NL1008209C2 - Central heating system supplied by geothermal energy - Google Patents

Abstract

The primary system (1) has a U-shaped tube (4) which is buried deep in the ground (8). Water is pumped (5) round the closed loop (7) between the tube (4) and a primary heat exchanger. The secondary loop is a heat pump (9) between the primary heat exchanger (6), compressor (11) and condenser (12). The final loop (13) is between the condenser (12) and the radiators (15).

Description

Short Title: Bottom heat exchanger.

The invention relates to a vertical bottom heat exchanger for, for example, a heat pump, a hot air system, an air-conditioning system or the like, which device consists of a pipe which is closed in itself and which has a 5 U-shaped part, which pipe is filled with a liquid and which conduit includes a circulation pump and a second circuit heat exchanger or evaporator, and which U-shaped portion of the conduit is or should be installed in the soil below the earth's surface.

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Commonly known are heat pumps, air-conditioning systems, etc., which extract heat from the soil using a bottom heat exchanger. The most famous heat pump is the compression heat pump, consisting of an evaporator, a compressor, a condenser and an expansion valve. With the aid of a vertical bottom heat exchanger consisting of a self-contained pipe with a U-shaped part, which U-shaped part is inserted into the bottom, a liquid is circulated with the aid of a circulation pump; this liquid 20 is then pumped past the heat pump evaporator, the liquid giving off heat and thereby cooling, then pumped through the U-shaped part located in the ground, where the liquid is reheated. The piping system together with the evaporator and the circulation pump form a self-contained first circuit. The evaporator then also forms part of a second closed circuit, which, in addition to the evaporator, also includes a condenser, a compressor and an expansion valve. The second circuit extracts heat 30 from the first closed circuit of the bottom heat exchanger via the evaporator. The liquid in the second closed circuit is compressed after it has passed through the evaporator using a compressor, further increasing the temperature of the heat pump liquid. The liquid is then passed along a condenser, where heat is extracted from the heat pump liquid by a third circuit.

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It is well known that the temperature of the soil is higher the deeper the earth's crust is penetrated. The heat pump makes use of this by inserting the U-shaped part of a closed pipe system into the ground to a desired depth. There is then a liquid in the pipe system, the solidification point of which is lower than the freezing point of water, so that the liquid can assume a temperature of below zero degrees during pumping. It has been found, however, that at such times 10 so much heat can be extracted from the soil by the bottom heat exchanger that the groundwater which is outside on the U-shaped part of the self-contained pipe freezes. As a result, the groundwater will no longer be able to flow around the U-shaped part and the heat transfer from the soil to the U-shaped part of the self-closed pipe will become much smaller, so that hardly any heat will be extracted from the soil. . Moreover, as a result of freezing of the bottom around the loop of the U-shaped part, forces can occur which are exerted on the pipe from the outside and which may cause leaks. As a result, the anti-freeze mixture will leak out and the bottom heat exchanger will no longer work and the soil will be contaminated there with the anti-freeze mixture.

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The object of the invention is a method for arranging in the soil below the earth's surface a vertical soil heat exchanger as well as on a vertical soil heat exchanger, whereby ice deposition is prevented from occurring.

This object of the invention is achieved with a vertical soil heat exchanger in that a hollow tube or tube, which is closed at the bottom with means, is arranged around the U-shaped part of the pipe, which hollow tube is provided with an inflow opening, so that only the groundwater penetrate into the space surrounding the hollow tube.

With these measures it is achieved that bottom heat exchanger and more specifically the U-shaped end, is surrounded only by groundwater and this groundwater can flow freely through the occurrence of natural convection, certainly as soon as it is passed through the bottom heat exchanger. cooled to below four degrees Celsius, where water expands again. Moreover, if the groundwater cools down to zero degrees, the water will freeze, so that a lot of heat can be extracted from the environment, moreover, if the environment of the pipe freezes, this will not make the pipe 10 heavier, because of the ice formed only water and no contains soil particles and is therefore lighter than water. This would not be the case if the pipe is surrounded by sand and water particles, because of that the self-weight of the pipe will increase if ice (with sand-grains) deposits around the pipe. In addition, if a leak occurs, the interior of the hollow tube can be easily cleaned by pumping out the hollow tube, ie as a source. If the probe is leaking, it can be easily removed and replaced with a new one. Also the 20 COP (Coefficient of performance, which is a coefficient that indicates the ratio between the heat supplied by the source and the electricity supplied to the source) value hardly decreases with prolonged use.

