DE102013005476A1 - Fridge and / or freezer - Google Patents

Abstract

The present invention relates to a refrigerator and / or freezer with at least one refrigerated compartment and at least one refrigerant circuit having at least one compressor and at least one evaporator for cooling said compartment and at least one upstream of the evaporator in the flow direction of the capillary arranged capillary the refrigerant circuit has a valve arranged upstream of the capillary, which communicates with the capillary in such a way, with the capillary being flowed through depending on the valve position with refrigerant, and wherein at least one control or regulating unit is provided, which communicates with the valve and the is designed such that it adjusts the valve position in response to the cooling demand prevailing in the compartment.

Description

The present invention relates to a refrigerator and / or freezer with at least one refrigerated compartment and at least one refrigerant circuit having at least one compressor and at least one evaporator for cooling said compartment and at least one arranged upstream of the evaporator capillary.

Cooling and / or freezing appliances known from the prior art usually have a refrigerant circuit which has a compressor, a condenser, a capillary as a throttle element and an evaporator. In the compressor, the refrigerant is compressed, the compressed refrigerant is supplied to the condenser and passes under the release of heat from the gaseous to the liquid state. The liquefied refrigerant in this way then enters the capillary, where it experiences a pressure drop. From the capillary, the refrigerant flows into the evaporator, in which it passes from the liquid to the gaseous state and thereby absorbs heat from the compartment to be cooled. The gaseous refrigerant then passes again via a suction line to the compressor, so that a total of a closed refrigerant circuit is present.

From the prior art it is further known that in the cooled interior of the device at least one temperature sensor is provided which determines the actual value of the temperature. This is compared with a setpoint. The compressor is turned on and off in response to this comparison, causing the temperature in the refrigerated compartment to fluctuate around a set point.

If a constant temperature is to be maintained, the compressor would have to run in continuous operation.

In known devices, the compressor is designed such that it always provides a sufficient cooling capacity or a sufficient flow rate of refrigerant in the storage of goods. If such a compressor is operated in continuous operation for the purpose of keeping the temperature constant, this has the disadvantage that a very low temperature is set in continuous operation. Because in order to provide a sufficient cooling capacity at a storage of goods, the performance of the compressor is usually much higher than is necessary to maintain the temperature typically set.

If the compressor is operated to keep the temperature constant in continuous operation, this results in a correspondingly increased energy consumption, which is above the energy consumption during normal operation of the device.

The present invention is based on the object to provide a refrigerator and / or freezer of the type mentioned, in which with low energy consumption, a constant or substantially constant temperature in the refrigerated space, in particular in a freezer can be achieved.

This object is achieved starting from a refrigerator and / or freezer with the features of the preamble of claim 1, characterized in that the refrigerant circuit has at least one arranged upstream of the capillary valve, which is in communication with the capillary, that the capillary depending on the valve position It is flowed through with refrigerant, and that at least one control or regulating unit is provided, which communicates with the valve and which is designed such that it adjusts the valve position in dependence on the cooling demand prevailing in the compartment.

Thus, in one embodiment, it can be achieved that the refrigeration capacity can be regulated by a cyclic activation of the solenoid valve, while the compressor is constantly in operation. In one position of the solenoid valve, refrigerant may flow through the at least one capillary, while the refrigerant in the other position may not flow through the at least one capillary. If necessary, the compressor can continue to operate without the internal temperature dropping too far. The reduced power consumption also reduces the flow rate of the compressor.

In one embodiment, it is provided that the refrigerant circuit has exactly one capillary, and that the valve is arranged directly or indirectly upstream of this capillary.

In one embodiment, the refrigerant circuit has at least two capillaries arranged upstream of the evaporator in the flow direction of the refrigerant, which are designed such that at least two of the capillaries have different flow rates, wherein the valve is in flow connection with the capillaries in such a way that depending on the valve position or a second or both or more or all of the capillaries are flowed through with refrigerant.

In this embodiment, it is thus provided that upstream of the at least one evaporator, preferably of the freezer compartment evaporator not only one capillary, but two or more are arranged as two capillaries, of which at least two have different flow rates. A flow rate is the amount of refrigerant per unit time that flows through the capillary at a certain pressure difference before and after the capillary. Assuming, for example, that in the inlet region of the capillaries there is in each case a specific pressure which essentially corresponds to the pressure on the pressure side of the compressor, a capillary with a low flow rate is produced at the same inlet-side pressure or at the same pressure difference over the length of the capillary Capillary with less refrigerant per unit time flows through than a relatively larger flow rate capillary.

