DE4116455A1 - Ground-heat- and water-extraction unit - has central pipe with bottom filter pipe and supporting concentric outer ones - Google Patents

Abstract

The combined unit extracts and stores ground heat and water, and comprises vertical pipes inserted in the ground with pumps, filters etc. It comprises a central pipe (1) with filter pipe (6) at the bottom, together with a baseplate (7) fixed to it above the filter pipe. Further pipes (2, 3, 4) resistant to water pressure and enclosing the central pipe are fixed to the baseplate at set intervals, and distance-pieces (20) evenly spaced round the periphery of first pipes (1, 3) secure second ones (2, 4 in position, and there is insulating material between pipes (2, 3), at the bottom of which there are ports (21). Above these ports the insulating material is sealed off by a plate (19) resistant to water pressure. USE/ADVANTAGE - Easy installation and repair, and storage device simultaneously provides heat and hot and/or cold water.

Description

The invention relates to a storage well collector Combination for heat storage and geothermal and water extraction, the combination for example with Solar panels, combined heat and power plants and other heating facilities, such as heat pumps, can be connected.

There are many ways to Store heat in the ground for later extraction or heat recovery from the ground. Such underground storage or underground collectors become over weighing part laid horizontally. Mostly for that Trenches made, in which the storage or Absorber or heating circuits are installed, whereupon the trenches are filled in again.

The disadvantage of these horizontally arranged systems stands in the large space requirement, the large energy consumption lusts and problems arise if they exist alongside such systems are retrofitted to the buildings should.

It is also already known to excavate in the ground appropriate depth, in which then a Reinforcement cage with the pipes of an absorber circuit It is introduced, after which the ver permanent space is filled with concrete. An afterthought Repair or removal and relocation of a such an absorber is practically impossible.

Furthermore, it has also been suggested that one another arranged pipes without insulation vertically in the ground to be arranged so that an absorber circuit is formed.

The disadvantage of this arrangement is a thermody Named short circuit between forward and reverse and thus in poor efficiency.

It is also known to be one of pipes, tubes or Like. Absorber circle formed spirally in a well to arrange a hole-like excavation without retaining walls (DE-OS 39 13 429). As a heat conductor between soil and The absorber circuit becomes a mushy, flowable one Mud poured into the well-like hole in the earth.  

With this arrangement, only shallow depths are possible, with light soils there is a risk that the earth completely or partially before inserting the absorber coincides.

The disadvantage here is that between forward and reverse no insulation is arranged, which also causes it to a thermodynamic short circuit can occur and thus the efficiency is poor.

Another disadvantage is that all previously known to regulations and systems but only for storage and Heat extraction.

The object of the invention is an inexpensive Spei cher-well-collector combination with which the known disadvantages are largely avoided and the vertical at any depth with little tech African and technological effort and space requirements can be put that easy to assemble and repa is friendly to nature, with the same warmth chert and / or won and cold and / or hot water can be promoted and characterized by a high We degree of efficiency.

The invention is known to go from one in the ground vertically arranged pipe system.

According to the invention, a centrally located tube on lower end of a filter tube, over which on a Pipe attached base plate at defined intervals the central tube other pipes are pressurized water resistant are arranged, with the first and third pipe on the circumference evenly spaced spacers to fix the two th and fourth tube are arranged and between the second and third pipe insulation is arranged and openings at the foot of the second and third tubes are seen, the insulation above this public through a pressure-resistant plate is sealed.

According to another characteristic, the insulation is made by Foaming produced.  

According to another characteristic is in the center Pipe in the area above the filter pipe with a pump a pressure pipe insulated riser pipe and in the upper one Area below the dynamic groundwater level another pump with a riser pipe.

Another feature of the invention is that Borehole in the lower area between the outer pipe and earth rich with coarse gravel and a barrier in the upper area layer, for example clay, is filled.

Surprisingly, it turned out that the Er is possible to store or to gain heat and promote cold and / or hot water at the same time.

Another advantage of the invention is that by arranging the insulation there is no thermody Named short circuit can occur, reducing the efficiency is significantly increased.

It is also advantageous that the Spei invention cher-well-collector combination vertical in any Depth inexpensively with little effort and space requirements can be manufactured.

Furthermore, there is the advantage that in areas with existing buildings if necessary without difficulty Such combinations can be mislaid and a subsequent repair or removal and new laying the combination according to the invention without problems is possible.

The invention will be closer to an embodiment are explained.

The Fig. Shows a cross section of a vertically buried storage-well-collector combination.

In the ground 18 , a borehole 5 of, for example, a diameter of 1 m is machined at any depth, for example 300 m, preferably using the air-lifting method. At the same time, a support tube 5 'equal to the earth hole diameter is introduced. After manufacture of the stabilized borehole 5 through the support tube 5 ', the pipe installation of the storage-well-collector combination takes place.

