Solar-Driven Steam Topping Cycle for a Binary Geothermal Power Plant

McTigue, Joshua D.; Kincaid, Nicholas; Wendt, Daniel; Gunderson, Joshua; Kitz, Kevin

doi:10.2172/1484347

Cited by 4 publications

(5 citation statements)

References 23 publications

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“…This LCOE value compares favorably with reported values for solar photovoltaic plus battery energy storage (PV+BES) systems in the open literature, i.e. $0.148/kWhe for a PV+BES system with 4 hours of electrochemical battery energy storage capacity (McTigue et al, 2018a;McTigue et al, 2018b). Addition of battery energy storage with more hours of storage would further increase PV+BES system LCOE and increase the separation between GeoTES and PV+BES.…”

supporting

confidence: 77%

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Flexible Geothermal Power Generation utilizing Geologic Thermal Energy Storage (Final Seedling Project Report)

Wendt

Huang

Zhu

et al. 2019

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This report concludes that there is a cost-effective strategy for seasonal storage of heat that will provide firm, but dispatchable, electrical generating capacity in times when other renewable energy is not available to meet demand. Deployment of the technology appears to require no new technology, but instead combines solar, geothermal, and conventional oil and gas drilling technologies in a novel way. The study basis is the use of sedimentary geologic formations as a medium for thermal energy storage (TES), specifically for heat collected in concentrating solar collectors.

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supporting

confidence: 77%

“…4. The LCOE for high capacity GeoTES systems is lower than the value of $0.148/kWh estimated by McTigue et al (2018aMcTigue et al ( , 2018b for a low capacity (4 hr) photovoltaic plus battery energy storage (PV+BES) system. Addition of increased BES capacity would result in significant increases in PV+BES LCOE.…”

Section: Discussionmentioning

confidence: 76%

Flexible Geothermal Power Generation utilizing Geologic Thermal Energy Storage (Final Seedling Project Report)

Wendt

Huang

Zhu

et al. 2019

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“…We have successfully completed all four tasks. The detail work regarding the tasks were summarized in the 68-page technical report [1]. In addition, one short article was published on the GRC bulletin [2] and one journal article [3] was just published on the high-impact journal: Applied Thermal Energy.…”

Section: Summary Of Research Resultsmentioning

confidence: 99%

Integration of a Concentrating Solar Steam Topping Turbine to an Existing Geothermal Binary Power Plant (CRADA CRD-17-700 Final Report)

Zhu

2020

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“…The current study concentrates on the development of a new-build geothermal-solar or geothermalgas hybrid plant [11], as opposed to the previous projects which largely considered retrofitting an existing geothermal plant with solar thermal.…”

Section: Recap Of Previous Projectsmentioning

confidence: 99%

“…Previous work by this group, including McTigue et al's 2020 article [7], considered starting from a known geothermal plant and adding solar in the form of a steam Rankine topping cycle which feeds additional heat into an ORC-bottoming cycle. McTigue et al [19] studied the different possible options for moving heat from the solar thermal system to the geothermal cycle and found that using a topping cycle to add heat to the bottoming cycle working fluid provided the best compromise between efficiency and complexity. [7], [20], [21], [22].…”

Section: Literature Reviewmentioning

confidence: 99%

Techno-Economic Analysis of Greenfield Geothermal Hybrid Power Plants using a Solar or Natural Gas Steam Topping Cycle

Wendt,

Neupane,

Simpson

et al. 2024

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The relatively low generation costs associated with wind, solar photovoltaic (PV), and natural-gas power plants make it challenging for geothermal power plants to produce and sell the power that has the reliability and sustainability characteristics that are greatly needed in U.S. power markets. This is especially true for geothermal resources with low-to-medium temperatures, which results in relatively low-thermal efficiency and generation costs that are higher than those for wind, solar PV, and natural gas. This analysis evaluates solar thermal-and natural-gas combustion waste heat recovery-based topping cycle hybridization of geothermal binary power plants. This approach provides several benefits that may allow geothermal power plants to generate power at more competitive costs. First, the addition of solar thermal energy or natural-gas combustion waste heat input to a geothermal power plant provides additional heat input that can be converted to electrical power. Second, the temperature level of the heat obtained from concentrating solar collectors or natural-gas combustion exhaust is higher than that of geothermal heat, which provides opportunities for improving the efficiency of the conversion of thermal energy to electrical power. Third, the ease with which solar thermal systems integrate with energy storage and the flexibility of natural gas means power generation can occur during peak demand periods. vi

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Solar-Driven Steam Topping Cycle for a Binary Geothermal Power Plant

Cited by 4 publications

References 23 publications

Flexible Geothermal Power Generation utilizing Geologic Thermal Energy Storage (Final Seedling Project Report)

Flexible Geothermal Power Generation utilizing Geologic Thermal Energy Storage (Final Seedling Project Report)

Integration of a Concentrating Solar Steam Topping Turbine to an Existing Geothermal Binary Power Plant (CRADA CRD-17-700 Final Report)

Techno-Economic Analysis of Greenfield Geothermal Hybrid Power Plants using a Solar or Natural Gas Steam Topping Cycle

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