In a preferred embodiment, by means of means such as a circulating pump, the water is pumped round or away from the standing hollow tube of the Bottom Heat Exchanger at desired moments, whereby an upward flow is established in the hollow tube, whereby 30 from outside the hollow tube can flow freely through the openings arranged there, the groundwater can flow freely into the space surrounded by the hollow tube. This can prevent the build-up of icing inside the hollow tube on the outside of the heat exchanger, because groundwater, the temperature of which is well above the freezing point, is supplied as soon as pumping is carried out from the vicinity of the lower end of the hollow tube. . Pumping the water out of the hollow upright tube back into the ground will require little energy, since the principle of communicating vessels is used.

Preferably, the hollow tube has a diameter of between 1000 and 50 mm, which makes it possible to guarantee a good flow of groundwater upwards and, moreover, there is always a fair amount of groundwater around the end of the U -shaped part ensuring good heat transfer.

If a bottom heat exchanger is used, the bottom end of the U-shaped part and the hollow tube of which is inserted at least 5 m and possibly even more than 100 m below the earth's surface, it is achieved that a temperature difference is sufficiently large to be able to install a properly functioning heat pump.

Preferably, the bottom heat exchanger is such that the inflow openings or perforations which holes of between 0.1 and 5 mm can be surrounded by a filter, which filter consists of an amount of gravel placed around the hollow tube, for example poured. This prevents soil particles and most certainly sand grains from easily entering the hollow tube, which could result in a disturbance of the operation of the bottom heat exchanger.

By measuring the temperature in the hollow tube or in the U-shaped pipe, it is ensured that measures can always be taken in time to prevent freezing occurring somewhere in the bottom heat exchanger. Depending on the measured temperature, the flow in the hollow tube can then be started, whereby the temperature will again rise above freezing point. As a result, it is also possible to pump a liquid such as water around 35 in the U-shaped pipe, so that in the event of leakage it is never necessary to fear that the soil will be contaminated.

The object of the invention is also achieved with a method of arranging a vertical soil heat exchanger in the ground below the surface of the earth, by first introducing a pipe approximately vertically to a certain desired depth in the ground, which pipe is closed near the bottom and is provided with through-holes for the groundwater over a certain length near the bottom and which pipe is further empty and then the U-shaped part of a self-closed pipe in the pipe to a certain desired depth is brought in. With this method it is achieved that a bottom heat exchanger 10 is placed in the ground in such a way that the ground water can easily flow along the bottom end of the bottom heat exchanger, so that the occurrence of freezing of the bottom end of the bottom heat exchanger becomes much smaller.

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The invention will be explained in more detail with reference to a drawing. In the drawing shows:

Fig. 1 a central heating system, which is supplied with heat by means of a heat pump and a bottom heat exchanger according to the invention;

Fig. 2 shows the bottom heat exchanger according to the invention.

Figure 1 shows three separate circuits 1, 2 and 3. The first circuit 1, which constitutes the bottom heat exchanger 4, consists of a pump 5 and an evaporator 6, which are interconnected by a conduit 7 closed in itself, through which the pump 5 circulates a liquid, the solidification point of which is less than zero degrees Celsius. On the one hand, the pipe 7 is led through the bottom and the pumped liquid hereby takes up heat from the bottom 8 below the earth's surface and on the other hand along the evaporator 6, which serves as a heat exchanger, and which evaporator 6 is also included in the second circuit 2, which second circuit 2 forms the actual heat pump 9, consists of a pipe 10 closed in itself, through which a liquid flows and in which circuit are included the evaporator 6, a compressor 11 and

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. I; A capacitor 12. The capacitor 12 is in turn cooled by the liquid flowing through the third circuit 3, which circuit here consists of a conduit 13 closed in itself, through which a liquid flows and 5 in which line 13 is received a circulation pump 14 and a plurality of radiators 15. The liquid from the third circuit is passed along the capacitor 12 and there exchanges heat with the liquid from the second circuit 2.

