The large transformer shortage has been a problem for years. Large transformer making is a craft, where the winding supports are made of hardwood, like furniture, and wound by hand. Then the windings go into a case that's an oil tank.
The build teams aren't that big - 30-50 people. The main barrier to entry is that it takes people who know how to hand-build big transformers. Utility buyers want a supplier who's going to be around half a century from now, since these things last that long.
Here's a summary of the market, from a transformer maker in China.[1]
Here's an AI-generated fake video of large transformer manufacturing. It's about half wrong.[2] But right enough to be worth watching. I'd like to see the prompts for this.
Virginia Transformer is the US's biggest maker of large transformers.[3] They advertise their "short lead times" of two years. The margins are low, and makers don't want to go idle between orders. This is a problem with much heavy machinery. It could be built faster, but when you catch up, everybody gets laid off and the factory sits idle. There goes your profit margin.
That's a good point. The AI slop video is inaccurate, but entertaining.
For comparison, here's the real deal - transformer winding at Virginia Transformer in the US.[1]
That video provides a good sense of why these things take so long to make.
All those wooden parts. All that slowly and carefully hand wound heavy wire. As they point out, if that wire can move at all, as the magnetic fields pushes and pulls on it, the vibration will, over time, wear out the transformer. It's a very fussy job to get the position and tension right, with wire firmly supported against movement in all directions. That's the difference between a lifetime of a few years and many decades.
It's a boring video.
Here's the whole manufacturing process at ETD in the Czech Republic.[2]
This shows roughly the same sequence of steps as the fake video, but it's real.
Big industrial bay with lots of transformers and overhead cranes. Sheets of lamination steel.
Winding. The moving and shipping of the big transformer.
All that is in both the real video and the AI slop.
This is the real video from the manufacturer, and it assumes that if you're watching, you know what you're looking at. There's little narration.
It's a confusing video.
Here's a small open frame transformer.[3] If you've done much electrical or electronics work, you've seen one, and may have replaced or installed one. When you see the big ones being built, the process makes sense. Same concept, with a laminated core, windings, insulation, and lead wires. The big ones have the same key parts, just much bigger. But if you don't know a transformer from a transistor, the manufacturer videos are just wallpaper.
And there's the problem. The AI slop version will give the average viewer a general idea of the process. The accurate videos from manufacturers require more background knowledge to comprehend.
The target audience is different. The manufacturers don't make those videos for the general public.
As far as I can tell, the video itself is 100% fake. A bad fake. I particularly love the part where the worker levitates a large coil of steel with his hands. The narration sounds OK, so just turn off your monitor.
You can’t “join up transformers”, a single-phase transformer is an iron core with two sets of copper or aluminum windings around it. As far as I know, the only way to increase the volt-amp rating is more iron and copper/aluminum. Wiring them in series doesn’t increase the volt-amp rating but you can use (3) paralleled single-phase transformers for a three-phase circuit, I occasionally see a set of three medium-voltage to 480V ‘pineapple’ transformers (with visible live parts!) at the service entrance for older buildings.
Why can’t we mass manufacture aircraft carriers by making a lot of small boats and joining them up?
It’s the same kind of problem.
(And notably, it’s not that it’s actually completely impossible to do it that way - just impractical compared to the alternative. You could actually make something that kind of sorta worked for an aircraft carrier by joining tens of thousands of small pontoons and support ships. Operationally, it would just suck compared to the alternative.)
It's a generic problem with flat demand in heavy industry. Shipbuilding, bridges, nuclear reactors - when the production backlog runs down and the factory goes idle, the factory dies. So do the companies that feed specialized parts into the process.
Governments keep making contracts with megacorp prime contractors, who stiff their suppliers at the first opportunity, instead of the SMEs that are essential to reliable long term capability. It's the bean counter obsession with counting delivered parts as the only basis for payment.
This would be a great opportunity for the government to get involved.. Tell them to just make two of every order they have now and the government will buy the second one at whatever price the customer is paying. Put the spares in a strategic repository and sell them at “cost” to whoever wants them. Would be a much better use of a few billion dollars than some asinine Star Wars II or another half a trillion into the war maw.
The head of Newport News Shipbuilding and Dry Dock, which builds the US aircraft carriers, once ran a full page ad announcing that if Congress would order two carriers at once, instead of one at a time, they'd throw in a third carrier for free. The total shutdown between jobs was that expensive for them.
Liquidity is expensive. Selling a carrier one at a time is like a retail business where you're expected to hold onto stock. If you don't build up an inventory to sell from and just sell one unit, you have to markup the price to cover the cost of the factory when it is idle.
The US Government selling off the helium reserve at cost over two decades effectively capped the global price, even while exploration costs got higher. So exploration was killed, no investments made in better extraction, processing or recycling.
Now that it's gone we're ultra dependent on a by-product of methane extraction and liquification for LNG transport. But most of the helium we extract as natural gas is not separated, as it just gets piped as gas. Helium is getting very very expensive.
You can have the government buy the equipment with the economy goes down, or you can have the government manufacturing it and letting the factory go idle when demand dries down.
But amplifying the orders just makes the problem worse.
Have the government only sell these in times of crisis. They're not competitors, but vendors of last resort. For general maintenance replacement, the gov should tell prospective buyers to take a hike.
The Biden administration invoked the Defense Production Act and used $250m of IRA funds to increase production of grid transformers. Guess what happened when Trump took office.
The problem expressed, I think, that it is not useful to scale up production quickly (or perhaps at all), because a factory catching up on all of their orders means that the factory goes idle. Idle factories can't afford to pay wages, so they lay off some or all of the workers -- and those folks go and find different jobs.
And when they leave, they take their institutional knowledge with them.
