building). There were always some tripped circuit breakers and the facility management had to dispatch someone to put them back on. Between those incidents were always some weeks were nothing happened, but when it happened it affected a lot of printer rooms.
In the end we found a monthly cronjob on a central printing server which triggered a testpage print on all connected printers. Took us quite some time since no one ever saw those test pages. Never underestimate the needed current for a room full of colour laser printers coming to live all at once.
Laser printers use a lot of power for a few seconds when coming out of standby.
Part of the printing process involves passing the paper covered in toner through a hot roller, to fuse (melt) the powder toner (ink) onto the page. That roller has to be up to temperature to print. It is normally heated by a powerful (ie. 1 kilowatt) light bulb inside a hollow roller. Sometimes if you peek through the vents in the printer, you can actually see the light it makes.
The light bulb is pulsed on and off to maintain the right temperature - but when coming out of standby it is solidly on for ~10 seconds. Manufacturers want their printers to warm up from standby quickly, so they put very powerful heaters in them, even though the steady state heat requirement isn't awfully much while printing.
Id THAT what that light is?! It always bothered in the back of my mind. It didn’t look very laser-y to me. Especially since the laser was supposed to be infrared.
I think the idea is that you have other stuff on the UPS too, and you'd prefer that stuff stay powered during an outage, but if your printer is on the UPS, it'll chew up all the power.
Depending on your supply (for instance in an old house), the printer current consumption can cause a voltage drop on nearby circuits, and this voltage drop can in turn trigger the UPS.
Not only you should not plug it in a UPS (the initial surge when a laser printer is on would likely surpass the power limit of your UPS too), a laser printer and an UPS should not be under the same circuit breaker. I know because due to a limitation to where I lived before, I have to put both under the same circuit breaker. Every time I print something, it is a power event (where I can hear that the UPS temporarily switched to battery powered mode.)
My UPS has a plug for the printer. It does only surge protection. This is convenient to have the full IT equipment of the office protected with just one box.
Does your UPS have a plug for laser printers, or just for printers?
It might be assuming an inkjet, which have much lower power draws: an inkjet will draw maybe 50W. A laser printer are generally in the mid-hundreds at least and some models can get into the high hundreds to low kW, you need a pretty heavy UPS to handle that and still power other systems.
For laser printer, it is specified on the plug. It protects only against power surge coming from the utility provider. It does not provide power to the printer, this is just a protection if your house is hit by lightning.
Laser printer is known to cause a surge event too. Normally there's a limited amount of surge protection available and routine surge would gradually used up the pool.
However, surge protection may not be as important. I heard an argument that it is basically snake oil (because an actual surge would normally be much more powerful and beyond a typical capacity they have, and some causes fire.)
In our office we were so over the rated current for the building that after the breaker tripped (which it inevitably did) it wasn't possible to just switch it back on. The moment you did all the servers and PCs went back on and it tripped again. You'd have to go around and pull out plugs all over the office then switch the breaker, then switch them all back on one by one. We also had regular electrical fires. Those were the good old days.
Having enough inrush current to trip a breaker doesn't seem so terrible or entirely unexpected, but electrical fires? That's certainly bad news, the breakers are supposed to be sufficient to protect the wiring.
> Having enough inrush current to trip a breaker doesn't seem so terrible or entirely unexpected
It should still not happen, since breakers are supposed to deal with inrush currents. A quick look at a random circuit breaker manufacturer page tells me that this particular breaker model is meant to instantly trip once the current is 3 to 5 times larger than the nominal current; less than that, it should take several seconds to trip, giving enough time for the inrush current to cease. So either the breaker (and the wiring) is underdimensioned, or the device is using too much power.
(IIRC, the trick is that most breakers have two independent trip mechanisms: a thermal one which has a built-in heat-dependent delay, and a magnetic one which is instant.)
> (IIRC, the trick is that most breakers have two independent trip mechanisms: a thermal one which has a built-in heat-dependent delay, and a magnetic one which is instant.)
precisely it. the magnetic one uses the fact that ac makes an electromagnet and they tune it so it snaps away quickly if there's a short.
Right, I don't think inrush should pop a breaker, and I'd replace that breaker to see if it's just got an over-sensitive magnetic trip (IME they get more and more sensitive the more they pop). But it's a safe failure, at least. If the thermal breaker isn't working, that's dangerous.
A single black and white laser printer made the lights in my dorm room dim for a fraction of a second. So yeah, that thing must've pulled quite a few amps.
Also: don't put a laser printer in your bedroom. It's unhealthy. Only learned about that after the fact.
> Also: don't put a laser printer in your bedroom. It's unhealthy.