If a high refrigeration demand prevails in the compartment, said valve can be adjusted to release the capillary at a high flow rate, i. H. the refrigerant passes to the evaporator through the high flow rate capillary.

If, on the other hand, a low refrigeration requirement prevails in the compartment, said valve can be adjusted such that the capillary is released through the valve at a low flow rate, i. H. the refrigerant passes to the evaporator through the low flow rate capillary.

In this way, it is possible by the choice of the capillary or the capillaries targeted to adjust the cooling capacity, preferably in such a way that in the compartment of the desired setpoint temperature is reached as quickly as possible and / or that the most constant storage temperature is maintained in the compartment ,

It is conceivable, for example, that with a very high refrigeration demand, the valve is switched so that both or more capillaries are unlocked simultaneously, so that the refrigerant flows simultaneously through several capillaries to the evaporator.

It is also conceivable that in the event that there is no need for refrigeration, the valve is able to shut off all capillaries.

In this embodiment, it is thus provided that the device, in particular a freezer or a freezer compartment, has at least one refrigerant circuit which has at least one valve which makes it possible to choose between at least two capillaries with different flow rates. Due to the different flow rates, at least two or, in the case of more than two capillaries, also more different cooling capacities are available.

It is conceivable that the valve is a multi-way valve. The valve may, for example, be electrically operated or be operated manually.

The different flow rates of the at least two capillaries can be produced, for example, by carrying out the capillaries with different inner diameters. The smaller the inner diameter, the greater the pressure loss that arises when flowing through the capillary and the lower the flow rate of the capillary.

Alternatively or additionally, it is conceivable to effect the different flow rates through different lengths of the capillaries. Thus, a capillary of small length over the length of the capillary has a lower pressure loss and thus a higher flow rate than a longer capillary.

It is thus conceivable to set the flow rate of the capillary via the parameters "inner diameter" and / or "length" of the capillary.

In a further embodiment of the invention it is provided that in the compartment at least one fan, preferably at least one fan variable in its speed is arranged. By using at least one fan, by means of which the cooled air in the compartment is circulated or promoted, can also influence the temperature in the compartment influence. The term "in the compartment" includes not only the case where the fan is located directly in the compartment, but also the case where the fan is in an evaporator module, which in turn is in the refrigerated compartment.

The fan is preferably designed such that the evaporator of the refrigerant circuit, by means of which the compartment is cooled, is arranged on the pressure side or suction side relative to the fan. This means that during operation the fan actively moves the air cooled by the evaporator away from the evaporator or supplies the air heated to the compartment to the evaporator.

The fan may be arranged together with the evaporator in one unit, that is in an evaporator module. This evaporator module can be located, for example, on the ceiling of the cooled interior or the inner container.

In order to be able to influence the temperature in the cooled compartment in a particularly exact manner, it is preferably provided that it is the fan is a fan whose speed is variable. Preferably, the fan is designed as a speed-controlled fan.

If, for example, it is determined by one or more temperature sensors in the cooled compartment that the temperature is above a desired value, it may be provided to turn on the fan and / or increase its speed in order to increase the delivery rate of the cooled air and thus the temperature in the cooled compartment to lower. If the temperature setpoint is reached, it may be provided to switch off the fan or reduce its speed in order to reduce the delivery rate of the cooled air again.

It is thus conceivable to select the operation of the fan and / or its speed as a function of whether the actual temperature value corresponds to the desired value or is above or below this. If the temperature is too low, for example, it may be provided to switch off the fan or reduce its speed.

It is therefore conceivable that the fan is in communication with the control or regulating unit in such a way that it is switched on or off depending on the cooling demand prevailing in the compartment or is varied in its rotational speed.

In a further embodiment of the invention, it is provided that the refrigerant circuit has at least one variable in its speed compressor. In this way it is possible to also influence the cooling capacity via the speed of the compressor. If a higher cooling capacity is required, that is, the actual value of the temperature is above the setpoint, the compressor can be turned on and / or its speed can be increased. If the cooling capacity is sufficient, that is, the actual value of the temperature is at the setpoint or in a setpoint range, the compressor can be turned off or its speed can be reduced. The same applies in the event that the actual value of the temperature is below a desired value.

