EP2005076A1 - Method for operating a refrigerating device comprising evaporators which are connected in parallel and refrigerating device therefor - Google Patents

Abstract

The invention relates to a method for operating a refrigerating device comprising a refrigerating circuit (15; 25; 35; 45) equipped with two evaporators (16, 17) which are arranged in a parallel manner in relation to each other and which cool refrigerating compartments (12, 13) that are thermally separated from each other and that have different temperatures, and also a refrigerating compressor (22) with which both evaporators (16, 17) can be supplied separately with a coolant. According to the invention, when a first compartment (12) requires a coolant, the evaporator (17) of the second compartment is initially supplied with a coolant, in a preparation step, and then the coolant circuit is closed to the evaporator (17) of the second compartment (13), and then only the evaporator (16) of the first compartment (12) is supplied with the coolant. In said preparation step, fluid coolant which is enriched in the evaporator of the second refrigerating compartment is flushed out such that it can be reused in the evaporator of the first refrigerating compartment. As a result, the coolant is displaced towards the evaporator of the coolest of the two refrigerating compartments, said displacement can be produced in the stationary phase of the coolant compressor and can be achieved in a simple and economical manner.

Description

Method for operating a refrigeration device with a parallel connection

Evaporators and refrigeration equipment for it

The present invention relates to a method for operating a refrigeration device with a refrigerant circuit having two evaporators arranged parallel to one another, which cool thermally separated cold compartments, which may have different compartment temperatures, and a compressor, with which both evaporators can be acted upon separately from each other with refrigerant. In addition, the present invention relates to such a refrigeration device for carrying out the operating method according to the invention.

From DE 199 57 719 A1, a refrigerator-freezer combination device is known, in which the refrigerating compartment and the freezer are arranged with arranged in parallel to each other, supplied by one and the same evaporator evaporators. A solenoid valve allows the refrigerator compartment evaporator and the freezer compartment evaporator to be charged separately with refrigerant, which allows separate control of the temperature of both compartments.

However, a parallel connection of the refrigerator compartment evaporator and the freezer compartment evaporator entails that refrigerant which is vaporized during the downtime of the compressor due to the different temperatures of the two evaporators in the refrigerator compartment evaporator tends to flow and condense in the freezer compartment evaporator. If, subsequently, the compressor is switched on due to a cold request of the refrigerating compartment and refrigerant is circulated through the refrigerating compartment evaporator, the available quantity of refrigerant is small and the achievable cooling capacity is low, so that long compressor running times are required or, in extreme cases, even malfunctions can occur.

In order to alleviate this problem, DE 199 57 719 A1 proposes that a section of the freezer evaporator, in which refrigerant collects during the stoppage phase of the compressor, be designed such that this section, with regard to its refrigerant intake volume, is at least almost completely filled with liquid refrigerant is designed in the stoppage phase of the compressor, and so too placing, that when the compressor is turned on due to a refrigeration request of the refrigerating compartment, the refrigerant flowing through the refrigerant circuit of the controlled refrigeration compartment evaporator entrains the liquid refrigerant from said portion of the freezer compartment evaporator, thereby transferring it into the refrigerant circuit of the controlled refrigeration compartment evaporator. The disadvantage, however, is that the entrainment effect is the weaker the smaller the mass flow rate through the refrigerating compartment evaporator. That is, the more liquid refrigerant has collected in the freezer compartment evaporator, the smaller is the rate at which it can be withdrawn from the freezer compartment evaporator and fed back to the refrigerant flow through the refrigerated compartment evaporator. This also results in extended compressor run times and thus increased energy consumption of the refrigerator. A complete solution of the problem is not reached yet.

The present invention has for its object to provide an operating method for an initially described refrigerator with mutually parallel evaporators and a refrigerator for performing the operating method, which allow a simple and inexpensive operation of the refrigerator.

The object is achieved with an operating method according to claim 1 and a refrigerating appliance according to claim 8. The dependent claims relate to preferred embodiments.