So the sustainable goal is to never be idle, and the way to accomplish this is to never catch up.
For an example of how idle factories can go sideways, look at the Polaroid film story: Polaroid closed. Everyone left. Some investors with a big dream eventually bought many of the physical assets that remained.
But owning some manufacturing equipment didn't help them much because the institutional knowledge of producing Polaroid film had already evaporated. They had to largely re-invent the process. (And they've done a great job of that, but it's still not the same film as the OG Polaroid was.)
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So anyway, suppose the government steps in and simply artificially multiplies transformer orders x2, and pays them fairly for this doubled production. Since transformers are tangible things and we can't just spin up more AWS instances to cover demand, the immediate result is that the "short" lead time on new orders has increased from 2 years, to 4.
That's not seeming to be very ideal. It seems to amplify the problem instead of resolve it.
I suppose that the government could also offer safeguards that would help protect the businesses (including suppliers for parts) once they eventually catch up on orders, and that this might motivate them to scale production sooner instead of later (or never).
Which -- you know -- that isn't unprecedented. As an example: The Lima Army Tank Plant, in Lima, Ohio, is place where I've spent a fair bit of quality time. It still exists and continuously has employees largely because the institutional knowledge of how to build tanks (and a few other war machines) is considered to be too important to lose. During lulls, it mostly just sits there on its expansive site, loafing along repairing stuff that comes in, and waiting for the day when things to turn bad enough that we need to start increasing our number of tanks again.
It needs to keep operating (at any expense), and so with the magic of the government money-printing machine: It does. But it's one of the most actively depressing industrial sites I've ever been to; like the life just gets sucked right out of you before even getting past the entrance gate.
We can certainly extend that kind of thing to transformer production. But should we?
Lead times increasing to four years doesn't necessarily mean that every order will take that long. Since the additional orders are just there to cover idle periods, the government could omit an expected delivery time so regular orders don't get delayed.
I think that would mean that the factory would switch from operating at 100% capacity (and never catching up), to 100% capacity (and never catching up).
For that kind of sameness, it seems like it'd be easier to do nothing at all.
I mean: I've got some MREs in the pantry along with some other shelf-stable food, and I've got some water stored (primarily to fill empty space in the chest freezer for various practical reasons, but it exists). I keep some basic first aid and survival stuff in the car (bandages, space blankets, stuff to catch fish with, stuff to cook with). I've got my camping gear, including a small off-grid solar power system, stored in organized totes that can be loaded up very quickly. And I try to keep a minimum of a couple hundred miles worth of fuel in the gas tank at all times.
I do these things just in case. The bulkiest items see frequent use. None of this cost me very much to buy, or to maintain. And none of these things can replace the lifestyle I've come to expect, but they might be able to buy me some time.
Can we afford to have a spare copy of the hard-to-produce parts of the electrical grid sitting in a warehouse?
Would we even want to rebuild the grid in the same shape if the shit really hit the fan and we had to start it over from scratch?
> Here's an AI-generated fake video of large transformer manufacturing. It's about half wrong.[2] But right enough to be worth watching. I'd like to see the prompts for this.
I'd like some sort of shared blocklist support for YouTube and Instagram. I'm sick and tired of content thieves and AI slop farms.
I worked in a machine shop of a large shipyard and 20 years ago they had CNC Winders for rebuilding armatures for Navy ships.
They replaced older versions that were NC winders.
So this "hand wound" story is just that.
Windings going into Oil Tank? I think you mean varnish tank... After the rotating assembly is balanced they go into a protective coating tank that is a varnish.
Afaik utility scale Transformers operate in cooling tanks. Maybe that's what they meant about "afterward" "oil" covers many things. I believe the constant cycling and thermal load can make heinous PCBs.
> So how did we get to a point where one component can hold trillion-dollar industries hostage? Turns out, a quirk of history made the entire world’s electricity systems reliant on transformers.
> At the end of the 19th century, when electricity was just starting to become a commercial source of energy, two businessmen fought to control its future in what came to be known as “the war of the currents.” Thomas Edison promoted the use of direct current (DC) and George Westinghouse, inventor and industrialist, was convinced that alternating current (AC) would prove more practical.
> In a clash of personality, finance and some genuine technical advantages, Westinghouse won out and the world has been mostly stuck with using AC as a means of generating and transmitting electricity. Transformers are necessary to make the AC system work.
This entire section is a glaring load of nonsense and needs to be removed. We had to start with AC for a variety of technical reasons, the main one being that boosting DC voltage pre-switching technology was impossible. DC cant pass through a transformer unless it is converted to some form of AC, usually in the form of PWM square waves these days. Before the invention of the mercury arc rectifier (And later valve) in 1902 you had boost DC using mechanical methods: generators. The problem there is physical, they did not have the ability to insulate the generator windings at high voltage potentials. They also had problems with DC voltages over 2000 volts on commutators [1] citing excessive arcing. Commutators are also a limiting factor in machine size as beyond several MW they dissipate too much power. So with all this the highest practical voltage for a DC grid using early electrical machinery is around 2 kV. Now imagine all that mechanical complexity on the distribution end. Meanwhile, early AC transmission was already in the tens of kilovolts: 11/22/33 kV (multiples of the early Edison 110 volt standard.)
As for the whole war of currents, I feel it is vastly overstated and was more a public spectacle than serious scientific dispute. It was already known from early on that AC was the future thanks to its ability to easily be transformed to higher voltages for transmission and back again with no moving parts. The "war" was likely Edison marketing to sell off the remaining inventory less desirable DC machinery.
Also it is quite a leap to the conclusion that HVDC eqipment will not have long lead times as well especially since there are quite a few less companies making it.