An influence on the temperature is of course possible not only by the change in the speed of the compressor, but also by the switching on and off of the compressor, that is, the present invention also includes a compressor that can only be operated at a constant speed.

Thus it is possible for the compressor to be in communication with the control or regulation unit in such a way that it is switched on and off or varied in its speed as a function of the cooling demand prevailing in the compartment.

In a further embodiment of the invention it is provided that at least one temperature sensor is provided, which is arranged such that it measures the temperature in the compartment or a representative value for this and that the control unit is in communication with the temperature sensor and said Valve and / or the fan and / or the compressor in response to the value determined by the temperature sensor controls or regulates. Preferably, the control is carried out in dependence on a difference between the setpoint and the actual value of the temperature.

In this way, it is possible to set or regulate the temperature in the cooled compartment to a desired value or setpoint range by the choice of the capillary or capillaries and / or by turning on or off the compressor and / or the fan or by changing the speed of the compressor and / or the fan. In contrast to conventional refrigerators and / or freezers, in which exactly one capillary is provided, which is arranged upstream of the evaporator, it is possible according to the invention to influence the provided cooling capacity by the choice of the number or type of capillary, and This allows, for example, to be able to set a desired desired value particularly quickly and / or to be able to provide a constant storage temperature over time.

In a further embodiment of the invention, it is provided that at least one collector for receiving unevaporated refrigerant is arranged between the evaporator and the compressor. This can ensure that only gaseous refrigerant reaches the compressor. This collector can thus be designed such that its outlet leading to the compressor is arranged in an upper region of the collector, so as to ensure that only gaseous refrigerant or refrigerant vapor is supplied to the compressor.

In a further embodiment of the invention, it is conceivable that at least one heat storage, preferably at least one latent heat storage is provided, wherein the heat storage is preferably arranged on the evaporator and / or such that the compartment can be cooled by means of the heat storage.

Thus, it is possible that when the compressor is switched off for a certain time by the heat storage or latent heat storage a temperature or the desired temperature in the cooled interior can be maintained. Preferably, the use of a fan or more fans is also conceivable. In this case, the cooling capacity is thus generated in particular when the compressor is switched off for a certain period of time by the at least one heat accumulator or latent heat accumulator and / or by the at least one fan.

Since the heat storage or latent heat storage deprives the cooled compartment heat and thus has a decreasing cooling capacity, can be done by a continuous and / or incremental increase in the fan speed compensation, d. H. The sinking cooling capacity of the heat accumulator can be compensated by an increasing fan speed, so that a total of a constant cooling capacity or a temperature as constant as possible is obtained in the cooled compartment.

In a further embodiment of the invention it is provided that the control or regulating unit is designed such that it operates the fan and / or the compressor in continuous operation or only temporarily turns on.

It is thus conceivable to leave the compressor permanently in operation and to make a different cooling capacity, for example by changing the speed of the compressor and / or by selecting one or more specific capillaries and / or by switching on or off or a speed change of at least one fan.

However, the invention also includes the case that the compressor is not permanently in operation, which can have energy advantages. In order to obtain the most constant possible temperature in the cooled interior in this case, it may be provided to let the fan permanently or temporarily during operation of the compressor. Thus, it is possible to provide a sufficient cooling capacity in the refrigerated compartment by the commissioning of the fan or possibly by an increase in the fan speed.

It is preferably provided that the control or regulating unit is designed such that it operates the fan with increasing speed over time.

In one possible embodiment of the invention, it is provided to operate the fan in continuous operation in order to obtain the most constant possible temperature in the cooled compartment.

Furthermore, it is advantageous if the device has at least one temperature sensor for measuring the ambient temperature of the device and if the control or regulating unit is designed such that it determines the speed of the compressor in dependence on the temperature setpoint for the refrigerated compartment and in dependence on the ambient temperature established. So it is possible, depending on the ambient temperature and / or the selected regulator position, that is, desired setpoint to select a speed of the compressor or set.

