DE102012002654A1 - Refrigerator and/or freezer e.g. chest freezer, has regulating unit that switches ON and/or OFF of compressor for temperature control within refrigerated compartment in response to correlated parameters of temperature in compartment - Google Patents

Abstract

The refrigerator and/or freezer has refrigerant circuit that includes evaporators for cooling refrigerated compartment. Several compressors are connected to the evaporators through suction line, so that refrigerant from the evaporator is flown to the compressor during refrigerant cycle. A measuring unit measures correlated parameters of temperature (T) in the refrigerated compartment. A regulating unit causes switching ON and/or OFF of the compressor for the purpose of temperature control within the refrigerated compartment in response to the measured value from measuring unit.

Description

The present invention relates to a refrigerator and / or freezer with at least one refrigerated compartment and at least one refrigerant circuit, wherein the refrigerant circuit comprises at least one evaporator for cooling the at least one compartment and at least one compressor which is connected to the evaporator via at least one suction line via which, during operation of the refrigerant circuit, refrigerant flows from the evaporator to the compressor, wherein the device further comprises at least one associated with the compressor control and / or regulating unit, which is designed such that it can be used to set a temperature in the cooled compartment causes the switching on and / or off the compressor.

In known from the prior art refrigerators and / or freezers, it is known to arrange one or more temperature sensors in the cooled interior and / or on the evaporator, which are in communication with a control and / or regulating unit. The control and / or regulating unit receives measured values from the temperature sensor (s) which are compared with setpoint values, the compressor of the refrigerant circuit being switched on or off on the basis of this comparison.

Furthermore, it is known in known from the prior art refrigerators and / or freezers to install a temperature sensor for evaporator defrosting and also for the temperature control on the evaporator and preferably at the coldest point of the evaporator. The temperature sensor is thus in direct thermal contact with the evaporator.

During the compressor runtime, a layer of ice can build up on the evaporator. With the help of the temperature sensor, which is attached to the evaporator, a secure defrosting of this ice layer can be ensured during the downtime of the compressor.

The compressor does not switch on again until the evaporator sensor reaches a certain temperature, the so-called switch-on temperature, at which a complete defrost of the evaporator is ensured.

In this arrangement, a disadvantage is that the temperature sensor is in constant contact with moisture or comes.

This contact with moisture, especially during the defrosting phase, involves the risk that moisture will enter the temperature sensor, damaging it or even causing it to fail. This risk is further increased by the fact that the infiltrated water can freeze during an operating cycle and then thaws again. The explosive force of the water can destroy the sensor capsule and thus lead to failure of the sensor.

The present invention is therefore the object of developing a refrigerator and / or freezer of the type mentioned in such a way that the described disadvantage of the sensor failure or damage to said sensor is reliably prevented.

This object is achieved by a refrigerator and / or freezer with the features of claim 1.

Thereafter, it is provided that at least one measuring device is provided for determining at least one parameter correlated with the temperature in the cooled compartment, which is in communication with the control and / or regulating unit, and in that the control and / or regulating unit is designed that it causes the switching on and / or switching off the compressor in dependence of the value determined by said measuring device.

This value is not a temperature reading and, in particular, is not a temperature reading determined by a temperature probe on the evaporator.

The present invention is thus based on the idea of determining by means of at least one measuring device at least one value of a parameter which correlates directly or indirectly (for example via the temperature of the refrigerant) with the temperature in the cooled compartment and based on this the control or Regulation of the refrigerator and / or freezer and in particular the temperature in the refrigerated compartment make. This procedure makes it possible to dispense with temperature sensors and thus to avoid the problem of icing of the temperature sensor described above.

It is preferably provided that the control or regulation of the temperature in the at least one cooled compartment of the refrigerator and / or freezer is not based on actual values for the temperature but based on actual values or parameters which correlate with the temperature.

