EP1637825A2 - Intermediate heat exchanger, heat pump and cooling system - Google Patents

Abstract

A heat pump or cooling circuit compressor (1) and expansion valve (3) provides heat to a condenser (2) and cooling to an evaporator (4) which connect with intermediate heat exchangers (7) containing carbon dioxide as a temperature transfer medium, freely circulating or pumped (8).

Description

The invention relates to an intermediate heat exchanger according to the preamble of claim 1. Furthermore, the invention relates to a heat pump or refrigeration system with at least one such intermediate heat exchanger and the use of an intermediate heat exchanger.

Intermediate heat exchangers, in particular heat pump or refrigeration systems, which are coupled between the working medium circuit of a heat pump or refrigeration system and to a heat exchanger connected in a circuit of a heat transfer medium, are known. Such intermediate heat exchangers have as heat exchange fluid brine or optionally with antifreeze water provided, wherein the heat exchange fluid is circulated and transfers heat between the coupled working fluid and the coupled heat transfer medium depending on the present temperature difference in one direction or in the other direction.

The use of such intermediate heat exchangers is particularly useful when the working medium circuit is to be safely separated from the circulation of the heat transfer medium to e.g. the entry of non-environmentally acceptable working medium, such as e.g. Freon or oils mixed with oils to avoid the circulation of the heat transfer medium, e.g. can be circulated groundwater. Furthermore, in the case of direct contact between the working medium circuit and the circulation of the heat transfer medium, e.g. due to damage to the heat exchanger due to mechanical stress or corrosion of the material of the heat exchanger, heat transfer medium penetrate into the working medium circuit and damage or destroy the sensitive compressors.

Finally, the fluids used for intermediate heat exchangers are not optimal in terms of their capacity for heat exchange or show a limited efficiency.

According to the invention, an intermediate heat exchanger, with which the above-mentioned disadvantages can be largely avoided, characterized by the features mentioned in the characterizing part of claim 1. A heat pump or refrigeration system according to the invention is characterized by the features of claim 14.

Carbon dioxide can easily enter into the working medium circuit of the heat pump or refrigeration system, without damaging the compressors or causing costly cleaning of the working medium circuit. If CO ₂ enters the circulation of the heat transfer medium, it will not damaged or CO _{2 is} not classified as harmful to the environment. In addition, CO _{2 has} best heat transfer properties, which can be optimally used, in particular, when the features of claim 2 are realized. The functional principle of heat pipes and thermosyphons is well known.

If the features of claim 3 are realized, then no external power supply is required in order to circulate the CO ₂ between the coupling region of the heat exchanger medium or fluid and the heat exchange region of the working medium circuit of the heat pump or refrigeration system. The enthalpies available for the heat exchange by the evaporation or condensation of CO ₂ are then used to advantage when the features of claim 4 are realized. In the lower part of the container liquid CO _{2 is} present, which is ready for evaporation and rises in the container to the top; In the upper region of the container, heat is withdrawn from the gaseous CO ₂ and this condenses and falls back into the liquid region in the form of droplets. There is a cycle of evaporating and condensing CO ₂ .

In a preferred embodiment, the features of claim 5 are realized. It is thus possible to supply heat to the condensed CO ₂ present in liquid form in the lower region of the container from a heat source and to evaporate CO ₂ ; this supplied heat can be dissipated with the heat transfer medium to a heat sink. In particular, the heat is removed from the condenser of the heat pump or refrigeration system. In this case, a cooling circuit or a circuit with groundwater, which acts as a heat source or conveys heat from the object to be cooled or from the groundwater, is connected to the evaporator of the heat pump or refrigeration system.

But it is also possible that the evaporator of the heat pump od. Refrigeration system is coupled for heat exchange to the overhead gas area of the CO ₂ -Kreislaufes and subtracts heat there. In this case, there located gaseous CO ₂ faster condenses and enters the Ankoppelbereich the heat transfer medium and absorbs heat from this while it drips into the underlying liquid region of CO ₂ . In this way, heat is supplied to the evaporator of the heat pump or refrigeration system which can be delivered to a heating circuit.