3D printers are even worse, depending on the filament type (ABS is worst?). Always ventilate!
A few papers printed over the course of years won't kill you. What will are the conditions of working adjacent to the office copier, 8-10 hours a day, for years.
Get an air purifier to capture particulates. (Supposedly, houseplants help too.)
This was a feature on SCSI disk controllers. I remember one controller that had dip switches to set the spin up sequence number, and then you would configure the controller to wait for all the drives to be spinning before it tried to bring the array online.
I'm going from memory here but each Ultra 320 SCSI HDD had a startup current of almost 2 Amps so if you had a disk shelf with 24 drives and stack a few shelves in each rack you could do some serious power damage if you didn't plan the startup sequence right.
On a per-machine basis, many server motherboards have out-of-the-box BIOS support for this feature. At least they used to. It's been a long time since I've built a server and mechanical hard drives are less common than they used to be.
I had a home hacked 1TB+ server, using 5.25in 23GB 8lb monster drives salvaged from a long life as a TV video bank (long, long ago, when dinosaurs walked the earth). There was 60+ actual spindles as i recall.
The drive array was powered by 6x, 400W ATX server supplies with my own wiring harness. This was enough to keep them running but they had to be sequenced carefully to keep from overdrawing the power supplies.
This was all on an UltraSPARC 6k so there was plenty of support for that; bringing up the system always sounded like multiple jet takeoffs tho. Took 15min. When the rack of 10k RPM "quick cache" disks spun up it was like a chorus of the whines of the damned.
I had a MicroVAX in my bedroom which booted with a tick-tack-tick-tack going faster and faster culminating in a crescendo where it sounded like the discs synced up or something.
I'd then login to a prompt and type DIR before I turned it off again. I just pulled the power switch, I had no idea how to do a proper shutdown.
There was some home computer - either an original Apple II or a Commodore PET, I don't remember - where if you splurged for the fancy second disk drive, the computer could be destroyed by a rogue program spinning up both drives at once. And since every program ran at the same protection level as the OS (because there were none), it was either two MOVs or two POKEs to the hardware registers to make it happen.
"The Shearon Harris site was originally designed for four reactors (and still has the space available for them), but cancellation of an aluminum smelter plant in eastern North Carolina in the 1970s resulted in three of the reactors being canceled."
A kilo of aluminum contains about 55 kw/h of embodied energy, I like to think of aluminum smelting as pretty much the direct conversion of electricity to metal.
That means that each MW/hr of production only makes 18 kg/hr, so a 900MW/hr nuclear plant only makes 8 tons of aluminum a hour. Its insane.
100% of that energy cost is the electrolysis, recycling has no comparable step. There are additional energy costs for processing the aluminum into useful items on top of this that are roughly the same for primary and recycled aluminum.
Overall, recycled aluminum requires only about 5% of the energy that primary aluminum requires.
First, a clarification: a kilowatt-hour is not a kilowatt per hour (1 kwh = 3.6 * 10^6 joules). Same goes for megawatt-hours. There's no such thing as a "900Mwh" reactor - it's a 900 megawatt reactor. During an hour, it'll produce 900Mwh* (3.24e+12 joules) and can smelt 16363 kg of aluminum. Behold the power (pun intended) of dimensional analysis.
Secondly, you're not wrong, the way that aluminum is smelted is by melting e.g. bauxite or another aluminum compound, and then electrolyzing the resulting fluid to extract pure aluminum. Usually the same electrodes are used for both operations. It's the very grandest scale of electrochemistry, and the reason that aluminum smelting plants are nearly universally located near cheap and highly available power sources.
* Something close to 900Mwh, anyway, given that reactor nameplate capacity is not always the actual running power or peak possible output, plus an allowance for maintenance. Other power sources have different capacity factors that would result in something below 900Mwh, but a typical fission plant is "up" continuously for our purposes
To illustrate this: aluminium costs about $2.25 per kilo wholesale [0], so that's about 4c per kWh or $40 per MWh.
There aren't many places where electricity can be produced close to that. Iceland is one and it's unsurprisingly the world's major bauxite importer and aluminium exporter. Wholesale electricity there goes for around $42/MWh [1].
OK, the smelters can do a bit better than the average wholesale rate, but not much - Iceland's electricity supply is not highly variable like solar or wind.
So the rest of the expenses of the process - mining, shipping half way around the world twice, capital costs - are all basically free compared to the electricity cost.
I grew up next to a hydroelectric dam on the Columbia River in Oregon where a large amount of the power went to smelting aluminum. That industry was a huge part of the industry in our small town that otherwise primarily produced cherries. I went on a tour there with my scout group and it made a serious impression on me, it was erie how you could literally feel the enormous amounts of current in the air.
