DE3032104A1 - Heat pump ground heat exchanger - has flow taking place in one direction only through U=shaped pipes - Google Patents

Abstract

The ground heat exchanger is for a heat pump, and comprises pipes laid vertically in the earth. The pipes (6) are U-shaped, medium flow taking place through them in one direction only. Between the supply (1) and return (2) manifolds there can be one or more pipe runs, within which the U-shaped pipes are connected so that flow of the heat-transfer medium takes place through them in series or parallel. Each run can have a stop valve in the supply and the return manifold. Each U-shaped pipe can be mounted in a single borehole, any empty space in the latter being filled in, and water mixed with antifreeze chemical can be used as the medium.

Description

Geothermal heat exchangers for heat pump systems

Geothermal heat exchanger for heat pump systems The invention relates to a Geothermal heat exchangers for heat pump systems, such as those used for energy-saving Heating of living spaces or commercial spaces can be used.

Such geothermal heat exchangers are so far designed that each the two pipes laid in the ground intermesh with each other, with that on the flow connected pipe is inside and the pipe connected to the return this takes inside tube. The outer tube is a blind tube, inside of which the frontally open inner tube ends. The heat carrier, generally water, which is mixed with an anti-freeze agent, is thereby by a feed pump guided into the inner tube and then flows through the outer tube, from which it flows into the return flow and from there into the heat pump.

This known geothermal heat exchanger is disadvantageous in several respects. If the heat pipes are made of plastic, this inevitably results in a greater wall thickness, as a result of which the heat transfer from the ground to within the Outer pipe flowing water is deteriorated. If, on the other hand, the outer tube is made Made of steel, the heat transfer from the ground to the one to be heated is true Water is better, but the disadvantage of corrosion has to be accepted. In addition, a steel pipe is much more expensive than a plastic pipe. Around the structure of these well-known geothermal heat exchangers in adaptation to the individual To be able to undertake the conditions and requirements of a geothermal heating system So heat pipes of various diameters are kept in stock and installed later The outer heat pipes are particularly expensive are. - In In any case, the sealing of the inner tube is at the point of entry into the outer tube difficult to manufacture and also very expensive in terms of material The invention is based on the object of providing a geothermal heat exchanger of the type described at the outset To create type that can be manufactured and assembled at significantly lower costs and at the same time ensures that the heat transfer medium is heated to a higher final temperature According to the invention this object is achieved in that the heat pipes as of the Heat carriers are formed in one direction through flowing pipes.

There are now only pipes between the flow and return of the geothermal heat exchanger one and the same diameter is used.

Only tubes of the same diameter are therefore required for the geothermal heat exchanger to be kept in stock. The same applies to the pipe connections between Vor and flow pipe. By having both legs of the tubes in one direction one after the other are flowed through, it is ensured that the heat transfer medium in the one leg flows in and out of the other leg of the tube all the way through the WR pipe can absorb heat from the ground, so that a higher final temperature of the heat transfer medium.

In a further development of the invention, each W pipe is in a single, the same receiving earth hole laid, with the remaining cavities through clammed earth are filled out. This will make the one you want Isolation of the two legs of the pipe against each other achieved and an internal heat exchange wipe both legs of the U-tube largely prevented.

Another very important advantage of the geothermal heat exchanger according to the invention results from the uniform, more conventional compared to the diameter of the outer tube Geothermal heat exchanger smaller diameter of the required Robmaterial. With the reduced Raw diameter is inevitably a reduction in the required wall thickness the pipes connected, which in turn result in an increase in the heat transfer Has. Due to the thinner wall thickness of the pipes, you can now even remove them the plastic, which basically has a higher thermal resistance manufactured using, which results in a significant reduction in the overall cost of the geothermal heat exchanger results. The joining of the individual tubes of the Geothermal heat exchanger using the appropriate adhesive is particularly simple and therefore afflicted with low manufacturing costs, possible, and also an absolute tightness the system can be guaranteed, in any case, however, is by the invention Geothermal heat exchanger ensures a significantly higher final temperature of the heat transfer medium, than this could be achieved by the previously known geothermal heat exchangers.

