Abstract
The work addresses the issue of solving a scientific-applied task on the substantiation of operation modes of the solar fruit dryer in order to improve energy efficiency of the technological process of fruit drying for small amounts of fruit processed at private farms. We have explored the use of solar energy for fruit drying at the latitude of the location of Rivne oblast, Ukraine, which has the average annual solar radiation power of the order of 3.41 kW∙h/m 2 per daylight. This makes it possible to receive from 1.5 to 2.3 kW∙h of energy per day from the air collector area of 1 m 2 . The series of analytical and experimental studies that we conducted has confirmed the possibility for a significant intensification of the process of fruit drying in the solar dryer. Compared with modern convective drying devices, the specific energy consumption when drying the fruit in the solar dryer is reduced by 3…3.7 MJ/kg. The degree of intensification grows by 3.3…12 times compared to drying devices of the mine and tunnel types. Such results were achieved by implementing the proposed design of a flat mirror concentrator, to enhance the slanting fluxes of morning and evening sun irradiation, and a heat accumulator, based on pebbles, for accumulating at night the excessive heat from the reserve source of energy. It was established that regardless of a blanching technique for fruit raw materials, the duration of drying in the solar dryer varies depending on physical parameters of the environment. In the process of drying, the experiments were carried out at a temperature of 289.15…333.15 K, and the duration of drying was from 50 to 74 hours. We have analyzed the effect of operational parameters on a change in the chemical indicators and quality of the dried fruit. Specifically, the content of vitamin C, which was 5.2 mg/% for pear, and 4.3 mg/% for apple. The acidity was 0.29 % for pear, and 0.46 % for apple. The content of dry nutrients was 87.5 % for pear, and 85.9 % for apple. The sugar content of fruit raw materials was 59.36 % for pear, and 57.8 % for apple.
Highlights
Research into technological process of fruit drying by sun rays must involve studying energy parameters of the heat carrier, physical-mechanical properties of fruit as the object of drying, as well as selection and substantiation of operation modes
The development of new, and the improvement of existing, technologies and drying devices are regulated both by the intensities of heat moisture exchange between a heat carrier and the object of drying and by the intensities of heat moisture transfer inside the material
When substantiating the modes of operation and estimating the kinetic and dynamic parameters, the authors failed to account for the theoretical moisture content in the original flow of the heat carrier, which would make it possible to describe the hourly changing of fruit mass Δm during drying
Summary
Research into technological process of fruit drying by sun rays must involve studying energy parameters of the heat carrier, physical-mechanical properties of fruit as the object of drying, as well as selection and substantiation of operation modes. When substantiating the modes of operation and estimating the kinetic and dynamic parameters, the authors failed to account for the theoretical moisture content in the original flow of the heat carrier, which would make it possible to describe the hourly changing of fruit mass Δm during drying.
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