More states revolt against datacenters - Historico da BBS TELESC.NET.BR

BBS:      TELESC.NET.BR
Assunto:  More states revolt against datacenters
De:       Mike Powell
Data:     Thu, 30 Apr 2026 10:35:30 -0500
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'The storm is here': Why you and your neighbors may be paying 
multibillion-dollar bill for AI data centers right now  but that may not last 
long as more US states join revolt against unjust 'socialist' approach to 
electricity bills

Date:
Wed, 29 Apr 2026 21:05:00 +0000

Description:
The hidden cost of AI: How data centers are driving electricity prices higher 
across multiple states, affecting you and your neighbors.

OPINION

Your electricity bill may soon
carry hidden costs tied to a technology boom you never asked for  and in some 
states, utilities are already spending billions to support it. Across the 
United States, the rapid expansion of AI data centers is forcing major grid 
upgrades at a pace rarely seen before. These hyperscale facilities, built to 
train and run artificial intelligence models, can consume as much electricity 
as entire towns, but in many cases, the cost of building the new 
infrastructure needed to support them is not being paid by the companies 
driving the demand. Instead, it is spread across residential customers 
through higher rates.

That practice is now under growing scrutiny from lawmakers, regulators, and 
grid operators who warn that households are being asked to subsidize private 
infrastructure. Not shifting costs onto other customers On April 24, 
regulators in Wisconsin issued a ruling requiring data centers to cover the 
full cost of the power infrastructure they require, explicitly stating that 
utilities must not shift those costs onto other customers. 

The decision, issued by the Wisconsin Public Service Commission, marked a 
shift from policy debate to enforceable regulation built around the 
beneficiary-pays principle. 

Similar legislation has already passed in states including Florida and 
Pennsylvania during the current session, suggesting the approach is spreading 
quickly as more states move to prevent residential customers from absorbing 
the cost of private infrastructure.

At the same time, questions are being asked about whether projected data 
center demand will materialize at the scale utilities once expected. 

The Electric Reliability Council of Texas (ERCOT), which manages electricity 
for roughly 90% of the state, recently acknowledged that its long-term demand 
forecasts are likely overstated, raising concerns that consumers could end up 
funding infrastructure built for growth that never fully arrives. 

I wanted to know more, so I spoke with Dr. Mark McNees , a Florida State 
University Jim Moran College of Entrepreneurship professor and author of the 
policy brief Who Pays for the AI Grid?  (linked in article link below)

He explained how AI data center expansion is driving electricity costs onto 
households, why utilities risk overbuilding infrastructure based on uncertain 
demand, and what states can do right now to ensure companies pay for the grid 
capacity they require. A storm is brewing when it comes to the real cost 
associated with AI data centers. How big is this storm, and what are the 
risks if left unchecked? The storm is not coming. It is here, and it arrived 
faster than most policymakers expected. 

The U.S. Energy Information Administration projects that electricity demand 
from data centers will double by 2030. That number sounds abstract until you 
translate it into consequences on the ground. 

Pennsylvania residential electricity rates rose 21.7% in 2025. West Virginia 
utility bills are now exceeding the average monthly mortgage payment in some 
households. Maryland electric bills are set to rise this summer as PJM, the 
grid operator serving 65 million people, struggles to handle data center 
demand it wasn't built to handle. 

This week, CNBC reported that the data center issue is threatening incumbent 
politicians in four competitive Pennsylvania congressional races. This is no 
longer an energy policy debate. It is a kitchen table economic issue in swing 
districts across the country. 

The structural problem is straightforward. A data center connecting to the 
existing grid triggers infrastructure upgrades: transformer upgrades, new 
transmission lines, and substation expansions. 

Those costs get socialized through the rate base, meaning every household and 
small business in the utility's territory pays a share of infrastructure they 
never asked for and will never directly use. The data center captures all of 
the commercial benefits. The ratepayer absorbs the capital cost. 

The risk of being left unchecked is not just high electricity bills. It is a 
stranded infrastructure. If a utility overbuilds to serve demand projections 
that later prove inflated, and data center demand shrinks because AI 
efficiency improves or contracts expire, those capital costs do not 
disappear. They sit in the rate base for decades, paid by ratepayers. 

That is cost externalization at one remove, and current policy frameworks in 
most states do not require regulators to stress-test demand projections 
before approving the infrastructure investment.

