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基于巴西太阳能条件的熔盐太阳能塔式电站与超临界CO2布雷顿循环集成的热力学评估
Thermodynamic assessment of a molten salt solar power tower integrated with a supercritical CO2 Brayton cycle under Brazilian solar conditions
| 作者 | Igor Marques Alves · Cristiana Brasil Maia |
| 期刊 | Solar Energy |
| 出版日期 | 2025年1月 |
| 卷/期 | 第 301 卷 |
| 技术分类 | 储能系统技术 |
| 技术标签 | 储能系统 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | Thermodynamic assessment of a CSP tower with sCO2 Brayton cycle in Brazil. |
语言:
中文摘要
摘要 本研究评估了一种装机容量为100 MWe的熔盐作为传热流体和热能储存(TES)介质的太阳能塔式电站(SPT)系统,并将其与超临界CO2再压缩布雷顿循环集成后的热力学性能。针对五个太阳能资源各异的巴西地点——查帕达杜斯吉马良斯(Chapada dos Guimarães)、加努阿里亚(Januária)、蒙特阿莱格里(Monte Alegre)、佩德罗利纳(Petrolina)和里奥格兰德(Rio Grande)——开展了仿真分析。所研究的热力循环模型依据文献数据进行了验证,并针对热效率进行了优化。当透平入口温度为565 °C、热输入为206.8 MWt时,循环效率达到48.36%。本文还对太阳倍数(SM = 1–3)和热能储存时长(TES = 0–15 h)进行了参数化分析。结果表明,在大多数选址中,采用15小时的TES和太阳倍数为3的配置可使容量因数(CF)达到最优,其中在查帕达杜斯吉马良斯最高可达100%。而位于南部的站点(里奥格兰德)则需采用较低的太阳倍数(2.5)以实现最佳性能。尽管各区域的法向直接辐射(DNI)存在差异,所有配置均表明在巴西部署光热发电(CSP)技术具备可行性。
English Abstract
Abstract This study evaluates the thermodynamic performance of a 100 MWe solar power tower (SPT) plant using molten salt as the heat transfer fluid and thermal energy storage (TES), integrated with a supercritical CO 2 recompression Brayton cycle. Simulations were conducted for five Brazilian locations with varying solar resources: Chapada dos Guimarães, Januária, Monte Alegre, Petrolina, and Rio Grande. The thermodynamic cycle was validated against literature and optimized for thermal efficiency. A turbine inlet temperature of 565 °C and a thermal input of 206.8 MWt resulted in a cycle efficiency of 48.36 %. Parametric analyses were performed for solar multiples (SM = 1–3) and TES durations (0–15 h). Results show that a 15-hour TES and SM of 3 optimized the capacity factor (CF) in most locations, reaching up to 100 % in Chapada dos Guimarães. The southern site (Rio Grande) required a lower SM (2.5) for optimal performance. Despite regional differences in direct normal irradiance, all configurations demonstrated the feasibility of CSP deployment in Brazil.
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SunView 深度解读
该熔盐塔式光热-超临界CO2联合循环技术对阳光电源储能系统具有重要启示。研究中15小时储能配置实现100%容量因子,验证了长时储能价值,与我司PowerTitan液冷储能系统的大容量、长周期调节能力高度契合。48.36%的循环效率优化思路可借鉴于ST系列PCS的能量管理策略。光热储能与光伏互补场景下,SG逆变器可与熔盐储能系统协同,通过iSolarCloud平台实现多能源智能调度,提升巴西等高辐照地区新能源电站的经济性与电网友好性。