There was so much current that the free-air magnetic field in the plant was literally palpable, the engineer giving us the tour did a demonstration similar to this video[1] which blew my young mind.
A portion of the land, and the substantial power-handling infrastructure (and proximity to the river for cooling) now powers a Google datacenter.
PJM, the grid operator for the northeastern US, has a "demand response fact sheet".[2]
There are various ways to buy large amounts of power. Big users will have a connection to the pricing system, getting better prices during low demand periods, higher prices during high demand periods, and shutoffs during very high demand periods.
Big power consumers usually pay for power at grid market rates, which vary from hour to hour. So they're tied into both the market system and the control system. This is done via a Curtailment Service Provider.[2] Some of those are power distribution companies, and others are just brokers.
Here's one in California.[3] There's a phone app, a web page, a connection to your meter, and an API for your own load's control system. Large power consumers connect to them, and they connect to the grid operator, which is CAISO for California. Once everything is connected, they can remotely tell your systems to reduce their load and verify that has happened, for which you get a price break.
There's the Peak Load Management Association, which you can join if you buy power by the gigawatt.[4]
I operated the dryers at a coal mine in the 1980s. We had to start the exhaust fans with the dampers closed and then slowly open them, or we'd take out the power for all of Northeastern British Columbia. I know because I knocked the power out by mistake one night. I suspect that high-drawing factories must employ similar strategies to slowly increase the draw.
> Each 775-ton flywheel can spin up to 225 rpm and store 3.75 GJ,[47] roughly the same amount of kinetic energy as a train weighing 5,000 tons traveling at 140 kilometres per hour (87 mph). Each flywheel uses 8.8 MW to spin up and can generate 400 MW (briefly)
Does that mean that the 775 ton flywheels could come to a complete stop in less than 13 seconds if fully used up?
180 comments
[ 2.8 ms ] story [ 238 ms ] threadConsider how many obscure but useful, necessary even, things we've learned over the past thousand years.
Before the internet it would all be hidden away, only quickly available to specific experts in their fields.
You'd have to go to a university library and dig for hours.
If it's not online it doesn't exist. /s We really need more of these obscure pieces of knowledge put online because people don't go to the library as much as they used to.
There's so much specialized knowledge out there, but often you'll only learn about it from someone else, or a highly technical book.
Like, say you want to frame and build your own house - there's bazzilions of YouTube videos about the beginning process. But very very few about the more advanced details you need to know.
I remember my mind being blown by the Cal engineering library. Endless stacks and stacks of dense foundational knowledge from the 1950s-1990s you would never find on Google. Books are massively underrated these days.
Hathi Trust itself grew out of Google's book-scanning initiative, and is shaped (and scarred) by copyright lawsuits.
That said, I hope some number of those works also find their way to Libgen and ZLibrary.
Advanced? All I need is some TooBa Fours and a Larry Haun book...
I'm sure the scientific publishers that charge $50 to view a single journal article will do everything in their power to prevent this...
This does bring up the issue of actual legal protections, though.
If you are training an LLM on the open web, or things posted for everyone to view for free, than that is OK I guess when it comes to legal ramifications. (Definitely not a lawyer)
When you start using data that you really don't have the rights too...and somehow someone finds out that their protected data is included in the dataset...then what?
Even if it is online, it probably doesn't exist either - see today's threads about communities moving from Reddit to Discord. The "cozy web" is undoing a lot of progress of the past decades. Might be that we'll all need to go to the university libraries and dig for knowledge ourselves, hoping any of the more recent experiences and discoveries end up being published as books, instead of dying in private Whatsapp groups.
That's an interesting factor of online knowledge - the most readily available one is the one that masses are interested the most because the views give the budget for people to care. It's also weirdy trendly, like how pandemic spawned a lot of woodworking channels coz people cooped up in their homes found a new hobby.
To add to the point this [1] random video is an example, it does go into terminology and reasoning behind each element but won't tell you what kind of lumber to get, how climate would affect that decision, how to isolate the house and a bunch of other things. You might look for them and probably find some info but at some point just looking for a dedicated book might be the saner option.
And uh, if someone knows a good one covering how to build and isolate your own shed I wouldn't mind recommendation...
- [1] https://www.youtube.com/watch?v=3fP0LZMEV5w
There is so much deep information available in any large university library that is simply not on the internet at all. If you're researching any historical topic, there are at least a few solid books (and possibly hundreds) that draw from primary sources, compared to a couple pages of text on Wikipedia and very little else. You mostly won't even find ebooks.
