SU1034654A1 - Vegetation structure - Google Patents

Description

2. A vegetation structure by the construction due to the use of salt A.1, characterized by the net energy, the roof panels are eliminated, in order to reduce energy consumption by two layers with a cavity that heats the air being heated in air to the duct.

The invention relates to agricultural production and can be used in conditions of closed moisture circulation, carried out by collecting and using precipitation from the area occupied by the structure in areas experiencing a lack of moisture for irrigation.

A vegetation structure is known that contains a skeleton, a translucent coating, a device for watering plants and maintaining a temperature of 1,

A greenhouse is known, containing a frame, a translucent coating with a layer reflecting the infrared part of radiation, air ducts and an air conditioner with a heat exchanger and CsG densitant collection C 1. However, this greenhouse does not provide sufficient reliability in supplying plants with moisture, and also has significant energy consumption for heating the circulating air.

The aim of the invention is to increase the reliability of providing planting with moisture, as well as reducing the energy consumption for heating the circulating air in the structure through the use of solar energy.

The goal is achieved by the fact that the vegetation structure is provided with water storage, gutters, drainage sleeves with a check valve, bottom waterproofing layer, a drain and an additional heat exchanger, and the top of the structure is foldable with waterproof interface along its perimeter with the walls of the frame and is provided with fixers An additional heat exchanger is located at the duct outlet into the plant growing zone, and the roof panels are double-layered with a cavity that communicates with the duct.

FIG. 1 shows the construction, a longitudinal section; in fig. 2 shows the construction during the collection of moisture in the form of rain and the implementation of the conditions of closed moisture circulation, the cross-section A-A in FIG. one; in fig. 3f is the same when collecting snow ..

The vegetation structure consists of a frame 1, equipped with an air duct 2, covered with a translucent coating 3 forming the internal cavity, heat exchanger 5 with condensate collector 6, additional heat exchanger 7, roof panels made of frame 8 forming the duct cavity 9 with each other and equipped with grooves 10 with drainage sleeves 11 with a check valve 12, the bottom hydrodisol of the water of the second layer 13 and the water storage 14. The bottom waterproofing layer can be equipped with a sand filter 15. In the air duct 2 there is a fan 16, On translucent coating 3 deposited 17, reflecting the infrared part of the radiation.

The device is equipped with a carbon dioxide generator 18, a cleaning device 19, an irrigation system 20, Frame 1 is connected to the duct cavity 2 by loops 21. The roof of the structure, made of hinged frames 8, is provided with waterproof mating 22 around their perimeter with the walls of frame 1 and is equipped with latches position 23 ..

The construction works as follows.

In the autumn-winter period, the split-roof panels are rotated in loops x 21 to one or another vertical position and, if necessary, secured with latches 23. This collects precipitation in the form of snow inside the structure, with the roof panels acting as snow retaining devices. In the spring-years

Research institute period Roof panels are closed; at 9T, a waterproof cavity of the internal cavity is achieved by means of waterproof mating 22. The drain in the water storage of the waterproofing LLO collects the moisture of the melting snow. The melodies 10 on the outside of the roof panels collect rainfall, which by drainage sleeves 11 are directed to the water storage 1, -Water discharge sleeves, equipped with non-return valves 12 to prevent moisture loss from evaporation into the atmosphere.

Maintaining the optimum temperature and relative humidity is as follows.

the air from the internal cavity k is sucked in by the fan 16 into the air duct 2 and, the passage through the heat exchanger S connected to the cooling machine is cooled to a certain temperature at which its absolute moisture content corresponds to the optimum relative humidity at the optimum temperature. The resulting condensate flows from the condensate collector 6 into the water storage I. Then the cooled air enters the cavity 9 of the roof panels forming the duct, where under the action of solar radiation, direct and reflected by the corresponding layer of the bottom frame 17, it partially warms up and enters the additional heat exchanger 7, connected to a heat engine, where it reaches the optimum temperature, then entering the internal cavity k,

A layer on a translucent coating that reflects the infrared portion of radiation can be formed, for example, by a layer of gold close in thickness to the monomolecular and others.

The required temperature regimes are regulated by the operation of the heating and heating machines, which can be carried out at the expense of the energy obtained from solar batteries located on the building.

The structure is provided with a carbon dioxide generator 18, by means of which an excess of oxygen formed during the growing season in the structure can be converted to carbon dioxide.

The vegetation facility allows agricultural production to be developed in arid areas without additional engineering land reclamation facilities.

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Claims (2)

1. A VEGETATION CONNECTING the infrared part of radiation, air ducts, and an air conditioner with a heat exchanger and a condensate collector; a bottom waterproofing layer, a drain and an additional heat exchanger, and the roof of the structure is hinged with waterproof mating along its perimeter with the walls of the frame and is equipped with position locks, moreover, additional heat oobmennik located SU,.,. 1034654 I34654 2. Vegetation plant for Claim 1, characterized in that, in order to reduce energy consumption for heating the circulated air in the building by using solar energy, the roof panels are double-layer with a cavity that is in communication with the duct.