DE4318671A1 - Method for operating a (composite) refrigeration system and (composite) refrigeration system for operating this method - Google Patents

Abstract

Method for operating a "compound" refrigerating plant which alternately runs through cooling and defrosting phases, comprising a refrigerant circuit (cycle), a compressor, a condenser, a throttling (expansion) valve and an evaporator via which the cooling of the cooling agent (nonfreezing solution, secondary fluid) circulating in a cooling agent circuit is performed. After the cooling agent is cooled it is fed to one or more air (unit) (coolers) (air cooling batteries) arranged in parallel and subsequently fed again to the evaporator by means of a pump. At least a portion of the cooling agent is heated during the cooling phase in indirect heat exchange or, by means of a further cooling agent circuit arranged between the refrigerant and cooling agent circuits, by the refrigerant, which is superheated during the cooling phase in the compressor. After termination of the cooling phase, the cooling agent heated in this way circulates for the purpose of defrosting the air coolers in the cooling agent circuit.

Description

The invention relates to a method for operating a (Compound) refrigeration system, alternating cooling and defrosting phases passes through, with a refrigerant circuit, a compressor, a condenser, a relief valve and an evaporator fer containing over which the cooling of in a cold Carrier circuit circulating refrigerant takes place after its cooling one or more arranged in parallel Air coolers and then again by means of a pump Evaporator is supplied.

The invention further relates to a (composite) refrigeration system for Operate this procedure.

In refrigerated cabinets with mechanical cooling is well known Lich on the air coolers one of the refrigerated goods or the environment Airborne amount of moisture in the form of snow and ice low. Therefore, it is necessary to exchange heat Defrosting areas from time to time, so an excessively strong one To prevent frost formation, so that the heat transfer and the Air flow within the refrigerator is not adversely affected is flowing. The periodic defrosting processes are carried out by ent speaking control devices triggered. Usually are  2-6 defrosts required per cooling point in 24 hours. Around the quicker this defrosting process takes place, the lower the disruption of the operation caused by him, the better the Cooling effect.

Refrigeration systems, also as multi-unit refrigeration systems poetry per refrigeration system, are used wherever several devices at different places and / or at different where temperatures need to be supplied with cold. At for example, in a supermarket there are several chilled and deep refrigerated cabinets as well as a refrigerator or freezer as Refrigeration consumers to one cooling and one freezer network location connected.

Starting from an applicant's internal state of the art, a method for operating a (composite) refrigeration system, which alternates between cooling and defrosting phases, is described with reference to FIG. 1.

This (composite) refrigeration system consists of two independent circuits. On the one hand there is a refrigerant circuit A and on the other hand a refrigerant circuit B. These two circuits A and B are “coupled” via the evaporator 1 . The gaseous refrigerant of the refrigerant circuit A leaving the evaporator 1 is compressed in the compressor 2 , strongly overheated and supplied to the Ver liquid 3 . In this takes place the cooling and liquefaction of the refrigerant in indirect heat exchange with z. B. air instead. The refrigerant is then expanded in the expansion valve 4 and in turn fed to the evaporator 1 . In this, the evaporating refrigerant releases its cold to the coolant circulating in the coolant circuit B. For the coolant circuit, a coolant is chosen which is always in liquid form at the pressures and temperatures in the coolant circuit, i.e. does not undergo any change in the state of aggregation. The cold carrier circuit B consists of the evaporator 1 from a coolant storage 5 , one or more valves 6 , 6 ', in parallel angeord Neten. . , one or more parallel air coolers 7 , 7 ',. . and a pump 8 ; this can also involve several pumps connected in series. Each of the air coolers 7 , 7 ',. . is with an electrical resistance heater 9 , 9 ',. . Mistake.

In the event that one of the air coolers 7 , 7 ',. . defrosted who is, the corresponding valve 6 , 6 ', for the defrosting duration. . to close and the associated electrical resistance heater 9 , 9 ',. . turn on. However, this defrosting procedure has major disadvantages. On the one hand, these are the relatively high investment costs for the installed resistance heaters with the associated cabling. On the other hand, the electricity costs for the heating services to be provided must not be neglected. Furthermore, it is necessary to provide a correspondingly high connected load, especially when several evaporators are defrosted in parallel.

The aim and object of the present invention is a method Ren to operate a (composite) refrigeration system that alternates Goes through cooling and defrosting phases, specifying that the above Avoids disadvantages.

This is achieved according to the invention in that at least one Part of the coolant during the cooling phases in the indirect Heat exchange or by means of a between the refrigerant and Coolant circuit arranged further coolant circuit run from the one overheated in the compressor during the cooling phase Refrigerant is warmed up and the warmed up so heated after End of the cooling phase for defrosting the air coolers in the Coolant circuit circulates.