In a further development of the invention, there are between the flow pipe and the return pipe of the geothermal heat exchanger arranged one or more pipe strings within which the Tube parallel or in series from the heat transfer medium flows through, switched are. This is an adaptation to the most diverse heating requirements and local conditions of the soil possible.

To ensure that the geothermal heat exchanger is used even when unpredictable Reasons (earth shifts, material defects, the pipes used, etc.) one or the other pipe for the reception and delivery of ground warmth useless should have become an operation of the entire plant, albeit at a reduced rate Scope of being able to maintain is in one embodiment of the invention each pipe string is equipped with a shut-off valve in the flow pipe and in the return pipe. The pipe or pipe pair that has become damaged in each case then by closing the associated one both shut-off valves are removed from the heating cycle, while the rest Part of the geothermal heat exchanger remains functional.

In summary, the geothermal heat exchanger according to the invention has opposite the following advantages that have become known so far: 1. It can compare the to iron pipes much cheaper plastic pipes with a uniform small Diameters are used that only have to lift a small wall thickness and therefore offer good heat transfer.

2. Bin internal heat exchange between the incoming and outgoing flowing heat carrier is through the into the earth bore, each a pipe takes in, grouted and compacted earth, which now both legs of the U-tube well insulated from one another, largely prevented; those in the heat pump available starting temperature of the heat transfer medium is higher than before.

3. The geothermal heat exchanger can be total, once because of the lower Material costs and on the other hand, because of the simpler assembly, much cheaper create, than the previously known geothermal heat exchangers.

The invention is described below with reference to that in the drawing illustrated embodiment explained in more detail. They show: FIG. 1 the view of a U-tube used according to the invention with a sectioned representation of the front and the return pipe, Fig. 2 shows the longitudinal section through a T-connection with parallel connection, FIG. 3 shows the Robx course in a pipe with a series connection, FIG. 4 shows the circuit diagram a system according to the invention when the heat pipes are connected in series, with each all flow and return lines of the heat pipes are combined to form a main line are, and in the main strand for the forward and the one for the return each a shut-off valve is arranged, Fig. 5 shows the circuit diagram of an inventive Plant in series connection of the heat pipes, the flow and the return each of the circles, which in this exemplary embodiment consist of two u-shaped warm pipes consists, a shut-off valve is connected, Fig. 6 is the circuit diagram of an inventive System with parallel connection of the arm pipes, according to the exemplary embodiments gladly. Fig. 4, also here all forward and reverse lines combined into one main line each and a gate valve is arranged in each of the two main strands and FIG. 7 the circuit diagram of a system according to the invention in parallel, each single circle consisting of two parallel-connected warm pipes in its V and Return can be shut off by a different valve each.

Gen. Fig. 1 extends between the flow pipe 1 and the return pipe 2 the U-tube 6 consisting of the two legs 3 and 4 and the U-bend 5. The geothermal heat exchanger according to the invention consists exclusively of such U-tubes 6, which are either connected in parallel in pairs, as in the exemplary embodiments 1, 6 and 7 or else, also in series connection between the flow pipe 1 and the return pipe 2 could be provided, like the embodiments according to Figures 3, 4 and 5 show. Both the assembly of the tubes 6 and their connection to the flow pipe 1 and the return pipe 2 always require constant Assembly operations and can therefore be rationalized in an economical manner.

The connection of a harness pipe 6 to the flow pipe 1 or the return pipe 2 takes place in the case of a parallel connection according to the exemplary embodiment according to FIG Way that, for example, on the leg 3 protruding from the borehole In Fig. 2 in the rest of the heat pipe 6, not shown, the T-piece 7 is glued will. The connecting pipes 8 are then inserted into the T-piece 7 from both sides and 9 plugged into the adjacent warm pipes: and easily through one fixed with a suitable adhesive.