The present invention further relates to a refrigerator and / or freezer with at least one refrigerated compartment and with at least one refrigerant circuit, wherein the refrigerant circuit comprises at least one evaporator for cooling the at least one compartment and at least one compressor which is connected to the evaporator via at least one suction line, flows through the refrigerant in the operation of the refrigerant circuit from the evaporator to the compressor, wherein the Device further comprises at least one associated with the compressor control and / or regulating unit, which is designed such that it switches off the compressor in the defrost mode of the device and turns on again in response to at least one parameter value.

Also, this parameter value is not a temperature reading and in particular not a temperature reading, which is determined by a temperature sensor on the evaporator.

According to the invention, it is provided that the parameter is at least one parameter that is directly or indirectly correlated with the temperature of the refrigerant, and that a measuring device is provided for measuring at least one value of this parameter, which is in communication with the control and / or regulating unit ,

Thus, it is provided that the defrosting of the evaporator is not based on a temperature reading, but based on at least one value that is correlated with the temperature of the refrigerant.

The measuring device may be a device for measuring the pressure in the suction line or elsewhere in the refrigerant circuit and said parameter may be formed by the pressure value determined by the measuring device.

In a particularly advantageous embodiment of the invention, it is provided that at least one measuring device detects the pressure in the suction line and that this measured value is the parameter used according to the invention.

So it is conceivable, for example, that the control and / or regulating unit is designed such that it turns on the compressor when the determined by the measuring device value of the parameter exceeds or reaches a first threshold. If the temperature in the cooled interior is heated, the pressure in the suction line (low-pressure side) also increases. This is determined by said measuring device and the pressure value is transmitted to the control unit. This switches on the compressor when the pressure in the suction line reaches or exceeds a certain threshold, d. H. when a switch-on pressure is reached.

Due to the operation of the compressor due to the evaporation of the refrigerant in the evaporator to a cooling of the compartment and thus also to a reduction of the pressure in the suction line. The control and / or regulating unit is designed such that it switches off the compressor when a lower limit value or a certain minimum pressure is reached or undershot.

Thus, it is possible to perform the temperature control in the refrigerated indoor space or in the refrigerated compartment due to the pressure measurement value and not based on a measured value determined by a temperature sensor. Thus, a temperature sensor for the purpose of temperature control in the compartment can be dispensed with.

The present invention can also be used advantageously in the context of the defrosting process of the evaporator of the refrigerator and / or freezer. In known refrigerators and / or freezers, the compressor is switched on again as part of the defrosting process when the temperature sensor on the evaporator measures or has reached a certain temperature, the so-called switch-on temperature. At this temperature there is a complete defrost of the evaporator.

According to the invention it is now provided not to use a temperature value, due to which the compressor is switched on again after the defrosting of the evaporator or the device, but the pressure in the suction line between the evaporator and the compressor.

Due to the pressure in the refrigerant circuit while the cooling unit or the compressor is switched off, can be deduced exactly on the temperature of the refrigerant. During defrosting, there is an increase in the temperature of the refrigerant and thus also an increase in the pressure in the refrigerant circuit or in the suction line. When defrosting the evaporator can be ensured by the selection of a suitable cut-in pressure, which is set or fixed, a scissors defrost (temperatures above 0 ° C).

It is conceivable that in the context of the defrosting process, the control and / or regulating unit switches off the compressor when the user side will give the command to defrost. The invention also covers the case that the device in turn initiates a defrosting process and to turn off the compressor.

As stated above, the pressure in the suction line or any other value or parameter correlated with the temperature of the refrigerant can now be used to determine whether the defrosting process has been completed. As soon as such a value, such as a limit for the pressure in the suction line is determined, the compressor can be turned on again and the normal cooling or freezing operation can be recorded.

It is conceivable that the compressor is a variable-speed compressor and that the control and / or regulating unit is designed such that it operates the compressor at a speed which is determined by the increase per unit of time of the value determined by the measuring device Parameters, preferably the pressure in the suction line depends.

In this case, for example, it is determined by the control and / or regulating unit, with which speed the temperature in the cooled compartment increases, for example, based on the increase of the pressure in the suction line per unit time. It is thus determined the gradient of the pressure increase. It is conceivable to operate the compressor at an even higher speed, at least when switching on or during the operating phase or during another period of time during operation, the greater the pressure increase per unit time in the suction line.