Yes this is the most glaring issue. There also two disconnects later in the article: at the end it laments how china has been increasing transformer manufacturing but the US government has done nothing. Then in the next sentence its mentions trumps tariffs have increased transformer costs, I. E. Government action to increase domestic production. It also glosses over the new DOE rule on how transformers are made…so maybe there is a larger story there relevant to the lack of supply.
Tariffs don't help onshore manufacturing when they apply to the materials that the manufacturing needs and might evaporate before the manufacturing capability is actually created. Tariffs needs to be applied carefully and consistently to actually encourage this.
Sure, I’m just saying the article was pretty long but pretty short and declarative on the impact of tariffs. Earlier in the article for example is said there was still a factory in the US where the magnetic core material was made.
We had targeted policies under Biden to increase US production of grid components. This entailed invoking the DPA and setting aside millions for manufacturing improvements. Trump paused all that and created blanket tariffs that don’t seem like they’re designed to onshore US manufacturing of these very specific components but do increase all the material costs. This is not an easy thing to fix with dumb tariffs, and it’s really easy to make everything worse.
I’m just noting the article doesn’t have anything specific of value to say about tariff’s. This is not directed at you but rather the reporters: I can read general opinions on tariffs or political parties anywhere; I need details relevant to transformers here to not just ignore other opinions
The early limit was because high voltage DC required producing it at the generator, whereas you could produce high voltage AC by generating at a lower voltage and then stepping it up with a transformer for long distance transmission.
The rules are changing because of switchmode voltage conversion, using transistors to switch the voltage at a high frequency, where the magnetics (transformers, inductors) can be much smaller and more efficient, then converting back to DC. This is how virtually all smaller power supplies have been made for years, the only question (which I don't know) being how far along we are at reaching the voltage levels of long distance transmission in this way.
I'd think that hustling us towards DC with electronic voltage conversion would be a reasonable strategic goal for dealing with the transformer problem, worthy of support by a government.
HVDC and UHVDC are used extensively for long distance transmission, notably for undersea cables and in China, which has made massive R&D investments in the technology in order to shift energy from West to East. Large solar, wind and hydro in the West.
However, DC does not make sense for a radial power distribution network. The article is propagating nonsense.
Virtually all HVDC transmission currently operating is point to point mostly for control reasons. My understanding is it's very difficult to coordinate multiple converter stations - power flow in DC networks is fully determined by the control systems of the converters unlike AC networks which in general lack active control devices (see the FACTS family of devices for examples that can be used in AC networks to actively control power flow).
Huge installed base of network elements, minimal efficiency improvements. Much better to invest in switch mode frequency stabilisation with batteries and soft open points (SOPs), which balance load between phases and distributors without needing a radial reconfiguration.
Radial DC is anachronistic thinking based on misunderstandings perpetuated by C-suite level just so stories like this Bloomberg nonsense.
> If a 100MW PV farm and a data center are separated by 1km (20 Olympic pools) - is there a way to avoid AC?
Not in any economical sort of way. A rectifier and two transformers is cheaper than directly switching HVDC. If you step up the voltage to 115kV, a 100MW three-phase AC circuit is only 500 amps.
That link talks about 5MW 35kv AC / 800v DC converters.. completely different thing, they try to sell a single-source PV invertor-to-35KV AC solution first, then 35KV to 800V DC second, to have a sorta complete solution of PV-to-datacenter. And it's only 5MW. And only 35KV AC. For moving 100MW even over a few km you would need 110KV at least. I think. An overhead wire can handle about 600A of current, that's the physical limit and the reason for kilovolts there.
Consider also that there is nothing existing in transmission and switching gear certified for HVDC it being rare one-off projects so far, while AC is ubiquitious, more-or-less mass-produced and many people are trained in its maintenance.
I mean if you wanna leapfrog china just throw more money into switched mode inverters and rectifiers. You don't have to use transformers. As long as you have a black cheque, there are plenty of options.
I think the article has things backwards. It's the shortage of stable demand that is holding back the building of transformers. A transformer factory that can make reliable, efficient, large transformers takes a long time to create because a lot of it relies on institutional memory. But it can be destroyed much more quickly by adverse market conditions and impatient investors.
Remember that the product has a typical lifetime measured in decades, there are huge numbers of large power transformers that have been in near continuous operation for over half a century. When one of those fails it is often more economical to repair it than replace it with a new one but that depends on there being institutions that understand what was done fifty years ago. All this requires the opposite of modern move fast and break things investing.
We had a decent domestic transformer manufacturing ecosystem for decades, and all the major manufacturers shut down their NA plants and moved them to South America to make a little bit more money. The problem is, as it often is, the perverse incentives of the religion of quarterly earning reports.
Capitalism is a fire - if you tend it well and regulate it, it serves a useful function. Let it burn out of control and it will consume everything.
We should learn something from the Cuban heavy transformer manufacturing enterprise. I mean I get that critical theory is that easy, but the step everyone always seem to
miss is a credible explanation how a centrally managed command economy is better. There is also basically no free market mechanisms functioning in power delivery in the United States. You can’t stick a solar panel in your backyard and sell the output.
>>You can’t stick a solar panel in your backyard and sell the output.
Sure you can. To everyone you run power lines to. Or did you mean you wanted a distribution system designed to profit you instead operate efficiently for everyone else?
> There is also basically no free market mechanisms functioning in power delivery in the United States. You can’t stick a solar panel in your backyard and sell the output.
Part of that is because most of the world's power grids are extremely dumb. There's no visibility anywhere, certainly not in real time - if you're lucky, there is some sort of alert monitor for overtemperature in local transformers, but no voltage/current monitoring on an individual consumer level and no current monitoring on both sides of a transformer.
