DE102009045882A1 - Geothermal probe for a geothermal heat pump - Google Patents

Abstract

A geothermal probe for extracting geothermal energy from a borehole in which the inner surface of the probe tube has the following roughness values: a) an arithmetic mean roughness value Ra in accordance with DIN EN ISO 4287 in the range from 1 to 15 µm, b) an average roughness depth Rz in accordance with DIN EN ISO 4287 in the range from 8 to 80 µm and c) a maximum roughness depth Rz1max in accordance with DIN EN ISO 4287 in the range from 10 to 500 µm, has an improved falling film during operation so that the entire surface of the probe tube is evenly wetted.

Description

The invention relates to a geothermal probe for the extraction of geothermal energy from a bore.

The extraction of geothermal heat from drilling is done by pumping thermal water from digested aquifers or by cooling the soil along a bore. The cooling of the soil is done with different geothermal probes. For the extraction of heat from the soil vaporizable refrigerants can be used, which gain the energy by the evaporation. Such direct evaporator probes are on the rise. Compared to brine probes, they offer a significantly higher level of efficiency and are seen by experts as the technology of the future. For example, systems based on propane, butane, ammonia or carbon dioxide exist, with propane being preferred. A distinction is made between near-surface geothermal energy for direct use, such as for heating and cooling, usually as heat pump heating, and deep geothermal energy for direct use in the heating market or indirectly for power generation. Deep geothermal probes with direct evaporators are also referred to as heat pipes or heat pipes.

In the DE 42 11 576 A1 and the DE 298 24 676 U1 arrangements of heat pipes are described in which the heating zone of the heat pipe and thus the evaporation of the liquid refrigerant is in the lower part of the tube. The vapor is generated by boiling the liquid refrigerant; it is then led upwards in a pipe and gives up its energy by condensation. This is used directly or with the assistance of a heat pump.

In the WO 01/04550 The refrigerant is passed through a channel in the probe and through a second channel upwards. By means of a spiral-shaped web, which must be produced consuming, a film evaporation is desired. With the embodiment described there, however, an evaporation of the refrigerant over the entire bore and thus probe length is not achievable, so that no complete removal of heat is made possible.

In utility model DE 20 2004 018 559 U1 describes a heat generator for the production of geothermal heat from a well, in which a condensate flow distributor is integrated in a probe tube. Although an all-round wetting is also to be achieved, a film evaporation is not feasible.

Finally, in the DE 10 2007 005 270 A1 describes a geothermal probe containing a condensate flow distributor with radially and / or tangentially to the wall of the probe tube arranged condensate-conducting devices. In this way, a radially distributed condensate film is to be generated.

The invention has for its object to produce in a geothermal probe by simple means a complete falling film, so that the entire inner surface of the probe tube is wetted evenly.

• a) einen arithmetischen Mittenrauwert Ra gemäß DIN EN ISO 4287 im Bereich von 1 bis 15 μm, vorzugsweise im Bereich von 2 bis 12 μm und besonders bevorzugt im Bereich von 3 bis 7 μm,
• b) eine gemittelte Rautiefe Rz gemäß DIN EN ISO 4287 im Bereich von 8 bis 80 μm, vorzugsweise im Bereich von 10 bis 60 μm und besonders bevorzugt im Bereich von 15 bis 40 μm sowie
• c) eine maximale Rautiefe Rz1max gemäß DIN EN ISO 4287 im Bereich von 10 bis 500 μm, vorzugsweise im Bereich von 15 bis 150 μm und besonders bevorzugt im Bereich von 25 bis 65 μm.

This object is achieved by a geothermal probe for obtaining geothermal heat from a bore, in which the inner surface of the probe tube has the following roughness characteristics:

• a) an arithmetic mean roughness Ra according to DIN EN ISO 4287 in the range from 1 to 15 μm, preferably in the range from 2 to 12 μm and particularly preferably in the range from 3 to 7 μm,
• b) an average roughness Rz according to DIN EN ISO 4287 in the range of 8 to 80 microns, preferably in the range of 10 to 60 microns and more preferably in the range of 15 to 40 microns and
• c) a maximum surface roughness Rz1max according to DIN EN ISO 4287 in the range of 10 to 500 .mu.m, preferably in the range of 15 to 150 .mu.m and particularly preferably in the range of 25 to 65 .mu.m.

The roughness measurement is according to DIN EN ISO 4288 performed in the Tastschnittverfahren. In the roughness measurement with a mechanical stylus, a probe tip made of diamond is moved over the surface of a sample at a constant speed. The measuring profile results from the vertical positional shift of the probe tip, which is usually detected by an inductive distance measuring system. For the metrological description of a surface standardized roughness parameters are obtained from the measuring profile.

Ra is the arithmetic mean roughness from the amounts of all profile values.