Accordingly, a method for operating a refrigeration device is provided, which has a refrigerant circuit comprising two mutually parallel evaporators of different refrigeration capacity, the cooling compartments thermally separated from each other, and a compressor with which both evaporators can be acted upon separately from each other with refrigerant. According to the invention, in a first cooling fan in a preparation step, first the evaporator of higher refrigeration capacity is supplied with refrigerant, then the refrigerant circuit is closed to this evaporator, ie a supply of refrigerant to this evaporator is prevented, and only the evaporator of lower refrigeration capacity is supplied with refrigerant , By providing in the preparation step admission of the evaporator higher cooling capacity with refrigerant liquid refrigerant, which is during the standstill phase of the compressor in the evaporator higher cooling capacity could have accumulated, pushed out of this and thus is also the refrigerant circuit of the evaporator lower cooling capacity available again. Thus, a shift of refrigerant to the colder of the two compartments, which occurs during the stoppage phase as described above, can be remedied in a simple, quick and energy-saving manner. The second refrigeration compartment, which is activated in the preparation phase, is therefore generally the one that has a lower compartment temperature than the first refrigeration compartment.

Preferably, the refrigerant circuit is closed to the evaporator of lower cooling capacity in the first compartment during the preparation step. Thus, only the evaporator higher cooling capacity is controlled in the second compartment and charged with refrigerant. The advantage of this is that only through an evaporator refrigerant must be promoted, which can be saved by the compressor energy. Thus, only the one compartment, namely the colder of the two compartments, in which a certain amount of liquid refrigerant has accumulated during the stoppage phase of the compressor, is preferably activated.

However, it is also possible to control both evaporators in the preparation step and to pressurize with refrigerant. Advantage of this is that both subjects can be treated the same, which simplifies the control logic. If the compartment that signals the refrigeration demand is the colder of the two compartments, a brief circulation of refrigerant through the warmer compartment before the colder one is supplied will not be disadvantageous except for a slightly delayed onset of refrigeration. Appropriately, the ability to preliminarily pressurize both evaporators with refrigerant, even in a refrigerator, which is not already determined by its construction, which of the subjects must have the lower operating temperature, since then at start-up of the compressor due to a refrigeration demand in one of the subjects It is not necessary to determine which one is the colder and thus primarily to be controlled subject of the two subjects.

Preferably, the preparation step is performed over a certain period of time after start-up of the compressor. The time span is chosen so that the evaporator of the - A -

first cold compartment after the preparation step, a sufficient or almost the entire amount of refrigerant can be provided.

Alternatively, the work done by the compressor can be measured and the preparation step completed when the work done reaches a predetermined level. Thereby, the duration of the preparation step becomes longer as the amount of liquid refrigerant accumulated in the colder evaporator becomes large and the refrigerant pressure against which the compressor operates is accordingly small, and it becomes shorter when the accumulated amount of the liquid refrigerant is small.

The compressor may be preceded by a refrigerant collector, which receives the flushed out during the preparation step from the evaporator of the second refrigeration compartment and optionally from the evaporator of the first refrigeration compartment, liquid refrigerant.

The present invention further includes a refrigerator for carrying out the above-described method of operation. Accordingly, a refrigeration device is provided with a refrigerant circuit, the two parallel arranged evaporators, the thermally separated cooling cold compartments, which may have different compartment temperatures, and a compressor, with both evaporators can be acted upon separately from each other with refrigerant. Furthermore, the refrigeration device comprises a control device for controlling the supply of refrigerant to the evaporators. According to the invention, the control device is set up to cause refrigerant to be supplied to the evaporator of the second compartment during a refrigeration requirement in a first of the compartments in a preparation step, then the refrigerant circuit to the evaporator of the second compartment is closed and only the evaporator of the first compartment is closed is charged with refrigerant.