Who Pays for AI Data Center Power? Fair Utility Rates, Solar+Storage, and
Floridas SB 484 -- https://youtu.be/ggi7pcG5cvk?si=ZpR8b934OzSqNa-6

Do you see a parallel in which some of the same hyperscalers leveraged 
telco infrastructure to build their empires? Remember the whole Net 
Neutrality debate from early 2000? The parallel is almost exact, which is 
worth noting. 

In the Net Neutrality era, the same companies now building data centers 
successfully argued that they should not be required to pay for the bandwidth 
their platforms consumed. Telecom companies had built the pipes. 

Tech companies rode those pipes to trillion-dollar valuations. When telecom 
providers argued they should be able to charge heavy users more to recover 
infrastructure costs, the tech industry responded with a coordinated 
campaign: charging heavy users more would stifle innovation, hurt consumers, 
and concentrate power in the hands of incumbent carriers. 

The argument now is identical, just one layer deeper in the infrastructure 
stack. Instead of pipes, it is the physical grid. And the response from the 
tech industry follows the same script: requiring data centers to fund the 
infrastructure, their load demands will slow AI development, cost jobs, and 
hurt the communities that host these facilities. 

The difference this time is that the cost of physical infrastructure is 
harder to obscure. You cannot download more transmission capacity. You have 
to build it, and it costs real money, and someone has to pay for it. 

The question is simply whether the entity creating the demand is the 
households and small businesses on the same grid, who had no say in the 
matter. 

There is also a timing dimension that did not exist in the Net Neutrality 
debate. The telecom infrastructure was already built before the dispute. 

The grid infrastructure for AI data centers is being decided right now, in 
state legislatures and regulatory proceedings across the country. 

The policy window is open and moving fast. That is different from a Net 
Neutrality fight over infrastructure that had already been paid for. Given 
how quickly things are evolving, can anything be done right now to eliminate 
the problem of socializing the cost of private grid infrastructure? Yes, and 
three states have already proved it this year. 

Florida passed SB 484 this legislative session. Pennsylvania passed HB 2606. 
This week, the Wisconsin Public Service Commission issued a ruling requiring 
data centers to cover the full cost of their energy needs, with explicit 
language that those costs must not be shifted to other customers. 

The policy fix is not a complicated concept. The entity that creates the load 
funds the infrastructure it demands. The implementation question is harder 
because utilities and data center developers will argue over how to calculate 
the attributable cost of a connection and what to do when demand fluctuates. 

Those are solvable technical problems. The harder work is political, because 
the same companies building these data centers are also significant for 
employers and political donors in the communities where they operate. 

Practically, what you can do right now: require data centers to fund the 
capital costs of any transmission or distribution upgrades needed to serve 
their connection. Require them to post a bond or performance guarantee 
against the demand they project. And require utilities to submit demand 
durability analysis before regulators approve major infrastructure 
investments, so that projections are scrutinized rather than accepted at face 
value. 

I am also in direct conversations with Florida state regulators on the 
implementation side of SB 484, so I have visibility into how the enforcement 
piece is actually taking shape on the ground. 

The White House extracted a pledge from major tech hyperscalers to 
voluntarily fund grid upgrades. That is a start, but a pledge without an 
enforcement mechanism is a press release. The states writing enforceable law 
are ahead of the federal posture on this. It's not a secret that the US grid 
is almost at breaking point, thanks partly to a lack of investment and 
long-term vision. Could it be that the grid itself becomes the hard upper 
ceiling on how fast and how far data centers are built? In some markets, it 
already is. 

Northern Virginia is the largest data center market in the world. Dominion 
Energy has been telling developers for two years that available substation 
capacity in parts of that market is exhausted. Some developers are waiting 
years in interconnection queues. 

High-voltage transformers currently have delivery timelines of 24 to 30 
months, with some specialty equipment at four years. You cannot build a grid 
at the pace Big Tech wants to build data centers. The physics and the 
manufacturing supply chain do not cooperate with the investment timeline. 

The smarter operators have already figured this out and are building on-site 
generation specifically to bypass the interconnection queue. Meta's facility 
in Aiken, South Carolina, installed 100 megawatts of on-site solar to reduce 
its reliance on the grid. 

