Scale and Regionality of Nonelectric Markets for U.S. Nuclear Light Water Reactors

Knighton, Lane Todd; Wendt, Daniel; Jaoude, Abdalla; Rabiti, Cristian; Boardman, Richard; Elgowainy, Amgad; Reddi, Krishna; Bafana, Adarsh; James, Brian D.; Murphy, Brian; Scheerer, Julia; Peterson, Fred

doi:10.2172/1615670

Title: Scale and Regionality of Nonelectric Markets for U.S. Nuclear Light Water Reactors

Technical Report · Tue Mar 31 00:00:00 EDT 2020

DOI:https://doi.org/10.2172/1615670· OSTI ID:1615670

^[1]; Wendt, Daniel ^[1]; Jaoude, Abdalla ^[1]; Rabiti, Cristian ^[1]; Boardman, Richard ^[1]; Elgowainy, Amgad ^[2]; Reddi, Krishna ^[2]; Bafana, Adarsh ^[2]; James, Brian D. ^[3]; Murphy, Brian ^[3]; Scheerer, Julia ^[3]; Peterson, Fred ^[3]

Idaho National Lab. (INL), Idaho Falls, ID (United States)
Argonne National Lab. (ANL), Argonne, IL (United States)
Strategic Analysis, Inc. (SA), Arlington, VA (United States)

This study assesses existing and potential industries that could conceivably be directly coupled to existing nuclear reactors. The goal is to identify the scale, location, and accessibility of the candidate industrial-product markets, as well as process feedstocks that are available near the plants to establish new industries. For example, CO₂ as a feedstock can be combined with H₂ to produce formic acid (FA), transportation fuels, and lubricants. These new plants can be entirely supported with the heat and electricity provided by a nearby NPP. The potential demand for nonelectric industrial products was assessed by documenting current and possible growth of nonelectricity product markets considered. This assessment used DOE- and industry-supported tools, data, and projections to capture regional industrial market opportunities. Electricity-capacity markets that reward large and reliable generators, such as NPPs, were considered because the electricity market will likely continue to be an important revenue source to NPPs. The key is to balance the needs of energy customers so as to optimize revenue for the affiliated energy customers or partners. In most cases, flexible plant energy delivery and power generation for the grid will require either energy storage or a stock of intermediate products to sustain the industrial customers when the NPP dispatches electricity to the grid. A diverse mix of temperate regions with operating NPPs around the U.S.—representing a variety of operating markets, local generation mix, and seasonal climates—were chosen for this market study. Both current and future market opportunities for candidate industrial-product markets surrounding these NPPs were studied. Figure 2 illustrates the regions chosen for this study. The success of developing nonelectric industrial-product markets as alternative revenue-generating sources for LWRs depends, not only on demand from growing existing markets, such as petroleum refining and NH₃ production, but also on the development of new markets such as light-duty (LD) and heavy-duty (HD) hydrogen FCEVs, synfuels, chemical production, biofuels, metal refining, injection of hydrogen into NG pipelines for gas power-generating units, FA, polymers, and close-coupled industrial heat applications, all of which can significantly increase demand relative to current levels while decarbonizing energy sectors. This study also presents a sample analysis of the economics of hydrogen production in an area of Minnesota, considering the capital and operating costs of a hydrogen plant as well as the local market demand for hydrogen. It includes some assumptions on electricity-grid pricing, showing how hydrogen could be integrated with an NPP and be competitive with the incumbent hydrogen-production process, steam methane reforming (SMR). The objectives of this study include: Provide U.S. NPP operators a robust sampling of the market demand location, scale, and accessibility (including storage and transportation) of the wide variety of industrial-product choices that can be produced using nuclear thermal energy and electricity proximate to a subset of U.S. NPPs to inform the industry of the potential opportunity; show examples and trade-off analyses of how U.S. LWR operators can access these markets, including storage and transportation of industrial products to their intended markets; and present a general analysis example for one industrial product (hydrogen) in one region (Minnesota area), including production, storage, and transportation, to show how nuclear-hybrid integrated energy systems (IESs) could access local markets and improve the profitability of an NPP.

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Research Organization:: Idaho National Lab. (INL), Idaho Falls, ID (United States)

Sponsoring Organization:: USDOE Office of Nuclear Energy (NE)

DOE Contract Number:: AC07-05ID14517

OSTI ID:: 1615670

Report Number(s):: INL/EXT-20-57885-Rev.000; TRN: US2104784

Country of Publication:: United States

Language:: English

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Title: Scale and Regionality of Nonelectric Markets for U.S. Nuclear Light Water Reactors

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