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Advances in Nuclear Power for Integrated Energy Systems

A special issue of Energies (ISSN 1996-1073). This special issue belongs to the section "B4: Nuclear Energy".

Deadline for manuscript submissions: 8 April 2025 | Viewed by 2866

Special Issue Editors


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Guest Editor
Division of Energy and Environment Science and Technology (EES&T), Idaho National Laboratory, P.O. Box 1625, Idaho Falls, ID 83415, USA
Interests: energy systems; nuclear energy; energy storage; bioenergy; clean hydrogen; concentrated solar power; modeling and simulation

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Guest Editor
Plant Analysis & Control and Sensors Department, Argonne National Laboratory, Lemont, 60439 IL, USA
Interests: nuclear engineering; nuclear safety; artificial intelligence; hybrid energy systems; modeling and simulation

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Guest Editor
Division of Nuclear Science & Technology (NS&T), Idaho National Laboratory, Fremont Ave, Idaho Falls, ID 83415, USA
Interests: integrated energy systems; advanced nuclear reactors; nuclear integration with industry; microreactor heat and power applications; thermal energy storage; waste heat recovery; experimental and thermal design

Special Issue Information

Dear Colleagues,

Due to combination of environmental and energy security concerns, the demand for low-carbon and low-polluting energy sources is increasing. Integrated energy systems offer the opportunity to increase the value proposition of advanced nuclear power in several ways: (1) taking advantage of synergies in combined heat and power, (2) opening new markets for nuclear heat, and (3) enhancing temporal and market power dispatchability. Reliable information describing the technological benefits and remaining challenges of integrating nuclear heat and power with diverse markets will assist in accelerating the deployment low-carbon and low-polluting advanced nuclear power. In this Special Issue, we will publish papers that focus on innovations in advanced nuclear energy for integrated energy systems.

The topics of interest for publication include, but are not limited to, the following:

  • Analyses of designs for full plants or specific subsystems that couple advanced reactors to other energy resources, such as photovoltaic energy, wind energy, hydroelectric energy and the production of chemicals, steel, cement, pulp and paper, and fuels, such as hydrogen;
  • Modeling, experimental results and cost analysis of designs for advanced reactors for electrical and thermal power dispatch;
  • Modeling or assessments of innovations, such as electric energy storage, thermal energy storage, and hydrogen production and storage, that potentially increase the dispatchability of advanced nuclear power;
  • Modeling or assessments of technologies that potentially increase the value or market opportunities for advanced nuclear power, such as temperature augmentation of reactor heat for high-temperature industrial applications;
  • Economic assessments of integrated energy systems that take advantage of advanced nuclear power to reduce society's dependence on polluting fossil fuels.

Dr. Tyler Westover
Dr. Richard B. Vilim
Dr. Rami M. Saeed
Guest Editors

Manuscript Submission Information

Manuscripts should be submitted online at www.mdpi.com by registering and logging in to this website. Once you are registered, click here to go to the submission form. Manuscripts can be submitted until the deadline. All submissions that pass pre-check are peer-reviewed. Accepted papers will be published continuously in the journal (as soon as accepted) and will be listed together on the special issue website. Research articles, review articles as well as short communications are invited. For planned papers, a title and short abstract (about 100 words) can be sent to the Editorial Office for announcement on this website.

Submitted manuscripts should not have been published previously, nor be under consideration for publication elsewhere (except conference proceedings papers). All manuscripts are thoroughly refereed through a single-blind peer-review process. A guide for authors and other relevant information for submission of manuscripts is available on the Instructions for Authors page. Energies is an international peer-reviewed open access semimonthly journal published by MDPI.

Please visit the Instructions for Authors page before submitting a manuscript. The Article Processing Charge (APC) for publication in this open access journal is 2600 CHF (Swiss Francs). Submitted papers should be well formatted and use good English. Authors may use MDPI's English editing service prior to publication or during author revisions.