Rz is the average of the five surface roughness values from the five individual measurement sections.

Rz1max is the largest roughness depth from the five individual measuring sections.

The geothermal probe consists of a probe tube, which is connected via a Verfüllbaustoff, such as bentonite, with the soil. The evaporation of the refrigerant condensate takes place on the inner surface of the probe tube. The transport of the resulting vapor upwards takes place in the center of the tube.

The inner diameter of the probe tube is usually in the range of 15 to 80 mm, preferably in the range of 20 to 55 mm and more preferably in the range of 26 mm to 32 mm.

The probe length is generally 60 to 200 m, in some cases larger or smaller lengths are possible. Preferably, the probe is 80 to 120 meters long.

As a refrigerant, for example, propane, butane, ammonia or carbon dioxide is used. According to the physical laws, the probe interior is thus under relatively high pressure. The ascended refrigerant vapor is compressed in a compressor and liquefied with it. When compressing condensation heat is released, which is dissipated as useful heat. The cooled liquid refrigerant is supplied to the probe again via an expansion unit and passed down as a falling film. When the geothermal heat is absorbed, the refrigerant evaporates again. With regard to details of the technical implementation, reference is made to the above-mentioned prior art.

The probe tube may for example consist of metal. In this case, the inner surface carries a rough coating.

However, the tube is preferably made of plastic and particularly preferably of a thermoplastic molding compound. Such pipes can be wound, so that the need is eliminated during assembly comparatively short pieces with each other z. B. to connect by welding.

The molding compound used must have sufficient rigidity so that the wall thickness can be made thin for reasons of heat transfer. In addition, the plastic that forms the matrix of the molding compound must be sufficiently resistant to the refrigerant and the moisture of the soil. This means that the wall must not swell, as this would be associated with undesirable changes in length.

Suitable plastics are, for example, fluoropolymers such as PVDF, PTFE or ETFE, polyarylene ether ketones such as PEEK, polyolefins such as polyethylene or polypropylene and polyamides.

Of the polyamides, preference is given in particular to those whose monomer units contain in the arithmetic mean at least 8, at least 9 or at least 10 C atoms. The monomer units can be derived from lactams or ω-aminocarboxylic acids. When the monomer units are derived from a combination of diamine and dicarboxylic acid, the arithmetic mean of the C atoms of diamine and dicarboxylic acid must be at least 8, at least 9 and at least 10, respectively. Suitable polyamides are, for example: PA610 (preparable from hexamethylenediamine [6 C atoms] and sebacic acid [10 C atoms], the average of the C atoms in the monomer units here is 8), PA88 (preparable from octamethylenediamine and 1.8-octanedioic acid) , PA8 (made from capryllactam), PA612, PA810, PA108, PA9, PA613, PA614, PA812, PA128, PA1010, PA10, PA814, PA148, PA1012, PA11, PA1014, PA1212 and PA12. The preparation of the polyamides is state of the art.

Of course, copolyamides based thereon can also be used, it also being possible for monomers such as caprolactam to be used as well.

Likewise, mixtures of different polyamides, provided sufficient compatibility can be used. Compatible polyamide combinations are known to the person skilled in the art; For example, the combination PA12 / PA1012, PA12 / PA1212, PA612 / PA12, PA613 / PA12, PA1014 / PA12 and PA610 / PA12 and corresponding combinations with PA11 are listed here. In case of doubt, compatible combinations can be determined by routine tests.

The thermoplastic molding compound may be filled with reinforcing fibers and / or fillers. The fibers or filler particles which press through at the surface thereby produce the required roughness. For this purpose, the molding composition contains 0.1 to 50 wt .-%, preferably 0.5 to 20 wt .-% and particularly preferably 3 to 10 wt .-% fillers and / or fibers. In one embodiment, the molding composition here contains only fibers. In another embodiment, the molding compound contains only fillers. In a further embodiment, the molding composition contains a mixture of fibers and fillers.

Suitable reinforcing fibers are, for example, glass fibers, carbon fibers, aramid fibers and potassium titanate whiskers, as well as fibers of higher melting polymers.

Examples of suitable fillers are titanium dioxide, zinc sulfide, silicates, chalk, aluminum oxide and glass beads.

With suitable reinforcing fibers or fillers, the thermal conductivity of the probe wall can be increased. For this purpose, as fiber material metal fibers or as a filler metal powder, carbon black, graphite, CNTs (carbon nanotubes), hexagonal boron nitride or combinations or mixtures of different materials can be used.

The molding composition may also contain the usual auxiliaries or additives, for example impact modifiers, plasticizers, stabilizers and / or processing aids.

In a further embodiment, the surface roughness is produced by compounding a second polymer which is incompatible or poorly compatible with the matrix polymer and therefore only relatively coarsely dispersed. Suitable combinations of materials are, for example, polyamide / polypropylene or polyamide / ethylene-acrylic ester-acrylic acid copolymer / polypropylene.