The design of the connections or heat exchangers through which the working medium of the heat pump or refrigeration plant or the heat transfer medium are conducted can have any shape and size. Advantageously, a plurality of such heat exchangers are arranged parallel to one another in the respective heat exchange region in order to achieve the best possible heat transfer. These Heat exchangers may be realized in the form of plates, pipes, coils or other heat exchangers having structure.

Advantageous are the features of claim 7, since thus a good heat transfer and a good separation of the CO ₂ from the heat transfer medium with which the CO _{2 is} in heat exchange, can be achieved.

According to the features of claim 9, a tubular container having a substantially vertically aligned axis is divided into three superimposed areas, namely a central coupling region through which or in which the heat transfer medium is guided, wherein above the coupling region of the evaporation region of CO ₂ to the evaporator side circuit for the working fluid and / or below the Ankoppelbereiches the area with liquid CO ₂ to which the condensate side circuit of the working medium of the heat pump od. Refrigeration system is coupled.

Such an intermediate coupling region exhibiting intermediate heat exchanger, in which below and above corresponding heat exchange areas for evaporator side or condenser side working media are formed, during operation of the heat pump od. Refrigeration as needed either to a condenser side provided heat exchanger of the working medium circuit or to a heat exchanger provided on the evaporator side be connected to the working medium circuit in order to provide appropriate heat or cooling power available.

Of particular advantage is an intermediate heat exchanger according to claim 10. This intermediate heat exchanger has an optimum efficiency and is easy to prepare and reliable. Particularly simple are the production and the construction of such an intermediate heat exchanger, if the features of claim 11 are met. The coupling to the condenser-side or evaporator-side circuit of the coolant of the heat pump od. Refrigeration system via the standing in intimate contact with the tubes casting or molding compounds, which ensure excellent heat transfer. Since each of the pipes filled with CO ₂ fulfills the function principle of a heat-pipe, it is ensured that an optimum heat transfer between the heat exchange regions and the coupling region is present. In addition, the individual pipes maintenance work easily accessible and in case of malfunction of a pipe, the remaining tubes can continue to perform their function, which is not possible with an integral container.

In an alternative embodiment of the intermediate heat exchanger, the features of claim 13 can be realized. Due to the forced circulation of CO ₂ by means of a pump, the heat transfer between the working medium circuit and be optimized the circulation of the heat transfer medium. It is not necessary in this case, to form the container as a heat-pipe. It is sufficient to pump the liquid CO ₂ through the Ankoppelbereich for the heat transfer medium and to wait for the evaporated CO ₂ drips after cooling, to pump it back into the circulation of the heat exchange fluid.

Also in this embodiment, the circuit for the CO _{2 is} advantageously oriented vertically.

In the following the invention will be explained in more detail with reference to the drawing.

Fig. 1 shows schematically the Arbeitsmedium- or refrigerant circuit of a known heat pump od. Refrigeration system. 2 schematically shows the evaporator-side working medium or refrigerant circuit of a heat pump or refrigeration system according to the invention with a switched intermediate heat exchanger according to the invention. 3 to 5 show schematically the working medium circuit of a heat pump according to the invention od. Refrigeration system with intermediate heat exchangers according to the invention. FIGS. 6, 7, 8 and 9 show embodiments of intermediate heat exchangers according to the invention.

1 schematically shows a heat pump or refrigeration plant 20 with a working medium or refrigerant circuit comprising a compressor 1, a condenser 2, an expansion valve 3 and an evaporator 4. The condenser circuit 2 is connected to a heat exchanger 31 to a circuit 5 of a heat transfer medium, e.g. Water, coupled, with which a heating system can be supplied. The evaporator or evaporator circuit 4 is coupled with a heat exchanger 30 to a circuit 6 of a heat transfer medium, e.g. to a groundwater reservoir, which emits heat to the evaporator 4 and the working medium.