Preferably, the control device has a valve with a first working position, in which the evaporator of the first compartment can be acted upon with refrigerant, and a second working position, in which the evaporator of the second compartment can be acted upon with refrigerant. The valve may be, for example, a 3/2-way valve. If the refrigerant circuit comprises only one such valve, then the refrigeration device can be operated such that only the second, colder evaporator is supplied with refrigerant in the preparation step. Preferably, the valve in addition to said first and second working position on a third working position, in which both evaporators can be acted upon with refrigerant. This makes it possible to use a single in the refrigerant circuit upstream of the evaporator valve, for example, a 4/3-way valve, a mode of operation of the refrigerator, are acted upon in the preparation step, both evaporators with refrigerant to flush out located in the evaporators liquid refrigerant ,

In addition to the above-described features of the refrigerator with only a single valve to control the refrigerant supply to the evaporators, it is also possible to provide a refrigerator, which has two valves with two working positions to control the refrigerant supply to the evaporators, wherein in a first working position of a In a second working position of the first valve and a first working position of the first valve downstream second valve of the evaporator of the second compartment can be acted upon with refrigerant, and in the second operating position of the first valve and a second working position of the second valve, the evaporator of both compartments can be acted upon with refrigerant. The two valves may be, for example, 3/2-way valves.

The refrigeration device according to the invention preferably has a retaining device, such as a check valve, for preventing undesired refrigerant flow in a connecting line between the two evaporators. Such a connection line is present, for example, when an output of a valve upstream of the evaporator is connected to both evaporators.

In a further alternative embodiment of the refrigeration device according to the invention, each evaporator for controlling the refrigerant supply in the refrigerant circuit is preceded in each case by a valve which can be switched between an open position and a closed position. This makes it possible to operate the refrigeration device such that in the preparation step when the compressor starts up, both valves are opened in order to flush out liquid refrigerant from both evaporators and subsequently, for example after a certain period of time to close the valve of the evaporator, which has reported no need for refrigeration.

The aforementioned valves for controlling the refrigerant supply to the evaporators are preferably electrically controllable valves, for example solenoid valves.

The refrigeration device according to the invention is preferably a cooling device, a freezer or a refrigerator-freezer combination device.

Further embodiments and advantages of the present invention will be explained below with reference to several embodiments of the present invention. Showing:

Fig. 1 shows a schematic representation of a refrigerator according to a first embodiment with two thermally separated cold storage compartments 12, 13, which have different compartment temperatures and in a refrigerant circuit

15 arranged in parallel circuit evaporators 16, 17 are cooled with a common compressor 22, wherein the evaporators 16, 17 in the refrigerant circuit 15, a 3/2-way solenoid valve 18 is connected upstream.

2 is a schematic representation of a second embodiment of a refrigeration device in which the two evaporators 16, 17, a 4/3-way solenoid valve 28 is connected upstream;

Fig. 3 in a schematic representation of a third embodiment of a refrigeration device, in which the two evaporators 16, 17 two successively arranged 3/2-way solenoid valves 38, 48 are connected upstream.

Fig. 4 shows a schematic representation of a fourth embodiment of a refrigeration device, in which each evaporator 16 and 17, a respective 2/1 -way solenoid valve 58, 68 is connected upstream.

In Fig. 1, a household refrigerating appliance is shown in a highly schematic representation, in its heat-insulating housing 1 1 two superimposed cold shelves 12 and 13th are located. These are thermally separated from each other by a thermally insulating intermediate bottom 14. During operation of the refrigeration device, the two cold storage compartments 12 and 13 have different compartment temperatures. These may be refrigerators or freezers.