Imagine a small pole transformer plus secondary-side distribution lines rated and fused for 100 kVA. Enough for a few farms. Now farm A and B each install an 80 kVAp solar panel set - and farm C, D and E consume 50 kVA each. Without the decentralized solar, the pole transformer fuse would have been triggered - but now, there's 150 kVA of consumption going on, fed by the 160 kVA solar panels, on a distribution line only supporting 100 kVA, that's now acting as a fuse. An immediate risk of damage, if not outright fire.
That is why large scale solar/wind or large consumers all need permits, plannings and sometimes dedicated lines and transformers.
The only other way to run a system without creating tons of new infra but still able to catch such dangerous situations is a detailed (!) network map on the utility side plus realtime monitoring of the transformer and all five farms input/output currents.
I've been wondering for awhile about the economics of the AC vs DC grid thing. Historically, AC made a lot more sense because transformers are simple and relatively straightforward to make. But now we have amazing capabilities to handle enormous amounts of power with modern IGBTs and similar power-switching transistors. (A modern high-end EV motor controller, for instance, might be able to handle a megawatt of power. Not continuously, but still.) Is a DC-DC converter now more economically viable than an equivalent transformer? The former is more techincally complicated, but the latter is bulky and requires large quantities of expensive input materials like copper.
A big problem with solid state electronics is fault current handling. The grid would become extremely brittle if it was purely a DC conversion setup. Semiconductors don't do too well outside their happy zone. All it takes is some wind and tree to fire up a very large arc welder. If you can't momentarily handle 10x+ the rated system capacity, you are gonna have a really bad time. Ordinary transformers in oil bath can take a hammering for many cycles. A semiconductor wouldn't make it through one.
That seems like it's within striking distance of competitive, no? You get some major advantages in size and production automation. Perhaps it's ok for it to die sooner if you can get it built now and then replace it later.
Or, alternatively, you switch to DC to get more current capacity over existing wires. (At a given voltage, a wire can generally carry more DC current because it doesn't have the same "skin effect" that AC has.) Even if the hardware at the substation is more expensive, it might be cheaper than upgrading the transmission lines.
well aside from being effectively 20 times more expensive over entire operation...
DC switches (as in, just a power switch) are vastly more expensive because while in AC you have 100 breaks in current a second, DC is constant so it is far harder to break. So even if you had device that could use both (not hard with SMPS, they have rectification as first step), it's still essentially " replace everything".
The protections side is a big problem - most HVDC has circuit breakers operating on the HVAC sides of the link so going to full DC transmission presumably wouldn't eliminate that equipment.
If you are not ready to lock yourself in a bunker after reading the article and watching that short, I strongly suggest you consider the inclined plane.
You’d better do it now. Very few locks work in the absence of transformers, springs and inclined planes.
That's in the ballpark of the Heathrow transformer that blew, I think.
I understand they will be not cheap, with tariffs and all, but nothing the Magnificent 7 or Heathrow could not afford.
It seems to me that (as the article points out) that production facilities are pretty old and production COULD be much more automated, and products improved if there was a will.
However, "Now those firms are seeing a rise in demand for transformers alongside the buildout of data centers for AI, but remain unsure if the trend will continue, says Gonzalez Isla. “Transformer companies aren’t going to open new plants only to shut it down after 10 years of business,” she says."
And THAT seems to be the crucial difference here between the transformer industry and, say, NVIDIA.
Standards/regulations that the transformers almost certainly don't meet, produced in factories that don't follow any standards or regulations, and then add in the cost and delay in shipping something like that.
China has the most sophisticated grid in the world, and is spending $100B a year on expanding and upgrading. They have a uniquely high share generated by renewables. It runs 800kV and will go higher after the upgrade. The first Small Modular Reactor will come online this year. If you think that’s all just being built in random factories without standards you’re very much mistaken.
China's energy generation mix is not uniquely high in renewables! Where on earth did you get that idea from? China has about the same % renewable generation as Australia, about 1/3rd. Brazil has 80%, Norway 90%, some have near 100%.
What China does have is a very high carbon emission intensity of electricity generation thanks to over half capacity coming from coal.
I was replying to a comment that brought up renewables. I can be of further assistance to help you follow the chain of comments if you let me know what part you're struggling with exactly.
The basic problem is easy to grasp, like the mess with charging cords for laptops before it, every large power transformer is a custom design. The fix would be to standardize on a much smaller number of options, and parallel them for the desired loads.
Think of it as analogous to USB-C power, on the megawatt/gigawatt scale. ;-)
People already parallel transformers. That's nothing new but it's usually undesirable because the extra ancillary equipment costs make paralleling more expensive than having a single transformer of equivalent rating if you are building it all at once.
But even fairly small standard specification distribution transformers are custom designs or very short runs. It's not economical to make the same design year after year because the relative prices of copper and core steel vary over time. A design made last year can be uneconomical to make this year because last year copper was relatively cheap so the designer used a lighter core and more copper to achieve the required efficiency. But if this year the copper price has gone up while the core steel price has gone down it would cost more to make the same design while the same specification could be achieved for a lower material cost by making a new design.
The new design is not a new type and for distribution transformers the effort required to design it is of the order of a man hour or two, far less than the difference in material costs.
For very large transformers (megavolt HVDC for instance) the situation is somewhat different and the design can take a very long time. But the opportunities for standardisation are relatively small because the quantity of units in the market is small and the manufacturers and regulators are always chasing ever greater efficiencies.
A far as specifications go there is already quite a lot of standardisation. But standards evolve over time and transformers can last for over half a century so you inevitably end up with a mixture of device types
Also, if one of your paralleled large power transformers fails you can't just buy an off the shelf replacement because no one keeps a stock of items that cost a million dollars each.