Keywords

  • nuclear energy
  • nuclear power
  • nuclear reactors
  • modeling and simulation

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Published Papers (3 papers)

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Research

23 pages, 6486 KiB  
Article
Modeling and Optimization of a Nuclear Integrated Energy System for the Remote Microgrid on El Hierro
by Logan Williams, J. Michael Doster and Daniel Mikkelson
Energies 2024, 17(23), 5826; https://doi.org/10.3390/en17235826 - 21 Nov 2024
Viewed by 322
Abstract
Nuclear microreactors are a potential technology to provide heat and electricity for remote microgrids. There is potential for the microgrid on the island of El Hierro to use a microreactor, within an integrated energy system (IES), to generate electricity and provide desalinated water. [...] Read more.
Nuclear microreactors are a potential technology to provide heat and electricity for remote microgrids. There is potential for the microgrid on the island of El Hierro to use a microreactor, within an integrated energy system (IES), to generate electricity and provide desalinated water. This work proposes a workflow for optimizing and analyzing IESs for microgrids. In this study, an IES incorporating a microreactor, thermal energy storage (TES) system, combined heat and power plant, and a thermal desalination plant was designed, optimized, and analyzed using Idaho National Laboratory’s Framework for Optimization of Resources and Economics (FORCE) toolset. The optimization tool, Holistic Energy Resource Optimization Network (HERON), was used to determine the optimal capacity sizes and dispatch for the reactor and thermal energy storage systems to meet demand. The optimized reactor and TES sizes were found to be 11.61 MWth and 58.47 MWhth, respectively, when optimizing the IES to replace 95% of the island’s existing diesel generation needs. A dynamic model of the system was created in the Modelica language, using models from the HYBRID repository, to analyze and verify the dispatch from the optimizer. The dynamic model was able to meet the ramp rates while maintaining reactor power with minimal control adjustments. Full article
(This article belongs to the Special Issue Advances in Nuclear Power for Integrated Energy Systems)
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30 pages, 2612 KiB  
Article
A Reduced-Order Model of a Nuclear Power Plant with Thermal Power Dispatch
by Roger Lew, Bikash Poudel, Jaron Wallace and Tyler L. Westover
Energies 2024, 17(17), 4298; https://doi.org/10.3390/en17174298 - 28 Aug 2024
Viewed by 682
Abstract
This paper presents reduced-order modeling of thermal power dispatch (TPD) from a pressurized water reactor (PWR) for providing heat to nearby heat consuming industrial processes that seek to take advantage of nuclear heat to reduce carbon emissions. The reactor model includes the neutronics [...] Read more.
This paper presents reduced-order modeling of thermal power dispatch (TPD) from a pressurized water reactor (PWR) for providing heat to nearby heat consuming industrial processes that seek to take advantage of nuclear heat to reduce carbon emissions. The reactor model includes the neutronics of the reactor core, thermal–hydraulics of the primary coolant cycle, and a three-lump model of the steam generator (SG). The secondary coolant cycle is represented with quasi-steady state mass and energy balance equations. The secondary cycle consists of a steam extraction system, high-pressure and low-pressure turbines, moisture separator and reheater, high-pressure and low-pressure feedwater heaters, deaerator, feedwater and condensate pumps, and a condenser. The steam produced by the SG is distributed between the turbines and the extraction steam line (XSL) that delivers steam to nearby industrial processes, such as production of clean hydrogen. The reduced-order simulator is verified by comparing predictions with results from separate validated steady-state and transient full-scope PWR simulators for TPD levels between 0% and 70% of the rated reactor power. All simulators indicate that the flow rate of steam in the main steam line and turbine systems decrease with increasing TPD, which causes a reduction in PWR electric power generation. The results are analyzed to assess the impact of TPD on system efficiency and feedwater flow control. Due to the simplicity of the proposed reduced-order model, it can be scaled to represent a PWR of any size with a few parametric changes. In the future, the proposed reduced-order model will be integrated into a power system model in a digital real-time simulator (DRTS) and physical hardware-in-the-loop simulations. Full article
(This article belongs to the Special Issue Advances in Nuclear Power for Integrated Energy Systems)
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26 pages, 10057 KiB  
Article
Integrated Steady-State System Package for Nuclear Thermal Propulsion Analysis Using Multi-Dimensional Thermal Hydraulics and Dimensionless Turbopump Treatment
by Rory Myers, Mark DeHart and Dan Kotlyar
Energies 2024, 17(13), 3068; https://doi.org/10.3390/en17133068 - 21 Jun 2024
Cited by 1 | Viewed by 1273
Abstract
Nuclear thermal propulsion is an evolving technology that can be utilized for long-distance space travel. This technology yields the advantage of a high thrust and specific impulse, but requires an examination of the potential design adjustments necessary to enhance its feasibility. The development [...] Read more.
Nuclear thermal propulsion is an evolving technology that can be utilized for long-distance space travel. This technology yields the advantage of a high thrust and specific impulse, but requires an examination of the potential design adjustments necessary to enhance its feasibility. The development of nuclear thermal propulsion requires a comprehensive understanding of the system-level behavior during transient and steady-state operation. This paper extends our previous research by including the proper handling of turbomachinery with multi-channel thermal hydraulic simulations only for steady-state solutions. The system-level approach presented here enables the treatment of the turbopump components through non-dimensional analysis that eliminates the assumption of constant efficiencies. All the other components within the system (e.g., reflector and core) can be discretized to multiple channels and layers, in which the full thermal hydraulic solution is established. The approach chosen here enables the realistic modeling of the propellant flow within the expander cycle by capturing the pressure losses, mass flow rate splits, and enthalpy gain for various operational conditions. The verification of the package is completed through point comparisons of previous investigations into similar system designs. Furthermore, sensitivity studies are used to benchmark the capabilities of the package and investigate solution variations due to the perturbation of operational conditions and regimes. The sensitivity studies performed here are important to capture variation in flow characteristics (e.g., temperature, pressure, mass flow rates) for different design objectives such as the thrust and specific impulse. This work demonstrates that system-level simulations lacking multi-channel capability and proper turbomachinery treatment may yield higher uncertainties in understanding the engine’s response and characteristics to changing various requirements. This is extremely important when screening the design space of such propulsion systems and when transient simulations are required. Full article
(This article belongs to the Special Issue Advances in Nuclear Power for Integrated Energy Systems)
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Planned Papers