For example, if a very large heat input, because the user has inserted a comparatively large amount of refrigerated and / or frozen food or the door, flap, etc. is open for a long time, the compressor can temporarily or permanently operated during the operating phase with a comparatively high speed become. If this is not the case, a lower speed can be selected.

The invention also detects the case that the compressor can be operated in several speed stages and that a speed step is selected as a function of the gradient of the pressure rise or of a rise of another temperature-correlated parameter.

Furthermore, it can be provided that the compressor is a variable-speed compressor and that the control and / or regulating unit is designed such that it operates the compressor at a speed which depends on the minor to that by the measuring device determined value of the parameter in the suction line exceeds an upper limit.

As part of the temperature control or the defrosting process, it may happen that the temperature or the pressure exceeds an upper limit at which the compressor is turned on, d. H. it can come to an "overshoot". If such a behavior is detected, it is conceivable to operate the compressor at an even greater speed, the greater the amount exceeding the limit value.

In this way it is possible to bring the temperature back to the desired temperature range as quickly as possible. In this case too, the compressor can be operated at certain speed levels and the choice of the speed level depends on the amount by which the limit value has been exceeded. This method can also be carried out if the compressor can be operated with a continuous speed spectrum.

It is conceivable that the device has no temperature sensor and / or that the device has no temperature sensor, which communicates with the control and / or regulating unit for the purpose of adjusting the temperature in the compartment and / or for the purpose of evaporator defrost.

In particular, it can be provided that the device has no temperature sensor, which is arranged on the evaporator of the device.

In this embodiment of the invention, the advantage is that it dispenses with one or the temperature sensor, which is associated with cost savings and also brings with it the advantage that the problem of icing of the temperature sensor is excluded.

Further details and advantages of the invention will be explained with reference to an embodiment shown in the drawing. The single figure shows the time course of the pressure in the suction line, the temperature in the cooled interior and the power consumption of the compressor of the refrigerant circuit.

In the illustrated figure, the time on the abscissa and the temperature T in the cooled interior, the pressure p in the suction line and the power consumption I of the compressor are shown on the ordinate.

When the compressor is off, the temperature in the refrigerated compartment rises and the pressure in the suction line increases. At time t1, the pressure in the suction line reaches an upper limit (pmax). This is detected by the control and / or regulating unit. This then causes the compressor to switch on as indicated by the power consumption.

During operation of the compressor, there is a decrease in temperature in the cooled internal space as well as a decrease in the pressure in the suction line, since the pressure in the suction line correlates with the temperature in the cooled interior or with the temperature of the refrigerant.

If the pressure in the suction line reaches a lower limit (pmin), the compressor is switched off (time t2).

Thereafter, the temperature in the cooled compartment rises again and also the pressure in the suction line. This process is repeated. If the pressure in the suction line reaches the upper limit again at time t3, the compressor is switched on again and the pressure in the suction line and the temperature in the interior sink.

This means that as soon as a certain minimum pressure is reached, the cooling unit is switched off (switch-off value). The pressure in the suction line (low pressure side) then increases until the switch-on value is reached. The cooling unit or the compressor switches on again.

Increases the interior temperature in the unit by increased heat input, as indicated in the figure with the sign "W", such as by a door opening or loading, the suction line pressure falls accordingly slower during subsequent switching on the compressor. This means that the refrigeration unit or the compressor must remain switched on longer, as can be seen from the field of power consumption of the compressor shown on the right.

The present invention can be used not only for the adjustment of the temperature control in the compartment, but also for the defrosting of the evaporator and / or the device itself.

This is because the pressure in the refrigerant circuit allows the temperature of the refrigerant to be precisely deduced when the compressor is switched off. This means that defrosting the evaporator by selecting a suitable cut-in pressure will ensure a safe defrost.

If, during the defrosting process, it is thus determined that the pressure in the suction line exceeds a certain limit value, it is concluded that the evaporator has defrosted and the compressor can be switched on again or the normal cooling mode can be started.