The at least two capillaries present in one embodiment can be arranged parallel or in series, wherein in the case of the series arrangement there is at least one bypass around one, both or more capillaries. Thus, it is possible to arrange two or more capillaries in parallel, so that upstream of the capillaries there is a branching point to two or more capillaries and the capillaries are recombined on the outlet side, preferably before or in the evaporator.

In one embodiment, the valve is a stepper motor valve. The opening of the valve can thus be controlled in many stages or continuously. Other valve shapes, such as the stepping motor valve, are designed in such a way that the flow through the at least one capillary or the throughflow of several or all capillaries can be varied in several stages or steplessly, can be used in one embodiment.

Due to the possibility of adapting the flow through the capillary or through individual capillaries to the respective operating situation, the refrigeration unit can be operated under different environmental conditions at the optimum operating point. Thus, a low energy consumption can be achieved. This offers advantages for the end customer, but also for the determination of the standard energy consumption at different temperatures. A determination of the energy consumption under different environmental conditions may be required in a future standardization of the energy consumption measurement. Currently, the energy consumption of refrigerators and / or freezers is only tested at one operating point. The devices are optimized accordingly to this operating point. The conditions that occur at the end customer, partly deviate greatly from the design conditions. Overall, in this embodiment, therefore, the design of the refrigeration unit can be better adapted to the conditions that occur in end customers, but also in the measurement of energy consumption for possible future standards.

According to a method for operating a refrigerator and / or freezer according to the invention, it can be provided that the flow through the at least one capillary with refrigerant or the number and / or type of capillaries flowed through by refrigerant is selected as a function of the refrigeration requirement in the compartment.

In principle, it is conceivable that the temperature in the cooled compartment is measured and compared with a desired value and that, depending on the comparison, the valve and / or the compressor and / or the fan is operated. The setting of the desired temperature in the compartment, for example a cooling compartment, cold storage compartment or freezer compartment can thus be made alternatively or cumulatively by the compressor and / or the fan and / or said valve or its position. It is thus conceivable that during operation, the internal temperature of the device, or the temperature is monitored in the cooled interior.

If a deviation from the rule setting, that is determined by the setpoint exceeds a predetermined threshold, the compressor speed and / or the fan speed and / or the position of the valve and in particular the multi-way valve is adjusted. Instead of adjusting the speed of the compressor and the fan and its switching on or off for the purpose of temperature adjustment of the invention is included.

In one embodiment, the duration of the intervals in which the at least one capillary is flowed through with refrigerant can be selected independently of one another or the same or different. In a further embodiment, the duration of the intervals in which the number and / or type of capillaries through which the refrigerant flows can be selected independently of one another or the same or different. The duration of the individual or all of these intervals is preferably less than one minute.

In the regulation of the refrigerant circuit, therefore, the valve can remain in one position for different lengths of time, for example, be opened and closed for different lengths of time. The solenoid valve preferably remains in one position for less than one minute. For example, the solenoid valve may be opened less than one minute and closed less than one minute. About the ratio of these two times, the flow rate and thus the cooling capacity and the power consumption of the compressor can be controlled. The ratio of these two times, or the ratio of two intervals may be between about 4: 1 and 1: 4 or between about 2: 1 or 1: 2.

The adaptation of the compressor speed and / or the fan speed can take place in predetermined steps or continuously.

Further details and advantages of the invention will be explained in more detail with reference to the embodiments illustrated in the drawings. 1 shows a schematic representation of a refrigerant circuit of a first embodiment of a refrigerator and / or freezer according to the invention. 2 shows a schematic representation of a refrigerant circuit of another embodiment of a refrigerator and / or freezer according to the invention.

The refrigerant circuit of in 1 embodiment shown comprises a compressor 1 , which is a condenser or condenser 2 is downstream.

After flowing through the condenser 2 the liquefied refrigerant enters the filter drier 3 ,

Downstream of the filter dryer 3 there is a multi-way valve 4 , which has an inlet and two outlets. The inlet stands with the filter dryer 3 or with the condenser in conjunction. One of the outlets leads to the capillary 5a and the other of the outlets to the capillary 5b , The two capillaries 5a and 5b are thus connected in parallel, as can be seen from the figure.

On the outlet side, the capillaries are brought together to form a common duct, which enters the evaporator 6 leads.

As can be seen from the figure, the evaporator 6 optionally be designed with a fan.

The fan and the evaporator 6 may be components of a common module or spatially separated or formed by different modules.

