DE10133931A1 - Geothermic heat utilization process involves using latent heat storage within functional collector - Google Patents

Abstract

The heat utilization process involves using latent heat storage within a functional collector (1). This collector is buried in the earth, and transfers heat to the line system there from material capable of storing latent heat encased in latent heat carriers (2). An unimpeded heat exchange takes place between this material and the surrounding earth region.

Description

The invention relates to a method for using geothermal energy according to the Preamble of claim 1 with heat storage in Heating systems, preferably for heat pumps and in combination with Solar systems and a device for performing the method.

Currently, various designs and materials are considered Earth collectors or storage used.

State of the art is the use of earth collectors in the form of probes, Flat or trench collectors. These collectors are designed so that the Soil existing heat as directly as possible to the heat transfer fluid will give up.

According to patent 197 28 637 C1 is an apparatus and a method for Heating a house with geothermal heat is known using the device has at least one concrete spike arranged in the ground. In at least one concrete spit is a liquid-carrying pipe system arranged. The liquid is in the concrete spit, which is due to the geothermal is warmed, also warmed, then a heat pump fed, which extracts part of the heat from the liquid and the cooled Liquid in turn supplies the at least one concrete skewer. The the Liquid extracted heat is supplied to a heating system in a house. The disadvantage of this solution is that the entire spike cools down quickly, especially with high heat requirements and / or low outside temperatures.

It is the object of the invention, a method and an apparatus for To use geothermal energy, thereby increasing the storage capacity of the Geothermal collectors and geothermal energy storage, especially in Peak load range is improved.

According to the invention, the method is defined in claim 1 described process steps can be implemented. The configurations of the method are described in claims 2 to 8.

The device for performing the method is by the Features described claim 9 solved. Detailed configurations of the Device are described in claims 10 to 19.

The advantage of these solutions is that by using the Conversion heat significant power reserves can be tapped. At the same time it is achieved that the process temperature is higher Heat requirement as the basis for high efficiency Heat pumps no longer sink.

An inexpensive installation option during the Development and structural work. It is also a retrofit to existing ones Systems can be implemented cost-effectively. Compact designs of the Functional collectors with high power reserves are possible. The efficiency Existing systems, particularly during peak periods, can be essential can be increased by the inclusion of latent heat storage material. Additional feeds of solar and waste heat are also special simple.

In interaction with a suitable heating system, e.g. B. The functional collector can also be used for underfloor heating or surface heating Supporting air conditioning in summer by cooling.

The invention is explained in more detail below on the basis of exemplary embodiments explained. The associated drawings show:

Fig. 1 Basic structure of the device, in which the functional collector with its storage liquid is directly integrated into the heat pump system of a heating system

Fig. 2 Basic structure of the device in which the functional collector is integrated via a heat exchanger to the heat pump system of a heating system.

Fig. 3 Basic structure of the device in which an additional heat exchanger is used for energy replenishment.

In the method for using geothermal heat, a heat transfer medium, such as a storage liquid 11 , flows through a line system in the ground, the line system being connected to functional collectors 1 , a combination of an earth collector and an earth store. The geothermal energy present in the underground storage is absorbed by the storage liquid 11 and passed on to a heat pump of the heat pump system 8 , in which part of the heat of the storage liquid 11 is removed and fed to a heating system of a house to be heated. The cooled storage liquid 11 then flows back into the line system in the ground. The functional collector 1 contains additional energy from latent heat storage material enclosed in latent heat carriers 2 with respect to geothermal energy. At the same time there is an unhindered heat exchange between the latent material and the surrounding soil. Unhindered heat exchange also takes place between the line system and the latent heat carriers 2 .

Is z. B. in winter with greater heat demand, the entire functional collector 1 is cooled down by the heat pump to such an extent that a change in condition in the latent heat carriers begins - the latent heat is additionally available to the heating system.

An unhindered heat exchange with the surrounding earth ultimately leads to the storage fluid 11 being heated again and possibly to renewed conversion (latent heat input) in the functional collector 1 .

In addition to the geothermal energy, heat from the latent heat storage material can be extracted from the latent heat transfer medium 2 during peak load times of the heat extraction, thereby ensuring and / or improving the economical operation of the heating system with the heat pump system 8 . Brine is used as the storage liquid 11 .

The heat exchange between the soil and latent heat storage material is achieved by the brine even at temperatures below the melting point of the latent heat storage material (e.g. H ₂ O = 0 ° C).

With an appropriate installation depth (frost limit) of the functional collectors 1 , the heat exchange with the soil leads to the heating of the entire storage contents, particularly when the system is at a standstill. This means that the heat of fusion is fed in again from the ground environment. A make-up, e.g. B. from solar or waste heat, can support this process very easily and effectively.

