Specific Problems with the EROEI of Solar PV
(1) Prospective EROEI calculations tend to have a bias toward what is “hoped for,” rather than serving as a direct calculation of what has been achieved. If the EROEI of an oil field, or of a hydroelectric plant that has been operation for many years, is desired, it is not terribly hard to find reasonable numbers for inputs and outputs. All a researcher needs to do is figure out pounds of concrete, steel, and other materials that went into the initial structure, as well as inputs needed on a regular basis, and actual outputs; with these, a calculation can be made. When estimates are made for new devices, the bias is always toward what is hoped to be achieved. How much electricity will a solar panel produce, if it is properly sited, properly maintained, maintenance costs are very low, the electric grid can actually use all of the electricity that the panel produces, and all parts of the system last for the expected life of the solar panel?
(2) All energy is given the same “weight,” whether it is high quality or low quality energy. Intermittent energy, such as is produced by solar PV, is in fact extremely low quality output, but there is no adjustment for this fact in the calculation. It counts the same as much better quality electrical output, such as that provided by hydroelectric.
(3) There is no charge for the use of capital. When capital goods such as solar panels are used to produce energy products, this has several negative impacts on the economy: (a) Part of the energy produced must go to pay for the interest and/or dividends related to long-term capital use, but there is energy cost assigned to this; (b) A country’s debt to GDP ratio tends to rise, as the economy is required to use ever more debt to finance all of the new capital goods; and (c) The wealth of the economy tends to become ever-more concentrated in the owners of capital goods, leaving workers less well off. EROEI calculations don’t charge for any of these deficiencies. These deficiencies are part of what makes it virtually impossible to scale up the use of wind and solar PV as a substitute for fossil fuels.
(4) EROEI indications tend to be artificially low, because they leave out hard-to-estimate costs. EROEI analyses tend to focus on amounts that are “easy to count.” For solar PV, the amount that is easiest to count is the cost of making and transporting the solar PV. Installation costs vary greatly from site to site, especially for home installations, so these costs are likely to be left out. Indirect benefits provided by governments, such as newly built roads to accommodate a new solar PV installation, are also likely to be omitted. The electric utility that has to deal with all of the intermittent electricity has to deal with a whole host of problems being dumped on it, including offsetting the impact of intermittency and upgrading the newly added electricity so that it truly meets grid standards. There are individual studies (such as here and here) that look directly at some of these issues, but they tend to be omitted from the narrow-boundary analyses included in the meta-studies, which researchers tend to rely on.
(5) Precisely how solar PV at scale can be integrated into the grid is unclear, so costs required for grid integration are not considered in EROEI calculations. There are a number of approaches that might be used to integrate solar PV into the electric grid. One approach would be to use complete battery backup of all solar PV and wind. The catch is that there is seasonal variation as well as daily variation in output; huge overbuilding and a very large amount of batteries would be required if the grid system were to provide electricity from intermittent renewables throughout the winter months, without supplementation from other sources. Even if storage is only used to smooth out daily fluctuations, the energy cost would be very high.
Another approach would be to continue to maintain the entire fossil fuel and nuclear generation systems, even though they would run only for a small part of the time. This would require paying staff for year-around work, even though they are needed for only part of the year. Other costs, such as maintaining pipelines, would continue year around as well.
A partial approach, which might somewhat reduce the energy needs for other approaches, would be to greatly increase the amount of electricity transmission, to try to smooth out fluctuations in electricity availability. None of these costs are included in EROEI calculations, even though they are very material.
(6) Solar PV (as well as other intermittent electricity, such as wind) causes direct harm to other types of energy producers by artificially lowering wholesale electricity prices. Wholesale prices tend to fall to artificially low levels, because intermittent electricity, including solar PV, is added to the electric grid, whether or not it is really needed. In fact, solar PV adds very little, if any, true “capacity” to a system, so there is no logical reason why prices for other producers should be reduced when solar PV is added. These other producers need the full wholesale cost of electricity, without the downward adjustment caused by the addition of intermittent energy sources, if they are to obtain a sufficient return on their investment to make it possible to continue to provide their services.
These issues tend to drive needed back-up electricity generation out of business. This is a problem, especially for nuclear electricity providers. Nuclear providers find themselves being pressured to close before the ends of their lifetimes, because of the low prices. This is true both in France and the United States.
In some cases, extra “capacity payments” are being made to try to work around these issues. These capacity payments usually result in the building of more natural gas fired electricity generating units. Unfortunately, these payments do nothing to guarantee that the natural gas required to operate these plants will actually be available when it is needed. But gas-fired generating units are cheap to build. Problem (sort of) solved!
(7) Electricity generation using solar PV cannot be scaled up very well. There are multiple issues involved, including cost, debt, difficulty in handling the variable output, and the adverse impact of the intermittent electricity on the profitability of other carriers.
https://ourfiniteworld.com/2016/12/21/e ... isleading/