Numerical Investigation of Jet Angle Effects on Thermal Dispersion Characteristics in Coastal Waters
Under the carbon neutrality framework, multiple coastal nuclear power plants in China have received construction approval. This development has drawn increased attention to the impact of thermal discharge on the marine environment. However, research on the diffusion effects caused by different therm...
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MDPI AG
2025-05-01
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| Series: | Journal of Marine Science and Engineering |
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| Online Access: | https://www.mdpi.com/2077-1312/13/5/931 |
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| author | Longsheng Li Hongyuan Shi Huaiyuan Xue Qing Wang Chao Zhan |
| author_facet | Longsheng Li Hongyuan Shi Huaiyuan Xue Qing Wang Chao Zhan |
| author_sort | Longsheng Li |
| collection | DOAJ |
| description | Under the carbon neutrality framework, multiple coastal nuclear power plants in China have received construction approval. This development has drawn increased attention to the impact of thermal discharge on the marine environment. However, research on the diffusion effects caused by different thermal discharge configurations remains limited. This study focused on the Jinqimen Nuclear Power Plant. It employed the MIKE 3 (2014) three-dimensional numerical model, combined with field observations, to systematically investigate thermal plume dispersion. Specifically, it examined the effects of different jet angles at the discharge outlet (0°, 30°, 45°, 60°, 90°, and free diffusion conditions). The results indicate that the jet angle significantly influences the thermal rise envelope area and thermal stratification characteristics. Under free diffusion conditions (without jet velocity), the thermal rise area is the largest, with high-temperature zones concentrated near the surface. As the jet angle increases from 0° to 90°, the area of low-temperature rise gradually decreases, while the area of high-temperature rise expands. Among all tested configurations, the 30° jet angle exhibits the best overall performance. It demonstrates high thermal diffusion efficiency and strong heat dilution capacity. Moreover, it results in relatively smaller temperature rise areas at the surface, middle, and bottom layers. Additionally, tidal dynamics directly affect the thermal dispersion pattern. Smaller high-temperature rise areas are observed during peak flood and ebb tides. In contrast, heat accumulation is more likely to occur during slack tide periods. This study provides a scientific basis for optimizing the layout of nuclear power plant discharge outlets. It also serves as an important reference for mitigating thermal pollution and reducing ecological impacts of coastal nuclear power plants. |
| format | Article |
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| institution | OA Journals |
| issn | 2077-1312 |
| language | English |
| publishDate | 2025-05-01 |
| publisher | MDPI AG |
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| series | Journal of Marine Science and Engineering |
| spelling | doaj-art-33c31cf167d64ed393879b0d545ed9032025-08-20T01:56:28ZengMDPI AGJournal of Marine Science and Engineering2077-13122025-05-0113593110.3390/jmse13050931Numerical Investigation of Jet Angle Effects on Thermal Dispersion Characteristics in Coastal WatersLongsheng Li0Hongyuan Shi1Huaiyuan Xue2Qing Wang3Chao Zhan4School of Hydraulic and Civil Engineering, Ludong University of China, Yantai 264025, ChinaSchool of Hydraulic and Civil Engineering, Ludong University of China, Yantai 264025, ChinaSchool of Hydraulic and Civil Engineering, Ludong University of China, Yantai 264025, ChinaSchool of Hydraulic and Civil Engineering, Ludong University of China, Yantai 264025, ChinaSchool of Hydraulic and Civil Engineering, Ludong University of China, Yantai 264025, ChinaUnder the carbon neutrality framework, multiple coastal nuclear power plants in China have received construction approval. This development has drawn increased attention to the impact of thermal discharge on the marine environment. However, research on the diffusion effects caused by different thermal discharge configurations remains limited. This study focused on the Jinqimen Nuclear Power Plant. It employed the MIKE 3 (2014) three-dimensional numerical model, combined with field observations, to systematically investigate thermal plume dispersion. Specifically, it examined the effects of different jet angles at the discharge outlet (0°, 30°, 45°, 60°, 90°, and free diffusion conditions). The results indicate that the jet angle significantly influences the thermal rise envelope area and thermal stratification characteristics. Under free diffusion conditions (without jet velocity), the thermal rise area is the largest, with high-temperature zones concentrated near the surface. As the jet angle increases from 0° to 90°, the area of low-temperature rise gradually decreases, while the area of high-temperature rise expands. Among all tested configurations, the 30° jet angle exhibits the best overall performance. It demonstrates high thermal diffusion efficiency and strong heat dilution capacity. Moreover, it results in relatively smaller temperature rise areas at the surface, middle, and bottom layers. Additionally, tidal dynamics directly affect the thermal dispersion pattern. Smaller high-temperature rise areas are observed during peak flood and ebb tides. In contrast, heat accumulation is more likely to occur during slack tide periods. This study provides a scientific basis for optimizing the layout of nuclear power plant discharge outlets. It also serves as an important reference for mitigating thermal pollution and reducing ecological impacts of coastal nuclear power plants.https://www.mdpi.com/2077-1312/13/5/931thermal dischargejet angletemperature risediffusion rangeMIKE 3 (2014) |
| spellingShingle | Longsheng Li Hongyuan Shi Huaiyuan Xue Qing Wang Chao Zhan Numerical Investigation of Jet Angle Effects on Thermal Dispersion Characteristics in Coastal Waters Journal of Marine Science and Engineering thermal discharge jet angle temperature rise diffusion range MIKE 3 (2014) |
| title | Numerical Investigation of Jet Angle Effects on Thermal Dispersion Characteristics in Coastal Waters |
| title_full | Numerical Investigation of Jet Angle Effects on Thermal Dispersion Characteristics in Coastal Waters |
| title_fullStr | Numerical Investigation of Jet Angle Effects on Thermal Dispersion Characteristics in Coastal Waters |
| title_full_unstemmed | Numerical Investigation of Jet Angle Effects on Thermal Dispersion Characteristics in Coastal Waters |
| title_short | Numerical Investigation of Jet Angle Effects on Thermal Dispersion Characteristics in Coastal Waters |
| title_sort | numerical investigation of jet angle effects on thermal dispersion characteristics in coastal waters |
| topic | thermal discharge jet angle temperature rise diffusion range MIKE 3 (2014) |
| url | https://www.mdpi.com/2077-1312/13/5/931 |
| work_keys_str_mv | AT longshengli numericalinvestigationofjetangleeffectsonthermaldispersioncharacteristicsincoastalwaters AT hongyuanshi numericalinvestigationofjetangleeffectsonthermaldispersioncharacteristicsincoastalwaters AT huaiyuanxue numericalinvestigationofjetangleeffectsonthermaldispersioncharacteristicsincoastalwaters AT qingwang numericalinvestigationofjetangleeffectsonthermaldispersioncharacteristicsincoastalwaters AT chaozhan numericalinvestigationofjetangleeffectsonthermaldispersioncharacteristicsincoastalwaters |