DE102014102005A1 - Method for operating a heat pump - Google Patents

Abstract

The invention relates to a method for operating a heat pump, in which a vaporous refrigerant is compressed with a compressor (1) in which the compressed refrigerant is condensed with a condenser (2) in which the condensed refrigerant is expanded with an expansion valve (3) is, in which the expanded refrigerant is supplied to a collector (4), wherein in the collector (4) separates a vapor phase of the refrigerant from a liquid phase of the refrigerant, wherein the liquid phase of the refrigerant to a throttle element (5) and supplied with This is further relaxed, in which the relaxed liquid phase of the refrigerant is evaporated with an evaporator (6), in which the evaporated refrigerant is supplied to the compressor (1). According to the invention it is provided that a measure of the overheating of the refrigerant before entry into the compressor (1) detected and this degree of overheating is used as a reference variable for controlling the expansion valve (3).

Description

The invention relates to a method for operating a heat pump according to the preamble of patent claim 1.

A method for operating a heat pump of the type mentioned is, for example, from the dissertation of Mr. Xu Xing titled "INVESTIGATION OF VAPOR INJECTION HEAT PUMP SYSTEM WITH A FLASH TANK UTILIZING R410A AND LOW-GWP REFRIGERANT R32" from 2012 known (see also 1 ). In this method, a vapor refrigerant is compressed with a compressor that condenses compressed refrigerant with a condenser, the condensed refrigerant expanded with an expansion valve, the expanded refrigerant supplied to a collector, wherein in the collector a vapor phase of the refrigerant from a liquid phase of the refrigerant separates, the liquid phase of the refrigerant fed to a throttle element and further relaxed with this, evaporates the expanded liquid phase of the refrigerant with an evaporator and the vaporized refrigerant is supplied to the compressor.

The invention has for its object to improve a method of the type mentioned. In particular, the simplest and most cost-effective method for regulating the fill level in the collector should be created.

This object is achieved by a method of the type mentioned by the features listed in the characterizing part of patent claim 1.

According to the invention, it is thus provided that a measure of the overheating of the refrigerant before entry into the compressor is detected and this degree of overheating is used as a reference variable for controlling the expansion valve.

In other words, the inventive solution is characterized by the fact that, for example, can be dispensed with costly level sensors in the collector, as always oriented by the overheating of the refrigerant before entering the compressor control of the accumulator upstream expansion valve, the required level in the collector always can be guaranteed.

By "overheating" is meant a state of the refrigerant in which it is heated above its evaporation temperature. The detection of this condition takes place via the determination of the temperature and the pressure of the refrigerant.

Other advantageous developments of the method according to the invention will become apparent from the dependent claims.

The inventive method including its advantageous developments according to the dependent claims will be explained in more detail with reference to the drawing of a preferred embodiment.

It shows

1 schematically the after Mr Xu Xing known, cited in the introduction of the prior art; and

2 schematically the refrigerant circuit for carrying out the method according to the invention.

To use such a heat pump shown is generally used a method in which a vapor refrigerant with a compressor 1 is compressed, the compressed refrigerant with a condenser 2 is condensed, the condensed refrigerant with an expansion valve 3 The relaxed refrigerant is relieved to a collector 4 is fed, being in the collector 4 separates a vapor phase of the refrigerant from a liquid phase of the refrigerant, the liquid phase of the refrigerant, which regularly but also contains small amounts of vapor fractions, then a throttle element 5 supplied and further relaxed with this, the relaxed liquid phase of the refrigerant with an evaporator 6 is evaporated, and finally the vaporized refrigerant back to the compressor 1 is supplied.

Essential for the inventive method is now that a measure of the overheating of the refrigerant before entering the compressor 1 recorded and this level of overheating as a reference variable to control the expansion valve 3 is used.

Decisive for the illustrated method is that to detect the overheating of the refrigerant whose temperature and pressure is determined. The overheating is calculated from these parameters. It is provided that a sensor 9 measures a measure of overheating. Preferably, the sensor 9 the evaporator 6 downstream. Furthermore, the sensor 9 preferably the compressor 1 upstream.

Using the expansion valve 3 a determination is made in the collector 4 reaching amount of refrigerant. According to the invention it is provided that the collector 4 via the expansion valve 3 less refrigerant is supplied when the refrigerant overheats at the compressor 1 decreases. As a result, the Liquid content before the throttle element 5 , This reduces the refrigerant mass flow, which causes the Sauggasüberhitzung at the inlet of the compressor 1 increases.

Furthermore, the invention provides that the collector 4 via the expansion valve 3 more refrigerant is supplied when the overheating of the refrigerant at the compressor 1 increases. As a result, the proportion of liquid in front of the throttle element increases as a result 5 , This increases the refrigerant mass flow, which causes the Sauggasüberhitzung at the inlet of the compressor 1 sinks.

Overall, in the method according to the invention (as already mentioned above), it is intended that small amounts of vaporous refrigerant be the throttle element 5 As the density of the vaporous refrigerant is smaller by about a factor of 50 than that of the liquid refrigerant, even small amounts of vaporous refrigerant reduce the mass flow rate through the throttling element 5 , Is the level in the collector 4 higher than the outlet opening to the throttle element 5 , is fed to this purely liquid refrigerant. If the level is lower than the outlet opening, pure vaporous refrigerant is discharged (not desired state). To the throttle element 5 To supply liquid refrigerant with small amounts of vapor refrigerant, the level is thus preferably controlled exactly to the height of the outlet opening (see 2 ).

