NL1032852C2 - Heat pump installation with compressor, includes internal heat exchangers arranged in series for heating suction gas - Google Patents

Abstract

The installation includes heat exchangers arranged in series, at least two being internal heat exchangers for heating the suction gas. The installation lacks a buffer vessel and comprises a compressor (C), an expansion device (G), an evaporator (D) and a coolant. An independent claim is also included for a method for recovering heat from a heat source, comprising the following steps: (A) evaporating coolant in an evaporator to remove heat from the heat source; (B) heating the coolant in a first heat exchanger (E) in a first heating step; (C) heating the coolant in a second heat exchanger (F) in a second heating step; (D) compressing the coolant to a supercritical level in a compressor; (E) cooling the superheated coolant in a third heat exchanger (A) in a first cooling step; (F) cooling the superheated coolant in the second heat exchanger in a second cooling step; (G) cooling the coolant in a fourth heat exchanger (B) in a third cooling step; (H) expanding the coolant in an expansion device; and (I) repeating.

Description

Improved heat pump. Background of the invention

Conventional heat pump systems consist essentially of a compressor, an evaporator, a condensing and an expansion member. By means of the evaporator, heat is extracted from a heat source (for example, water heated by geothermal heat) and this is transferred in the heat exchanger to, for example, a hot water supply for a home. Ammonia or a synthetic compound is used as the refrigerant in these installations. Such an installation usually has a COP of approximately 3.6.

Description of the prior art

The disadvantage of many of the existing systems is that because the processes take place subcritically, the temperature level to be achieved is limited. The heat release in the condenser 15 takes place below the critical temperature, ie there is a phase transition at a constant temperature (the condensing temperature at the prevailing pressure), which is not too low given the technical limitations of the compressors and because of the efficiency of the installation often does not exceed 60 ° C. In practice, warm aters of 55 ° C can be made with this. As the target temperature is chosen higher, the efficiency decreases because it can only be achieved by means of a higher pressure, whereby the compressors have a higher energy consumption and the efficiency of the heat pump decreases. Moreover, the pressure to be achieved is limited by the technical limits of the compressor.

By using CO2 as a refrigerant, it is possible to make the cycle run transcritically, which already partially removes the above limitations.

Hitherto known heat pump installations operating in the transcritical area are mainly used for heating water or air for domestic use on the basis of geothermal heat or industrial waste heat. See, for example, DE 10 2004 015297. This describes a heat pump that "pumps up" geothermal energy for use in a household using CO2. The cycle takes place transcritically. However, no temperatures and pressures are specified here.

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Description of the invention

There is therefore a need for a system with which higher temperatures can be achieved without reducing the efficiency of the installation.

5 This problem can be overcome by choosing a compressor specially developed for the use of CO2. Carbon dioxide in combination with the compressors specially developed for this purpose enable much higher pressing pressures, so that the installation can operate transcritically, that is, the heat is delivered to the medium to be heated at temperatures above the critical temperature. Because no phase transition occurs here (the refrigerant remains gaseous), the heat transfer takes place at a constant pressure, which gives much more room for maneuver with regard to the temperature to be achieved. Because these compressors have permissible compressed gas temperatures of 150 ° C, the target temperature can even be selected above 100 ° C. Thanks to the smaller pressure ratio at which the heat is generated, the efficiencies of the process are higher than those of the subcritical processes. An additional advantage of using CO2 is that in the event of leakage or breakage of the installation, in particular in the heat exchanger installed in the earth's surface, the environment is not damaged.

The object of the present invention is not only to heat water or air to medium temperature (approx. 35-50 ° C) but also to heat water for a heating installation to a relatively high temperature (70 -80 ° C) in such a way that the efficiency of the installation is equal or better than that of a conventional one.

This is achieved by means of an installation according to the features of claim 1.

The suction gas is heated to achieve a higher heat output at the higher temperature level (not only more heat, but also at a higher temperature). This is done on the one hand by applying a high pressing pressure and on the other hand by heating up the suction gas 30 with the aid of heat from the supercritical CO2 which has already relinquished part of its heat for heating up water at a high temperature level.

By combining suction gas heating and compression with a small pressure ratio, compressed gas temperatures of 150 ° C can be achieved, whereby the efficiency of the heat pump is at least equal to that of the conventional subcritical processes. Furthermore, by allowing the medium (CO2) to exchange heat with itself several times, it is possible to combine both functions (hot water supply and central heating) in one system.