The refrigeration compartments 12, 13 are cooled by means of a refrigerant circuit 15 with two evaporators 16, 17 arranged in parallel, the evaporator 16 being associated with the first, upper compartment 12 of the evaporator 16 and the second, lower compartment 13. The evaporators 16 and 17 are shown as coldwall evaporators, which are each mounted on the insulating side on an inner wall of the compartments 12 and 13 and which have a circuit board on which a refrigerant line is formed meandering. Notwithstanding the illustrated embodiment, however, the evaporators 16, 17 may be formed as arranged horizontally in the tray 12 or 13, passing through the compartment wire tube evaporator, for example, when it comes to the cold shelves 12 or 13 are freezers. Also, an evaporator in no-frost construction, which is housed in a separated from the compartment 12 and 13 and communicating with him by a forced ventilation chamber, comes into consideration.

The refrigerant circuit 15 has a single compressor 22. To the compressor 22, a condenser 19 is connected on the pressure side, which is connected on its output side with an electrically controllable 3/2-way solenoid valve 18. An output of the solenoid valve 18 is connected via a throttle tube 20 to the evaporator 16 of the first refrigeration compartment 12 and a further output of the solenoid valve 18 via a further throttle pipe 21 to the evaporator 17 of the second refrigeration compartment 13. The throttle tubes 20 and 21 are spirally formed and are used to reduce the pressure of the condenser 19 to the evaporators 16, 17 flowing liquid refrigerant.

The evaporators 16 and 17 are the output side connected to the suction side of the compressor 22, wherein the compressor 22, a refrigerant collector 23 is connected upstream. This takes from the two evaporators 16, 17 effluent liquid refrigerant and prevents liquid refrigerant can get into the compressor 17. The 3/2-way solenoid valve 18 is used to control the forcibly circulated by the compressor 22 refrigerant to the evaporators 16 and 17 out. In a working position I of the solenoid valve 18, liquid refrigerant is fed via the throttle 20 exclusively to the evaporator 16 of the first refrigerating compartment 12, ie the refrigerant circuit to the evaporator 17 is closed. In addition to the working position I, the solenoid valve 18 has a working position II, in which the forcibly circulated, liquefied refrigerant is fed via the throttle 21 exclusively to the evaporator 17 of the second refrigerating compartment 13, ie, the refrigerant circuit to the evaporator 16 is closed.

In each of the cold shelves 12, 13 is ever a temperature sensor 24 and 26, which measures the respective compartment temperature or evaporator temperature and forwards it to an evaluation unit 30, which is part of a control device of the refrigerator, which controls the refrigerant supply to the evaporators 16, 17 , The evaluation unit 30 controls the solenoid valve 18, which is also part of the control device, as a function of the temperatures detected by the temperature sensors 24 and 26, respectively, and gives this one of the working positions.

The household refrigerating appliance shown in Fig. 1 is operated by at each startup of the compressor 22 due to a refrigeration demand in one of the cold storage compartments 12, 13 first the evaporator of the coldest compartment is controlled via the solenoid valve 18 and charged with refrigerant. As a result, the accumulated in the colder evaporator refrigerant is purged, making it the refrigerant circuit of the warmer refrigeration compartment can be made available again.

In a KühlVGefrier combination device, which will now be assumed below, the temperature ranges of the two compartments are fixed, so that a fixed assignment of the working positions I or Il of the solenoid valve 18 to the colder of the two evaporators 16, 17 is. For example, if the first compartment 12 in a temperature range of about + 4 ^ to +8 ⁹ C and the second compartment 13 operated in a temperature range of about -18 ° C to - 22 ° C, so is on the working position Il of the solenoid valve 18 of Evaporator 17 of the colder compartment 13 is driven. If a cooling requirement of the warmer refrigeration compartment 12 is determined via the temperature sensor 24, the solenoid valve 18 is initially brought into its working position II when the compressor 22 starts up in a preparatory step. As a result, refrigerant is forced through the throttle 21 into the evaporator 17 of the colder refrigeration compartment 13. These refrigerants may be gaseous at the beginning of operation of the compressor or, if liquid, evaporate rapidly upon entry into the evaporator 17, so that a large volume flow is achieved in the evaporator 17 using a small mass of refrigerant. As a result of this volume flow, the liquid refrigerant accumulated during the standstill phase of the compressor 22 is forced out of the evaporator 17, the mass of refrigerant used for pushing out, since vapor, being substantially smaller than that of the liquid refrigerant forced out. The squeezed refrigerant is first received by the refrigerant collector 23 located on the suction side of the compressor 22.

