DE9403070U1 - Device for inserting an earth probe into a borehole - Google Patents

Description

Device for inserting a geothermal probe into a borehole

The subject of the invention is a device for inserting a geothermal probe into a borehole according to the preamble of claim 1.

It is known that geothermal energy extraction systems pump water or another medium through a hair-needle-shaped pipe inserted into a borehole, thereby extracting heat from the earth's interior. Such geothermal probes, which are provided with a 180° bend at the bottom of the borehole and are usually made of plastic, e.g. polyethylene, are assembled on site from ring-shaped wound pipes by welding in bends to connect the two pipes at the lower end to a length corresponding to the depth of the borehole.

These pipes retain the curvature imposed on them during manufacture and storage even after they have been unwound from the ring and can therefore only be inserted into the narrow borehole with difficulty. In many cases, the borehole is completely or partially filled with water, so that, due to the low specific weight of the pipes to be inserted, they are buoyant when immersed in the liquid, which further hinders insertion. In addition, there is also a not insignificant amount of friction on the borehole wall, as the pipes rest against it due to their own bending.

From Swiss patent no. 653120 it is known to give the section of the plastic pipes that is located at the bottom of the borehole an extension and more mass by means of a steel pipe or a steel rod that is connected to the pipes with clamps. In order to also prevent damage to the curved part of the hair-needle-shaped

To prevent the pipes from bending, a heat-shrinking cap is placed over the bends.

This well-known device has proven to be extremely effective and can be used for installing geothermal probes to depths of up to 120 m and even 150 m.

For some time now, there has been a desire to install geothermal probes much deeper in order to use a single borehole instead of several probes placed next to each other, which also require several boreholes. For boreholes that are more than 150 m deep, probe pipes with a larger diameter must be used due to internal friction when the heat-conducting fluid circulates. Since these pipes are also delivered to the construction site in the form of rings, the pipes have a curvature that cannot be eliminated by laying them out on the ground or by inserting a rod. In most cases, the pipes cannot be stretched before laying because there is not enough space to lay out the 300 m long probe in a stretched manner. These thicker pipes, for example 2" in diameter, that are now to be used naturally also have a greater wall thickness and are therefore much stiffer than the 1" or smaller pipes that have been used up to now.

The object of the present invention is to create a device with which one or more pairs of pipes can be easily inserted into a borehole. A further object of the invention is to design the device in such a way that the probe can be pulled out of the borehole again during installation if, for some reason, there is too much resistance to complete lowering.

This object is achieved according to the features of claim 1. Further advantageous embodiments of the invention are described in the

-3- dependent claims defined.

The casing, which consists of a steel pipe, not only allows the formation of a perfectly stretched area at the tip of the geothermal probe, but also protects the curved area of the hairpin-shaped connected pipes and the connecting area of the curved area with the ends of the pipes from damage caused by the rough borehole wall. Furthermore, by using a thick-walled, smooth pipe, a high mass can be concentrated at the tip of the geothermal probe, so that it can be lowered into the borehole together with the conical, truncated cone or hemispherical tip with little friction. Parts protruding from the wall of the borehole cannot damage the probe and are usually knocked off or ground blunt by the steel pipe. The closure that closes the steel pipe at the front can be removed so that the device can be pushed onto the lower end of the pipes from below on the construction site for the assembly of the curved parts. The pipes leaving the steel pipe at the top are guided into holes in the cover. This ensures that the water-carrying pipes in the steel pipe are centered exactly. Holes leading into the interior of the steel pipe allow water to pass from bottom to top when the probe is inserted into a borehole filled with water. The clamp holding the water-carrying plastic pipes together inside the steel pipe makes it possible to pull a ground probe that has already been partially inserted into the borehole out of the borehole without subjecting the bends welded to the ends of the plastic pipes to too high a tensile load. Insertion pipes can be screwed onto the threaded bolt on the cover of the device and used to increase the weight of the probe on the one hand and to push the probe downwards on the other. As soon as the probe is inserted, the screwed-on pipes, which have a right-hand thread, can be detached from the steel pipe by an additional clockwise turn and lifted out of the borehole. The insertion tube detached from the probe can be used to insert a heat-conducting compound before it is pulled out of the borehole.

· &iacgr;

-A-

For example, bentonite can be used.