The compressor is known per se in the prior art and will not be discussed further here.

The present invention will now be described by way of example, with reference to the following figures, in which Figure 1 is a principle diagram of the installation according to the invention.

Figure 2 represents the mollier diagram containing the cycle and the various elements (evaporator, heat exchangers). The dotted lines show the temperature variation with a constant pressure of 39.7 bar.

The CO2 is compressed in the compressor to a pressure of 105 bar and a temperature of 148 ° C. This then heats water in a heat exchanger A from 60 to 80 ° C, thereby decreasing itself from 148 to 65 ° C. In a heat exchanger F this CO2 still gives off heat to CO2 that is on the suction side of the compressor in the cycle and that, warmed from 30 to 50 ° C, enters the compressor.

20 The CO2 from 65 ° C drops to 57 ° C and then exchanges heat with other water. The temperature of the CO2 drops to 32 ° C. This CO2 exchanges heat with CO2 that comes from the evaporator and heats it from 12 ° C to 30 ° C. (this is the CO2 that is further heated to 50 ° C in the above step before it enters the compressor). The CO2 from 32 drops to a temperature of 22 ° C, and in an expansion valve G 25 the CO2 expands and the temperature further drops to the evaporation temperature of 5 UC. By means of geothermal heat, the liquid CO2 is evaporated in a vaporizer and heated to a temperature of 12 ° C. This CO2 is heated to 30 ° C in the above step.

In essence, all heat exchangers are connected in series.

Insofar as the installation is used for heating an object, a mixture of water and antifreeze or even a non-aqueous liquid can also be used as medium instead of water. A construction is also conceivable in which air is heated directly.

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The above numbers are examples to clarify the explanation and do not limit the scope of the invention in any way.

The control of a cold process proposed in our application WO 2006011789, including a vaporizer in which the number of operating circuits can be controlled, can also be used in the present invention. For the details of this, reference is made to this application. This makes it possible to maintain an optimal COP at all times. Finally, it is to be noted that it is a feature of the invention that the installation does not comprise a buffer tank of any kind. The use of such a vessel is made superfluous by the use of the above-mentioned cycle control.

The installation described can be used for heating large or small objects, possibly with adjustments known in the art with a view to scaling up.

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Claims (12)

A heat pump installation without a buffer vessel, comprising a compressor, an expansion member, an evaporator, a refrigerant, characterized in that the installation further comprises heat exchangers placed in series, at least two of which are internal heat exchangers which serve to heat up the suction gas. 2. Heat pump installation as claimed in claim 1, characterized in that it comprises at least three heat exchangers, at least two of which are internal heat exchangers for heating the suction gas and at least one for heating a medium. 3. Heat pump installation as claimed in any of the foregoing claims, characterized in that it comprises four heat exchangers, two of which are internal heat exchangers for heating the suction gas, and two for heating a medium. Heat pump installation according to one of the preceding claims, characterized in that the medium is water. 20 Heat pump installation according to one of the preceding claims, that the installation is transcritical. 6. Heat pump installation according to one of the preceding claims, characterized in that the refrigerant is carbon dioxide. A heat pump installation as claimed in any one of the preceding claims, characterized in that the capacity of the evaporator is adjustable. A heat pump installation according to claim 7, characterized in that it is electronically controlled. A method for absorbing heat from a heat source, characterized in that it comprises the following steps: a) evaporating the refrigerant in an evaporator (D) extracting heat from the heat source; b) heating the refrigerant in a first heat exchanger (E) in a first step; C) heating said refrigerant in a second step in a second heat exchanger (F); d) compressing the refrigerant in a compressor (C) to a supercritical pressure; e) cooling the superheated refrigerant in a first step in a third heat exchanger (A) in a first step; f) cooling the superheated refrigerant in the second heat exchanger (F) in a second step; g) cooling the refrigerant in a third heat exchanger (B) in a third step; H) cooling the refrigerant in the first heat exchanger (E) in a fourth step; i) expanding the refrigerant by means of an expansion member (G); j) step a) 20 The method of claim 9, wherein a medium is heated in steps e) and g). 25 A method according to claims 9-10, characterized in that it is CO2. 12. Method as claimed in claim 10, characterized in that the medium comprises at least partially water. 1032852