Fig. 2 shows schematically an intermediate heat exchanger 7, as it can be generally switched for heat exchange between the circuits 4, 6 and / or 2, 5. The heat transfer fluid of the intermediate heat exchanger 7 is circulated in this and circulates and transfers heat between the respective circuits 4 and 6, as shown schematically in Fig. 2. In the same way, another heat exchanger 7 transfers heat between the circuits 2 and 5. In refrigeration systems, the intermediate heat exchanger 7 is arranged in the evaporator circuit 4, to obtain only a coupling to the heat transfer medium of the heat source. As indicated in Fig. 3, a heat absorption can take place from the groundwater. When used for heating systems, an arrangement of the intermediate heat exchanger takes place in the condenser circuit 2 in order to obtain a coupling to the heat transfer medium of the heat sink. As indicated in FIG. 4, heat can be released to a heating circuit.

In principle, the heat exchanger fluid in the intermediate heat exchanger 7 could be conveyed by means of a pump 8 in the circulation inevitably. Advantageously, liquid CO _{2 is} conveyed by the pump 8, which is thereby brought into contact with the heat transfer medium in heat transfer contact and heated or vaporized. The vaporized CO ₂ then enters into contact with the evaporator circuit 4, releases heat therefrom, is thereby liquefied and returns to the area of the liquefied CO ₂ .

A corresponding transport of the heat exchange fluid could also be due to Kapillarwirkungserfolgen, eg by arranging felt webs, the liquid CO ₂ conduct.

Advantageously, the intermediate heat exchanger is in the form of an upright heat exchanger 7, and the in its upper region has at the bottom of the CO ₂ -Flüssigbereich the gaseous portion of the CO _2.

Fig. 3 shows schematically an embodiment of a heat pump od. Refrigeration system 20 with an intermediate heat exchanger 7, which is designed as a thermosiphon or heat pipe. The heat exchange between the evaporator-side working medium circuit 4 and the heat exchanger 4 and the circuit 6 of the heat transfer medium of the heat source or of the heat exchanger 5 which flows through it takes place via the thermosiphon or heat pipe 7, which is advantageously arranged vertically in the position of use it is also possible, horizontal or inclined arranged heat-pipes or other forms of heat-pipes, for example, by capillary action, the CO ₂ transporting or back conductive heat-pipes to use; In practice, a thermosyphon or a vertical heat pipe have been the main reinforcement.

In the lower region 9 of the heat pipe 7 is in operation liquid CO ₂ ; in the upper region 10 of the heat pipe 7 is in operation gaseous CO ₂ . Provided that the CO ₂ contained in the lower part 9 is heated in the coupling region 36 by a corresponding heat supply by the heat transfer medium of the circuit 6, vaporizes this and rises and falls in heat exchange region 34 in contact with the heat exchanger of the circuit 4, of the evaporator side working medium of the refrigerant circuit of the Heat pump od. Refrigeration system 20 is flowed through. The working medium extracts heat from the heat exchanger fluid, ie the CO ₂ , that this condenses and drips into the lower region 9.

4 shows an embodiment of an intermediate heat exchanger or a heat pump or refrigeration system 20, in which the condenser circuit 2 is coupled to the circuit 5 of a heat transfer medium of the heat sink via a thermosiphon or a heat pipe 7. The located in the lower part 9 of the heat pipe 7 liquid CO ₂ is heated in the heat exchange region 32 and evaporated; In the upper region 10 of the heat pipe 7, heat is taken from the gaseous CO ₂ from the heat transfer medium of the circuit 5 and the CO _{2 is} condensed. The CO ₂ leaks from the upper portion 10 in the lower region from and represents a further evaporation available. In the case of the use of a thermosyphon or a heat pipe 7, the circulation of CO _{2 is carried out} by the different weight of liquid CO ₂ and gaseous CO ₂ or by capillary action.

