SU1603160A1 - Solar-energy dryer - Google Patents

Abstract

The invention relates to devices for placing and drying agricultural products, mainly vegetable raw materials, without an artificial source of heat. used in agriculture and everyday life. The purpose of the invention is to improve the quality of drying. The solar dryer contains a drying chamber 11, which is a frame 1 and a sloping roof, which are covered with a transparent film 9 capable of transmitting the sun's rays. At the top of the frame is placed the moisture-absorbing element (E) 12, which has the property of absorbing moisture. Inside the drying chamber 11, removable means 8 are placed to accommodate plant materials 16. The drying process takes place when the thermal solar energy through the transparent film 9 is applied to the vegetable raw material 16, releasing moisture from it, and the rising airflow in the form of mist condenses on the surface E 12 and absorbed into it. Circulating outside air through the through cavity 13 creates the effect of through and at the same time, in contact with the outer surface E 12, wets out moisture, thereby producing drying of the loaded raw material. 4 hp ff, 5 ill.

Description

The invention relates to devices for the placement and essence of agricultural products, mainly vegetable raw materials, and can be used in agriculture and in everyday life.

The aim of the invention is to improve the quality of drying.

FIG. depicts helio-dryer, side view; in fig. 2 - the same, front view; in fig. 3 - the same; side view, flat roof version; in fig. 4 is the same, an embodiment with a moisture-absorbing element in the form of a cylindrical surface; in fig. 5 - thermal valve drive.

Solar dryer contains frame 1 and inclined roof elements 2. The frame 1 is made of wooden slats or metal elements that form the pillars 3 of the carcass 1, connected by cross-links 4 and longitudinal links 5 and 6. On the uprights 3

carrier elements 7 are installed, on which removable means 8 are installed (sieve, lattices, mesh trays) for accommodating vegetable raw materials. The frame 1 is covered with a transparent film 9, and at the base of the frame 1 there is a mesh bottom 10 which allows air to pass into the drying chamber 11. At the top of the frame 1, a moisture absorbing element 12 is pivotally mounted, able to open slightly when the temperature inside the drying chamber rises and to take intermediate position (Fig. 1). The frame 1, covered with a transparent film 9, the bottom 10 and the moisture-absorbing element 12 form a drying chamber 11. The top of the frame I closes the inclined roof elements 2 (transparent cover), fastened with a longitudinal bond 6 and covered with a transparent film 9, and form a through cavity 13 open on TorO5

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ladies 14. The side surfaces of the frame I and the inclined elements 2 of the roof are covered with a transparent film 9, for example, polyethylene. The opening or removable wall 15 serves to load the plant material 16.

The mist condenses on the surface of element 12 and is absorbed into it. The air passing through the through cavity 13 creates a through effect and erodes moisture, thereby reducing the moisture content of the upper part of the roof cover 2 inside the chamber 11. Since the bottom of the chamber 11 is reticulated, the upward air flow intensifies the drying process, and the condensate formed on the walls of the chamber 11 flows down through the mesh bottom. In the event of a sharp rise in temperature inside chamber 11 and abundant moisture separation, the moisture absorbing element 12 rotates around the hinge, while chamber 11 is connected to the through cavity 13, which provides direct ventilation and feeding of the raw material. The rotation of the moisture-absorbing element 12 occurs due to the expansion of the working fluid in the cylinder (Fig. 5).

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They are not expanding and protruding beyond the borders of the uprights 3 of the frame 1 in order to avoid water getting onto the moisture-absorbing element 12 in case of rain.