Somehow the best, most extensive free digital resource is a podcast like Age of Napoleon, which synthesizes information from many books.
It's actually a minor plot point in Stephen King's "The Stand" that after a viral apocalypse wipes out most of humanity, the survivors try to restart the electrical grid in a town.
The first attempt proves fatal because they haven't properly isolated the circuits throughout town, so when they connect the plant to the main grid the plant's generators explode from trying to support the load of every home where someone died spontaneously while running a hair dryer.
But to really know something, you have to have studied it, even in the modern era. I can read an instantly-available wikipedia article about power generation, but I'm only scraping the absolute surface.
https://pt.wikipedia.org/wiki/Museu_da_Eletricidade_(Lisboa)
So the entire grid is in phase, by which I mean every generator, load, &c is operating on the same AC pulse (handwave-handwave ignoring smaller loads, transformations, etc.). But that phase isn't instantaneous; it's near-light, and the grid is long enough for that to matter in places.
So every point in the grid can't be perfectly in phase with every other point, right? Because we have both lightspeed delays and loops, so even if point A is receiving power from two substations in-phase, point B (with different lengths of wire to those two substations) should be receiving it out-of-phase, right? How do we balance that in the grid?
Maybe imagine a line of buoys in the ocean as a wave passes.
(Perhaps the obvious answer is correct here: "Grids don't work that way; you'd never do that.")
Weird how all the replies so far misunderstood your question.
I'm pretty sure for home electronics the phase difference doesn't even matter that much. Everything sensitive seems to be converted to DC anyway.
Maybe it matters in large industrial applications, I have no idea. But I also imagine in their situation it's probably pretty straightforward to clean up the power supply.
In my imagination, the specialists are brought in only to learn that the RPMs in one motor were juiced because someone didn’t practice cable management
But... If you had a worldwide electricity grid running at 60Hz, it would start to matter, and you would make sure to use local capacitors/inductors to make phase shifts to make sure that you didn't have big circulating currents in loops (they just are wasting energy)
Imagine a triangle with 2 generators 100km apart, and a factory almost due south of one generator:
ga ......... gb
__f
I think the offset would be something like sin(gb.f) - sin(ga.f)
But really this comment is bait for an EE to school me.
Here's a video of old school mercury arc rectifiers as payment: https://www.youtube.com/watch?v=YhaQqgXrMMU
If you have local generation you want to combine with grid power you usually just sync your local generation to the grid. If you don't want to do that you can just use a DC intertie that is local. Basically you'd have two AC -> DC converters and a single DC -> AC converter.
The airport or hospital will procure transformers that have the same winding configuration and impedance so the phase shift and voltage drop across them will also be the same. The low voltage windings of the transformers at the hospital can be paralleled so they both feed the load. Reverse power protection would be implemented so the hospital can’t back feed the distribution line.
What phase difference do you expect in this case? What effect would it have?
Everyone isn't always in phase with every other station's phase at that exact moment in time. They're just in phase with their local part of the grid's phase. Though amount that is different is milliseconds, not seconds as in the stadium wave example.
This mostly came from reading this: https://electronics.stackexchange.com/a/291328
So the grid doesn't need to balance it, no.
And from the receiving end's perspective, power will be exactly one phase out of sync if the cables differ in length by 5000 km. I'm assuming that isn't really a problem people have to worry about, but my background is in physics and not engineering (i.e. maybe there's some industrial applications that I'm not thinking of).
You'd have to have 2 different routes from same power source that differed in hundreds of kilometers in length and that just doesn't really happen. And small phase difference would just cause uneven loading
Also that power would be "used up" closer to the power source and you'd be sucking off power from closer sources.
[1] https://en.wikipedia.org/wiki/High-voltage_direct_current#Ba...
That’s described on https://en.wikipedia.org/wiki/Synchronization_(alternating_c....
Firstly, you design your generator to have the same wave form and phase sequence as the grid.
Then, you power up your generator and make sure the voltage, frequency and phase angle of the electricity it generates matches that of the grid.
The moment that’s (more or less) the case, you connect the grids, preferably on a zero crossing. That Wikipedia page describes a setup with incandescent bulbs that can be used to manually detect that moment, but nowadays, it’s done using electronics.
not in phase as such, but in sync.
because you only have to match your 60hz(or 50hz) to what you receive locally, so long as the waveform is reasonably stable its not that much of an issue.
Because everything is effectively a bunch of elastically linked pendulums, you tend to reach equilibrium, so long as the load doesn't act too much as a dampener
If everything is in a line, you just sync to your local phase, but if you have wires in a triangle that's impossible, and they basically just ignore it, in practice it doesn't happen often enough to cause any problems.
