Optimization of sound insulation of flat panel photobioreactors for bioenergy facades

Martin Kerner
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引用次数: 1

Abstract

Flat panel photobioreactors consisting of different layers of glass panes, designed to allow heat and microalgae biomass production in a water layer by solar radiation at the facade of buildings (i.e. bioenergy facade), were acoustically examined and further developed for increased sound insulation against external noise exposure. The sound insulation was first examined by simulations on double-, triple- and four-skin bioreactor variants. Parameters such as the distance between panes, the number and types of layers, as well as the material and thickness of the glass panes, were varied. Especially the influence of decoupling layers and an airlift on the sound reduction index was evaluated. Based on the simulation results, a modular prototype was developed which could be converted into a double-, triple- or four-skin structure as required. The sound reduction of these was studied in an acoustic window laboratory experimentally. The highest measured weighted sound reduction index of 51 dB was obtained with a four-skin photobioreactor variant with four glass pane layers and a water layer. The weighted sound reduction indexes for alternative four-skin opaque prototype variants with a plasterboard layer were 2—3 dB lower. The double- and triple-skin variants achieved 43—47 dB. The use of XPS as insulation material in the outer air layers of the triple- and four-skin variants reduced the weighted sound reduction index by 2 dB. The airlift needed for turbulent mixing of the microalgae had no effect on the sound insulation but increased the average ambient noise level by up to 10 dB. With 51 dB, the four-shell photobioreactor prototype achieves sound insulation class 5 according to the german regulation VDI 2719 for windows and thus fulfills the function of a sound insulation element in the facade of buildings or in a soundproof wall.

生物能源外墙平板光生物反应器的隔声优化
平板光生物反应器由不同的玻璃板层组成,旨在通过建筑物立面(即生物能源立面)的太阳辐射在水层中产生热量和微藻生物量,并对其进行了声学检查和进一步开发,以增加对外部噪音暴露的隔音效果。首先通过对双层、三层和四层生物反应器的模拟来检验隔音效果。窗格之间的距离、层的数量和类型以及玻璃窗格的材料和厚度等参数是不同的。着重分析了去耦层和气升对隔声性能的影响。基于仿真结果,开发了模块化原型,可根据需要转换为双层、三层或四层蒙皮结构。在声窗实验室内对这些材料的降噪进行了实验研究。采用四层玻璃板和一层水层的四层光生物反应器的加权减声指数最高,为51 dB。带有石膏板层的四层不透明原型变体的加权减声指数降低了2-3 dB。双蒙皮和三蒙皮变体达到43-47分贝。在三层和四层外壳的外层空气层中使用XPS作为绝缘材料,加权减声指数降低了2 dB。微藻湍流混合所需的气升力对隔声没有影响,但使平均环境噪声水平提高了10 dB。根据德国VDI 2719标准,该四壳光生物反应器原型具有51 dB的隔音性能,达到了5级隔音等级,从而实现了建筑物立面或隔音墙的隔音元件的功能。
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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