Switching to USB-C was trivial because most of the devices involved are essentially consumables with lifetimes measured in handfuls of years ad often much less so the old stuff withers away rapidly. That is not the case with large capital projects such as national electrical networks
And if we didn't have all these data centers would we still be "bottlenecked?"
Or is this a case of blind greedy investment outcompeting civilian life once again? Probably given that Bloomberg feels the need to throw it's voice for the cause.
Possibly the easiest way to bring any metropolitan area or region into the Stone Age for unknowable amounts of time is simply to destroy large, bespoke transmission (rather than distribution) transformers. Crazy people shooting out the cooling systems have done this several times.
Meaningful grid security means these items need rapid, standardized, domestic production capacity and cold spares distributed offsite and ready to be deployed should anything happen to ones in use. These are critical items that must not be neglected to reactive actions disaster recovery.
It might be easier for DC transmission components to be standardized. Sure, anything with complex controls has a lot more opportunity to fail to interoperate, but DC gear can often be configured for different voltage ratios and can much more directly control how much current flows where.
Maybe the grid needs a multi-source agreement for equipment like the network industry has for optics.
Also the sewer system backs up after about a week because the pumping and lift stations need power to operate.
The water system shuts down because the tanks aren't reserve supply they're pressure support.
And solar plus storage will keep you running for maybe a week if you're conservative and mostly don't use anything...which doesn't help you if it's months till replacement.
solar + storage + water sheath fireplace can run pretty much till you run out of wood.
But yes, unless you spend serious money (own sewer, water from underground etc), it's basically solution for "the power pole is down", not any grid wide problems.
> unless you spend serious money (own sewer, water from underground etc)
It is often the case (at least where I live) that having a septic system and well is far more economical than obtaining a property with access to city utilities.
Way stations still need power to accept and refrigerate shipments. Distribution isn't just on trucks - although they could act as a small stopgap that also prevents them from making deliveries while being used as storage.
"Transformers are necessary to make the AC system work."
This isn't quite wrong but the motivation is backwards: AC is necessary to make transformers work.
1. All grids need to move energy at high voltage and low current to minimize losses.
2. This requires a mechanism to step voltages up and down for transmission.
3. In 1890 the only such mechanism was the transformer.
4. Transformers only work on AC, not DC.
Hence our legacy grid is AC.
Nowadays we have an additional mechanism: Power electronics. Power electronics work on both AC and DC, so transformers with their huge requirements for copper and steel are no longer necessary.
We need to accelerate the transition of our grid to DC because DC grids are simpler and cheaper than AC grids.
Grid-scale power electronics are also extremely niche and expensive, perhaps moreso than transformers. HVDC is used where it has a significant advantage, but ease of conversion is not one of those.
> so transformers with their huge requirements for copper and steel are no longer necessary.
smelting some copper and steel and wounding it up is far, far, far, far cheaper than replacing it with power silicon(which might be smaller, but overall needs tons more of energy to produce)
It will be also less reliable. Transformers deal with any overload far better and routinely run for like 50+ years
transformers are infrastructure, 100% duty cycle with a significant overload capacity that can be 3 times name plate, right there with dams and bridges, and if one developes a fault, realy bad things happen and you get a crater.
There very nature makes them imensely heavy and very compact, all of the equipment used to form the parts is gargantuan, and materials to build them come in units that must be moved by house sized forklifts, consider changing a tire on such a forklift.
Remember that the largest transformers travel on the heaviest rail cars, specials, these things are way heavier than anything else per ft³.
Which gets us to cold,warm, or hot idle, or decomisioning, which are your choices when a huge factory has no work, hot idle means limited production, warm means some of the guys hang out and tinker with stuff, cold means, locked up,no employees but security, as decomisioning something like this has strategic considerations, or should.
An article that deeply buries the lede under elementary facts about electrical transmission.
Transformers are made in specialized factories and use specialized components made in even more specialized factories. Expanding production requires not just immediate demand but commitment to future demand because a factory is a very expensive thing. The big thing is that increased demand often involves a demand that won't continue for a long period of time.
You could see the same thing with both masks and vaccines during covid - ramping up ten factories to meet a temporary demand would be very expensive.
Maybe few manufacturers of specialized components colluded to not increase much production capacity, even with increased demand, so that prices don't collapse.
They're also heavy. The tragedy of Russia destroying the Ukrainian An-225 was it was one of the only ways to move very big grid scale transformers on short notice.
The build teams aren't that big - 30-50 people. The main barrier to entry is that it takes people who know how to hand-build big transformers. Utility buyers want a supplier who's going to be around half a century from now, since these things last that long.
Here's a summary of the market, from a transformer maker in China.[1]
Here's an AI-generated fake video of large transformer manufacturing. It's about half wrong.[2] But right enough to be worth watching. I'd like to see the prompts for this.
Virginia Transformer is the US's biggest maker of large transformers.[3] They advertise their "short lead times" of two years. The margins are low, and makers don't want to go idle between orders. This is a problem with much heavy machinery. It could be built faster, but when you catch up, everybody gets laid off and the factory sits idle. There goes your profit margin.
[1] https://energypowertransformer.com/2025-u-s-power-transforme...
[2] https://www.youtube.com/watch?v=ZVVCCG0KkaE
[3] https://www.vatransformer.com/shortest-lead-times/
You probably got a lot from this video, because you know which half is wrong. I'd probably get negative knowledge from this video, because I don't.
This may be a new incarnation of the "curse of knowledge," where one over-estimates the value of AI slop if they already know the subject...