In one embodiment, the probe tube may be single-layered and thus consist of one of the above-described molding compositions over the entire wall thickness. In a further embodiment, the probe tube is multi-layered, wherein the inner layer consists of one of the molding compositions described above and the other layers have functions that are not sufficiently perceived by the layer of the surface-molding compound, such as flexibility, impact resistance or blocking effect against the refrigerant or the moisture of the soil. If the layers do not sufficiently adhere to one another, adhesion promoters can be used according to the prior art.

• – Polyamid (beispielsweise PA12)/Haftvermittler/Polypropylen oder Polyethylen;
• – Polyamid (beispielsweise PA12)/Haftvermittler/Ethylen-Vinylalkohol-Copolymer (EVOH)/Haftvermittler/Polyamid;
• – Polyamid/Haftvermittler/EVOH/Haftvermittler/Polypropylen oder Polyethylen;
• – Polyamid/Haftvermittler/Fluorpolymer (beispielsweise PVDF oder ETFE);
• – Polyamid/haftungsmodifiziertes Fluorpolymer.

Suitable layer sequences from the inside to the outside are, for example:

• Polyamide (for example PA12) / adhesion promoter / polypropylene or polyethylene;
• Polyamide (for example PA12) / adhesion promoter / ethylene-vinyl alcohol copolymer (EVOH) / adhesion promoter / polyamide;
• - polyamide / adhesion promoter / EVOH / adhesion promoter / polypropylene or polyethylene;
• Polyamide / coupling agent / fluoropolymer (for example PVDF or ETFE);
• Polyamide / adhesion modified fluoropolymer.

Suitable adhesion promoters for the combination of polyamide and polyolefins are, for example, with maleic anhydride functionalized polyolefins.

Polyamides such as PA12 and EVOH can be prepared, for example, with the aid of maleic acid-functionalized polyolefins or by means of polyamide blends EP 1 216 826 A2 be connected to each other.

For the connection between EVOH and polyolefins, for example, maleic acid-functionalized polyolefins are suitable as adhesion promoters.

Adhesion promoters for the connection of polyamides and fluoropolymers are known, for example, from US Pat EP 0 618 390 A1 whereas adhesion-modified fluoropolymers are known, for example, by admixing small amounts of polyglutarimide EP 0 637 511 A1 , by functionalization with maleic anhydride or by incorporation of carbonate groups accordingly EP 0 992 518 A1 can be produced.

In order to support the effect of the surface roughness, the probe tube may additionally contain internals, as known from the prior art, for example DE 10 2007 005 270 A1 , are known.

With the invention, it is achieved that the falling film has a uniform layer thickness over the circumference of the probe; Stripping or tearing of the film is prevented. Due to the enlarged surface, a better heat exchange is possible; at the same time, the flow rate is reduced, counteracting flooding of the lowermost part of the probe.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 4211576 A1 [0003]
• DE 29824676 U1 [0003]
• WO 01/04550 [0004]
• DE 202004018559 U1 [0005]
• DE 102007005270 A1 [0006, 0036]
• EP 1216826 A2 [0033]
• EP 0618390 A1 [0035]
• EP 0637511 A1 [0035]
• EP 0992518 A1 [0035]

Cited non-patent literature

• DIN EN ISO 4287 [0008]
• DIN EN ISO 4288 [0009]

Claims (6)

Geothermal probe for obtaining geothermal heat from a bore, characterized in that the inner surface of the probe tube has the following roughness values: a) an arithmetic mean roughness Ra according to DIN, EN ISO 4287 in the range of 1 to 15 microns, b) an average roughness Rz according to DIN C) a maximum roughness depth Rz1max according to DIN EN ISO 4287 in the range of 10 to 500 μm, the roughness measurement being carried out in accordance with DIN EN ISO 4288. Geothermal probe according to claim 1, characterized in that Ra is in the range of 2 to 12 microns, Rz in the range of 10 to 60 microns and Rz1max in the range of 15 to 150 microns. Geothermal probe according to claim 1, characterized in that Ra is in the range of 3 to 7 microns, Rz in the range of 15 to 40 microns and Rz1max in the range of 25 to 65 microns. Geothermal probe according to one of the preceding claims, characterized in that the probe tube consists of one or more layers, each consisting of a thermoplastic molding material. Geothermal probe according to claim 4, characterized in that the probe tube or the innermost layer of the probe tube consists of a molding compound whose matrix consists of fluoropolymer, polyaryleneetherketone, polyolefin or polyamide. Geothermal probe according to one of claims 4 and 5, characterized in that the probe tube or the innermost layer of the probe tube consists of a molding composition containing 0.1 to 50 wt .-% reinforcing fibers and / or fillers.