 Google 's Project Pegasus in Georgia includes a dedicated on-site 
substation. This is not altruism. It is a faster path to capacity than 
waiting for a utility to upgrade infrastructure for years. 

The risk is that operators who cannot or will not fund their own generation 
continue to rely on the existing grid, exhaust available capacity, and force 
utilities to request rate cases to fund expensive upgrades. 

That cycle is already running in Michigan, Maryland, and elsewhere. The grid 
is not breaking, but it is bending under load it was not designed to carry, 
and the repair bill is landing on ratepayers. Isn't there a risk that many of 
the clients using the power-hungry AI data centers are just buying time until 
something better comes up, therefore removing, in their views, the need to 
invest sustainably in the grid? This is the most underreported risk in the 
entire debate, and almost no one is discussing it at the policy level. 

Some of these buildouts are not driven by measured demand projections. It is 
driven by competitive fear. Companies are reserving capacity not because they 
know they will use it, but because they cannot afford to let a competitor 
have it first. 

That is not a durable, long-term electricity demand. It is fear-driven 
capital expenditure, and fear-driven capex tends to correct when the fear 
subsides or the competitive dynamics shift. 

AI efficiency is also improving at a rate that electricity demand projections 
do not fully account for. The DeepSeek announcement earlier this year 
demonstrated that models can produce comparable output at dramatically lower 
cost. 

If the energy footprint per inference drops by 70 or 80 percent over the next 
four to five years, a significant portion of the grid infrastructure 
currently being built will not be needed at the projected scale. 

The infrastructure, however, will already be built, and the cost will already 
be in the rate base. 

ERCOT's admission this week that its long-term Texas demand forecast is 
"likely overstated" is the most important sentence published in the energy 
industry in months. 

The organization responsible for keeping the lights on for 90% of Texas is 
publicly saying it may have been oversold on data center demand projections. 
That is the durability problem with demand made explicit and on the record. 

The policy fix is a demand stress-test requirement. Before a utility can get 
regulatory approval to build major new infrastructure to serve data center 
demand, it should be required to demonstrate that the demand is contractually 
committed, not just projected. 

Regulated utilities should not be allowed to build speculative infrastructure 
on the backs of ratepayers, even when a tech company is doing the 
speculation. In most states right now, they can. Based on your research, is 
it feasible for these companies to become energy-independent, or is the 
reliance on the public grid an unavoidable feature of the current AI gold 
rush? Partial energy independence is feasible right now. Full independence is 
a longer-horizon question. 

Solar paired with battery storage can realistically cover 30 to 60 percent of 
a large data center's energy load at current economics, depending on 
location, land availability, and storage capacity. It is now the cheapest and 
fastest way to deploy new generation capacity, faster to build than gas 
turbines, and cheaper per megawatt-hour over a 20-year horizon. 

When Meta built its Aiken, South Carolina, facility, it partnered with a 
solar developer to install 100 megawatts of on-site generation. That was not 
a sustainability statement. It was the fastest path to the capacity it 
needed. 

For baseload power at hyperscale, 24 hours a day, seven days a week, the 
current technology stack hits a ceiling. Battery storage at the scale 
required to power a one-gigawatt data center for extended periods remains 
cost-prohibitive. 

Small modular nuclear reactors are the most credible path to full energy 
independence for large facilities, but commercial deployment at scale is 
eight to ten years away under optimistic scenarios. 

The grid as a backstop is unavoidable in the near term. Which is exactly why 
the accountability argument matters. If you are going to rely on the public 
grid as your emergency capacity, you should fund the infrastructure that 
capacity requires. 

The companies making the largest AI infrastructure investments in history can 
afford to pay for the grid upgrades their facilities demand. The question is 
whether they will be required to, or whether they will continue to 
externalize that cost while internalizing the commercial benefit. 

The states that have answered that question clearly are ahead. The rest are 
still deciding.

Link to news story:
https://www.techradar.com/pro/the-storm-is-here-why-you-and-your-neighbors-may
-be-paying-multibillion-dollar-bill-for-ai-data-centers-right-now-but-that-may
-not-last-long-as-more-us-states-join-revolt-against-unjust-socialist-approach
-to-electricity-bills

$$
--- MultiMail/DOS
 * Origin: Capitol City Hub (1:2320/105)

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