DE10200106B4 - Arrangement and laying of pipelines for an earth collector in combination with a seepage system - Google Patents

Abstract

ground collector, consisting of a pipe system of horizontally extending pipes with pipe bends connecting the ends, as well as an inflow and outflow the heat medium, with one over the drainage system arranged in the pipe system of the ground collector, those with a rainwater drainage system connected and has a control and distribution shaft, the one covered with a fleece running diagonally above the pipe system Drainage tube (11) is connected.

Description

The The invention relates to the arrangement and installation of pipelines for one Earth collector in combination with a seepage system and related with the use of geothermal energy through Heat pumps with the aim of minimizing costs as well as civil engineering work. Becoming present for the geothermal energy Earth collectors made of plastic pipes used to dig up of the entire soil according to the dimensions of the earth collector require to the frost-free depth of at least 1.2 m. This is on developed land due to existing terraces, tree and shrub stock is not always possible. A Combination with a seepage system to increase the line through the heat flow from heated Rainwater in the earth layers is not yet known.

A solution is known, such as a ground collector for heat pumps in the form of an elongated plate-shaped heat exchanger element arranged upright in the ground, to which a pipeline is attached for the supply and discharge of a heat exchanger medium, which extends essentially over the entire length of the heat exchanger element, characterized the heat exchanger element is driven downwards into the ground in its longitudinal direction ( DE 29 13 333 A1 ). Such a trained earth collector is from the US 4106 555 known. The elongated plate-shaped heat exchanger element is arranged transversely in the ground, wherein the introduction into the ground by means of two spaced at the longitudinal direction of the heat exchanger mounted post with guide slots, in which the heat exchanger element can be inserted from above and this can be pushed to the bottom. This solution requires that at the point at which the heat exchanger element is to be introduced, it must first be excavated accordingly. After connecting the cables, the trench is filled again. So areas with groundwater can not be developed, at best with considerable effort. Another disadvantage is that buried solutions conduct the heat worse than the original compact soil. Thus, the desired heat extraction is lower. The digging of the heat exchanger elements is relatively time consuming and costly due to the necessary civil engineering work. In the DE 29 13 333 A1 the object is achieved in that the heat exchanger element is driven in its longitudinal direction by ramming into the ground down. Damage to the property surface is thereby avoided. The disadvantage of this solution is that the required surfaces for conventional heat pump sizes also require a great deal of depth. A large depth requires stable heat exchanger components and these in turn require considerable material and cost. It is not possible to inspect any damage caused by burial through underground obstacles and thus a permanent solution can not be guaranteed. According to the prior art, these problems are better solved by deep drilling. No attention is paid to the frost-free area to be secured from the top of the ground to - 1.2 m.

In the CH 644682 is described an earth collector for heat pumps, whose collector tubes run horizontally one above the other in the ground. At the ends, vertically routed header pipes connect the collector pipes with each other and provide for the supply and discharge of the heat medium. For the installation of the collector considerable civil engineering work is required.

The DE 30 37 755 A1 describes a manufacturing process for earth collectors in which pipes or hoses are laid horizontally, parallel next to each other in the ground.

The pipes and hoses are made of two opposite trenches of about 0.8 m width with a horizontal drill or similar. laid. In these trenches run the manifolds. The disadvantage is in DE 36 32 543 the cost of the drilling process and the insufficient contact due to the larger cross-section of the bore opposite the tubes and thus called lower efficiency. This is wrong. During drilling, a mixture of clay and water, which hardens, remains between the hole and the inserted pipe Betonit.

In DE 3632543 A1 several hose bands are preferably made of plastic of the same or different length, laid with their broad side to the heat flow direction at any distance next to each other. These hose bands are laid in soil or solidifying media. This solution requires that at the point at which the heat exchanger element is to be introduced, it must first be excavated accordingly. Another solution that requires digging in DE 3913429 A1 described.

There becomes a spiral Absorber in a well-like hole with a diameter of 1.5 m and a depth of 10-12 m and then filled with a cement or earth mud. adversely appears that the heat-releasing surrounding the well absorber area low is opposite that of a surface absorber with pipe distances of about 0.5 m.

In the DE 100 08 760 A1 describes a solution in which on four levels with a vertical distance of 0.4 m Erdkollektoren in a vor existing excavation are mounted. This solution mainly uses rainwater, dirty water or products from biological treatment plants in a limited space by means of a room cell with built-in heat pump combined with a well system. This solution is for special applications is very complicated and maintenance-intensive and uses only a small part of the geothermal energy.

None the solutions shown however combines the earth collector with a seepage system, so that on the one hand by the infiltration wastewater costs saved and on the other hand the heat yield the earth collector is increased by the humidity.

Of the Invention is based on the object, a ground collector for use the geothermal energy through heat pumps in combination with a seepage system, with which Goal, the effectiveness of the earth collector and to minimize costs and civil engineering work.

According to the invention Problem solved by the cited in claim 1 features.

The advantages achieved by the invention are in particular that with the arrangement of the ground collector 1 corresponding 1 , consisting of plastic pipes 2 , with connecting bow 3 at a depth of min. 1.4 m (frost-free) next to and above each other / offset ( 2 ), depending on the required and existing area of the plot by means of a breakdown by means of ground penetrating rockets or hydraulic horizontal drilling of two parallel trenches a start trench 4 and a target trench 5 made with the dimensions about 1 m wide × 1.4 m depth.