The envisaged intermediate heat exchanger 7 physically or mechanically separates the heat exchanger sections or circuits 4 and 6 or 2 and 5 so that the working medium of the heat pump or refrigeration system is certainly not in contact with the heat transfer medium of the heat source or heat sink or of heating or heating Cooling circuits passes.

The heat-pipe 7 is dimensioned accordingly or made long, so that there is a sufficient distance. In any case, it is avoided that the circuits 2 or 5 and 4 or 6 are formed in the same heat exchanger or that these heat exchangers are closely coupled with each other, so that a mixing of working fluid and heat exchange fluid in case of damage is avoided with certainty.

FIG. 5 shows a preferred embodiment of a heat pump or refrigeration system in which the working medium circuit is connected to corresponding heat exchangers of the circuits or heat exchangers 5 and 6 for a heat transfer medium both on the compressor side and on the evaporator side via a heat pipe 7 which heat taken from the compressor side or heat can be supplied to the evaporator side.

In the embodiment according to FIG. 6, the intermediate heat exchanger is formed by a heat pipe, which comprises a container 11 with a lower region 9 for liquid CO ₂ and an upper region 10 for gaseous CO ₂ , which regions 9, 10, in particular into the bottom and top end portions of this in use upright or vertical standing container 11 are formed. The upper region of the container 11 is provided with connections 13 which are connected to the evaporator-side circuit 4 of the heat pump or refrigeration system 20 and in the heat exchange region 34 pass the evaporator-side working medium through the upper region 10 of the container 11 over a number of turns 14. Below this heat exchanger 14 is a heat exchange region 36 for the heat transfer medium. The circuit 6 of the heat exchange medium comprises a heat exchanger with a number of vertically arranged tubes 15 extending between two perforated plates 16. Intermediate plates 17 allow a cascade-like passage for the heat transfer medium, with which the located in the lower region 9 liquid CO ₂ or possibly condensing CO ₂ is heated. The container 11 constitutes a heat pipe 7, in which in the heat exchanger region 34 and the coupling region 36, a corresponding heat application of the or a corresponding heat removal from the CO ₂ takes place. Due to the large number of existing tubes 15 there is a good heat transfer between the CO ₂ and the heat transfer medium, which is supplied and discharged via the terminals 18.

Fig. 7 shows an intermediate heat exchanger in the form of a heat pipe 7, which essentially corresponds to an upside down intermediate heat exchanger according to FIG. 6. However, the connections 13 are now connected to the heat pump or cooling system 20 on the condenser side, and the CO ₂ which is located in the lower region 9 is caused to evaporate due to the relatively heat-generating refrigerant of the heat pump or refrigeration system 20 in this case. With the heat transfer medium supplied via the connections 18, heat is withdrawn from the evaporated CO ₂ , so that it condenses again. The trained by a heat exchanger 6 Ankoppelbereich 36 to the functioning as a heat-pipe container 11 is above the heat exchange region 32 and the windings 14 of this condenser side of the heat pump od. Refrigeration 20 connected heat exchanger.

In such containers 11, a pressure of about 60 to 100 bar is maintained, at a temperature of 40 to 50 °. In this area, a heat pipe for CO _{2 has} a very suitable for the present purpose efficiency.

The tubes 15 of the heat exchanger in the coupling region 36 are advantageously parallel and end with perforated plates 16. Thus, a stable, easy-to-produce structure is created in which the heat transfer medium, advantageously water, circulates, while passing through the tubes, the CO ₂ in circulation or in countercurrent circulated.