According to the invention, it is further preferably provided that for regulating the expansion valve 3 a constantly working, electronic control unit 7 , in particular a PID controller, is used. That is, there is a closed loop for the expansion valve 3 before, in which the hot gas superheating is the reference variable. Preferably, the expansion valve 3 designed as an electronic or thermostatic expansion valve.

Furthermore, it is particularly preferred that with the electronic control unit 7 the throttle element 5 is controlled. That is, the throttle element 5 is preferably controlled via a map depending on the operating point of the heat pump. By means of the throttle element 5 a determination is made from the collector 4 reaching amount of refrigerant, which subsequently the evaporator 6 is supplied. The throttle element 5 is preferably designed as an electronic expansion valve. Alternatively, it may also be designed as a fixed diaphragm or capillary, wherein it is not in these embodiments of the control unit 7 is controlled.

It is particularly preferred for the method that, if necessary, refrigerant, preferably exclusively vaporous refrigerant, from the collector 4 bypassing the throttle element 5 and the evaporator 6 (via the refrigerant line 8th or intermediate injection line) the compressor 1 is supplied. This causes the refrigerant in the compressor 1 is injected in vapor form. This intermediate injection serves to increase the performance and efficiency of the heat pump.

Furthermore, as in 1 shown that provided by the expansion valve 3 coming refrigerant at a lower area of the collector 4 is introduced in these. In the collector 4 the refrigerant flow is calmed, liquid refrigerant settles down in the collector 4 off, while vaporous refrigerant at the top of the collector 4 lingers. Therefore, this becomes the throttle element 5 flowing liquid refrigerant at a lower portion of the collector 4 led out of this. Furthermore, this is bypassing the throttle element 5 and the evaporator 6 the compressor 1 supplied vapor refrigerant at an upper portion of the collector 4 led out of this. This collector 4 said element is alternatively referred to as a flash tank.

To the vaporous refrigerant for the intermediate injection from the collector 4 bypassing the throttle element 5 and the evaporator 6 the compressor 1 supply, the discharged refrigerant via a refrigerant pipe 8th guided.

Finally, particularly preferred embodiments of the heat pump are provided, in which the evaporator 6 is designed as a fin evaporator. Further preferred is the capacitor 2 designed as a plate capacitor.

A heat pump according to the invention is optionally designed for heating or cooling. That is, the refrigerant cycle is designed to be reversible. In this case, the conveying direction of the compressor 1 vice versa and accordingly in 2 the throttle element 5 to overheat at the compressor 1 regulated expansion valve 3 and the expansion valve 3 to the throttle element 5 ,

LIST OF REFERENCE NUMBERS

1

compressor

2

capacitor

3

expansion valve

4

collector

5

throttle element

6

Evaporator

7

control unit

8th

Refrigerant line

9

sensor

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• Xu Xing titled "INVESTIGATION OF VAPOR INJECTION HEAT PUMP SYSTEM WITH A FLASH TANK UTILIZING R410A AND LOW-GWP REFRIGERANT R32" from 2012 [0002]
• Xu Xing [0011]

Claims (10)

Method for operating a heat pump, in which a vaporous refrigerant with a compressor ( 1 ) is compressed, in which the compressed refrigerant with a condenser ( 2 ) is condensed, in which the condensed refrigerant with an expansion valve ( 3 ) is relaxed, in which the expanded refrigerant to a collector ( 4 ), whereby in the collector ( 4 ) separates a vapor phase of the refrigerant from a liquid phase of the refrigerant, wherein the liquid phase of the refrigerant is a throttle element ( 5 ) is fed and further relaxed with this, in which the expanded liquid phase of the refrigerant with an evaporator ( 6 ) is vaporized, in which the vaporized refrigerant to the compressor ( 1 ), characterized in that a measure of the overheating of the refrigerant before entering the compressor ( 1 ) and this degree of overheating as a reference variable for regulating the expansion valve ( 3 ) is used. A method according to claim 1, characterized in that for detecting the overheating of the refrigerant whose temperature and the pressure is determined. Method according to claim 1 or 2, characterized in that by means of the expansion valve ( 3 ) a determination of one in the collector ( 4 ) reaching amount of refrigerant takes place. Method according to one of claims 1 to 3, characterized in that the collector ( 4 ) via the expansion valve ( 3 ) less refrigerant is supplied when the refrigerant overheats at the compressor ( 1 ) decreases. Method according to one of claims 1 to 4, characterized in that the collector ( 4 ) via the expansion valve ( 3 ) more refrigerant is supplied when the refrigerant overheats at the compressor ( 1 ) increases. Method according to one of claims 1 to 5, characterized in that for controlling the expansion valve ( 3 ) a continuously operating electronic control unit ( 7 ), in particular a PID controller is used. Method according to claim 6, characterized in that with the electronic control unit ( 7 ) the throttle element ( 5 ) is controlled. Method according to one of claims 1 to 7, characterized in that by means of the throttle element ( 5 ) a determination of one from the collector ( 4 ) reaching amount of refrigerant takes place. Method according to one of claims 1 to 8, characterized in that the throttle element ( 5 ) is preferably controlled as a function of the operating point of the heat pump via a map. Method according to one of claims 1 to 9, characterized in that, if necessary, refrigerant, preferably exclusively vaporous refrigerant, from the collector ( 4 ) bypassing the throttle element ( 5 ) and the evaporator ( 6 ) the compressor ( 1 ) is supplied.

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