抛物线槽
可再生能源
热能储存
储能
太阳能
集中太阳能
分布式发电
太阳能
光伏系统
电
工艺工程
发电
电力系统
环境科学
抽蓄发电
独立电源系统
汽车工程
光伏
工程类
计算机科学
热能
发电成本
电气工程
功率(物理)
电网储能
基本负荷发电厂
化石燃料
能源开发
火力发电站
风力发电
能源
能源供应
调峰发电厂
高效能源利用
热的
间歇式能源
计算机数据存储
市电
机械工程
作者
Olcay Kaan Çakır,Sule Erten‐Ela,Mesut Ekmekçi
标识
DOI:10.58559/ijes.1739723
摘要
The rapid increase in global energy demand, the finite nature of fossil fuel resources, and the onset of climate instability have collectively accelerated the development of renewable energy technologies and rendered the transition to these alternatives inevitable. In this context, Concentrated Solar Power (CSP) systems have emerged as a compelling alternative technology by offering thermal energy storage capabilities and the potential for uninterrupted electricity generation. The effectiveness of these systems extends beyond the high temperatures achieved through solar concentration; thanks to their energy storage capabilities and operational flexibility, CSP technologies are increasingly able to compete with fossil-fuel-based power plants. CSP systems can generate electricity during daylight hours and, through integrated thermal storage units, continue to supply power at night or under suboptimal solar conditions. These features enhance energy security and contribute significantly to decarbonization targets in power generation. This review comprehensively examines various CSP technologies, including power tower systems, parabolic trough collectors, dish-Stirling engines, and linear Fresnel reflectors. The fundamental working principles, thermal energy storage methods, and efficiency levels of each system are discussed in detail. Furthermore, the advantages and limitations of each CSP technology are evaluated. In conclusion, with advancements in heat transfer fluids, optical tracking systems, and AI-assisted control technologies, CSP systems are projected to play a strategic role in large-scale renewable energy production and become a reliable source of baseload power in the future.
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