Figure 2 shows the bottom heat exchanger 4 according to the invention. A cylindrical tube 16 is arranged in the bottom which, depending on the desired amount of heat that will be extracted from the bottom, can be arranged, for example, 50, 100, 150 meters deep. Subsequently, the water is pumped upwards into this tube 16, so that no soil particles are present anymore, so that only groundwater is still in the tube. In this example, a filter 21 of approximately 2 meters, through which the groundwater and heat can flow, is arranged near the bottom side over a distance which corresponds at least to the length over which the hollow tube is perforated. The placement and the length of the filter as well as the other dimensions, such as the depth that the U-shaped tube has been introduced into the soil, per se depend on the maximum amount of heat that must be able to be extracted from the soil at a given moment . The U-shaped part 17 of the pipe 7 is located inside the cylindrical tube 16, which here has an internal diameter of 200 mm. The internal diameter of the pipe 7 here is 40 mm. In this example, two U-shaped parts 17 in the tube 16 are placed one behind the other. A pump 18 is arranged near the top of the pipe 16, the supply pipe 19 of which is located below the groundwater surface and the water is pumped from the pipe via the pump 18 back to the groundwater on the outside of the pipe 16.

Claims (11)

1. Vertical bottom heat exchanger for, for example, a heat pump, a warm air system, an air-conditioning system or the like, which device consists of a pipe which is closed in itself and has a U-shaped part, which pipe is filled with a liquid and in which pipe a circulation pump is included. and a heat exchanger or evaporator of a second circuit, and which U-shaped part of the pipe is or must be arranged in the ground below the earth's surface, characterized in that around the U-shaped part of the pipe a the bottom is provided with a hollow tube or sleeve closed with means, which hollow tube is provided with an inflow opening, so that only the groundwater can penetrate into the space surrounding the hollow tube. 15 Soil heat exchanger according to claim 1, characterized in that the water in the upright hollow tube can be moved at desired moments by means of means. 20 Soil heat exchanger according to claim 2, characterized in that the means for moving the water in the hollow tube consist of a pump which pumps the water from the hollow standing tube back into the surrounding tube. , groundwater. Soil heat exchanger according to any one of claims 1, 2 or 3, characterized in that the inflow opening for the groundwater consists of several perforations over a part of the tube wall of the hollow tube. Soil heat exchanger according to one of Claims 1, 2 or 3, characterized in that the inflow openings or perforations of the tube are surrounded by a filter. 35 Soil heat exchanger according to one of the preceding claims, characterized in that the hollow tube has a diameter of between 1000 and 50 mm. Soil heat exchanger according to one of the preceding 5 claims, characterized in that the bottom end of the U-shaped part and the hollow tube is introduced at least 5 m below the earth's surface. Soil heat exchanger according to one of the preceding claims, characterized in that the temperature is measured near the underside of the U-shaped pipe. Soil heat exchanger according to any one of the preceding claims, characterized in that a plurality of a self-closed pipe with a U-shaped part are arranged in the hollow tube 15. 10. Method for arranging in the soil below the earth's surface a vertical soil heat exchanger, characterized in that first a tube is introduced approximately vertically into the ground to a determined desired depth, which tube is closed near the bottom and over a given length is provided with grommets for the groundwater and which pipe is further empty and then the 25 U-shaped part of a pipe closed in itself is introduced into the pipe to a determined desired depth. 11. Method according to claim 10, characterized in that before the U-shaped part is inserted, the part of the tube provided with openings or perforations is provided with a filter such as an amount of gravel. i