The force exerted by the insertion tube on the probe is only transferred to the tubular end, so that it works its way down through the borehole. The plastic tubes running upwards from the tubular end through the borehole are pulled along during insertion.

The invention is explained in more detail using an illustrated embodiment.

Figure 1 is a perspective view of a hairpin-shaped geothermal probe with a steel tube casing,

Figure 2 shows a hairpin-shaped ground probe according to the state of the art.

The lower section 1 of a hairpin-shaped plastic tube 3 of a conventional geothermal probe 5 shown in Figure 2 is stretched by two clamps 7 with a steel rod or steel tube 9 arranged between the plastic tubes 3. A cap 11 made of heat-shrinkable plastic film surrounds the curved section 13 (shown in Figure 2 as an exploded view).

The two plastic pipes 3 in Figure 1, which illustrates the invention, are connected to one another at their lower end by a 180° or two 90° bends 15 by means of mirror welding. The section of the plastic pipes 3 that adjoins the bends 15 is located within a steel pipe 17, the upper end of which is closed by a cover 19 and the lower end by a closure 21. The closure 21 partially penetrates the steel pipe 17 and can be connected to the steel pipe 17 by a thread 23 or a radially running screw connection (not shown). The cover 19 is welded to the upper end of the steel pipe 17 and has two holes 25 for the plastic pipes 3 to pass through. A threaded bolt 27 is also attached, e.g. welded, to the surface of the cover 9. The thread

The bolt 27 has a left-hand thread into which the lower end of an insertion tube 29 made up of several pieces is screwed. The individual pieces of the insertion tube 29 have right-hand threads (not shown). The insertion tube 29 is intended and designed to be connected to a pump for introducing and circulating a heat-conducting liquid in the borehole.

At a distance a from the apex S of the bend 15, a retaining clamp 31 is arranged, with which the two pipes 3 are held in place. The retaining clamp 31 serves to ensure that, in the event of the geothermal probe 5 being pulled out of the borehole, the tensile force exerted by the steel pipe 17 on the pipes 3 is not introduced into the area of the bends 15, but rather at a distance from them.

In the steel pipe 17 and/or in the closure 21 and/or in the cover 19, bores or recesses 33 are provided, which allow the access of water from the borehole into the interior of the steel pipe 17 and from there through the cover 19 into the space above the cover 19.

In a further embodiment of the invention, axially extending ribs 35 can be attached to the outer surface of the steel pipe 17, which facilitate the lateral flow of water in the borehole from bottom to top.

In summary, the following can be stated :

At the lower end of the geothermal probe (5) there is a steel pipe (17) with a conical closure (21) and a cover (19) provided with holes (25). The plastic pipes (3) are held axially within the steel pipe (17) by a retaining clamp (31). A threaded bolt (27) enables the connection to an insertion pipe (29) which is used to introduce a heat-conducting medium into the borehole after the geothermal probe (5) has been set. (Figure 1)

Claims (7)

••••-&bgr;- Protection claims 1. Device for introducing a geothermal probe (5) into a borehole, with a hairpin-shaped, liquid-carrying plastic pipe (3), a casing (17) surrounding the plastic pipe (3) at its lower section (1) lying on the bottom of the borehole, characterized in that the casing (17) consists of a steel pipe (17), on the lower end of which a removable closure (21) is placed and the upper end of which is closed by a cover (19) having two through openings (25) for the plastic pipes (3). 2. Device according to claim 1, characterized in that a threaded bolt (27) with a left-hand thread for fastening an insertion rod or tube (29) is arranged on the cover (19). 3. Device according to one of claims 1 or 2, characterized in that the closure (21) is inserted into the lower end of the steel tube (17) is inserted or screwed in. 4. Device according to one of claims 1 to 3, characterized in that the closure (21) is conical, frustoconical or hemispherical in shape. 5. Device according to one of claims 1 to 4, characterized in that holes (33) leading into the interior of the steel tube (17) are provided in the steel tube (17) and/or in the cover (19) and/or in the closure (21). 6. Device according to one of claims 1 to 5, characterized in that at a distance (a) from the apex (S) of the plastic pipe (3) a gap is formed between the two pipe legs running side by side. connecting clamp (31). 7. Device according to one of claims 2 to 6, characterized in that the upper end of the introduction tube (29) is designed to be connectable to a pump for introducing a heat-conducting medium. Patent Attorney