Downstream of the evaporator 6 the refrigerant enters the collector 7 , There liquid is separated from gaseous refrigerant and only the gaseous refrigerant passes through the suction line between the collector 7 and the compressor 1 back to the compressor 1 ,

In the cooled compartment there is at least one temperature sensor which records the actual value of the temperature in the compartment. Furthermore, it is a control unit provided that compares this actual value with a setpoint of the temperature or with the rule creation. If it is determined that a correction is required, ie that the actual value is above or below a desired value or setpoint range, the control unit adopts the compressor 1 , the fan or the valve 4 or affect several or all of these components.

As can be seen from the figure, the capillary 5b a shorter length than the capillary 5a , The capillary 5b thus has a higher flow rate, that is, the flow rate per unit time through the capillary 5b is greater at the same compressor pressure than at the capillary 5a , It is thus possible to adjust or influence the cooling capacity by selecting the capillary. If a high cooling capacity is desired, for example because the user has introduced a larger amount of warm goods into the compartment, the valve becomes 4 switched so that not the capillary 5a but the capillary 5b is traversed by refrigerant, allowing the evaporator 6 a comparatively large amount of refrigerant is supplied and thus a high cooling capacity is available.

If such a high refrigeration capacity is not required, the control or regulating unit becomes the valve 4 switched so that not the capillary 5b but the capillary 5a flows through refrigerant. Due to the higher flow resistance of the capillary 5a In this case, the flow rate of the refrigerant is lower, so that the amount of refrigerant that is ultimately the evaporator 6 is supplied and thus the cooling capacity is reduced.

Further parameters for setting or providing the cooling capacity are the switching on and off of the compressor and / or the fan or the change in the speed thereof. So it is conceivable, for example, that is adjusted at a detected deviation between the actual value and setpoint temperature in the cooled compartment, especially in the freezer compartment, the compressor speed and / or the fan speed and / or the position of the multi-way valve.

Thus, it is altogether possible to relatively quickly reduce a deviation between the actual value and the nominal value of the temperature or to keep the temperature in the cooled compartment constant over time.

Instead of the parallel arrangement of the two capillaries shown in the figure 5a and 5b can also be provided a series connection of these two capillaries, wherein one or more bypass lines may be provided to one or both of the capillaries, so that only one or both of the capillaries are flowed through, depending on whether the bypass line is enabled or not.

It should also be noted that not only two parallel or series capillaries can be used, but also more than two capillaries. All of these capillaries can have different flow rates. It is also conceivable to form several groups of capillaries, wherein the capillaries within a group have the same flow rate, but the groups have different flow rates.

In the in 2 In the embodiment shown, the same parts are given the same reference numerals, so far as the description of the 1 is referenced.

In this embodiment, only one capillary is in the refrigerant circuit 5a available. At the valve 4 it is a stop valve. In the example shown, the stop valve 4 designed as a three-way valve, the input side with the dryer 3 or the liquefier 2 communicates, and the output side with the capillary 5a communicates. Another exit is closed. Of course, other embodiments of a suitable valve or stop valve are conceivable within the scope of the invention.

In this embodiment, if necessary, by a clocked control of the valve, the cooling capacity can be controlled while the compressor is constantly in operation. In one position of the valve, for example, solenoid valve, refrigerant flows through the capillary, in the other position, the refrigerant can not flow.

The solenoid valve can be opened and closed the same or different times. For example, during operation of the device, the solenoid valve is opened for less than 1 minute and closed for less than 1 minute.

In both in 1 and 2 embodiments shown may be in the valve 4 to act a valve by means of which the flow through the at least one capillary or the flow of several or all capillaries in several stages or can be changed continuously. For example, in this context, a stepping motor valve can be used. Of course, however, other valve forms are conceivable.

Due to the possibility of adapting the flow through the capillary or through individual capillaries to the respective operating situation, the refrigeration unit can be operated under different environmental conditions at the optimum operating point. Thus, a low energy consumption can be achieved or determined under different environmental conditions. Currently, the energy consumption of refrigerators and / or freezers is only tested at one operating point. The devices are optimized accordingly to this operating point. The conditions that occur at the end customer, partly deviate greatly from the design conditions. Overall, in this embodiment, therefore, the design of the refrigeration unit can be better adapted to the conditions that occur in end customers, but also in the measurement of energy consumption for possible future standards.