As far as I know, in your example, one of the two circuits will be transmitting more power from the substations to point B than the other. There's a device called a phase-shifting transformer (https://en.wikipedia.org/wiki/Phase-shifting_transformer) which can be used to adjust the phase angle of the circuits, and that way, adjust how much of the power is carried by each circuit.
(The following sentence from that article probably goes to the core of the answer for your question: "For an alternating current transmission line, power flow through the line is proportional to the sine of the difference in the phase angle of the voltage between the transmitting end and the receiving end of the line.[1]")
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We built a whole application to manage a certain workflow between multiple systems, and our users kept using email instead, because it turns out that the users on the other end don't check the system, but they do check their email.
You also have people who are drilled in following procedures, especially when failures in process become very public.
New Zealand had to build an aluminum plant in the 1960s and figured out it would be more efficient to bore miles underground, build turbines, install a huge power station, and wire it tens of miles to the smelting plant. It relies on a vertical drop between Lake Manapōuri and the open ocean to create the gravitational potential to turn the turbines. When the smelting station doesn't use the full capacity the power station has to immediately reduce output, otherwise it can overload the transmission lines to the rest of the grid.
Manapouri Power Station is the name if anyone is interested in reading more. It has an interesting history. https://en.wikipedia.org/wiki/Manapouri_Power_Station
This comment reminded me of a cute tool I used to have installed back in the WinXP days called "Screen Calipers". It was a super sweet tool. 100% skeumorphic :D
http://www.iconico.com/caliper/
Not everywhere is the American west where it doesn’t rain a lot and water sources are being used way past their capacity.
The longer route (which actually flows next to the farm my mum grew up on) doesn't even go near a major population centre. The largest town (Tuatapere) has a population of 500 people.
They are at it now. That place closing down would lose 1000+ jobs if n a region that doesn’t have a ton of options, the world would lose a greenish supply of aluminium and I would potentially get a discount on my power bill when I stop subsidising that massive company (that smelter uses a bit over 10% of NZs electricity).
Oh, and Rio Tinto have dumped toxic waste in various places too.
https://www.powercompare.co.nz/n/tiwai-point-aluminium-closu...
https://www.rnz.co.nz/news/national/468066/tiwai-point-toxic...
Moral hazard [1]. Government officials make these decisions because they can win political points by doing so. Usually, they get to take credit for being “job creators.” Opposition politicians who try to raise the issue of risks, potential debts, environmental degradation, etc. can be quickly branded as anti-jobs and their valid criticisms dismissed.
Down the road, when the chickens come home to roost, the politicians who approved the deal are nowhere to be found. Since there’s no law allowing the public to hold those politicians financially accountable for their past decisions the effect of moral hazard has run its full course, leaving the public holding the bag.
As for why (even new generations of) politicians would continue to cave to these companies’ demands: no one wants to be left taking the blame for job losses.
[1] https://en.wikipedia.org/wiki/Moral_hazard
Why? They could build their own power source.
That said, I’d like a discount when my internet line speed drops below advertised due to everyone else using the internet.
Consider every dollar spent as an interest baring loan. Spending money on a power plant not used wastes it and making everything more expensive.
Scalable loads makes the return on investment for variable load renewables and constant load nuclear much better. The most expensive power are the peaker plants that have to run only a handful of hours per day.
More scalable grid connected loads like aluminum processing makes building capacity and especially renewable capacity cheaper.
The power plant can’t easily supply the National grid, as the lines aren’t there with sufficient capacity. The lines are being built but Rio Tinto have used these facts to get to a position where they are subsidised by the rest of the country.
The power plant also has a finite life, and it’s passed its midpoint.
Additionally, that smelter has also had government subsidies to stay open. I see no great loss in letting it die.
https://en.wikipedia.org/wiki/Kemano
https://en.wikipedia.org/wiki/Kenney_Dam
My brain however has in the past created incredible nightmares based on the scale of what I experienced there. I just _had_ to see what the tailrace output looked like and was not disappointed by this nightmare fuel: https://www.youtube.com/watch?v=qlhSzs4JXE0
The scale of it all was quite terrifying to my young mind as I imagined all the unseeable hazards beneath the water’s surface, on which it capitalized during my sleeping moments.
It remains today as both one of the most exhilarating and the stupidist things I've done.
Equatorial tide changes through a narrow gorge are insane enough before adding in salt water crocodiles on one side and sharks on the other (well, both on both sides to be honest).
