Parameters affecting biomass drying during combustion in moving grate furnaces

Q3 Earth and Planetary Sciences

Energetika Pub Date : 2019-05-15 DOI:10.6001/ENERGETIKA.V65I1.3976

L. Vorotinskienė

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引用次数: 3

Abstract

The most efficient way so far to extract energy from renewable sources is combustion of solid fuel. Solid fuel furnaces of moderate capacity (5–10 MW) equipped with reciprocating grates are most popular. Grate combustion is a well-developed technology; however, to burn biofuel in this type of furnaces in the optimal and safe way, the fuel must be of high quality and have at least constant moisture content. However, increasing demand for biofuel results in increasing prices. To remain in the market and to stay competitive, heat producers choose to utilise moist biofuel of lower quality, whose moisture content can vary and reach up to 60% wt. The burning on the grate of such biofuel is complicated as the drying process occupies most of the space in the furnace. The purpose of this work was to analyse processes taking place in a furnace, such as: primary air supply, influence of flue gas recirculation and radiation from hot surfaces of the furnace to biofuel drying. Analysis of the data obtained would provide technical decisions facilitating optimal fuel combustion in a furnace without additional investments. Analysis of biofuel drying was performed in an experimental setup with a fixed fuel bed. The experiments were performed with wood chips and four different drying fluid temperatures. The results of experimental studies have shown that the drying rate of biofuels upper layers is strongly influenced by radiation from hot surfaces and the moisture content of the sample decreases by 18% wt.

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影响移动炉排燃烧过程中生物质干燥的参数

迄今为止，从可再生能源中提取能源的最有效方法是燃烧固体燃料。配备往复式格栅的中等容量(5-10兆瓦)固体燃料炉是最受欢迎的。炉排燃烧是一项发达的技术;然而，为了在这种类型的炉子中以最佳和安全的方式燃烧生物燃料，燃料必须具有高质量并且至少具有恒定的水分含量。然而，对生物燃料需求的增加导致了价格的上涨。为了留在市场上并保持竞争力，热能生产商选择使用质量较低的潮湿生物燃料，其水分含量可以变化，最高可达60% wt。这种生物燃料炉排上的燃烧是复杂的，因为干燥过程占据了炉子中的大部分空间。这项工作的目的是分析炉内发生的过程，例如:一次空气供应、烟气再循环的影响以及炉热表面辐射对生物燃料干燥的影响。对获得的数据进行分析将提供技术决策，以促进炉子中燃料的最佳燃烧，而无需额外投资。在固定燃料床的实验装置中对生物燃料的干燥进行了分析。实验用木屑和四种不同的干燥液温度进行。实验研究结果表明，生物燃料上层的干燥速度受到热表面辐射的强烈影响，样品的水分含量下降了18%。

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

Energetika Energy-Energy Engineering and Power Technology

CiteScore

2.10

自引率

0.00%

发文量

期刊介绍： The journal publishes original scientific, review and problem papers in the following fields: power engineering economics, modelling of energy systems, their management and optimization, target systems, environmental impacts of power engineering objects, nuclear energetics, its safety, radioactive waste disposal, renewable power sources, power engineering metrology, thermal physics, aerohydrodynamics, plasma technologies, combustion processes, hydrogen energetics, material studies and technologies, hydrology, hydroenergetics. All papers are reviewed. Information is presented on the defended theses, various conferences, reviews, etc.