Opportunities and challenges in using particle circulation loops for concentrated solar power applications

IF 32 1区 工程技术 Q1 ENERGY & FUELS
Gilles Flamant , Benjamin Grange , John Wheeldon , Frédéric Siros , Benoît Valentin , Françoise Bataille , Huili Zhang , Yimin Deng , Jan Baeyens
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引用次数: 21

Abstract

Concentrated Solar Power (CSP) is an electricity generation technology that concentrates solar irradiance through heliostats onto a small area, the receiver, where a heat transfer medium, currently a fluid (HTF), is used as heat carrier towards the heat storage and power block. It has been under the spotlight for a decade as one of the potential or promising renewable and sustainable energy technologies.

Using gas/solid suspensions as heat transfer medium in CSP has been advocated for the first time in the 1980′s and this novel concept relies on its possible application throughout the full CSP plant, i.e., in heat harvesting, conveying, storage and re-use, where it offers major advantages in comparison with the common heat transfer fluids such as water/steam, thermal fluids or molten salt. Although the particle suspension has a lower heat capacity than molten salts, the particle-driven system can operate without temperature limitation (except for the maximum allowable wall temperature of the receiver tubes), and it can also operate with higher hot-cold temperature gradients. Suspension temperatures of over 800 °C can be tolerated and achieved, with additional high efficiency thermodynamic systems being applicable. The application of high temperature particulate heat carriers moreover expands the possible thermodynamic cycles from Rankine steam cycles to Brayton gas cycles and even to combined electricity generating cycles.

This review paper deals with the development of the particle-driven CSP and assesses both its background fundamentals and its energy efficiency. Among the cited systems, batch and continuous operations with particle conveying loops are discussed. A short summary of relevant particle-related properties, and their use as heat transfer medium is included. Recent pilot plant experiments have demonstrated that a novel bubbling fluidized bed concept, the upflow bubbling fluidized bed (UBFB), recently adapted to use bubble rupture promoters and called dense upflow fluidized bed (DUFB), offers a considerable potential for use in a solar power tower plant for its excellent heat transfer at moderate to high receiver capacities.

For all CSP applications with particle circulation, a major challenge remains the transfer of hot and colder particles among the different constituents of the CSP system (receiver to storage, power block and return loop to the top of the solar tower). Potential conveying modes are discussed and compared. Whereas in solar heat capture, bubbling fluidized beds, particle falling films, vortex and rotary furnaces, among others, seem appropriate, both moving beds and bubbling fluidized beds are recommended in the heat storage and re-use, and examined in the review.

Common to all CSP applications are the thermodynamic cycles in the power block, where different secondary working fluids can be used to feed the turbines. These thermodynamic cycles are discussed in detail and the current or future most likely selections are presented.

Since the use of a back up fuel is recommended for all CSP systems, the hybrid operation with the use of alternative fuel back-up is also included in the review.

The review research is concluded by scale-up data and challenges, and provides a preliminary view into the prospects and the overall economy of the system. Market prospects for both novel concentrated solar power are expected to be excellent. Although the research provided lab- and pilot-scale based design methods and equations for the key unit operations of the novel solar power tower CSP concept, there is ample scope for future development of several topics, as finally recommended.

聚光太阳能应用中粒子循环的机遇与挑战
聚光太阳能发电(CSP)是一种发电技术,通过定日镜将太阳辐照度集中到一个小面积的接收器上,在接收器上,传热介质(目前为流体(HTF))被用作热载体,流向储热和电源块。作为一种潜在的或有前途的可再生和可持续能源技术,它已经在聚光灯下十年了。在20世纪80年代首次提倡在CSP中使用气体/固体悬浮液作为传热介质,这一新颖的概念依赖于它在整个CSP工厂中的可能应用,即在热量收集,输送,储存和再利用中,与水/蒸汽,热流体或熔盐等常见传热流体相比,它具有主要优势。虽然颗粒悬浮液的热容量低于熔盐,但颗粒驱动系统可以在没有温度限制的情况下运行(除了接收管的最大允许壁温),并且还可以在更高的冷热温度梯度下运行。悬浮温度超过800°C可以容忍和实现,额外的高效热力学系统是适用的。高温颗粒热载体的应用进一步扩大了热力学循环的可能性,从朗肯蒸汽循环扩展到布雷顿气体循环,甚至扩展到联合发电循环。本文综述了粒子驱动光热技术的发展,并对其背景、基本原理和能效进行了评价。在列举的系统中,讨论了带有颗粒输送回路的批处理和连续操作。简要概述了相关颗粒的相关性质,以及它们作为传热介质的用途。最近的中试工厂实验表明,一种新的鼓泡流化床概念,即上流鼓泡流化床(UBFB),最近被用于使用气泡破裂促进剂,称为密集上流流化床(DUFB),在太阳能塔式发电厂中具有相当大的潜力,因为它在中高接收容量下具有出色的传热能力。对于所有具有颗粒循环的CSP应用,一个主要的挑战仍然是在CSP系统的不同组成部分(接收器到存储,电源块和返回循环到太阳能塔的顶部)之间传递热粒子和冷粒子。对可能的输送方式进行了讨论和比较。而在太阳能热捕获中,鼓泡流化床、颗粒落膜、涡旋炉和旋转炉等似乎是合适的,在蓄热和再利用中推荐移动床和鼓泡流化床,并在综述中进行了研究。所有CSP应用的共同点是动力块中的热力学循环,其中可以使用不同的二次工作流体来为涡轮机提供动力。详细讨论了这些热力学循环,并提出了当前或未来最可能的选择。由于建议所有CSP系统使用备用燃料,因此使用替代燃料备用的混合操作也包括在审查中。通过对规模数据和挑战的总结,对系统的前景和整体经济性进行了初步的展望。这两种新型聚光太阳能的市场前景都很好。尽管该研究为新型太阳能发电塔CSP概念的关键单元操作提供了基于实验室和中试规模的设计方法和方程,但正如最后建议的那样,未来有几个主题的发展空间很大。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Progress in Energy and Combustion Science
Progress in Energy and Combustion Science 工程技术-工程:化工
CiteScore
59.30
自引率
0.70%
发文量
44
审稿时长
3 months
期刊介绍: Progress in Energy and Combustion Science (PECS) publishes review articles covering all aspects of energy and combustion science. These articles offer a comprehensive, in-depth overview, evaluation, and discussion of specific topics. Given the importance of climate change and energy conservation, efficient combustion of fossil fuels and the development of sustainable energy systems are emphasized. Environmental protection requires limiting pollutants, including greenhouse gases, emitted from combustion and other energy-intensive systems. Additionally, combustion plays a vital role in process technology and materials science. PECS features articles authored by internationally recognized experts in combustion, flames, fuel science and technology, and sustainable energy solutions. Each volume includes specially commissioned review articles providing orderly and concise surveys and scientific discussions on various aspects of combustion and energy. While not overly lengthy, these articles allow authors to thoroughly and comprehensively explore their subjects. They serve as valuable resources for researchers seeking knowledge beyond their own fields and for students and engineers in government and industrial research seeking comprehensive reviews and practical solutions.
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