DE102015003244A1 - Fridge and / or freezer - Google Patents

Abstract

The present invention relates to a refrigerator and / or freezer with a device body and with a cooled interior and with a refrigerant circuit having a variable speed compressor, wherein a control unit is provided which controls the compressor such that the compressor speed during the Running time of the compressor is gradually or continuously reduced.

Description

The present invention relates to a refrigerator and / or freezer with at least one appliance body and with at least one cooled interior and with at least one refrigerant circuit having at least one variable speed compressor.

In refrigerators or freezers with such a VCC compressor, that is with a variable-speed compressor, this is usually operated during the run at a certain speed level. If, after a certain time, a cooling demand continues to exist, the compressor switches to a higher speed level, if necessary, until the maximum permissible speed level has been reached.

If, however, the run time of the compressor is shorter than a certain time, the compressor switches off and the next time it is switched on, ie in the next runtime, it operates at a lower speed level, the lowest level being specified by a minimum allowable speed level.

2 shows the time dependence of the evaporation temperature as a function of the operation of the compressor. In 2 is with the reference numeral 1 the evaporation temperature, with the reference numeral 2 the power consumption of the compressor and the reference numeral 3 the target or target temperature of the cooled interior marked.

If the compressor is switched off, as is the case in phase A, the result is a comparatively high evaporation temperature. In the runtime of the compressor, which is identified by the reference B, the evaporation temperature decreases 1 like this 2 is apparent.

At the beginning of run time B of the compressor is the evaporation temperature 1 at a comparatively high level. This is due to the fact that during the service life A of the compressor or compressor there is a pressure equalization in the refrigerant circuit via the capillary. Therefore, after the start of the compressor, the pressure difference between the high and low pressure side must first be established.

This causes that in this time the evaporation temperature 1 is lowered slowly, like this 2 evident.

After a certain period of compressor operation is the evaporation temperature 1 at an energetically optimal level. This is characterized in that the temperature difference between the cooled interior and the evaporator is large enough to transfer enough heat from the cooled interior to the evaporator. At this time, however, the evaporation temperature is not so low that there is an unnecessarily large temperature difference between the cooled interior and the evaporator, which has an energetic negative effect.

Like this 2 As will be apparent, the longer the compressor is operated, the lower the evaporation temperature becomes. Will a certain level of evaporation temperature 1 Of course, this falls short of course, to a cooling of the cooled interior, but an energetically optimal operation is no longer guaranteed.

The present invention is therefore the object of developing a refrigerator and / or freezer of the type mentioned in such a way that an energetically optimal operation of the device is guaranteed.

This object is achieved by a refrigerator and / or freezer with the features of claim 1. Thereafter, it is provided that the device has at least one control or regulating unit which controls the compressor so that the compressor speed is reduced gradually or continuously during the life of the compressor. The present invention thus deviates from 2 made a reduction in the compressor speed during run time A of the compressor.

This reduction in the speed ensures that the evaporation temperature does not assume unnecessarily low values. An energy unnecessarily high temperature difference between the cooled interior and the evaporator is thus avoided.

It is preferred that the compressor speed is reduced according to a fixed schedule or timing during the life of the compressor.

It is conceivable, for example, a gradual or continuous reduction with a certain gradient or with a certain duration and height of the individual stages.

In a preferred embodiment of the invention, means for measuring the evaporation temperature or a temperature correlated therewith, such as the evaporator temperature, etc., are provided. The control unit may be configured to reduce the compressor speed in response to the measured temperature.

In this case, therefore, the compressor speed is not reduced after a fixed predetermined, that is rigid timing, but depending on the measured evaporation temperature or a measured and thus correlated temperature.

This makes it possible to set the compressor speed optimally so that no too low temperature values, but also not too high temperature values are achieved.

Means may be provided for measuring the evaporation temperature or a temperature correlated therewith, and the control or regulation unit may be designed so that the compressor speed is reduced only after reaching a certain measured temperature. In this case, the compressor is operated at a certain initial speed and only then a reduction (stepwise or continuously) made when the measured evaporation temperature or a measured and thus correlated temperature has reached or fallen below a certain value. This temperature may be characterized, for example, in that the evaporation temperature corresponds to the setpoint temperature of the cooled compartment or by a certain value below or above.

Furthermore, it can be provided that means for measuring the evaporation temperature or a temperature correlated therewith are provided and that the control or regulating unit is designed so that the compressor speed is reduced so that the measured temperature from a certain point in time constant or substantially remains constant.

So it is possible to keep the evaporation temperature at a certain, energetically optimal level.

The present invention further relates to a method for operating a refrigerator and / or freezer according to one of claims 1 to 5, wherein the method is characterized in that the compressor speed is reduced during the runtime of the compressor stepwise or continuously.

As stated above, this reduction can be done according to a fixed scheme or even variable. The evaporation temperature or a temperature correlated therewith can be measured and the compressor speed can be reduced as a function of this measured temperature.

If, for example, the evaporation temperature or the temperature correlated therewith is comparatively high, the compressor speed can be reduced later and / or by a lower value than at lower evaporation temperatures or temperatures correlated therewith.

In a further embodiment of the invention, it is provided that the evaporation temperature or a temperature correlated therewith is measured and the compressor speed is reduced only after reaching a certain measured temperature. This has the advantage that initially a comparatively rapid cooling or lowering of the evaporation temperature or the correlated temperature takes place and only then is a lowering of the compressor speed made.