The switch-on times of the heat pump system 2 are designed depending on the heat requirement of the heating and / or the system-specific requirements, such as optimization of the running time and wear of the heat pump system 2 .

The device for carrying out the method consisting of a functional collector 1 , which is formed from the earth collector and earth storage. The functional collector 1 is integrated in the liquid circuit of the heat pump system 8 . For this purpose, a return 3 and an inlet 4 are operatively connected to the heat pump system 8 , to which a heating system of a house to be heated is connected. The inlet 4 and the return 3 of the heat pump system 8 are operatively connected directly to the interior of the functional collector 1 , whereby the same storage liquid 11 is present in the heat pump circuit and in the functional collector 1 .

The outer surface of the functional collector 1 is to be designed in such a way that heat exchange with the ground is as unobstructed as possible. For this purpose, for example, ribs can be arranged on the outer surface of the functional collector 1 .

Latent heat carriers 2 are arranged in the functional collector 1 .

A distributor 7 can additionally be arranged in the return 3 and the inlet 4 so that further liquid circuits, such as a plurality of function collectors 1 , can be connected. A control and revision opening 6 and a ventilation device 5 are advantageously arranged on the top of the functional collector 1 .

The latent heat transfer medium 2 is poured into the functional collector 1 , as shown in FIG. 1, or introduced in an orderly manner into the functional collector 1 . For heat exchange, almost the entire surface of the latent heat store 2 is in operative connection with the storage liquid 11 .

As shown in FIG. 2, the latent heat carriers 2 are designed as stackable bodies 12 . Spacers 13 , such as cams, are arranged on the surface of the bodies 12 , which ensure a distance from the adjacent bodies 12 for the storage liquid 11 to flow through. The mass of the latent heat transfer medium 2 and the latent heat storage material can either be designed so that the buoyancy of the storage liquid 11 does not change the location of the bodies 12 in the functional collector 1 or the latent heat transfer medium 2 with a holding device 14 connected to the functional collector 1 , as shown in FIG. 2. are in operative connection and thus the buoyancy effect on the latent heat transfer medium 2 is prevented.

In a second exemplary embodiment, in contrast to the first exemplary embodiment, the inlet 4 and the return 3 of the heat pump system 8 are operatively connected to one or more heat exchangers 9 arranged in the functional collector 1 as a closed system and the heat exchangers 9 are surrounded by a separate storage liquid, such as brine. The further structure and the mode of operation correspond to the first embodiment.

The different mode of operation consists only in the additional heat transfer between the brine and the medium in the heat exchangers 9 . The low volume of the medium in the liquid circuit of the heat pump system 8 is particularly advantageous in this solution.

Furthermore, low brine contents are advantageous for the functional collector 1 .

In two other embodiments, at least one heat exchanger 15 in addition to the first or second embodiment in the function collector 1 in each case arranged, which is connected via a line system 10 with one or more energy dessert devices, such as solar and / or waste heat, in operative connection.

Here, too, the further structure and mode of operation correspond to the first or second embodiment.

In addition, the heat exchanger 15 acts in such a way that the entire storage content can be additionally heated in a separate circuit by other heat sources, preferably solar or waste heat. Solar energy can be fed into the functional collector 1 , for example, even at temperatures greater than the conversion point of the latent heat storage material. List of the reference numerals used 1 functional collector
2 latent heat transfer media
3 Heat pump return
4 Inlet for heat pump
5 venting device
6 Inspection and inspection opening
7 distributors
8 heat pump system
9 heat exchangers
10 line system of a solar system or the like.
11 storage fluid
12 Stackable body
13 spacers
14 holding device
15 heat exchangers of solar systems or the like.

Claims (19)