[1] https://www.youtube.com/watch?v=3dIhCmo3g0c
[2] https://www.youtube.com/watch?v=4xYg73DV0V0
https://mvdirona.com/jrh/Work/index.html
Several dams in the highlands create multiple reservoirs, the water is then fed through kilometres of tunnels before it reaches a ~400m vertical penstock to the Fljótsdalur underground power station (the power station is about 40km / 25mi inland, while the smelter is on the coast)
Before starting up the fans, the guy running the control booth picked up the phone and had a short conversation, roughly
"Hi, this is [name] at the wind tunnel; can we turn it on?"
[someone on the other end replies]
"Great, thanks."
I asked who he was calling, and he explained that he had to check with the power company before powering it on. This was mid-winter, so grid demand was low; apparently during the summer (when everyone has ACs on), the start-up load could cause brownouts!
Load drops, the big spinny generators stop having so much resistance and accelerate.
Load increases and the big spinny generators have more load, synchronously slowing down.
So in simplest system just feeding your generator more when frequency is below nominal and less when it is above is enough
I'm glad there's at least two of us ;)
Some systems still use grid frequency for timekeeping.
If you own a mechanical rotary timeswitch, it's got a synchronous motor spinning 50 or 60 times a second, then a series of gears, gearing it down to 1 rotation per day.
https://www.theguardian.com/world/2018/mar/08/european-clock...
Very, very well done
Almost all cheap / "simple" consumer mains appliances, including non-"smart" microwaves, ovens, alarm clocks, etc. still use mains frequency as their time reference.
Due to the growing complexity of power grids and in Europe, international power-grid politics and infighting, the grid frequency is becoming less stable and you see these devices fluctuate badly more often than they used to. https://hackaday.com/2018/03/09/europe-loses-six-minutes-due...
I find this incredibly hard to believe. Crystals are incredibly cheap and waaaaaay more accurate than anything that the grid does.
If you're not an actual motor, sensing the grid is both an engineering challenge and a non-trivial expense.
The grid has poor short-term performance, but the long-term frequency is averaged out to be exactly 50/60Hz.
Turns out it had a button combo for “switch between 50Hz and 60Hz mode” that was similar to its combo for (what I thought I was setting) “switch between 12- and 24-hour mode”. (I think the 12/24 switch was “hold the hour button down while plugging in” and the 50/60 switch was “hold both buttons down while plugging in”.)
"What happens when I turn on an electric device in my house?"
"A turbine in a power plant spins more slowly for just a moment."
Practical engineering has a great video about power black starts that give some insight into this complicated machine.
https://www.youtube.com/watch?v=uOSnQM1Zu4w
The most difficult bit for an operator is to make sure the generator is synchronized before they actually connect it. Only after it's synchronized can they start actually feeding power in.
You can't just turn these things on and off at will like a regular motor. To extend the gears analogy, gears need to be synchronised before they can engage - just like synchronous AC generators.
Generator spins at 50hz Motor spins at 50hz
Add load to the motor, it starts slowing down both itself and the generator. Generator governor increases input energy, frequency goes up. Both are in phase all the time.
Remove load, both start spinning faster. Reduce governor to regulate it to 50hz again.
It's a bit harder with inverters but the idea is similar, you follow the grid phase and if you want to send energy to the grid you will be slightly early to the grid phase and if you want to take energy from the grid your phase will slightly lag.
PS One of the answers in the SO thread mentions JET in the UK. I spent a few summers there as an electrical engineering student (it's home to the MAST and JET fusion reactors). When the JET tokamak ignites a plasma, it can't sustain it for very long (we are not yet at the point of extracting enough energy to sustain the reaction). As a result they need to ignite the plasma and keep it hot. They can't do it for more than 1-10 seconds. During that time, they draw massive amounts of power - they're permitted to draw up to 1% of the UK's capacity for a short period, whilst they simultaneously dump all the energy stored in two gigantic flywheel generators housed in a nearby building. I've never been there when the flywheels are running but I've climbed around beneath them. There's nothing quite like massive engineering :)
Other problem is that for renewables to be profitable you want to push all the energy out all the time, especially in peak. Even now solar installation users have problem with that when there is too many small solar installations installed on same street the voltage goes too high and the inverters just trip and stop pushing the power to the grid, losing owner money.
We just need to have more cheaper storage solutions. Technically utilities could just put a bunch of batteries near concentration of residential solar and just basically sell the service of "storing the kilowatts" to them (say "you can receive 80% of what you put into it in next 48 hours"), all while having the capacity to use that stored joules in case a peak needs to be handled
[0] https://arstechnica.com/tech-policy/2021/05/texas-power-outa...