In essence, the intermediate heat exchangers according to FIG. 6 and FIG. 7 have the same structure; In use, the coupling region 36 is at coupling to the evaporator circuit of the heat pump od.Kälteanlage below the terminals or below the heat exchanger connected to the evaporator circuit and when connected to a condenser circuit of a heat pump od.Kälteanlage above the terminals or the condenser side heat exchanger ,

Fig. 8 shows an embodiment of an intermediate heat exchanger in the form of a heat pipe 7, which is formed by the container 11. The coupling region 36 of the heat transfer medium is below windings 14 of the heat exchanger of the heat exchange region 34 (heat source), which is connected to the evaporator side circuit of the heat pump od. Refrigeration system 20. Below the Ankoppelbereiches 36 is the heat exchange region 32 (heat sink) whose turns 14 and Heat exchangers with the terminals 13 on the compressor side to the working medium circuit of the heat pump od. Refrigeration system 20 are connected. Depending on the need or intended use of the heat pump or refrigeration system 20, a coupling of the working medium in the heat exchange region 34 or in the heat exchange region 32 to the coupling region 36 can now take place.

9 shows an embodiment of an intermediate heat exchanger, in which a plurality of closed, elongated tubes 25 are arranged side by side, in particular parallel to one another. These tubes are filled with CO ₂ . The pressure of the CO ₂ is about 40 to 80 bar. These pipes 25 are in their upper as a heat exchange region 34 (heat sink coupling) acting area pressed or potted with a molding compound or molding compound 19, in which molding or casting compound 19 lines or windings 14 of at least one heat exchanger are included, which the heat exchange function for exert the evaporator-side working medium circuit of the heat pump od. Refrigeration system 20 in the heat exchange region 34.

In the lower part of the tubes 25, these are enclosed in a heat exchange region (heat source coupling) 32 of molding or casting compounds 19, which molding or casting compounds 19 the corresponding lines or windings 14 of at least one heat exchanger for heat exchange with condensate-side working medium of the heat pump od Refrigeration system 20 included.

The pressing or casting compounds are good heat-conducting, so that the heat exchange between the tubes 25 and the flowed through by the working medium lines or heat exchangers can be done well. In the central region of the combined tubes 25 is the Ankoppelbereich 36 for coupling the heat transfer medium. In itself, the coupling region 36 can also be formed or filled with casting or molding compounds 19 and heat exchangers and lines for the heat transfer medium contained therein. Up and down to the casting or molding compounds are limited by end surfaces 29. It is also possible to pour out or forget the heat exchanger areas 32, 34 and the coupling area 36 and all lines, pipes and heat exchangers 14 located therein, together with the tubes 25 with pouring masses 19.

In the case shown, however, the coupling region 36 is bounded by two perforated plates 16, between which the heat transfer medium is passed. The coupling region is formed in the present case similar to the coupling region 36 as described in connection with FIGS. 6 and 7, ie the heat transfer medium flows around the tubes 25.

Each one of the tubes 25 constitutes a heat-pipe 7; in the lower or lowermost region of each tube 25 is the area 9 with liquefied CO ₂ ; in the upper or uppermost region of each tube 25 is the area 10 with gaseous CO ₂ .

It is quite possible to form such tubes 25 combined with casting or molding compounds with a coupling region 36 and only one heat exchange region 32 or 34 arranged either above or below it so that intermediate heat exchangers similar to those shown in FIGS. 6 and 7 are formed Intermediate heat exchangers are.

The tubes 25 may be placed in a container 21 which is for protective purposes only, but is not part of the heat pipes formed by each individual tube 25.

Provided according to the invention and particularly advantageous is the use of a erfindugnsgemäßen intermediate heat exchanger. For the heat exchange between a circuit in which are performed as fluid or Schadfluid wastewater, radioactive fluid, oil or oil-containing fluids, bath water and a cycle of Nutzfluid, in the groundwater, utility or service water or recirculation water provided is performed. This is a safe separation of environmentally harmful fluid and usable fluid, in particular for heat recovery or heat dissipation from the harmful fluid, achieved. This use of an intermediate heat exchanger according to the invention can be carried out as an alternative to the special use of the intermediate heat exchanger in heat pump or refrigeration systems.