For comparison, here's the real deal - transformer winding at Virginia Transformer in the US.[1] That video provides a good sense of why these things take so long to make. All those wooden parts. All that slowly and carefully hand wound heavy wire. As they point out, if that wire can move at all, as the magnetic fields pushes and pulls on it, the vibration will, over time, wear out the transformer. It's a very fussy job to get the position and tension right, with wire firmly supported against movement in all directions. That's the difference between a lifetime of a few years and many decades.
It's a boring video.
Here's the whole manufacturing process at ETD in the Czech Republic.[2] This shows roughly the same sequence of steps as the fake video, but it's real. Big industrial bay with lots of transformers and overhead cranes. Sheets of lamination steel. Winding. The moving and shipping of the big transformer. All that is in both the real video and the AI slop. This is the real video from the manufacturer, and it assumes that if you're watching, you know what you're looking at. There's little narration.
It's a confusing video.
Here's a small open frame transformer.[3] If you've done much electrical or electronics work, you've seen one, and may have replaced or installed one. When you see the big ones being built, the process makes sense. Same concept, with a laminated core, windings, insulation, and lead wires. The big ones have the same key parts, just much bigger. But if you don't know a transformer from a transistor, the manufacturer videos are just wallpaper.
And there's the problem. The AI slop version will give the average viewer a general idea of the process. The accurate videos from manufacturers require more background knowledge to comprehend. The target audience is different. The manufacturers don't make those videos for the general public.
[1] https://www.youtube.com/watch?v=Bodj4f3L4RU
[2] https://www.youtube.com/watch?v=G3O979En_kQ
[3] https://www.mscdirect.com/product/details/20594073
Dumb question: why can’t we mass manufacture smaller transformers and join them up?
https://en.wikipedia.org/wiki/Transformer#Construction
If you’re really careful you could have parallel sets of series transformers feeding into a common feed.
At a much larger scale, that is exactly what the grid is, actually.
It just sucks dramatically from an operational perspective compared to having one correctly sized transformer.
It’s the same kind of problem.
(And notably, it’s not that it’s actually completely impossible to do it that way - just impractical compared to the alternative. You could actually make something that kind of sorta worked for an aircraft carrier by joining tens of thousands of small pontoons and support ships. Operationally, it would just suck compared to the alternative.)
https://commoncog.com/cash-flow-games/#3-pre-payments-in-the...
Liquidity is expensive. Selling a carrier one at a time is like a retail business where you're expected to hold onto stock. If you don't build up an inventory to sell from and just sell one unit, you have to markup the price to cover the cost of the factory when it is idle.
Now that it's gone we're ultra dependent on a by-product of methane extraction and liquification for LNG transport. But most of the helium we extract as natural gas is not separated, as it just gets piped as gas. Helium is getting very very expensive.
But amplifying the orders just makes the problem worse.
That means that eventually the factory goes idle, when all the demand is serviced by the spares.
They have been:
https://www.energy.gov/oe/transformer-resilience-and-advance...
The problem expressed, I think, that it is not useful to scale up production quickly (or perhaps at all), because a factory catching up on all of their orders means that the factory goes idle. Idle factories can't afford to pay wages, so they lay off some or all of the workers -- and those folks go and find different jobs.
And when they leave, they take their institutional knowledge with them.
So the sustainable goal is to never be idle, and the way to accomplish this is to never catch up.
For an example of how idle factories can go sideways, look at the Polaroid film story: Polaroid closed. Everyone left. Some investors with a big dream eventually bought many of the physical assets that remained.
But owning some manufacturing equipment didn't help them much because the institutional knowledge of producing Polaroid film had already evaporated. They had to largely re-invent the process. (And they've done a great job of that, but it's still not the same film as the OG Polaroid was.)
---
So anyway, suppose the government steps in and simply artificially multiplies transformer orders x2, and pays them fairly for this doubled production. Since transformers are tangible things and we can't just spin up more AWS instances to cover demand, the immediate result is that the "short" lead time on new orders has increased from 2 years, to 4.
That's not seeming to be very ideal. It seems to amplify the problem instead of resolve it.
I suppose that the government could also offer safeguards that would help protect the businesses (including suppliers for parts) once they eventually catch up on orders, and that this might motivate them to scale production sooner instead of later (or never).
Which -- you know -- that isn't unprecedented. As an example: The Lima Army Tank Plant, in Lima, Ohio, is place where I've spent a fair bit of quality time. It still exists and continuously has employees largely because the institutional knowledge of how to build tanks (and a few other war machines) is considered to be too important to lose. During lulls, it mostly just sits there on its expansive site, loafing along repairing stuff that comes in, and waiting for the day when things to turn bad enough that we need to start increasing our number of tanks again.
It needs to keep operating (at any expense), and so with the magic of the government money-printing machine: It does. But it's one of the most actively depressing industrial sites I've ever been to; like the life just gets sucked right out of you before even getting past the entrance gate.
We can certainly extend that kind of thing to transformer production. But should we?
For that kind of sameness, it seems like it'd be easier to do nothing at all.
I mean: I've got some MREs in the pantry along with some other shelf-stable food, and I've got some water stored (primarily to fill empty space in the chest freezer for various practical reasons, but it exists). I keep some basic first aid and survival stuff in the car (bandages, space blankets, stuff to catch fish with, stuff to cook with). I've got my camping gear, including a small off-grid solar power system, stored in organized totes that can be loaded up very quickly. And I try to keep a minimum of a couple hundred miles worth of fuel in the gas tank at all times.
I do these things just in case. The bulkiest items see frequent use. None of this cost me very much to buy, or to maintain. And none of these things can replace the lifestyle I've come to expect, but they might be able to buy me some time.
Can we afford to have a spare copy of the hard-to-produce parts of the electrical grid sitting in a warehouse?