The difficulty is not "keeping them in phase", that just happens (aside from initial connection), it's the whole load prediction and handling, when to tell which plant to start producing more or less energy, with variety of plants having shorter or longer ramp-up/down periods
By far and away the easiest way to control production - i.e. brake/feather turbines or dump PV, is frequency shifting, as I’ve batteries and inverters in several locations and while networking them would be possible, it’s unnecessary. It’s typically intended for grid-tie operations, but here I use it to control our tiny isolated grid.
It’s a pretty small range (50.2-53hz) over which they shift, but it’s more than enough.
https://www.victronenergy.com/live/ac_coupling:fronius
I also discovered that some cheaper LED drivers are extremely sensitive to frequency shifts, and bulbs just flat out flat out die within weeks.
Huh, that's just outright bizzare. The most adding few hz should do is change power by few %
Battery production is currently shifting from hundreds of gwh per year to twh per year worth of production. They last quite long too. If you cycle 1 twh of battery every day, it would run out in about a decade (assuming 3000 cycles or so). And if you do that, that amounts to absorbing and serving about 365 twh.
The worlds entire electricity production is measured in peta watt hour (pwh). About 25 phw. or 25000 twh. So, with battery production scaling int he tens of twh per year, there may soon be enough battery to absorb and produce that kind of volume. Doesn't mean it will be used exclusively for that. But it drives the point home that we are talking some very non trivial levels of standby power. That's car batteries, home batteries, grid batteries, etc. connected to the grid. Mostly neither charging or discharging most of the time.
Tesla and a few others are starting to experiment with virtual energy providers. That might go from a few GW to having in the order of TW of power available on demand very shortly. There are about half a million tesla home batteries out there apparently. Even a few thousand of those already add up to quite a bit of collective power. Imagine that scaling to millions of connected batteries. They'd be the largest power supplier, by far, in most markets.
That won't run the grid for hours/days obviously. But it does eliminate a lot stand by capacity that is expensive and poorly utilized.
That's also the future for energy intensive industries. They'll want to generate most of their power locally (because that's cheaper) and use batteries to buffer it and fall back to the grid only when that runs out and export to the grid whenever there's a surplus locally. So, that reduces load on the grid and evens out a lot of the load spikes. And a lot of the time they'll be feeding energy into the grid. Anything energy intensive is going to compete on cost. And that means investing in local production and batteries.
Systems had been slowly added over the years, but because the power system is pretty reliable around here, they'd never had to start things up from a complete power failure.
On one of my first IT jobs at a big manufacturing company my team was tasked to find out why there are regular power outages in some printer rooms (there were rooms with shared printers on each floor of the office building). There were always some tripped circuit breakers and the facility management had to dispatch someone to put them back on. Between those incidents were always some weeks were nothing happened, but when it happened it affected a lot of printer rooms.
In the end we found a monthly cronjob on a central printing server which triggered a testpage print on all connected printers. Took us quite some time since no one ever saw those test pages. Never underestimate the needed current for a room full of colour laser printers coming to live all at once.
Part of the printing process involves passing the paper covered in toner through a hot roller, to fuse (melt) the powder toner (ink) onto the page. That roller has to be up to temperature to print. It is normally heated by a powerful (ie. 1 kilowatt) light bulb inside a hollow roller. Sometimes if you peek through the vents in the printer, you can actually see the light it makes.
The light bulb is pulsed on and off to maintain the right temperature - but when coming out of standby it is solidly on for ~10 seconds. Manufacturers want their printers to warm up from standby quickly, so they put very powerful heaters in them, even though the steady state heat requirement isn't awfully much while printing.
Not only you should not plug it in a UPS (the initial surge when a laser printer is on would likely surpass the power limit of your UPS too), a laser printer and an UPS should not be under the same circuit breaker. I know because due to a limitation to where I lived before, I have to put both under the same circuit breaker. Every time I print something, it is a power event (where I can hear that the UPS temporarily switched to battery powered mode.)
It might be assuming an inkjet, which have much lower power draws: an inkjet will draw maybe 50W. A laser printer are generally in the mid-hundreds at least and some models can get into the high hundreds to low kW, you need a pretty heavy UPS to handle that and still power other systems.
However, surge protection may not be as important. I heard an argument that it is basically snake oil (because an actual surge would normally be much more powerful and beyond a typical capacity they have, and some causes fire.)
It should still not happen, since breakers are supposed to deal with inrush currents. A quick look at a random circuit breaker manufacturer page tells me that this particular breaker model is meant to instantly trip once the current is 3 to 5 times larger than the nominal current; less than that, it should take several seconds to trip, giving enough time for the inrush current to cease. So either the breaker (and the wiring) is underdimensioned, or the device is using too much power.
