SU1657893A1 - Geliodrier-hothouse - Google Patents

Abstract

The invention relates to solar technology, to solar dryers transformed into a greenhouse, and allows to reduce the consumption of materials and increase the drying efficiency. Heli-greenhouse contains dryers. chamber (K) 1 with a transparent outer wall 3 and an absorbing film wall (C) 4 forming the air heater 2 with openings 10 and filters 11 placed in them. In K 1 there are lattices 5 for the material being dried 6. At outlet K 1 placed fan 7, which creates a vacuum in it. The air heated in the air heater 2, through the holes 10 and the filters 11 enters K 1, where it washes material 6, dries it and is removed by the fan 7. C 4 not only shields K 1 and heats the air, but also filters, evenly distributes and turbulizes it. In the working condition in the drying mode, the C 4 takes a volumetric shape that improves its optical, thermal and aerodynamic properties. In the cold season, C 4 is dismantled and the structure works as a greenhouse. 2 Il. Ё Os SL J 00 th with

Description

The invention relates to solar technology, solar thermal drying mainly agricultural products.

The purpose of the invention is to improve the quality of drying due to the uniform distribution of the drying agent throughout the chamber while simultaneously shading the material being dried and reducing material consumption due to the use of a film absorber with relatively high strength and thermal characteristics.

FIG. 1 shows a solar thermal greenhouse, section; FIG. 2 shows the composite modular design of a solar drying greenhouse, axon-meter.

A solar dryer - a greenhouse contains a drying chamber 1, the fence of which is made as an air heater 2 communicating with the chamber 1 of the heater 2 with a transparent outer 3 and 4 absorbent absorbing inner walls installed in the chamber 1 of the grill 5 for the material to be dried 6, the fan 7 and communicated with the air heater 2 and chamber 1, respectively, inlet and outlet ducts 8 and 9. Wall 4 is made of film material and provided with openings 10 with opaque filters 11 installed in them, and fan 7 at the inlet is connected to the outlet duct 9.

The fan 7 is connected to the outlet duct 12, the outer intake duct 13, the recirculation duct 14. The air ducts 8, 13 and 14 are provided with flaps 15.

Heli-greenhouse works in the drying mode as follows.

The dried material 6 (mainly agricultural produce) is loaded onto trays (not shown), which are placed on the gratings 5. The centrifugal fan sucks the exhausted moist air from chamber 1, which leads to a decrease in air pressure in it. Through the filters 11. installed in the holes 10, dry air heated in the heater 2 begins to flow into chamber 1, which evenly flushes material b, moves towards the fan 7. The uniform distribution of the drying agent over the volume of chamber 1 under reduced pressure in it promotes intense and uniform drying.

The wall 4 of the chamber 1 for convective drying, made of an elastic film material, ensures uniform distribution of the heated dry air, and also protects the material 6 from direct sunlight, preventing decomposition of the nutrients in the dried material 6, which allows it to retain its flavor and nutritional properties. Filters

11 prevent penetration into chamber 1 not only of pollution from the atmosphere, but also solar radiation.

The drying agent air is heated by solar energy absorbed by the opaque parts of the structure, mainly the wall 4. The outside air entering through the duct 13 is mixed with the recirculation duct through the duct 14. Emission from the worked air is done through the duct 12 connected to the outlet of the centrifugal fan 7. Part of the exhaust air can be returned through the air duct 14 to the solar dryer. The air flow is controlled by the flaps 15. In the cold period of the year, the walls 4 of the chamber 1 are dismantled, and the flaps 15 are moved to the closed position, closing the air ducts 8, 13 and 14. Thus, the structure is transformed into a solar thermal. The perforated non-translucent elastic film wall 4 under the action of vacuum in the drying chamber 1 is pressed against the grid 5 and takes the form

0 volume scavenger. Holes 10 should be located in the center of its recesses. Such a shape allows an increase in the area and absorption capacity of the light-receiving surface, as well as

5 improves the aerodynamic parameters of the structure by reducing the loss of air pressure at the inlet to the opening 10, where the corresponding section of the wall 4 takes the form of a confuser. In the working state 0, the wall 4 undergoes weak oscillations, which intensifies the process of heat transfer. All this allows reducing the material consumption of the structure and increasing the efficiency of the drying process due to intensification

5 heat exchange processes.

The strength characteristics of the wall 4, in which the inelastic filters 11 serve as reinforcing elements and prevent the destruction of the wall in the area of the holes 10,

0 and the absence of the need for thermal insulation of the chamber 1 from the air heater 2 allows thin films to be used to form the wall 4, which also reduces the material consumption of the structure.

five

Claims (1)

Invention Formula Solar water heater, containing a drying chamber, the enclosure of which is made as an air heater communicating with the chamber with a transparent outer and absorbing removable inner walls, installed in the lattice chamber for the material being dried, and communicating with the air heater and the chamber respectively the inlet and outlet ducts, by that In order to improve the quality of drying and reduce material consumption, the absorbing wall is made of film material and provided with openings with opaque filters installed in them, and a fan is connected to the outlet duct. 72 13 YU FIG. 2