Would we even want to rebuild the grid in the same shape if the shit really hit the fan and we had to start it over from scratch?
I'd like some sort of shared blocklist support for YouTube and Instagram. I'm sick and tired of content thieves and AI slop farms.
They replaced older versions that were NC winders.
So this "hand wound" story is just that.
Windings going into Oil Tank? I think you mean varnish tank... After the rotating assembly is balanced they go into a protective coating tank that is a varnish.
> At the end of the 19th century, when electricity was just starting to become a commercial source of energy, two businessmen fought to control its future in what came to be known as “the war of the currents.” Thomas Edison promoted the use of direct current (DC) and George Westinghouse, inventor and industrialist, was convinced that alternating current (AC) would prove more practical.
> In a clash of personality, finance and some genuine technical advantages, Westinghouse won out and the world has been mostly stuck with using AC as a means of generating and transmitting electricity. Transformers are necessary to make the AC system work.
This entire section is a glaring load of nonsense and needs to be removed. We had to start with AC for a variety of technical reasons, the main one being that boosting DC voltage pre-switching technology was impossible. DC cant pass through a transformer unless it is converted to some form of AC, usually in the form of PWM square waves these days. Before the invention of the mercury arc rectifier (And later valve) in 1902 you had boost DC using mechanical methods: generators. The problem there is physical, they did not have the ability to insulate the generator windings at high voltage potentials. They also had problems with DC voltages over 2000 volts on commutators [1] citing excessive arcing. Commutators are also a limiting factor in machine size as beyond several MW they dissipate too much power. So with all this the highest practical voltage for a DC grid using early electrical machinery is around 2 kV. Now imagine all that mechanical complexity on the distribution end. Meanwhile, early AC transmission was already in the tens of kilovolts: 11/22/33 kV (multiples of the early Edison 110 volt standard.)
As for the whole war of currents, I feel it is vastly overstated and was more a public spectacle than serious scientific dispute. It was already known from early on that AC was the future thanks to its ability to easily be transformed to higher voltages for transmission and back again with no moving parts. The "war" was likely Edison marketing to sell off the remaining inventory less desirable DC machinery.
1. https://en.wikipedia.org/wiki/Commutator_(electric)
What is a current (pun!) practical limit?
If a 100MW PV farm and a data center are separated by 1km (20 Olympic pools) - is there a way to avoid AC?
I know there are future solutions [1]
[1] https://techcrunch.com/2025/04/07/former-tesla-exec-drew-bag...
The rules are changing because of switchmode voltage conversion, using transistors to switch the voltage at a high frequency, where the magnetics (transformers, inductors) can be much smaller and more efficient, then converting back to DC. This is how virtually all smaller power supplies have been made for years, the only question (which I don't know) being how far along we are at reaching the voltage levels of long distance transmission in this way.
I'd think that hustling us towards DC with electronic voltage conversion would be a reasonable strategic goal for dealing with the transformer problem, worthy of support by a government.
However, DC does not make sense for a radial power distribution network. The article is propagating nonsense.
Why not? Pure geeky curiosity.
Point to point is just two nodes, but scaling that outward would be very expensive
AC transmission is relatively cheap in comparison
Radial DC is anachronistic thinking based on misunderstandings perpetuated by C-suite level just so stories like this Bloomberg nonsense.
Not in any economical sort of way. A rectifier and two transformers is cheaper than directly switching HVDC. If you step up the voltage to 115kV, a 100MW three-phase AC circuit is only 500 amps.
Consider also that there is nothing existing in transmission and switching gear certified for HVDC it being rare one-off projects so far, while AC is ubiquitious, more-or-less mass-produced and many people are trained in its maintenance.
Remember that the product has a typical lifetime measured in decades, there are huge numbers of large power transformers that have been in near continuous operation for over half a century. When one of those fails it is often more economical to repair it than replace it with a new one but that depends on there being institutions that understand what was done fifty years ago. All this requires the opposite of modern move fast and break things investing.
Capitalism is a fire - if you tend it well and regulate it, it serves a useful function. Let it burn out of control and it will consume everything.
Sure you can. To everyone you run power lines to. Or did you mean you wanted a distribution system designed to profit you instead operate efficiently for everyone else?
Part of that is because most of the world's power grids are extremely dumb. There's no visibility anywhere, certainly not in real time - if you're lucky, there is some sort of alert monitor for overtemperature in local transformers, but no voltage/current monitoring on an individual consumer level and no current monitoring on both sides of a transformer.
Imagine a small pole transformer plus secondary-side distribution lines rated and fused for 100 kVA. Enough for a few farms. Now farm A and B each install an 80 kVAp solar panel set - and farm C, D and E consume 50 kVA each. Without the decentralized solar, the pole transformer fuse would have been triggered - but now, there's 150 kVA of consumption going on, fed by the 160 kVA solar panels, on a distribution line only supporting 100 kVA, that's now acting as a fuse. An immediate risk of damage, if not outright fire.
That is why large scale solar/wind or large consumers all need permits, plannings and sometimes dedicated lines and transformers.
The only other way to run a system without creating tons of new infra but still able to catch such dangerous situations is a detailed (!) network map on the utility side plus realtime monitoring of the transformer and all five farms input/output currents.
DC switches (as in, just a power switch) are vastly more expensive because while in AC you have 100 breaks in current a second, DC is constant so it is far harder to break. So even if you had device that could use both (not hard with SMPS, they have rectification as first step), it's still essentially " replace everything".
I challenge you to name one that cannot and that also makes it into high school curricula or How Things Work.
https://mst3k.fandom.com/wiki/A_Case_of_Spring_Fever_(short)
https://m.youtube.com/watch?v=vzKfAFsbRSk
If you are not ready to lock yourself in a bunker after reading the article and watching that short, I strongly suggest you consider the inclined plane.