The present invention as well as the described embodiment is not limited to the pressure in the suction line as a parameter, but also includes any other parameter, the temperature z. B. in the cooled interior, the temperature of the refrigerant or with the evaporator temperature, etc. is correlated.

It may thus also be a parameter other than the suction line pressure, such. B. at a pressure elsewhere in the refrigerant circuit.

A significant advantage of the invention is that a failure of an evaporator sensor can be avoided, since the regulation of the temperature as well as the defrosting process by means of different sizes, as the temperature can be made.

The present invention is not limited to any particular type of device. It includes refrigerators and / or freezers, chests, etc. Nor is it limited to a particular type of evaporator or evaporator arrangement. It may thus be, for example, a refrigerator part evaporator, freezer evaporator, etc.

Claims (10)

Refrigerating and / or freezing appliance with at least one refrigerated compartment and with at least one refrigerant circuit, wherein the refrigerant circuit comprises at least one evaporator for cooling the at least one compartment and at least one compressor which is connected to the evaporator via at least one suction line, over which during operation of the refrigerant circuit, refrigerant flows from the evaporator to the compressor, the device further comprising at least one control and / or regulating unit connected to the compressor, which is designed such that it switches on or off to set a temperature in the refrigerated compartment Switching off the compressor causes, characterized in that at least one measuring device is provided for determining at least one value of at least one correlated with the temperature in the cooled compartment parameter, which is not a Temperaturistwert is, wherein the measuring device is in communication with the control and / or regulating unit, and that the control and / or regulating unit is designed such that it is the switching on and / or switching off the compressor for the purpose of temperature setting in the Compartment in response to the value determined by said measuring device causes. Refrigerating and / or freezing appliance with at least one refrigerated compartment and with at least one refrigerant circuit, wherein the refrigerant circuit comprises at least one evaporator for cooling the at least one compartment and at least one compressor which is connected to the evaporator via at least one suction line, over which during operation of the refrigerant circuit refrigerant flows from the evaporator to the compressor, the device further comprises at least one associated with the compressor control and / or regulating unit, which is designed such that it switches off the compressor in the defrost mode of the device and in dependence reconnects at least one parameter value, characterized in that the parameter is not a temperature value determined by a temperature sensor on the evaporator, but at least one correlated with the temperature of the refrigerant parameters and the s a measuring device for measuring at least one value of this parameter is provided, which is in communication with the control and / or regulating unit. Cooling and / or freezing appliance according to claim 1 or 2, characterized in that it is a device for measuring the pressure in the suction line in the measuring device and that said parameter is the pressure value determined by the measuring device in the suction line. The refrigerator and / or freezer according to one of the preceding claims, characterized in that the control and / or regulating unit is designed such that it switches on the compressor when the value of the parameter determined by the measuring device exceeds or reaches a first limit value. The refrigerator and / or freezer according to one of the preceding claims, characterized in that the control and / or regulating unit is designed such that it switches off the compressor when the determined by the measuring device value of the parameter reaches or falls below a second threshold, wherein the second threshold is below the first threshold of claim 4. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that the control and / or regulating unit is designed such that it switches off the compressor when the user side, the request is given to initiate a defrost or if a device side Defrost is initiated. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that it is the compressor is a variable-speed compressor and that the control and / or regulating unit is designed such that it operates the compressor at a speed which of the rise / time unit of the value determined by the measuring device of the parameter in the suction line depends. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that it is the compressor is a variable-speed compressor and that the control and / or regulating unit is designed such that it operates the compressor at a speed which of depends on the extent to which the determined by the measuring device value of the parameter in the suction line exceeds an upper limit. The refrigerator and / or freezer according to one of the preceding claims, characterized in that the device has no temperature sensor and / or that the device has no temperature sensor which communicates with the control or regulation unit for the purpose of setting the temperature in the compartment and / or for the purpose of evaporator defrosting. Refrigerating and / or freezing appliance according to one of the preceding claims, characterized in that the device has no temperature sensor which is arranged on the evaporator of the device.

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