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Numerical simulatio...
Numerical simulation study of boiling critical heat flux characteristics of graphene nanofluids
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- Hou, Yandong (author)
- Northeast Elect Power Univ, Sch Energy & Power Engn, Jilin, Peoples R China.
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- Huang, Jianwei (author)
- Northeast Elect Power Univ, Sch Energy & Power Engn, Jilin, Peoples R China.
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- Cai, Rui (author)
- Northeast Elect Power Univ, Sch Energy & Power Engn, Jilin, Peoples R China.
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- Liu, Wenyu (author)
- Northeast Elect Power Design Inst CO LTD, New Energy Engn Co, Technol Dev Dept, China Power Engn Consulting Grp, Changchun, Peoples R China.
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- Zhang, Chao (author)
- Northeast Elect Power Univ, Sch Energy & Power Engn, Jilin, Peoples R China.
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- Li, Weichao (author)
- Northeast Elect Power Univ, Sch Energy & Power Engn, Jilin, Peoples R China.
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- Gao, Chuntian (author)
- Northeast Elect Power Univ, Sch Energy & Power Engn, Jilin, Peoples R China.
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- Xiang, Yan (author)
- KTH,Kärnkraftssäkerhet
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Northeast Elect Power Univ, Sch Energy & Power Engn, Jilin, Peoples R China Northeast Elect Power Design Inst CO LTD, New Energy Engn Co, Technol Dev Dept, China Power Engn Consulting Grp, Changchun, Peoples R China. (creator_code:org_t)
- Elsevier BV, 2024
- 2024
- English.
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In: Progress in nuclear energy (New series). - : Elsevier BV. - 0149-1970 .- 1878-4224. ; 172
- Related links:
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https://urn.kb.se/re...
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https://doi.org/10.1...
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Abstract
Subject headings
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- IVR-ERVC (In-Vessel Retention – External Reactor Vessel Cooling) is a critical accident management method for ensuring the integrity of the reactor pressure vessel (RPV) lower head. One of the most crucial aspects within this method is to enhance the CHF (Critical Heat Flux) on the outer surface of the reactor pressure vessel (RPV) lower head. This paper explores the application of graphene nanofluids in IVR-ERVC. This paper uses computational fluid dynamics to numerically simulate the CHF characteristics of graphene nanofluids under different undercooling, mass flow rate, concentration, tilt angle, and gap size conditions and analyzes the impact of different factors on CHF and the coupling effects between different factors. The undercooling range is 5 K–100 K, the mass flow rate range is 150 kg/(m2∙s) to 3000 kg/(m2∙s), the concentration range is 0–1%, the inclination angle range is 0°–90°, and the gap sizes are 10 mm and 20 mm. The results show that the CHF can be effectively improved by adding nano-graphene into the base solution, and the CHF increases with the increase of subcooling degree, mass flow rate, concentration, dip Angle and gap size. Within the simulation range, the strengthening effect on CHF weakens when raising the undercooling and mass flow rate. And the larger the concentration and inclination angle within the simulation range, the better the enhancement effect on CHF. The maximum increase was 290%, while the average increase was 75.6%. This article studies the coupling effects between different parameters through numerical simulation. It can be concluded that increasing the mass flow rate weakens the enhancement of subcooling and concentration on CHF, increasing the subcooling weakens the enhancement effect of mass flow rate and concentration on CHF, and increasing the concentration enhances the enhancement effect of subcooling and mass flow rate on CHF. Enhance the mass flow rate will weaken tilt angle effect, while increasing the concentration will enhance the strengthening effect of tilt angle on CHF.
Subject headings
- TEKNIK OCH TEKNOLOGIER -- Maskinteknik -- Energiteknik (hsv//swe)
- ENGINEERING AND TECHNOLOGY -- Mechanical Engineering -- Energy Engineering (hsv//eng)
Keyword
- Rectangular channel
- Graphene nanofluids
- Heat transfer enhancement
- Numerical simulation
- Critical heat flux
- In-vessel-retention
Publication and Content Type
- ref (subject category)
- art (subject category)
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