You’d better do it now. Very few locks work in the absence of transformers, springs and inclined planes.
E.g., https://lindahongli.en.made-in-china.com/product/SAapQolWVUY...
That's in the ballpark of the Heathrow transformer that blew, I think.
I understand they will be not cheap, with tariffs and all, but nothing the Magnificent 7 or Heathrow could not afford.
It seems to me that (as the article points out) that production facilities are pretty old and production COULD be much more automated, and products improved if there was a will.
However, "Now those firms are seeing a rise in demand for transformers alongside the buildout of data centers for AI, but remain unsure if the trend will continue, says Gonzalez Isla. “Transformer companies aren’t going to open new plants only to shut it down after 10 years of business,” she says."
And THAT seems to be the crucial difference here between the transformer industry and, say, NVIDIA.
https://evernewtransformer.com/pt/how-to-purchase-power-tran...
If I were to desperately need a power transformer, I'd consider going down this route in parallel to waiting for years for a "blessed" one.
What China does have is a very high carbon emission intensity of electricity generation thanks to over half capacity coming from coal.
Think of it as analogous to USB-C power, on the megawatt/gigawatt scale. ;-)
But even fairly small standard specification distribution transformers are custom designs or very short runs. It's not economical to make the same design year after year because the relative prices of copper and core steel vary over time. A design made last year can be uneconomical to make this year because last year copper was relatively cheap so the designer used a lighter core and more copper to achieve the required efficiency. But if this year the copper price has gone up while the core steel price has gone down it would cost more to make the same design while the same specification could be achieved for a lower material cost by making a new design.
The new design is not a new type and for distribution transformers the effort required to design it is of the order of a man hour or two, far less than the difference in material costs.
For very large transformers (megavolt HVDC for instance) the situation is somewhat different and the design can take a very long time. But the opportunities for standardisation are relatively small because the quantity of units in the market is small and the manufacturers and regulators are always chasing ever greater efficiencies.
A far as specifications go there is already quite a lot of standardisation. But standards evolve over time and transformers can last for over half a century so you inevitably end up with a mixture of device types
Also, if one of your paralleled large power transformers fails you can't just buy an off the shelf replacement because no one keeps a stock of items that cost a million dollars each.
Switching to USB-C was trivial because most of the devices involved are essentially consumables with lifetimes measured in handfuls of years ad often much less so the old stuff withers away rapidly. That is not the case with large capital projects such as national electrical networks
Or is this a case of blind greedy investment outcompeting civilian life once again? Probably given that Bloomberg feels the need to throw it's voice for the cause.
But whenever it’s AI data centers being discussed, they’re not talked about as a tax, but that they don’t have enough power.
As if the former is a detriment to humanity and the latter is a benefit that deserves more resources, when the opposite is extremely true.
“Hello! I like money!” - Mr. Krabs
Or perhaps there’s even some Malthusianism at play?
Meaningful grid security means these items need rapid, standardized, domestic production capacity and cold spares distributed offsite and ready to be deployed should anything happen to ones in use. These are critical items that must not be neglected to reactive actions disaster recovery.
https://en.wikipedia.org/wiki/Metcalf_sniper_attack
https://en.wikipedia.org/wiki/Moore_County_substation_attack
https://en.wikipedia.org/wiki/Electrical_grid_security_in_th...
Maybe the grid needs a multi-source agreement for equipment like the network industry has for optics.
The water system shuts down because the tanks aren't reserve supply they're pressure support.
And solar plus storage will keep you running for maybe a week if you're conservative and mostly don't use anything...which doesn't help you if it's months till replacement.
But yes, unless you spend serious money (own sewer, water from underground etc), it's basically solution for "the power pole is down", not any grid wide problems.
It is often the case (at least where I live) that having a septic system and well is far more economical than obtaining a property with access to city utilities.
They're off grid, and can be swapped out if the PV panels or immersion pumps fail.
Ideally you should be pumping into tanks in any case, for the buffer, and those tanks can be placed on a hill to gravity feed .. or pump with a motor.
Here's a typical setup, sans old windmill: https://youtu.be/iZAMm_S3GNQ?t=383
(same rough area (W.Australian wheatbelt) not our land)
You'd be better off with an air sourced hear pump for hot water anyway - the one in my house uses less power then my dehumidifier.
Which have days worth of backup generator power
> refrigerated food distribution
Do you think refrigerated trucks trail big long extension leads to a socket somewhere?
This isn't quite wrong but the motivation is backwards: AC is necessary to make transformers work.
1. All grids need to move energy at high voltage and low current to minimize losses.
2. This requires a mechanism to step voltages up and down for transmission.
3. In 1890 the only such mechanism was the transformer.
4. Transformers only work on AC, not DC.
Hence our legacy grid is AC.
Nowadays we have an additional mechanism: Power electronics. Power electronics work on both AC and DC, so transformers with their huge requirements for copper and steel are no longer necessary.
We need to accelerate the transition of our grid to DC because DC grids are simpler and cheaper than AC grids.
smelting some copper and steel and wounding it up is far, far, far, far cheaper than replacing it with power silicon(which might be smaller, but overall needs tons more of energy to produce)
It will be also less reliable. Transformers deal with any overload far better and routinely run for like 50+ years
Transformers are made in specialized factories and use specialized components made in even more specialized factories. Expanding production requires not just immediate demand but commitment to future demand because a factory is a very expensive thing. The big thing is that increased demand often involves a demand that won't continue for a long period of time.
You could see the same thing with both masks and vaccines during covid - ramping up ten factories to meet a temporary demand would be very expensive.
This is a problem in strategic reserve territory.