Is 100 Percent Renewable Energy Possible?

By Paul Homewood


An interesting analysis from energy expert, Norman Rogers at American Thinker:


American Thinker

The people who are best described as members of a renewable energy cult are lately promoting the idea that we should run the country on 100% renewable energy, whatever that is.  I say “whatever that is” because different branches of the cult have different definitions of renewable energy.  It seems to be a matter of fashion and prejudice.

One definition of renewable energy is that it is naturally replenished on a human timescale.  Solar energy and wind energy fit in nicely with that definition.  Most fans of renewable energy explicitly reject renewable hydroelectricity if it involves damming a river.  Most renewable energy-lovers are also dam-haters.  They literally feel that fish are more important than people.

Global warming, which supposedly is caused by emissions of CO2 from burning fossil fuels, is frequently cited as a justification for using renewable energy.  But hydro and nuclear, energy that does not emit CO2, is excluded from the renewable universe.

The only energy that satisfies all branches of the cult and can be scaled up to provide large amounts of energy is wind and solar.  Even if hydro were allowed, there are not enough good sites to provide enough energy for the needs of the U.S.  Hydro currently supplies only 7% of our electricity.  The problem with wind and solar is that they make for erratic energy that comes and goes.  In the case of solar, it goes every night.

If we are to power the country on wind and solar, there has to be a way to fill the gaps when the wind dies or the sun sets.  Currently, that job falls mostly on fossil fuel plants that are abused to speed up and slow down as necessary to compensate for the erratic wind and solar.  The fossil fuel plants are being abused because they were not originally designed for ramping up and down rapidly to follow wind and solar.

The Texas electric system has a large wind power element, capable of generating 18,000 megawatts if every wind turbine is receiving sufficient wind.  On average, the system provides about 6,000 megawatts, sometimes more and sometimes less, with rapid variations.  The erratic nature of the Texas wind generation is illustrated by the graph below, showing hour-by-hour generation for ten days in 2016.

If Texas wind power were a core source of power, the ups and downs would have to be smoothed out.  If backup generating plants are not used, storage of electricity is necessary, storing electricity when output is too high and releasing stored electricity when output is too low.

I ran a one-year simulation of a battery storage system large enough to maintain an average of 6,000 megawatts of output from the Texas wind system.  It turned out that that the battery would have to be able to store 430 hours of average power output.  A lithium ion battery big enough for that would cost about $500 billion, or about ten times what it cost to build the entire wind system.  Such a battery would have to be replaced every ten years.  On the other hand, six nuclear plants big enough to supply 6,000 megawatts continuously would cost about $36 billion.  Natural gas-generating plants to supply 6,000 megawatts would cost $6 billion.  The gas would cost about $1.16 billion per year.

Another way to store electricity is pumped storage.  A dual hydroelectric system pumps water to an upper reservoir to store electricity and lets the water run down to a lower reservoir through a turbine to recover the stored electricity.  Typically, 25% of the electricity is lost.  For the Texas wind system, to store enough energy using pumped storage, upper and lower lakes with 500 feet of vertical separation would each have to be 92 square miles in size and 100 feet deep.  The turbines would cost about $12 billion.  Creating such lakes in East or West Texas with the required vertical separation would be a hugely expensive and difficult undertaking – perhaps impossible, given the lack of mountains in East Texas and the lack of water in West Texas.  Such a hydroelectric system would be equal to the biggest system in the U.S., the Grand Coulee dam on the Columbia River.  The Grand Coulee dam is one of the largest structures ever built by mankind.  Yet 6,000 megawatts of generation is a small fraction of the needs of Texas, which run as high as 70,000 megawatts.


Full story here.


I ran a similar analysis for the UK last week, and arrived at similar conclusions.

In fact the wind capacity and output numbers are pretty similar betwee, the UK and Texas. I estimated that we would need 3 days of storage, whereas Norman reckins about 18 days. However, he has looked at annual data, whereas mine was based on just one month. It may be that there are big seasonal variations in Texas – eg very little wind in summer – which would mean much more storage would be needed.

This is unlikely to be the case in the UK.


June 8, 2018 at 05:31AM

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