直接辐射吸附床和间接辐射吸附床与太阳能集热器的热能储存实验比较

Energy Storage Pub Date : 2024-04-18 DOI:10.1002/est2.623
Kapil Narwal, Fatemeh Massah, Roger Kempers, Paul G. O'Brien
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摘要

利用太阳能加热吸附剂可实现热能储存和吸附制冷,且对环境影响较小。这项研究比较了利用太阳能加热吸附剂以储存热能的两种不同方法:(1) 将吸附剂暴露在通过太阳能集热器窗口透射的入射光下,以及 (2) 通过加热高吸收率的太阳能集热器盖,然后将太阳能吸收器的热量传递给位于其下方的吸附剂。为了进行这种比较,我们使用沸石 13X 和水作为吸附剂-吸附剂对,对三种情况的吸附剂床进行了实验。在第一种情况下,吸附剂床的顶部是一块聚碳酸酯板,沸石直接被透过该板的太阳模拟光加热。第二种情况是在聚碳酸酯板下面放置一块发黑的铝板,通过吸收入射光产生热量。第三种情况是将发黑的铝吸收器直接放在沸石珠的顶部,吸收器与反应器壁隔离,以避免热量损失。结果表明,当光线直接照射到沸石 13X 上时,能量存储密度(ESD)为 43.6 kWh/m3(63.4 Wh/kg);当光线照射到将热量传递给位于其下方的沸石珠的发黑吸收板上时,能量存储密度(ESD)为 33.3 kWh/m3(48.4 Wh/kg)。然而,当发黑的吸收板与吸附床壁隔热时,ESD 值提高到 48.9 kWh/m3(71.0 Wh/kg)。这些结果表明,为了提高储能密度,最佳的吸收器布置对于增强吸附过程非常重要。
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An experimental comparison of thermal energy storage in directly and indirectly radiated adsorbent beds integrated with solar thermal collectors

Adsorbents heated using solar energy can be used to achieve thermal energy storage and sorption refrigeration with low environmental impacts. This research compares two different methods of heating adsorbents with solar energy to store thermal energy: (1) by exposing the adsorbents to incident light transmitted through a solar collector window, and (2) by heating a highly absorbing solar collector cover, and then transferring the heat from this solar absorber to adsorbents located beneath it. To carry out this comparison experiments are conducted for three cases of adsorbent beds using zeolite 13X and water as the adsorbent-adsorbate pair. In the first case, the top of the adsorbent bed is a polycarbonate sheet, and the zeolites are heated directly by solar-simulated light transmitted through this sheet. In the second case, a blackened aluminum sheet is placed beneath the polycarbonate sheet to generate heat by absorbing incident light. For the third case, the blackened aluminum absorber is placed directly on top of the zeolite beads and the absorber is isolated from the walls of the reactor to avoid heat losses. The outcomes reveal an energy storage density (ESD) of 43.6 kWh/m3 (63.4 Wh/kg) when light is directly incident onto the zeolite 13X and an ESD of 33.3 kWh/m3 (48.4 Wh/kg) when light is incident onto a blackened absorber plate that transfers heat to Zeolite beads residing beneath it. However, ESD values were improved to 48.9 kWh/m3 (71.0 Wh/kg) when the blackened absorber plate was thermally insulated from the walls of the adsorbent bed. These results demonstrate the importance of an optimal absorber arrangement in enhancing the adsorption process for the purpose of elevating energy storage densities.

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