The series connection of U-tubes 6 according to the exemplary embodiment Fig. 3 is the mutual connection of the individual tubes 6 by tube angles 10 in which the connecting pipes 8 and 9 in the same way as on the occasion of the exemplary embodiment described according to Fig. 2, inserted and fixed by gluing.

The basic structure of the pipe system is thus within the scope of the invention Geothermal heat exchanger given.

FIGS. 4-7 give circuit diagrams of some advantageous exemplary embodiments of entire systems again.

According to Fig. 4, the tubes 6, so the heat pipes, between that of the heat pump 11 coming forward pipe 1 and the return pipe leading to the circulation pump 12 2 connected in series in pairs. The shut-off valve is in the return pipe 2 13 and in the flow pipe 1, the shut-off valve 14 is used to the wax merobre 6 in To be able to disconnect from the heat pump 11 in the event of a malfunction.

The embodiment like. Fig. 5 also shows the series connection of pairs of heat pipes 6 again, with the difference compared to the exemplary embodiment according to Fig. 4 that each heat pipe pair 6 by itself by correspondingly longer supply lines 15 and 16, which lead to the basement room, in which the heat pump 11 with the other installation parts is housed, to the there located before and Return pipes 1 and 2 is performed.

Each connection pipe 15 or 16 contains a shut-off valve 17 so that a pair of the series-connected heat pipes 6 can be shut off and no longer participates in the circulation. This has the advantage that now in the event of a malfunction within a pair of heat pipes, only this one pair of heat pipes from the circuit must be taken while the others continue to work.

The same applies to the two exemplary embodiments according to the figures 6 and 7. According to FIG. 6, the warm pipes 6 connected in parallel are all directly connected to the flow pipe 1 and the rick run pipe 2 and there are only two shut-off valves 18 and 19 are available, which are conveniently located in the same room, in which the heat pump 11 is also arranged. Such a system is cheaper to install, however, has the disadvantage that if the heat pipes become defective 6 the entire system was to be shut down.

On the other hand, in the system according to FIG Harmer pipes 6 per pair by separate connecting pipes 20 and 21 with the flow pipe 1 and the return pipe 2 connected, in turn each heat pipe pair by two shut-off valves 22 assigned only to these, separately from the others, are switched off will be dealt with if this requires any malfunctions.

List of drawing positions 1 flow pipe 2 return pipe 3 legs 4 legs 5 U-elbow 6 pipe 7 T-piece 8 pipe string 9 pipe string 10 pipe elbow 11 Heat pump 12 Circulation pump 13 Shut-off valve 14 Shut-off valve 15 Connection pipe 16 Connection pipe 17 shut-off valves 18 shut-off valves 19 shut-off valves 20 connection pipe 21 connecting pipe 22 shut-off valves

Claims (5)

A n p r e c h e: 1. Geothermal heat exchanger for heat pump systems, consisting from heat pipes laid vertically in the ground, thus not shown e t that the heat pipes as flowed through by the heat transfer medium only in one direction Pipes (6) are formed. 2. Geothermal heat exchanger according to claim 1, characterized in that g e k e n n -z e i c h n e t that between the flow pipe (1) and return pipe (2) one or more Pipe strings (8, 9) extend within which the pipes (6) are parallel or in series are switched through by the heat transfer medium. 3. geothermal heat exchanger according to claim 1 and 2, characterized g e -k e n n z e i c h n e t that each pipe string (8, 9) with a shut-off valve (10) in the flow pipe (1) and / or in the Recklarrrohr (2) is equipped. 4. geothermal heat exchanger according to claim 1 - 3, characterized g e -k e n n z e i c h n e t that each U-tube (6) is arranged in a single earth bore and free spaces within the same are closed. 5. Erdwärmetasuscher according to claim 1 - 4, characterized g e -k e n n z e i c h e t that a water antifreeze mixture is used as the heat transfer medium.