DE3216358A1 - Heat exchange and heat storage installation for a greenhouse - Google Patents

Abstract

The installation puts us in a position to be able to store and use, in the long term, large proportions of the excess heat produced. The method described makes it possible to fit the installation in any existing greenhouse and to make substantial proportions of the energy supply self-sufficient. The level of efficiency is determined partly by the density of the suspended P.E. tubes and partly by the density and depth of the heat exchangers in the soil.

Description

Kaarst 2, April 29th, 1982

Description of the patent application

of Mr. Karl-Gerd Compes, Maco Hof, 4044 Kaarst 2

Concerning: heat exchange and heat storage system for greenhouses

The invention relates to a system to store excess heat in the long term in order to avoid heat peaks to supply heat to the heat valleys in order to create a balanced climate for the plants.

It is known that there are experiments and facilities where Heat is collected by means of solar cells and water tanks are heated up, which then serve as storage Need to be retrieved again. ·

The costs of this system are out of proportion TO the results, especially in our part of the world.

The invention is based on the object of obtaining waste heat inexpensively and storing it in the long term.

According to the invention, this object is achieved in such a way that .between the outer skin of the glass house, consisting of glass and a shading fleece stretched below it at a distance of 10 cm, P.E hoses can be hung up. These hoses are through

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a collector system combined into a supply and a return line. The bottom is 4.5 m deep Holes drilled with a power drill. The drill pipe is to be lengthened by parts of 1 m so that you can work in a narrow, low space. The entire drill string consists of worm thread parts, so that the drill string during the drilling process does not need to be excavated. The ejection turns up slowly. In the desired We let the drill run through for about 10 minutes, held on trestles. Solidified in time the borehole in such a way that the drill pipe can be easily excavated by hand without a tripod or other auxiliary devices, which make the drilling process very difficult in the glass house, if not would make impossible. We insert the heat exchanger into the drilled hole. The heat exchanger consists of PVC pipes; an outer one is locked at the bottom, an inner open at the bottom. Through the inner pipe, heated water is drawn down in the roof space pumped and then flows up between the inner and outer pipe and gives off heat on the way. Several Boreholes are made through a supply and a return line connected to the flow and return of the hose system under the roof. (Scheme drawing)

It is important, first of all, that the free space in the borehole between the borehole and the heat exchanger is well filled, if possible with Beflttonit, which is used in the event of slight vibration of the heat exchanger is filled dry, so that existing air in the borehole escapes.

It is important, secondly, that the heat exchangers on the head piece are fitted with slides so that they can be connected in parallel

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to enable the system; the primary energy requirement is reduced to approx. 20% compared to series connection. I am with the sliders. in the. Location, to run in the system in such a way that I can ventilate all exchangers well and drive on evenly.

The entire system is using water as a heat transfer medium filled. A pressure expansion device increases the pressure. The system is operated closed.

A circulation pump, which is controlled by a temperature difference controller, is installed in the supply line. With a selected and set difference to the floor storage, the pump runs and, on the other hand, with a second selected difference between the storage and the attic, the pump runs again, so that I do the same. a controller can charge and discharge the storage, so that I can cool and heat the greenhouse with the same system.

Claims (1)

Claims ■ · Heat exchange and heat storage system for greenhouses Characterized in that too much heat generated in the greenhouse from the roof space of the greenhouse is fed to the floor of the greenhouse and if necessary again from the floor of the room or the Attic space is supplied to prevent the ingress of cold.