Claims (15)

Cooling and / or freezing apparatus having at least one cooled compartment and having at least one refrigerant circuit, the at least one compressor and at least one evaporator for cooling said compartment and at least one arranged in the flow direction of the refrigerant upstream of the evaporator capillary, characterized in that the refrigerant circuit has at least one arranged upstream of the capillary valve, which communicates with the capillary in such a way that the capillary is flowed through depending on the valve position with refrigerant, and that at least one control or regulating unit is provided, which communicates with the valve and the like is designed that it adjusts the valve position in response to the cooling demand prevailing in the compartment. The refrigerator and / or freezer according to claim 1, characterized in that the refrigerant circuit has at least two arranged upstream of the evaporator capillaries, which are designed such that at least two of the capillaries have different flow rates, and that the valve is in communication with the capillaries in that, depending on the valve position, a first or a second or both or several or all of the capillaries are flowed through with refrigerant. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that in the compartment at least one fan, preferably at least one fan variable in its speed is arranged, wherein it is preferably provided that the fan with the control unit in such Connection is that this is turned on or off depending on the prevailing in the compartment refrigeration demand or varies in its speed. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the refrigerant circuit comprises at least one compressor, preferably a variable in its speed compressor, wherein it is preferably provided that the compressor is in communication with the control or regulating unit, that this is switched on or off depending on the prevailing in the compartment refrigeration demand or varies in its speed. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that at least one temperature sensor is provided, which is arranged such that it measures the temperature in the compartment cooled by the evaporator or a value representative thereof and that the control unit or control unit is in communication with the temperature sensor and controls said valve and / or the fan and / or the compressor in dependence of the value determined by the temperature sensor and / or in dependence of a difference of this value to a desired value or regulates. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that between the evaporator and the compressor at least one collector for receiving non-vaporized refrigerant is provided and / or that at least one heat storage, preferably at least one latent heat storage is provided, wherein the Heat storage is preferably arranged on the evaporator and / or such that the compartment can be cooled at least temporarily by means of the heat accumulator. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that the control or regulating unit is designed such that it operates the fan and / or the compressor in continuous operation or only temporarily turns on and / or that when the compressor Fan at least temporarily or permanently turns on, it is preferably provided that the control or regulating unit is designed such that it operates the fan with increasing speed over time when the compressor is turned off. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that the device has at least one temperature sensor for measuring the ambient temperature of the device and that the control or regulating unit is designed such that it the speed of the compressor and / or the fan depending on the temperature setpoint for the refrigerated compartment and depending on the ambient temperature. Refrigerating and / or freezing appliance according to one of claims 2 to 8, characterized in that the at least two capillaries are arranged in parallel or in series, wherein in the case of the series arrangement there is at least one bypass around one, both or more capillaries. The refrigerator and / or freezer according to one of the preceding claims, characterized in that it is the valve is a stepper motor valve and / or that the valve is designed so that the flow through the at least one capillary or the flow of several or all Capillaries can be changed in several stages or steplessly. Method for operating a refrigerator and / or freezer according to one of the preceding claims, characterized in that the flow through the at least one capillary with refrigerant or the number and / or type of capillaries flowed through by refrigerant is selected depending on the refrigeration demand in the compartment , A method according to claim 11, characterized in that the temperature is measured in the cooled compartment and compared with a desired value and that in dependence of the comparison, the valve and / or the compressor and / or the fan is switched or operated. A method according to claim 11 or 12, characterized in that the duration of the intervals in which the at least one capillary flows through or is not flowed through by means of refrigerant can be selected independently of one another or the same or different, and / or that the duration of the intervals in which the number and / or type of capillaries flowed through by refrigerant differs, can be selected independently of one another or the same or different. Method according to one of claims 11 to 13, characterized in that the duration of the intervals in which the at least one capillary is flowed through or not flowed through with refrigerant, is less than one minute, and / or that the duration of the intervals, in each of which differentiates the number and / or type of capillaries through which the refrigerant flows, each being less than one minute. Method according to one of claims 11 to 14, characterized in that the flow through the at least one capillary or the flow of several or all capillaries depending on the refrigeration demand in the compartment is changed in several stages or continuously.

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