The article presents an analysis of the technological stages of the production of solid biofuel from energy wood species, it is noted that up to 70% of the total energy consumption is spent on drying processes in technological processes. The urgency and advantages of low-temperature drying of such wood have been substantiated. It is noted in the work that the heat and humidity modes should ensure an increase in the energy efficiency of the process and a high calorific value of the resulting fuel. The purpose of the article is to intensify the process of dehydration of energy wood to obtain solid biofuel, to determine the effect on the process of convective low-temperature drying of the operating parameters of the drying agent, the size and shape of the raw material, and the specific load on the drying surface. Energy willow was used as an object for dehydration, the initial moisture content of which varied over a wide range from 45 to 60% per wet weight; dehydration was carried out until the material reached residual moisture content of 5...6%. Studies on the effect of the temperature of the drying agent on the kinetics of moisture exchange prove that an increase in temperature from 80 to 100 °C intensifies heat and mass transfer and reduces the duration of the process by up to 25%. The results of experimental studies of the effect of the specific load on the dehydration process showed that an increase in load has a positive effect on the productivity of the drying unit and increases the volume of processed raw materials. At the same time, the total duration of dehydration from the minimum load to the maximum increases by 3.5 times. It is noted in the work that a significant parameter of influence on the kinetics of drying and increasing the efficiency of the process is the method of grinding the raw material. The most intensive mode corresponds to the method of grinding willow by combining abrasion and impact. With this method of grinding, the drying time is reduced from 15 to 25% in comparison with the others considered. The combination of the specified conditions and parameters of low-temperature drying provides an economical process and obtaining dried willow with low and evenly distributed residual moisture. The use of such material in the technological cycle of biofuel production guarantees the reliable operation of the combustion device for a long time.
The article considers peat as an effective alternative fuel. Its reserves and directions of use in the world and in Ukraine presented and analyzed. The analysis showed that the geological reserves of peat in Ukraine are equivalent to 600 billion cubic meters of natural gas. The main reserves of peat are concentrated in the districts of Polissia. Industrial peat extraction can take place in 12 regions: Volyn, Rivne, Zhytomyr, Kyiv, Cherkasy, Poltava, Sumy, Chernihiv, Khmelnytskyi, Ternopil, Lviv, and Ivano-Frankivsk. It has been shown that, compared to traditional energy carriers, peat fuel has a lower heat of combustion and a fairly high ash content, but during combustion it emits almost no toxic substances and, accordingly, pollutes the environment much less. In home furnaces, peat fuel burned with a higher efficiency than coal, and the ash used as fertilizer. The estimated cost of 1Gj of lower heat of combustion of various types of fuel according to the data of recent years shows a noticeable advantage of peat fuels. The cost of thermal energy obtained from burning 1 ton of peat briquettes is 2 times cheaper than when using coal, 3 times cheaper than gas, and 4 times cheaper than fuel oil. Peat fuel is suitable for use in all types of modern solid fuel combustion devices, which increases the prospect of its implementation on the domestic and foreign fuel markets. The technology for using plant biomass as a filler in peat briquettes and granules developed. Special attention paid to wood, buckwheat husk, sunflower and other grain crops, which have a lower ash content and a higher heat of combustion, the potential of which waste is significant, and the fuel characteristics are able to increase the heat of combustion of composite peat briquettes or peat granules and reduce their ash content. Taking into account that peat used in large quantities as fertilizer for agriculture, a technology developed according to which humic substances first removed from peat for fertilizer, and then biomass added to this peat and a composite peat fuel obtained. This technology involves the integration of technology and extraction of humic substances into the production cycle of a peat briquette plant for the production of composite fuel. The wide implementation of the developed technology of composite peat briquettes at peat briquette factories will allow to increase the production of briquettes by almost 2 times without increasing the consumption of peat raw materials and to produce peat fuel in the range of 0.18-0.2% of geological reserves, which is equivalent to the replacement of more than 1 billion m3 of natural gas. All this allows us to draw a conclusion about the positioning of peat fuel as an effective local type of fuel, which is an alternative to gas and coal.
Розглянуто шляхи поєднання технології отримання гумінових речовин та виробництва композиційного палива. Обґрунтовано енергоефективну схему виробництва композиційного палива. Запропоновано методи розрахунку вмісту складових палива.
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