After completion of the earth collector 1 , before filling the pipe trenches, is in the start ditch 4 and ditch 5 a known infiltration system 6 , consisting of the infiltration tube 7 in DN 200 or 300 and a control and distribution shaft 8th and a control and Spülschacht 9 , at a depth of about 800 mm above the ground collector 1 arranged. The combination in the described arrangement on the one hand ensures that the civil engineering work around the start ditch 4 and ditch 5 On the other hand, the efficiency is reduced by the leakage of warm rainwater in relation to the year approximately in the first third of the earth collector 1 is increased by increasing the moisture content of the soil.

simultaneously is due to the water and natural sedimentation of the Distance between the hole and the plastic tube so minimized that the heat transfer positively influenced.

By the infiltration system will be the wastewater costs for rainwater from the roof and sealed surfaces on the property considerably reduced.

advantageous Embodiments of the invention are in the claims 2 to 5 indicated.

The Invention will be explained below with reference to an embodiment. In the associated Show drawing:

1 : a ground collector with a seepage system in plan view and

2 : a ground collector with two infiltration systems.

The ground collector is advantageously made of plastic pipes 2 , the end alternately with connecting sheets 3 are connected and so form a continuous pipe system. The plastic pipes 2 be at a depth of min. 1.4 m depending on the required and existing area of the property side by side or offset one above the other by interrogation by means of ground impact rockets or hydraulic horizontal drilling method brought into the ground. For this purpose, two parallel pipe trenches, a start ditch 4 and a target ditch 5 , produced. Via connecting lines, the ground collector is connected to a heat pump.

After completion of the earth collector and before filling the pipe trenches, is in the start ditch 4 a seepage system 6 , which is connected to a roof drainage system arranged. This consists of a control and distribution shaft 8th and a control and Spülschacht 9 , each end and outside of the earth collector assembly in the start ditch 4 are introduced. The control and distribution shaft 8th and the control and Spülschacht 9 are with a percolating tube 7 connected in DN 200 or 300, which lies at a depth of approx. 800 mm above the ground collector. In the ditch 5 is diagonal to the control and distribution shaft 8th a second control and flushing shaft 10 brought in. The control and distribution shaft 8th and the control and Spülschacht 10 are through a drainage pipe 11 connected. The drainage pipe 11 can also be retracted by means of floor penetration rocket or hydraulic horizontal drilling methods or placed in the open trench. For better water release and protection against dirt, the Draina gerohr 11 be fleece coated. Behind the control and distributor bay 8th is in the drainage pipe 11 a shut-off device 12 arranged. With the obturator 12 If necessary, cold rainwater can be held back in winter.

The resulting rainwater is in the control and distribution shaft 8th introduced and on the one hand in the infiltration tube 7 in the start ditch 4 and on the other hand into the drainage pipe 11 led over the earth collector. The rainwater seeps into both the start ditch 4 as well as above the earth collector, thus moistening the surrounding soil.

Since the resistance in the percolation in the infiltration tube 7 of the start trench 4 is greater in the vertical than in the fleece-coated drainage pipes 11 , the warm rainwater is corresponding to the plastic pipes 2 the earth collector constantly surrounded by water or moisture or the entire area is kept moist for a long time, which significantly improves the heat transfer.

The fleece coated drainage pipe 11 can via the inspection shafts and distribution shafts 8th be rinsed.

As in 2 is shown in both the start ditch 4 as well as in the target ditch 5 a leaching system 6 and a seepage system 6 ' brought in. This is advantageous if, in addition to a roof drainage and a sealed open space to drain. The second infiltration system 6 ' consists of the control and flushing shaft 10 and a control and distribution shaft 13 also with a percolating tube 7 in DN 200 or 300 are connected. This infiltration system 6 ' may be located at or below the open space and the infiltration system 6 is in turn connected to the roof drainage system. The control and distribution shafts 8th and 13 the two infiltration systems 6 and 6 ' are covered with the fleece-coated drainage pipe 11 connected. About the drainage pipe 11 Part of the rainwater can enter the infiltration system 6 ' be derived, which also leads to an increase in soil moisture.

It is not shown that the rainwater can be collected in a rainwater cistern. In dry periods, rainwater can then enter the infiltration system via a pumping system or dosing system 6 be supplied so that a uniform soil moisture can be achieved.

2

Plastic pipe

3

compound bow

4

start digging

5

target ditch

6

Drainage system

6 '

Drainage system

7

seepage pipe

8th

inspection and distribution shaft

9

inspection and flushing shaft

10

inspection and flushing shaft

11

drainage pipe

12

shutoff

13

inspection and distribution shaft

Claims (5)

An earth collector, comprising a pipe system of horizontally extending pipes with pipe bends connecting the ends, and an inlet and outlet pipe of the heating medium, with a percolation system arranged above the pipe system of the earth collector, which is connected to a rainwater drainage system and has a control and distribution shaft which is covered by a drainage pipe running diagonally above the pipe system ( 11 ) connected is. Ground collector according to claim 1, characterized in that the infiltration system consists of a seepage system ( 6 ) located next to the control and distribution shaft ( 8th ) a control and Spülschacht ( 9 ) and a connecting this infiltration tube ( 7 ), which is arranged in an end region of the pipe system. An earth collector according to claim 2, characterized in that the infiltration system comprises a second infiltration system ((2)) arranged in the other end region of the pipe system ( 6 ' ), consisting of a control and distribution shaft ( 13 ), a control and Spülschacht ( 10 ) and the infiltration tube ( 7 ). Ground collector according to claim 3, characterized in that the digestion system ( 6 ) and the infiltration system ( 6 ' ) with the drainage pipe ( 11 ) are connected. Ground collector according to one of claims 1 to 4, characterized in that the infiltration system is preceded by a rainwater retention tank is.