The moisture-absorbing element 12 is a flat or cylindrical structure (or other configuration) made of cotton fabric, cardboard or other material capable of absorbing moisture 17 separated by the sun and preferably combining the functions of the thermal valve 18, i.e., opening slightly with a significant increase in temperature to ventilate the substance The chamber 11 is attached to the frame 1 by a hinge 19 and a cylinder 20, a sliding shaft 21 is connected by an axis 22 mounted on a thermal valve 18. A return spring is installed in the cylinder 20 and on the sliding rod 21 23, and at the end of the stem there is an eye 24, through which it communicates with the axis 22 and the thermal valve 18. The cylinder 20 is filled with working fluid 25. 5 The spring 23 facilitates the return of the slide bar 21 to its original position as the working fluid 25 is cooled, which is compressed. The eyelet 24 is intended to prevent the permanent opening-closing of the thermal valve 18, since the sliding rod 21 can constantly move back and forth depending on temperature fluctuations. The axis 22 is set selectively on a thermal valve during installation, taking into account the properties of the working fluid (expansion coefficient) and the maximum temperature allowed in the drying chamber 11. The cylinder 20 is installed in a convenient place in the drying chamber 11.

Solar dryer works as follows.

Prepared vegetable raw materials: mushrooms, fruits, years, medicinal herbs are evenly spread using 8 layers. The solar dryer is installed in an area open to the sun 17. The pallets are then installed on the carrier elements 7 in a certain way at a height with the condition to allow the moist, dried air to pass to the moisture-absorbing element 12 for absorption and evaporation. Thermal solar energy influences plant material 16, increases the temperature and evaporates moisture from the raw material. Rising wet stream in the form of

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measures 11 are reticulated, then upward air flow intensifies the drying process, and the condensate formed on the walls of chamber 11 flows down through the reticular bottom. In the event of a sharp rise in temperature inside chamber 11 and abundant moisture separation, the moisture absorbing element 12 rotates around the hinge, while chamber 11 is connected to the through cavity 13, which provides direct ventilation and feeding of the raw material. The rotation of the moisture-absorbing element 12 occurs due to the expansion of the working fluid in the cylinder (Fig. 5).

Possible embodiments of the helio-dryer according to FIG. 3 and 4. In this case, the roof is made single-pitch, and the moisture-absorbing element 12 is made in the form of a cylindrical surface (Fig. 4).

The proposed solar dryer allows for improved drying quality. The dried products in the solar dryer are not susceptible to burning and constant supervision during the planting process, which creates the convenience of its use in everyday life and in garden plots.

Claims (5)

1. A solar dryer containing a transparent drying chamber with shelves to accommodate the dried raw material and a transparent top coating, characterized in that, in order to improve the quality of drying, a desiccant element is installed between the top coating and the dried raw material to form a through cavity 40 automatic thermal valve, and the bottom of the chamber is made of mesh. 2. The helium trap under item 1, characterized in that the moisture-absorbing element is located on the entire width and length of the chamber. 3. The helium dryer under item 1, characterized in that the moisture-absorbing element is made in the form of a cylindrical surface. 4. A solar thermal trap according to claim 1, characterized in that the moisture-absorbing element is made of cotton fabric or cardboard. 5. A solar dryer according to claim 1, characterized in that the top coating is made expanding upwards. 50 The mist condenses on the surface of element 12 and is absorbed into it. The air passing through the through cavity 13 creates a through effect and erodes moisture, thereby reducing the humidity of the bone inside chamber 11. As the bottom of the bone inside chamber 11. Since the bottom of chamber 11 is reticulated, the upward air flow intensifies the process drying, and the condensate formed on the walls of the chamber 11 flows down through the mesh bottom. In the event of a sharp rise in temperature inside chamber 11 and abundant moisture separation, the moisture absorbing element 12 rotates around the hinge, while chamber 11 is connected to the through cavity 13, which provides direct ventilation and feeding of the raw material. The rotation of the moisture-absorbing element 12 occurs due to the expansion of the working fluid in the cylinder (Fig. 5). Possible embodiments of the helio-dryer according to FIG. 3 and 4. In this case, the roof is made single-pitch, and the moisture-absorbing element 12 is made in the form of a cylindrical surface (Fig. 4). The proposed solar dryer allows for improved drying quality. The dried products in the solar dryer are not susceptible to burning and constant supervision during the planting process, which creates the convenience of its use in everyday life and in garden plots. Invention Formula Jt eleven Id 1 16 810 // /// /// U / /// 1 14 Figg 15 R H u / /////////////// 5 W 18 eleven