To supply the evaporator 16 of the warmer refrigeration compartment 12 with liquid refrigerant, the solenoid valve 18 is switched to its working position I. Switching can take place, for example, after a set period of time after compressor start-up in which the refrigerant has been flushed out of the evaporator 17. Under the low pressure prevailing on the suction side of the compressor 22, the refrigerant gradually evaporates in the refrigerant collector 23 and is then available again to the refrigerant circuit of the warmer refrigerating compartment 12.

In order to set the switching timing, the work performed by the compressor 22 since the power is turned on may also be monitored and switched over when this work exceeds a predetermined value. Namely, the smaller the amount of refrigerant to be expelled from the evaporator 17, the higher the pressure against which the compressor 22 operates. Thus, the switching is faster, if the amount of refrigerant to be expelled is small. Alternatively, the power of the compressor may also be monitored and switched when an increase in compressor power suggests that the liquid refrigerant taken up in the refrigerant collector 23 begins to evaporate.

Are the cold storage compartments 12 and 13 with respect to their compartment temperatures variable, so depending on the device setting or operating state, the first refrigeration compartment 12 or the second refrigeration compartment 13th may have the lower temperature range, then one of the compartments 12, 13 is determined by means of the temperature sensors 24, 26, which is the momentarily colder and thus to be controlled in the preparation step at a refrigeration request.

FIG. 2 also shows a schematic representation of a second embodiment of a refrigeration device which, in accordance with the refrigerator shown in FIG. 1, has two cold compartments 12 and 13 with different compartment temperatures which are thermally separated from one another, and evaporators 16 arranged in parallel to one another in a refrigerant circuit 25 , 17 are chilled. For controlling the refrigerant feed to the

Evaporators 16, 17, the refrigerant circuit 25 has a 4/3-way solenoid valve 28. A first output of the solenoid valve 28 is via a throttle tube 20 directly to the evaporator

17 of the upper refrigeration compartment 12 connected. A second output of the solenoid valve 28 is connected via a throttle pipe 21 directly to the evaporator 17 of the lower refrigeration compartment 13. A third output of the solenoid valve 28 is via a connection line

31, a branch point 32 and a branch line 33, which branches off to the throttle tube 20, both to the evaporator 16 of the upper refrigeration compartment 12 and over the

Connecting line 31, the branch point 32 and a branch line 34 to the throttle tube

21 branches off, connected to the evaporator 17 of the lower refrigeration compartment 13.

In a first working position I of the solenoid valve 28, which releases the first output, there is only the evaporator 16 of the upper refrigeration compartment 12 in

Refrigerant circuit with the compressor 22. In a second operating position Il des

Solenoid valve 28, which releases the second output, is located exclusively the

In a third working position III, which releases the third output of the solenoid valve 28, both evaporators 16, 17 are coupled into the refrigerant circuit to the compressor 22, so that both evaporators 16, 17 at the same time Refrigerants can be acted upon. In order to prevent an overflow of the refrigerant in the working positions I and Il via the branch lines 33, 34 in the respective other, not to be supplied evaporator, located in each

Branch line a check valve 36 and 37th

If a cooling requirement in one of the cold storage compartments 12, 13 is determined by the evaluation unit 30 via the temperature sensors 24, 26, then the compressor 22 starts up in one Preparing step that solenoid valve 28 first placed in the working position III, in which both evaporators 16, 17 are in the refrigerant circuit with the compressor 22 and thus acted upon with refrigerant. As a result, the liquid refrigerant accumulated in both evaporators 16, 17 is flushed out and initially taken up by the refrigerant collector 23. In accordance with the embodiment described with reference to FIG. 1, the solenoid valve 28 is now switched to the refrigeration demand reporting refrigeration compartment 12 or 13 in its corresponding working position I or II, which either exclusively the evaporator 16 of the upper refrigeration compartment 12 or exclusively the evaporator 17 of the lower cooling compartment 13 are brought into the refrigerant circuit with the compressor 22 and charged with refrigerant. The preparatory step has the effect that the evaporator 16 or 17 requesting cooling is provided with a sufficient amount of refrigerant or almost the entire amount of refrigerant in the refrigerant circuit 25.

