Nuclear Power provides the performance we need

Published by mzconsultng on

We often speak about the incredible energy density of nuclear fuel; a pellet the size of the end of your finger can deliver as much energy as a ton of coal.  In addition to producing a large amount of energy from a very small amount of resource, the plants themselves offer another important benefit, their exemplary operating performance.  They operate at very high capacity factors (the amount of energy produced / the total energy that would be produced if the unit ran nonstop) meaning they provide us with a reliable 24/7 energy source to support our energy hungry economies. 

In fact, even as the global fleet ages, it just keeps on getting better.  In 2018, the US fleet produced the most energy ever, exceeding the previous peak from 2010 even though 7 units have been retired and only two new ones have come on stream.  The annual capacity factor in the US for 2018 was 92.3%.  This should come as no surprise since the US fleet has operated around 90% CF for the past 20 years.  This is a testament to the technology and its robustness.  Not only does nuclear operate extremely well, it does so at all times during its very long life.  It has no early life breaking in period and no end of life deterioration in its performance.  It just continues to provide the energy we need day after day, year after year.

Let’s contrast this with the world’s most talked about generation sources, wind and solar.  Not only are they intermittent, because the wind doesn’t always blow and the sun doesn’t always shine, but on average they produce relatively small amounts of energy from a given plant, i.e. a low capacity factor.  Wind farms usually operate about 35% of the time and solar only about 15% of the time.  Not only does each generator produce a relatively small amount of energy, it can’t be called upon to produce it when it is needed.

This is why it is frustrating and frankly, deceptive, when supporters tout how much capacity of new renewables is being added to the grid, without mentioning the inconvenient truth of how little energy they are really contributing.  The following figure shows how much capacity is expected to be added to the global grid in the World Energy Outlook (WEO) 2018 Sustainable Development Scenario.

Source: IEA World Energy Outlook 2018

At first look, it seems like wind and solar are leading the charge to decarbonize the world energy system – 180 GW of new solar, 120 GW of new wind and only 17 GW of new nuclear.  But now let’s transform these capacities into energy.  The WEO assumes that nuclear runs about 80% of the time, wind 30% and solar 15%.  So, what does this mean?  Building 10 times the amount of solar and about 7 times the amount of wind as nuclear results in only about TWICE as much energy being produced from these sources as from new nuclear.  Yes, you heard that right.  Building 180 GW of solar running 15% of the time produces only about double the energy in a year as building 17 GW of nuclear plant that runs 80% of the time.  And to top it off, the nuclear energy is also reliable and predictable.  Of more importance, it also means that there is a need for much more land to place all these wind and solar plants, a huge increase in the materials mined to manufacture them, a much larger and more complex transmission system, and a storage system that is not yet technologically feasible to accommodate their intermittency ( or more likely gas generation to back them up); all leading to higher costs of energy, less system reliability and more carbon emissions. 

A successful narrative has been created that renewables are a good way to meet all our energy needs, but it is based on how they make us feel, not on science.  Who doesn’t like the sound of harnessing nature and getting our energy from the wind and the sun?  In reality, we simply cannot make the wind blow or the sun shine.  We cannot imagine our way to a clean energy future with solutions that sound good but are incapable of giving us the result we so desperately need.  In fact, the WEO bases its low carbon scenario on implementing large efficiency gains to reduce demand as a massive renewables new build program alone cannot meet the carbon reduction targets. 

Looking at these numbers, should we be investing in these enormous quantities of renewables (and the back up / storage needed to accommodate their intermittency) or is there a better path to a lower cost decarbonized energy system.   Nuclear power delivers what we need when we need it – large quantities of economic, reliable and low emission energy.

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4 Comments

KOCHERRY JOHN SEBASTIAN · May 2, 2019 at 4:26 am

I have been wondering whether theoretically, the current level of global power generation can be supplied by only hydro, wind and solar? In that case, the area of land that need to be used for the purpose.?

Carlos · May 4, 2019 at 1:09 pm

Well done analysis, Milt

Peter bird · May 5, 2019 at 9:55 pm

Milt, I part company with you on this. Yes we shd be building enormous amounts of renewables. And yes, we shd be building lots of new nuclear capacity. And yes, we shd be building more storage. We need all three to address the decarbonising challenge. Base load nuclear and non-despatchable solar as wind are complements, not competitors. Trashing solar and wind is just pandering to the fossil lobby

Robert Hargraves · May 6, 2019 at 8:11 am

The low-hanging fruit is substituting nuclear power for new fossil power plants in the developing nations.

World electric power use averages 3000 gigawatts (GW).
http://thorconpower.com//home/mzconsu1/public_html/blog/wp-content/uploads/2019/04/WorldWattsPerCapita.jpg
The height of each colored block represents the average electric power consumption per capita. The width is proportional to the regional population, so the area represents regional average electric power generated and used.

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