The inventive method for operating a (Compound) refrigeration system saves the otherwise additional electricity  costs for defrosting the evaporators. It enables about that defrosting that is gentle on the goods through short defrosting and Cooling down phases. In addition, the electrical is reduced Total connected load considerably.

The invention and further refinements thereof, in particular the methods described in the subclaims or the refrigeration system described, are explained in more detail with reference to FIGS. 2 to 5. Identical components have the same reference numbers.

Fig. 2 shows the inventive method for operating a (composite) refrigeration system (hereinafter referred to nurmehr refrigeration system). The refrigeration system in turn consists of 2 voneinan the independent circuits. On the one hand there is a refrigerant circuit A and on the other hand a refrigerant circuit B. The latter has 2 coolant stores, namely a so-called "cold" coolant store 5 and a so-called "warm" coolant store 5 '. The cold storage tank 5 and 5 'can be integrated into the coolant circuit B by means of the valves 10 and 11 or 12 and 13 .

During the cooling phases, the valves 12 and 13 are closed and the valves 10 and 11 are opened, so that the coolant circulates from the cold coolant store 5 in the coolant circuit B and dissipates the heat absorbed via the air coolers 7 and 7 'from the respective refrigeration units. Again, it goes without saying that in addition to the two air coolers shown in this and the following figures, further air coolers can be arranged in parallel. The refrigerant circuit A is also in operation during the cooling phase in order to absorb the heat absorbed by the refrigerants in the air coolers 7 and 7 'by evaporating the refrigerant in the evaporator 1 and to release it via the condenser 3 . In addition, the compressed superheated refrigerant also gives off heat to the coolant stored in the coolant storage 5 '. The refrigerant circuit is switched over for the defrost phase. For this purpose valve 11 is closed and valve 13 is opened. The cold coolant from the coolant circuit B is fed or "pressed" into the cold coolant storage 5 via the still open valve 10 , so that the liquid level rises here. At the same time, the warm coolant flows out of the coolant store 5 'into the circuit via the open valve 13 , so that the liquid level in the coolant store 5 ' drops. The two coolant storage 5 and 5 'are open containers which are connected to one another via an overflow line. When the cold coolant has completely reached the "cold" coolant store 5 , valve 12 is opened and valve 10 is closed. The warm coolant is now pumped around in the coolant circuit B by means of the pump 8 until the air coolers 7 and 7 'are defrosted independently. After the defrosting process is completed, valve 13 is closed and valve 11 is opened. In this way reaches the reverse traffic th effect as at the beginning of the defrosting process, that is, the circulating during the defrosting operation in the secondary refrigerant circuit B warm refrigerant is conveyed into the refrigerant memory 5 'and the cold heat transfer fluid from the "cold" refrigerant accumulator 5 flows back into the coolant circuit B. Then valve 12 is closed and valve 10 is opened. The refrigerant circuit is put back into operation and the cooling of the air coolers 7 and 7 'begins.

The refrigeration system shown in Fig. 3 consists of 2 refrigerant circuits A and A 'and 2 refrigerant circuits B and B'. For the sake of clarity, the presentation of the refrigerant stores 5 , 5 ', 15 and 15 ' upstream and downstream valves has been omitted. The in the refrigerant circuit A through the evaporator 1 , the compressor 2 , the Verflüs siger 3 and the expansion valve 4 circulating refrigerant heats the refrigerant stored in the "warm" refrigerant storage 15 'of the refrigerant circuit B', while that in the refrigerant circuit A 'by the Evaporator 1 ', the United poet 2 ', the condenser 3 'and the expansion valve 4 ' circulating refrigerant warms the coolant of the coolant circuit B stored in the "warm" coolant storage 5 '. With this procedure, the waste heat of the refrigerant circuit in operation can be supplied to the "warm" coolant reservoir of the circuit to be defrosted during the defrosting of a refrigerant circuit. This means e.g. B. that during the defrosting of the refrigerant circuit B 'of the' warm 'refrigerant storage 15 ' circulating refrigerant is heated by the refrigerant of the refrigerant circuit A.

This approach has two advantages. First, ver the defrost time is reduced because the warm coolant during the Defrost phase is heated. On the other hand, the vorzu decreases Keeping warm coolant quantity, as a continuous heating during the defrost phase by the refrigerant of the other refrigerant circuit. In this procedure then, however, must then cold during the defrosting of one carrier cycle, so z. B. the refrigerant circuit B ' Refrigerant circuit A must be switched on.