Claims (11)

Intermediate heat exchanger (7), in particular for a heat pump od. Refrigeration system (20), the at least one heat exchange region (32, 34) for coupling to a working medium circuit, in particular the Wärmepumpen od. Refrigeration system (20) and at least one Ankoppelbereich (36) a heat transfer medium circuit has, in order to transfer heat between the working medium and the heat transfer medium, wherein for circulating heat between the respective heat exchange region (32, 34) and the coupling region (36) in the intermediate heat exchanger (7), a heat exchange fluid is circulated or circulated,
characterized in that
the heat exchange fluid is CO ₂ , which is guided between the at least one heat exchange region (32, 34) and the coupling region (36) either self-circulating in the free circulation or pumped in the forced circulation. Intermediate heat exchanger according to claim 1, characterized in that the intermediate heat exchanger (7) is formed with the circuit for the CO ₂ in the form of a thermosyphon or a heat pipe or a heat pipe and / or - That the thermosyphon or the heat pipe in the form of at least one in use position vertically arranged tube (25) or vertically extending container (11) are present, in which the cycle of CO ₂ by the different weight of liquid and gaseous CO ₂ , ie by gravitational force, is maintained. Intermediate heat exchanger according to claim 1 or 2, characterized in that the intermediate heat exchanger (7) in the operating position in its lying down or bottom portion (9) has a condensation or liquid range with waiting for evaporating CO _2, in particular for coupling a heat source, and in its upper or uppermost region (10) has an evaporation or gas receiving area with CO ₂ ready for condensing, wherein the CO ₂ , in particular for coupling a heat sink, between these areas (9, 10) is circulated or countercurrent. Intermediate heat exchanger according to one of claims 1 to 3, characterized in that the intermediate heat exchanger (7) comprises a container (11) in a top position of use lying heat exchange region (34), in particular for coupling a heat sink, at least one connection (13) and /or at least a heat exchanger (14) for the contacting and / or admission and / or passage of working medium, in particular the evaporator-side working medium of the heat pump or refrigeration system (20), and in an underlying coupling region (36), in particular for coupling a heat source, connections ( 18) and / or at least one heat exchanger (15) for the contacting and / or loading and / or passage of the heat transfer medium,
or that the container (11) in an overhead Ankoppelbereich (36), in particular for coupling a heat sink, connections (18) and / or at least one heat exchanger (15) for the contacting and / or loading and / or passage of the heat transfer medium and in a underlying heat exchange region (32), in particular for coupling a heat source, terminals (13) and / or at least one heat exchanger (14) for the contacting and / or loading and / or passage of working fluid, in particular capacitor-side working medium of the heat pump (20) .
or that the container (11) both above and below the Ankoppelbereiches (36), in particular for coupling a heat source or heat sink, in each case a heat exchange area (32, 34), in particular for coupling a heat source or heat sink, terminals (13) and / or at least one heat exchanger (14) for working medium, in particular on the one hand for evaporator-side working medium and on the other hand for condensate-side working medium of the heat pump od. Refrigeration system (20). Intermediate heat exchanger according to one of claims 1 to 4, characterized in that the heat exchanger (14) for the evaporator side and / or condenser side working medium of the heat pump od. Refrigeration system (20) and / or the heat exchanger (15) for the heat transfer medium in the form of at least a conduit and / or turn and / or plate guided through or in the container (11) and / or a pipe are formed in the heat exchange region (32, 34) and / or coupling region (36) of the container (11). Intermediate heat exchanger according to one of claims 1 to 5, characterized in that in the Ankoppelbereich (36) of the container (11) a plurality of tubes (15) in the container (11) are arranged in the position of use of the heat exchanger (7) vertically aligned and from Heat transfer medium are lapped and connect the underlying area (9) for liquid CO ₂ with the overhead area (10) for gaseous CO ₂ and / or - That the connections (13) and / or heat exchanger (14) for the evaporator side or condenser side working fluid of the heat pump - od. Refrigeration (20) above and / or below the