INVESTIGATION OF GRANULAR NATURAL STONE MATERIALS AS PHOTOTHERMAL ABSORBERS FOR SUSTAINABLE AND ENVIRONMENTALLY FRIENDLY ENERGY HARVESTING

Q3 Engineering

Journal of Applied Engineering Science Pub Date : 2024-03-10 DOI:10.5937/jaes0-47834

Alfan Sarifudin, I. Yaningsih, Budi Kristiawan, Aditya Wibawa, Takahiko Miyazaki, K. Thu, A. Silitonga, Hwai Chyuan Ong

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引用次数: 0

Abstract

The development of cost-effective and environmentally friendly solar thermal technologies that deliver high performance poses several challenges, where the collector and absorber components play a pivotal role. This research addresses these issues by investigating enhanced temperature generation using a 30 cm × 30 cm Fresnel lens collector under solar illumination from a xenon lamp. Natural stone materials (andesite, coal, and pumice), characterized by granular structures with an average diameter of 1.68–2.00 mm, were selected because of their abundance and eco-friendliness. This research is focused on evaluating the effect of Fresnel lens on temperature generation performance. Two types of temperature generation tests were carried out: wet tests (where the natural stone materials were immersed in distilled water) and dry tests (where the natural stone materials were used in dry conditions). The morphologies of the natural stone materials were examined using an optical microscope and scanning electron microscope. Furthermore, the optical properties of the natural stone materials were analyzed using an ultraviolet–visible (UV–VIS) spectrophotometer. The findings revealed that there were significant improvements in the photothermal absorber performance with the use of a Fresnel lens in dry tests, where the highest temperature was achieved for coal (103.25 °C), followed by andesite (89.00 °C) and pumice (73.00 °C). The impurities varied between the materials, where the impurities were most dominant for pumice while coal was more uniform. Further examination using scanning electron microscope showed that all materials had light-trapping structures in the form of rough surfaces, pores, and crack gaps. Andesite was dominated by rough surfaces, while coal and pumice were dominated by crack gaps and pores, respectively. However, based on the UV–VIS spectrophotometric results, there were no correlations between the optical properties (absorbance, reflectance, and transmittance) and temperature achieved by the photothermal absorber materials. This research demonstrates the potential of using natural stone materials as photothermal absorbers in combination with a Fresnel lens collector for low-to-medium temperature solar thermal applications.

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将粒状天然石材材料作为光热吸收器用于可持续和环保型能源采集的研究

开发具有成本效益和环境友好型的高性能太阳能热技术面临着若干挑战，其中集热器和吸收器组件起着关键作用。为了解决这些问题，本研究利用一个 30 厘米 × 30 厘米的菲涅尔透镜集热器，在氙灯的太阳光照射下研究如何提高温度。之所以选择天然石材（安山岩、煤和浮石），是因为它们具有平均直径为 1.68-2.00 毫米的颗粒状结构，数量丰富且生态友好。本研究的重点是评估菲涅尔透镜对温度生成性能的影响。研究人员进行了两种温度产生试验：湿试验（将天然石材浸入蒸馏水中）和干试验（在干燥条件下使用天然石材）。使用光学显微镜和扫描电子显微镜检查了天然石材的形态。此外，还使用紫外-可见（UV-VIS）分光光度计分析了天然石材的光学特性。研究结果表明，在干燥测试中使用菲涅尔透镜后，光热吸收器的性能有了明显改善，其中煤的温度最高（103.25 °C），其次是安山岩（89.00 °C）和浮石（73.00 °C）。不同材料的杂质含量各不相同，其中浮石的杂质含量最高，而煤的杂质含量较为均匀。使用扫描电子显微镜进行的进一步检查显示，所有材料都有以粗糙表面、孔隙和裂缝间隙形式存在的捕光结构。安山岩以粗糙表面为主，而煤和浮石则分别以裂隙和孔隙为主。然而，根据紫外-可见分光光度法的结果，光热吸收材料的光学特性（吸光度、反射率和透射率）与所达到的温度之间没有关联。这项研究表明，将天然石材作为光热吸收材料与菲涅尔透镜集热器相结合，可用于中低温太阳能热应用。

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

Journal of Applied Engineering Science Engineering-Engineering (all)

CiteScore

2.00

自引率

0.00%

发文量

122

审稿时长

12 weeks

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