The below list represents only planned manuscripts. Some of these manuscripts have not been received by the Editorial Office yet. Papers submitted to MDPI journals are subject to peer-review.

Title: Trade-off Studies of a Radiantly Integrated TPV-Microreactor (RITMS) Design
Authors: Naiki Kaffezakis; Dan Kotlyar
Affiliation: Georgia Institute of Technology
Abstract: Advancements in thermophotovoltaic technologies enable a new alternative for the electrification of nuclear power. These solid-state heat engines are more robust and likely cheaper to manufacture than the turbomachinery used in traditional microreactor concepts. The radiantly integrated, TPV-microreactor system (RTIMS) described in this work takes a novel approach in utilizing direct electric conversion of thermal power radiated from the active core. Without intermediary energy transfer, this direct coupling allows for system efficiencies well above 30%. While providing an introduction to the concept, the early RITMS work lacked an integrated computational sequence and economics-by-design approach, resulting in a failure to fully capture the physics of the system or to properly evaluate design parameter importance. The primary purpose of this paper is to describe and demonstrate a computational sequence that fully couples the conductive-radiative heat transfer with a neutronics solution and to provide design specific cost estimation. This new computational framework is deployed in reexamining multi-physics behavior of the RITMS design and to perform consistent trade-off studies. A favorable RITMS design was selected based on performance and fuel cycle costs, which was deemed feasible when considering cost uncertainty. Able to operate on 7% enriched fuel, this RITMS case was selected to balance fuel utilization with total power output.

Title: Nuclear cogeneration to support a net zero, high renewable electricity grid
Authors: Juan Matthews; Willam Bodel; Gregg Butler
Affiliation: University of Manchester
Abstract: UK Government projections anticipate increasing electricity use, provided by variable renewables (i.e. wind and solar PV). A side effect of increasing the proportion of variable renewable genera-tion is increased support costs, including curtailment, energy storage, and (most significantly) the cost of supplying electricity for periods of high demand when variable renewables generation is low. As the proportion of variable renewable capacity increases, demand for supporting capacity increases but the capacity factor of the support generation decreases, raising the support costs. Use nuclear power for dedicated baseload supply makes the situation worse. This paper explores in the UK context an original low-cost solution using nuclear cogeneration with hydrogen produc-tion as the main application. Electricity is diverted at low cost to the grid at times of high de-mand when renewables are not available. This ensures nuclear maintains a high capacity factor. When higher temperature advanced systems become available, using thermal energy storage will increase the nuclear electrical capacity. This “Flexible Nuclear” scenario substantially reduces support costs for accommodating variable renewables, saving £14bn/yr and 80% reduction in CO2 equivalent emissions, compared to a recent UK Government scenario utilising a large capac-ity of hydrogen and unabated gas generation at very low capacity factors.

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