Fig. 4 shows a further embodiment of the method according to the invention. Here, in addition to two coolant circuits B and B 'and two refrigerant circuits A and A', a further coolant circuit c is provided. About the evaporator 21 , the refrigerant circuit A and the refrigerant circuit B, which is located at a so-called "normal cooling temperature level" of about -10 ° C, coupled to each other, while via the evaporator 21 'the refrigerant circuit A' is coupled to the refrigerant circuit B ' , the latter being at a so-called "freezing temperature level" of approximately -35 ° C. The in the refrigerant circuits A and A 'circulating refrigerant is compressed by means of the compressors 22 and 22 ', the condenser 1 and 1 'supplied and in this in indirect heat exchange against a heat carrier to be heated, which is supplied via lines 44 and 45 , liquefied. The liquefied refrigerant is then expanded in the expansion valves 20 and 20 ', providing cooling, and supplied to the evaporators 21 and 21 '. In these, it is heated and evaporated in indirect heat exchange with the coolants to be cooled from the coolant circuits B and B '. The heat given off in the condensers 1 and 1 'to the coolant is, after temporary storage in the coolant reservoir 31, via the lines 40 and 41 and 42 and the control valves 32 and 33 and 34 either the recooler 3 or in the coolant stores 5 'or 15 ' provided shear heat exchanger supplied. The coolant supplied via line 40 to the recooler 3 is, after it has cooled by means of the pump 30, in turn via lines 44 and 45 to the condensers 1 and 1 ', respectively. Upstream of the pump 30 , the supply of the cooled subcurrent of the coolant removed via the line 43 from the coolant stores 5 'and 15 '.

Fig. 5 shows a further embodiment of the method according to the invention, again consisting of two refrigerant circuits A and A ', two refrigerant circuits B and B' and another refrigerant circuit C. Again, the refrigerant circuit A and the refrigerant circuit B are at "normal cooling temperature level", while in Refrigerant circuit A 'and refrigerant circuit B'"freezing temperature level" prevails. In the present case, the heat released in the condenser 1 'of the refrigerant circuit A' is not released to the coolant of the additional coolant circuit C but to the partial coolant stream of the coolant circuit B branched off via line 50 . The heated in the condenser 1 'of the refrigerant circuit B is fed back via line 51 into the refrigerant circuit B. This variant is advantageous for compressors 22 'of the refrigerant circuit A', which are restricted in the area of application with regard to pressure and / or temperature ratio, since the end pressure and the condensation temperature are lower in comparison with FIG. 4.

The defrosting of the refrigerant circuit B 'takes place in the same manner as in FIGS . 3 and 4. However, with this procedure, the networking of the two refrigerant circuits A and A' has a disadvantageous effect on the defrosting of the refrigerant circuit B. During the defrosting phase of the air coolers 7 and 7 ', the refrigerant circuit A' must be switched off for application reasons. However, this means that the air coolers 17 and 17 'of the refrigerant circuit B' are no longer adequately cooled. In this case, it is advisable to cool the refrigerant circuit B 'beforehand and to save the refrigeration power in the "cold" refrigerant storage 15 .

It is obvious to the person skilled in the art that, in addition to the procedures of the method according to the invention shown in FIGS. 2 to 5, further variants, which cannot be discussed in detail here, would be conceivable.

Claims (4)

1.Method for operating a (composite) refrigeration system, which alternately goes through cooling and defrosting phases, with a refrigerant circuit, comprising a compressor, a condenser, a pressure relief valve and an evaporator, via which the cooling medium circulating in a cooling medium circuit is cooled, which after its cooling one or more air coolers arranged in parallel and then fed back to the evaporator by means of a pump, characterized in that at least a part of the coolant during the cooling phases in the indirect heat exchange or by means of a further arranged between the coolant and coolant circuit The coolant circuit is heated by the overheated refrigerant in the compressor during the cooling phase and the heated coolant circulates after the end of the cooling phase to defrost the air coolers in the coolant circuit. 2. Procedure for operating a (composite) refrigeration system Claim 1, preferably a combination at least two (compound) refrigeration systems, especially one normal cooling and a freezer (composite) refrigeration system, thereby characterized in that at least part of the refrigerant  of the first coolant circuit from the refrigerant second refrigerant circuit heated and at least one Part of the coolant of the second coolant circuit of the refrigerant of the first refrigerant circuit is warmed. 3. Procedure for operating a (composite) refrigeration system Claim 1, preferably a combination at least two (compound) refrigeration systems, especially one normal cooling and a freezer (composite) cooling system, as well as min least another refrigerant circuit, thereby ge indicates that the heating and / or liquefaction of the refrigerants circulating in the refrigerant circuits through indirect heat exchange with the coolant another coolant circuit and so heated coolant at least part of the coolant gers of the first and the second refrigerant circuit warmed up. 4. (Compound) refrigeration system to operate the process according to Claims 1 to 3, characterized in that the or the refrigerant circuits between the evaporator and the or the air coolers arranged parallel to one another Have "warm" and a "cold" coolant storage and a heat exchanger in the "warm" coolant storage is provided.