Fig. 3 shows a third embodiment, in which, in accordance with that of Fig. 2, a simultaneous control of both evaporators 16, 17 is possible. At this

Embodiment are the two evaporators in the refrigerant circuit 35 two 3/2-way

Solenoid valves 38, 48 connected upstream. A first 3/2-way solenoid valve 38 is connected to the condenser 19 on the input side. A first output of the solenoid valve 38 is over the

Throttle tube 20 is connected directly to the evaporator 16 of the upper refrigeration compartment 12, and a second output of the solenoid valve 38 is connected to the input of the second 3/2-way

Solenoid valve 48 connected. A first output of the second solenoid valve 48 is via the

Throttle pipe 21 is connected directly to the evaporator 17 of the lower refrigeration compartment 13. A second output of the second solenoid valve 48 is connected via a connecting line 40 and a

Branch point 42 on the one hand via a branch line 43 via the throttle tube 20 to the evaporator 16 of the upper refrigeration compartment 12 and on the other hand connected via a branch line 44 via the throttle tube 21 to the evaporator 17 of the lower refrigeration compartment 13. The

Branch lines 43, 44 each include a check valve 36, 37, respectively.

In a first working position I of the first solenoid valve 38, which releases the first output, there is only the evaporator 16 of the colder compartment 12 in the refrigerant circuit with the compressor 22. This position can be selected when only the compartment 12 reports refrigeration demand. In a working position Il of the first solenoid valve 38 and in a working position I of the second solenoid valve 48 is exclusively the evaporator 17 of the lower refrigeration compartment in the refrigerant circuit with the compressor 22. In the working position Il of the first solenoid valve 38 and a working position Il of the second solenoid valve are both compressors 16, 17 in the refrigerant circuit with the compressor 22nd

When the warmer compartment 13 indicates refrigeration demand, the solenoid valves 38 and 48 are first brought into a second phase at the start of the compressor 22 in each case to their second working position Il to rinse liquid refrigerant from the evaporators 16, 17. Subsequently, the valve 48 is switched to its working position I to pressurize only the evaporator 17 with refrigerant.

In the fourth embodiment shown in FIG. 4, each of the evaporators 16, 17 is preceded by a 2/1-way solenoid valve 58 or 68, which is located in the respective direct supply line to the respective evaporator 16, 17. The solenoid valves 58, 68 are therefore as well as the evaporators 16, 17 arranged in the refrigerant circuit 45 in parallel to each other. The solenoid valves 58 and 68 each have an open position and a closed position. About the evaluation unit 30, the solenoid valves 58 and 68 are driven.

When a refrigeration demand in one of the cold storage compartments 12 or 13, initially both solenoids 58 and 68 are brought into their open position at start-up of the compressor, whereby both evaporators 16, 17 are acted upon with refrigerant, whereby in the evaporators 16, 17 befindliches, liquid refrigerant is rinsed out. If a sufficient amount of water is flushed out, the refrigeration compartment 12 or 13, which does not request refrigeration, is decoupled from the refrigerant circuit 45 by bringing the respective upstream solenoid valve 58 or 68 into its closed position.