(IIRC, the trick is that most breakers have two independent trip mechanisms: a thermal one which has a built-in heat-dependent delay, and a magnetic one which is instant.)
precisely it. the magnetic one uses the fact that ac makes an electromagnet and they tune it so it snaps away quickly if there's a short.
Also: don't put a laser printer in your bedroom. It's unhealthy. Only learned about that after the fact.
3D printers are even worse, depending on the filament type (ABS is worst?). Always ventilate!
A few papers printed over the course of years won't kill you. What will are the conditions of working adjacent to the office copier, 8-10 hours a day, for years.
Get an air purifier to capture particulates. (Supposedly, houseplants help too.)
I'm going from memory here but each Ultra 320 SCSI HDD had a startup current of almost 2 Amps so if you had a disk shelf with 24 drives and stack a few shelves in each rack you could do some serious power damage if you didn't plan the startup sequence right.
The drive array was powered by 6x, 400W ATX server supplies with my own wiring harness. This was enough to keep them running but they had to be sequenced carefully to keep from overdrawing the power supplies.
This was all on an UltraSPARC 6k so there was plenty of support for that; bringing up the system always sounded like multiple jet takeoffs tho. Took 15min. When the rack of 10k RPM "quick cache" disks spun up it was like a chorus of the whines of the damned.
I'd then login to a prompt and type DIR before I turned it off again. I just pulled the power switch, I had no idea how to do a proper shutdown.
https://en.wikipedia.org/wiki/Shearon_Harris_Nuclear_Power_P...
"The Shearon Harris site was originally designed for four reactors (and still has the space available for them), but cancellation of an aluminum smelter plant in eastern North Carolina in the 1970s resulted in three of the reactors being canceled."
That means that each MW/hr of production only makes 18 kg/hr, so a 900MW/hr nuclear plant only makes 8 tons of aluminum a hour. Its insane.
Overall, recycled aluminum requires only about 5% of the energy that primary aluminum requires.
Secondly, you're not wrong, the way that aluminum is smelted is by melting e.g. bauxite or another aluminum compound, and then electrolyzing the resulting fluid to extract pure aluminum. Usually the same electrodes are used for both operations. It's the very grandest scale of electrochemistry, and the reason that aluminum smelting plants are nearly universally located near cheap and highly available power sources.
* Something close to 900Mwh, anyway, given that reactor nameplate capacity is not always the actual running power or peak possible output, plus an allowance for maintenance. Other power sources have different capacity factors that would result in something below 900Mwh, but a typical fission plant is "up" continuously for our purposes
There aren't many places where electricity can be produced close to that. Iceland is one and it's unsurprisingly the world's major bauxite importer and aluminium exporter. Wholesale electricity there goes for around $42/MWh [1].
OK, the smelters can do a bit better than the average wholesale rate, but not much - Iceland's electricity supply is not highly variable like solar or wind.
So the rest of the expenses of the process - mining, shipping half way around the world twice, capital costs - are all basically free compared to the electricity cost.
[0] https://markets.businessinsider.com/commodities/aluminum-pri...
[1] https://www.datacenterdynamics.com/en/opinions/time-for-an-i...
There was so much current that the free-air magnetic field in the plant was literally palpable, the engineer giving us the tour did a demonstration similar to this video[1] which blew my young mind.
A portion of the land, and the substantial power-handling infrastructure (and proximity to the river for cooling) now powers a Google datacenter.
[1]: https://www.youtube.com/watch?v=HsuSo7aFGhk
A heavy contactor powers on stage 1, stage 1 powers another heavy contactor powering stage 2, stage 2 does the same with stage 3.
When mains voltage is too low, the contactor cannot close. This way this allows for tens of milliseconds of separation in between power ons.
Big power consumers usually pay for power at grid market rates, which vary from hour to hour. So they're tied into both the market system and the control system. This is done via a Curtailment Service Provider.[2] Some of those are power distribution companies, and others are just brokers.
Here's one in California.[3] There's a phone app, a web page, a connection to your meter, and an API for your own load's control system. Large power consumers connect to them, and they connect to the grid operator, which is CAISO for California. Once everything is connected, they can remotely tell your systems to reduce their load and verify that has happened, for which you get a price break.
There's the Peak Load Management Association, which you can join if you buy power by the gigawatt.[4]
[1] https://pjm.com/-/media/about-pjm/newsroom/fact-sheets/deman...
[2] https://www.pjm.com/markets-and-operations/demand-response/c...
[3] https://cpowerenergy.com/wp-content/uploads/2018/01/CAISO_DR...
[4] https://www.peakload.org/
Does that mean that the 775 ton flywheels could come to a complete stop in less than 13 seconds if fully used up?