In a further embodiment of the invention, it is provided that the evaporation temperature or a temperature correlated therewith is measured and the compressor speed is reduced such that the measured temperature remains constant at least at a certain time or remains substantially constant.

As stated above, this can be achieved by setting an optimum evaporation temperature over the runtime or over a part of the runtime of the compressor.

Further details and advantages of the invention will be described with reference to an embodiment shown in the drawing.

Show it:

1 : the timing of the evaporation temperature, the power consumption of the compressor and the target temperature of the refrigerated compartment according to the invention and

2 the timing of the evaporation temperature, the power consumption of the compressor and the target temperature of the refrigerated compartment according to the prior art.

The present invention relates according to the embodiment, a refrigerator and / or freezer with a refrigerant circuit having a compressor, a downstream condenser, an evaporator for cooling the cooled interior and extending between the condenser and evaporator capillary. From the evaporator, a suction line leads to the compressor, so that there is a total of a closed refrigerant circuit.

Furthermore, a control unit is provided which controls or regulates the compressor.

In a preferred embodiment of the invention, the control unit is designed such that an adaptive compressor control is performed.

The compressor is variable speed, that is he can z. B. depending on one or more parameters are operated at different speeds.

1 shows the evaporation temperature 1 , the power consumption 2 of the compressor and the temporally constant target temperature 3 of the refrigerated compartment over time.

The compressor is alternately turned on and off as known in the art, the phases in which the compressor is turned on are termed transit times and the phases in which the compressor is off are termed idle times.

1 shows by the reference numeral A stop times of the compressor, that is, times when the compressor is not running.

When reporting the cooling demand, z. B. due to the measurement in the cooled compartment of the compressor is turned on, as is out 1 is apparent. In this case, the compressor is operated immediately after switching on a higher speed than is the case after a known control, as in 2 is shown. This has the consequence that the evaporation temperature 1 is lowered faster to an energetically optimal level.

In prior art devices, compressor speeds in the range of 1200 to 1400 rpm are common. Compressors used today allow compressor speeds of up to 4500 rpm. Thus, it is conceivable that the compressor is operated according to the invention at a speed which is above the known speeds between 1200 to 1400 U / min. For example, after being turned on, the compressor according to the invention may be operated at a speed which is in the range> 1400 rpm, and preferably> 2000 rpm to 4500 rpm.

These values are preferred, exemplary values that do not limit the invention.

If the compressor is operated longer, the evaporation temperature would be 1 continue to fall and thus the device no longer work in the energetically optimal operating point with respect to the low pressure side. The low pressure side includes the evaporator, which is arranged to extract heat from the refrigerated compartment.

To avoid that the temperature falls too far, the speed of the compressor is how out 1 evident, reduced over time. This can be done gradually or continuously.

In this case, the reduction according to the embodiment takes place such that the evaporation temperature 1 remains constant over the period C or only slightly decreases or changes.

In the embodiment according to 1 Thus, first, the compressor is operated at a comparatively high speed and there is a lowering of the speed at a fixed predetermined time or at a time at which the evaporation temperature has reached a certain value. For example, this value may be the value of the target temperature 3 of the subject. A value deviating therefrom, such as, for example, a certain amount (absolute or percentage) above or below the desired value of the compartment, is also conceivable. From this point on the speed of the compressor will turn off 1 seen gradually lowered so that the evaporation temperature remains constant over the remaining duration of the life of the compressor.

By means of the present invention it is achieved that the evaporator or the evaporation temperature lies at an optimum operating point or assumes an optimum value over a substantial part of the running time of the compressor. The evaporation temperature is adjusted to provide sufficiently efficient cooling of the cooled compartment, while avoiding too low temperatures that would result in inefficient operation of the device.

Claims (10)

Refrigerated and / or freezer with a device body and with a cooled interior and with a refrigerant circuit having a variable speed compressor, characterized in that a control or regulating unit is provided which controls the compressor such that the compressor speed during the term of the Compressor is gradually or continuously reduced. The refrigerator and / or freezer according to claim 1, characterized in that the control or regulating unit is designed such that the Compressor speed is reduced after a fixed predetermined time. The refrigerator and / or freezer according to claim 1, characterized in that means are provided for measuring the evaporation temperature or a temperature correlated therewith and that the control or regulating unit is designed such that the compressor speed is reduced as a function of the measured temperature. Cooling and / or freezing appliance according to one of the preceding claims, characterized in that means are provided for measuring the evaporation temperature or a temperature correlated therewith and that the control or regulating unit is designed such that the compressor speed only from reaching a certain measured temperature is reduced. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that means are provided for measuring the evaporation temperature or a temperature correlated therewith and that the control or regulating unit is designed such that the compressor speed is reduced such that the measured temperature remains constant or substantially constant at a certain point in time. A method of operating a refrigerator and / or freezer according to one of claims 1 to 5, characterized in that the compressor speed is reduced during the running time of the compressor stages or continuously. A method according to claim 6, characterized in that the compressor speed is reduced after a fixed predetermined time. A method according to claim 6 or 7, characterized in that the evaporation temperature or a correlated temperature is measured and that the compressor speed is reduced as a function of the measured temperature. Method according to one of claims 6 to 8, characterized in that the evaporation temperature or a correlated temperature is measured and that the compressor speed is reduced only after reaching a certain measured temperature. Method according to one of claims 6 to 9, characterized in that the evaporation temperature or a correlated temperature is measured and that the compressor speed is reduced so that the measured temperature remains constant at a certain time or remains substantially constant.

Images