1.Procedure for the use of geothermal energy, in which heat is extracted from the ground via one or more geothermal collectors and a heat pump system connected to it and preferably used for heating buildings, characterized in that latent heat storage is also used within a functional collector ( 1 ) , 2. The method according to claim 1, characterized in that the functional collector ( 1 ) in the ground for the transfer of heat to the piping system in the ground contains additional heat from latent heat storage material, contained in latent heat transfer media ( 2 ) and between the latent heat storage material and the surrounding soil an unhindered heat exchange takes place. 3. The method according to claim 1, characterized in that the unhindered heat exchange between the line system and the latent heat carriers ( 2 ) is carried out by a direct or indirect heat exchange. 4. The method according to claim 1, characterized in that with greater heat demand, for example in winter, the entire functional collector ( 1 ) is cooled down by the heat pump system ( 8 ) to such an extent that a change in state in the latent heat carriers ( 2 ) begins and this latent heat is given to the heating system is also available. 5. The method according to claim 1, characterized in that an unhindered heat exchange with the surrounding soil again leads to the heating of the storage liquid ( 11 ) and possibly to the re-melting of the latent heat storage material, for which purpose heat is absorbed from the environment. 6. The method according to claim 1, characterized in that in addition to the geothermal energy during peak periods of heat removal, additional conversion heat can be extracted from the latent heat storage material of the latent heat transfer medium ( 2 ) and thus an economical operation of the heating system with heat pump system ( 8 ) is guaranteed and / or improved. 7. The method according to claim 1, characterized in that brine is used as the storage liquid ( 11 ) and this ensures that no ice formation (conversion) occurs even at low temperatures and the unhindered heat exchange between the soil and latent heat carriers ( 2 ) and the heat pump cycle take place can. 8. The method according to claim 1, characterized in that the switch-on times of the heat pump system ( 2 ) are designed depending on the heat requirement of the heating and / or the system-specific requirements, such as runtime optimization and wear of the heat pump system ( 2 ). 9. An apparatus for performing the method according to claim 1, consisting of an underground storage in which the liquid circuit is integrated and is operatively connected via a heat pump to the heating system of a house to be heated, characterized in that an earth collector is designed as a functional collector ( 1 ) is arranged in the latent heat transfer medium ( 2 ). 10. The device according to claim 6, characterized in that the latent heat transfer medium ( 2 ) poured or arranged in the functional collector ( 1 ) that almost the entire surface of the latent heat transfer medium ( 2 ) with the storage liquid ( 11 ) is operatively connected for heat exchange. 11. The device according to claims 6 and 7, characterized in that the latent heat carriers ( 2 ) are designed as stackable bodies ( 12 ) and spacers ( 13 ), such as cams, are arranged on the surface, which are opposite the adjacent bodies ( 12 ) ensure a distance to the flow of the storage liquid ( 11 ) or brine. 12. The device according to claim 6, characterized in that the specific weight of the latent heat transfer medium ( 2 ) and the latent heat storage material can be designed so that the buoyancy of the storage liquid ( 11 ) or brine does not cause a change in location of the body in the earth collector ( 1 ). 13. The device according to claim 6, characterized is that the latent heat carrier (2) are provided and a connected to the ground collector (2) holding means (14) in operative connection thus a possible lift of the latent heat carrier (2) is prevented. 14. The apparatus according to claim 6, characterized in that one or more heat exchangers ( 9 ) are arranged in the functional collector ( 1 ) and brine is used as the heat exchanger between the medium of the liquid circuit and the latent heat carriers ( 2 ). 15. The apparatus according to claim 6, characterized in that the inlet ( 4 ) and return ( 3 ) of the heat pump system ( 8 ) for the storage liquid ( 11 ) are directly connected to the interior of the functional collector ( 1 ), so that the same storage liquid ( 11 ) is present in the heat pump circuit and in the function collector ( 1 ). 16. The apparatus according to claim 6, characterized in that the inlet ( 4 ) and return ( 3 ) of the heat pump system ( 8 ) for the storage liquid ( 11 ) are directly connected to the interior of the functional collector ( 1 ), whereby the same storage liquid ( 11 ) is present in the heat pump circuit and in the functional collector ( 1 ) and, in addition, at least one heat exchanger ( 15 ) is arranged in the functional collector ( 1 ), which is connected via a line system ( 10 ) to one or more energy supply devices, such as for solar and / or waste heat, is in operative connection. 17. The apparatus according to claim 6, characterized in that the inlet ( 4 ) and return ( 3 ) of the heat pump system 8 with one or more heat exchangers ( 9 ) arranged in the functional collector ( 1 ) are operatively connected as a closed system and the heat exchanger ( 9 ) are surrounded by separate storage liquid, such as brine. 18. The apparatus according to claim 6, characterized in that the inlet ( 4 ) and return ( 3 ) of the heat pump system ( 8 ) with one or more heat exchangers ( 9 ) arranged in the functional collector ( 1 ) are operatively connected as a closed system and the heat exchanger ( 9 ) are flowed around by separate storage liquid, such as brine, and at least one heat exchanger ( 15 ) is additionally arranged in the functional collector ( 1 ), said heat exchanger ( 15 ) being connected via a line system ( 10 ) to one or more energy supply devices, such as for solar and / or for waste heat, is in operative connection. 19. The apparatus according to claim 6, characterized in that the outer surface of the functional collector ( 1 ) is designed so that there is a good heat exchange with the ground.