It consists of a centrally arranged tube 1 , at the lower end of a filter tube 6 , z. B. is attached by a screw connection. A base plate 7 fastened to the tube 1 is arranged above the filter tube 6 .

On this base plate 7 further tubes 2 , 3 and 4 are attached at defined intervals around the central tube 1 , for example by a pressurized water-resistant screw connection. The tubes have the following diameters, for example:
The tube 1 of 200 mm,
the tube 2 of 300 mm,
the tube 3 of 400 mm,
the tube 4 of 500 mm
and the pipe segments from which the total length is made up, for example a length of 5 m each. On pipe 1 and 3 are evenly distributed on the circumference from spacers 20 for fixing the pipes 2 and 4 be fastened. Between pipe 2 and 3 , an insulation 8 is arranged, which is preferably introduced by foaming plastic. At the foot of the tubes 2 and 3 in the area Be above the base plate 7 openings 21 are introduced . Above these openings 21 , the insulation 8 is sealed by a plate 19 against the pipes 2 and 3 and thus against the water pressure water test.

The prefabricated rough construction is lowered into the borehole 5 step by step with a crane. For example, by means of a clip that is placed around the tube 4 , the bracket is carried out. The assembly process is repeated until the rough construction has reached the base of the borehole.

Expediently, temperature sensors are also arranged on the tube 4 in order to obtain control values. At closing, the filling of the borehole 5 takes place between the tube 4 and the support tube 5 'in the lower region with coarse gravel 9 and in the upper region with a barrier layer 10 , for example with clay. Then the support tube 5 'is pulled from the ground 18 .

Now takes place in the tube 1 in the area above the filter tube 6 , preferably below the base plate 7 , the introduction of the pump 13 with a riser pipe 14 , which is encased with a pressure-water-resistant insulation 15 to convey cold water. Subsequently, the pump 16 is installed with the riser 17 in the upper region of the pipe 1 under the dynamic groundwater table to promote warm water.

There is now the possibility of storing warm water in the circuit via the pipe 11 as a flow and the pipe 12 as a return. The warm water can be taken from various heat generating devices, for example, from combined heat and power plants, heating devices, heat pumps, etc.

Linking with a is particularly advantageous Solar collector, as described in DD-PS No. 2 87 985 has been written. These collectors are based on a multi-channel plastic hose band system and draw is characterized by high efficiency. The heat withdrawal takes place in the opposite direction.

With the pump 13 , cold groundwater from the pipe 1 , which also represents the well, is conveyed. The cold groundwater standing inside the pipe 1 is evenly heated by the storage of hot water by means of heat generating devices and through the openings 21 made in the pipes 2 and 3 and can be used with the pump 16 as hot water, so cold or hot water can be used individually or can be removed simultaneously from pipe 1 , i.e. the well.

Heat can also be stored at the same time as this process security and geothermal energy.

Claims (6)

1. Storage-well-collector combination for heat storage and geothermal and water production, essentially consisting of a vertically arranged in the ground pipe system with associated fittings, such as pumps and filters, characterized in that a centrally located pipe ( 1 ) at the lower end a Fil terrohr ( 6 ) and above the filter tube ( 6 ) on a tube ( 1 ) attached base plate ( 7 ) at defined intervals around the central tube ( 1 ) further re tubes ( 2 , 3 , 4 ) pressure water resistant are arranged, on the tube ( 1 , 3 ) on the circumference evenly distributed spacers ( 20 ) for fixing the tubes ( 2 , 4 ) are arranged and between the tube ( 2 ) and ( 3 ) an insulation ( 8 ) is arranged and on Bottom of the tubes ( 2 , 3 ) openings ( 21 ) are provided, the insulation ( 8 ) above these openings ( 21 ) being sealed by a water pressure-resistant plate ( 19 ). 2. Storage fountain collector combination according to claim 1, characterized in that the insulation ( 8 ) is preferably introduced by foaming. 3. Storage well-collector combination according to claim 1-2, characterized in that in the tube ( 1 ) in the area above the filter tube ( 6 ), a pump ( 13 ) with a pressure-water-insulated riser pipe ( 14 ) is arranged. 4. Storage fountain collector combination according to claims 1-3, characterized in that a pump ( 16 ) with a riser ( 17 ) is arranged in the upper region of the tube ( 1 ) below the dynamic groundwater table. 5. Storage fountain collector combination according to claim 1-4, characterized in that the borehole ( 5 ) in the lower region between the pipe ( 4 ) and soil ( 18 ) with coarse gravel ( 9 ) and in the upper region with a barrier layer ( 10 ) is filled out. 6. Storage fountain collector combination ach claim 1-5, characterized in that the barrier layer ( 10 ) consists of clay.