tubes (15) open into the container (11) or arranged in this are and / or - That the Ankoppelbereich (36) of the heat transfer medium in the container (11) by an upper and a lower perforated plate (16) is limited, the recesses of the tubes (15) penetrated by gas and / or liquid-tight or with the end portions of the tubes (15 ) are gas- and / or liquid-tight connected. Intermediate heat exchanger according to one of claims 1 to 6, characterized in that the intermediate heat exchanger (7) has a plurality of separate CO ₂ circuits in the form of in the position of use of the intermediate heat exchanger (7) vertically extending, closed and filled with CO ₂ tubes (25) , each of which fulfills the functional principle of a thermosyphon or a heat pipe,
wherein each of the tubes (25) in an overhead heat exchange region (34), in particular for coupling a heat sink, with at least one heat exchanger (14) for loading and / or coupling of evaporation-side working medium of a heat pump od. Refrigeration (20) is contacted and in an underlying coupling region (36), in particular for coupling a heat source, connections (18) and / or at least one heat exchanger (16, 26) are provided for the contacting and / or admission of the tubes (25) with the heat transfer medium,
or wherein at least one heat exchanger (15, 26) is coupled to each of the tubes (25) in a coupling region (36), in particular for coupling a heat sink, for contacting and / or pressurizing the tubes (25) with heat transfer medium and in one underneath lying heat exchange region (32), in particular for coupling a heat source, connections (13) and / or at least one heat exchanger (14) for contacting and / or admission of the tubes (25) with working medium, in particular condensate-side working medium of the heat pump or. 20), are arranged
or wherein each of the tubes (25) both above and below the Ankoppelbereiches (36), in particular for coupling a heat source or heat sink, in a heat exchange region (32, 34), in particular for coupling a heat source or heat sink, terminals (13) and / or at least one heat exchanger (14) for the contacting and / or admission of the tubes (25) with working medium, in particular with condensate-side working medium or working medium of a heat pump or refrigeration system (20) on the evaporator side, optionally, wherein the tubes (25) for contacting with the working medium and / or the heat transfer medium in the coupling region (36) and / or in at least one heat exchange region (32, 34) poured into high thermal conductivity casting or molding compounds and / or are pressed , in which casting or molding compounds are formed or contained as heat exchanger lines (14) or pipes for the working medium and / or the heat transfer medium. Intermediate heat exchanger according to one of claims 1 to 7, characterized in that the container (11) is tubular and in the position of use, the axis of the tube is substantially vertically aligned. Intermediate heat exchanger (7) according to any one of claims 1 to 8, characterized in that the intermediate heat exchanger (7) in the operating position in its lying down or bottom portion (9) has a condensation or liquid range with standing by for evaporating CO ₂ and, in its top or to the uppermost region (10) has a gas receiving space with ready for condensing CO ₂ and that preferably in the lower or lowermost region (9) of the intermediate heat exchanger (7), in particular in the liquid region of the CO ₂ , a pump (8) is located the CO _{2 is} conveyed from the lower region to the upper region (10) and thereby guided through the coupling region (36) and at least one heat exchange region (32, 34). Heat pump od. Refrigeration system with at least one intermediate heat exchanger according to one of claims 1 to 9, with at least one heat exchange region (32, 34) to the working medium circuit of the heat pump od. Refrigeration system (20) is coupled and with at least one coupling region (36) a heat transfer medium is coupled to transfer heat between the working medium and the heat transfer medium, wherein advantageously for heat transfer between the heat exchange region (32, 34) and the coupling region (36) in the intermediate heat exchanger (7) as the heat exchange fluid CO ₂ is circulated. Use of an intermediate heat exchanger according to one of claims 1 to 10, for the heat exchange between a working cycle in which working medium, e.g. Wastewater, radioactive fluid, oil or oil-containing fluids, bath water, is guided and a heat transfer medium circuit in which a Nutzfluid, e.g. Groundwater, utility or service water or intended for recirculation water, is guided.

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