Claims

claims

1 . Method for operating a refrigeration device having a refrigerant circuit (15; 25; 35; 45) with two evaporators (16, 17) of different refrigerating capacity arranged in parallel, which cool thermally separated cold compartments (12, 13), and a compressor (22), with the two evaporators (16, 17) are separated from each other acted upon with refrigerant, characterized in that when a cooling demand in a first (12; 13) of the compartments in a preparation step initially at least the evaporator (17; 16) higher refrigerant power supplied with refrigerant Then, the refrigerant circuit to this evaporator (17; 16) is closed and only the evaporator (16;

17) lower refrigerant capacity is supplied with refrigerant.

2. The method according to claim 1, characterized in that in the preparation step, both evaporators (16, 17) are acted upon by refrigerant.

3. The method according to claim 1, characterized in that in the preparation step, the refrigerant circuit to the evaporator (16; 17) of the first compartment (12; 13) is closed.

4. The method according to any one of the preceding claims, characterized in that the preparation step over a certain period of time after start-up of the compressor (22) is performed.

5. The method according to any one of claims 1 to 3, characterized in that the preparation step is carried out until the power of the compressor (22) a

Exceeds limit.

6. The method according to any one of claims 1 to 3, characterized in that the preparation step is carried out until the power of the compressor (22) exceeds a limit.

A method according to any one of the preceding claims, characterized in that the second compartment (13; 12) has a lower compartment temperature than the first compartment (12; 13).

8. Refrigeration appliance for carrying out an operating method according to one of the preceding claims with a refrigerant circuit (15; 25; 35; 45) having two evaporators (16, 17) of different refrigerating capacity arranged in parallel to one another and cooling refrigeration compartments (12, 13) thermally separated from each other, a compressor (22), with which both evaporators (16, 17) can be acted upon separately with refrigerant, and a control device (30) for controlling the supply of refrigerant to the evaporators (16, 17), characterized in that the control device (30) is arranged to cause, when a refrigerant demand in a first (12; 13) of the subjects, in a preparation step, at least the evaporator (17; 16) of higher cooling capacity (13; 12) is supplied with refrigerant, then the refrigerant circuit to this Evaporator (17; 16) is closed and only the evaporator (16; 17) lesser

Cooling capacity is supplied with refrigerant.

9. Refrigerating appliance according to claim 8, characterized in that the control device a valve (18, 28) with a first working position (I), in which the evaporator (16) of the first compartment (12) can be acted upon with refrigerant, and a second

Working position (II), in which the evaporator (17) of the second compartment (13) can be acted upon with refrigerant.

10. Refrigerating appliance according to claim 9, characterized in that the valve (28) has a third working position (III), in which both evaporators (16, 17) can be acted upon with refrigerant.

1 1. Refrigerating appliance according to claim 10, characterized in that it is the valve (28) is a 4/3-way valve.

12. Refrigerating appliance according to claim 8, characterized in that the control device has two valves (38, 48), each with two working positions (I, II), wherein in a first working position (I) of a first (38) of the valves of the evaporator

(16) of the first compartment (12) can be acted upon with refrigerant, in a second working position (II) of the first valve (38) and a first working position (I) of the first valve (38) downstream of the second valve

(48) the evaporator (17) of the second compartment (13) can be acted upon with refrigerant, and in the second working position (II) of the first valve (38) and a second working position (II) of the second valve (48), the evaporator (16 , 17) of both compartments (12, 13) can be acted upon with refrigerant.

13. Refrigerating appliance according to claim 12, characterized in that it is the valves to 3/2-way valves.

14. Refrigerating appliance according to one of claims 10 to 13, characterized by a retaining device, in particular a check valve (36, 37), for preventing a flow of refrigerant in a connecting line (33, 34, 43, 44) between the two evaporators (16, 17).

15. Refrigerating appliance according to claim 8, characterized in that each evaporator (16, 17) in the refrigerant circuit (58) in each case a valve (58, 68) is connected upstream, which is switchable between an open and a closed position.

16. Refrigerating appliance according to one of claims 8 to 15, characterized in that it is the valves (18; 28; 38,48; 58,68) are electrically controllable valves, in particular solenoid valves.