DE102018115866A1 - Refrigerator and / or freezer - Google Patents

Abstract

The present invention relates to a refrigerator and / or freezer with a cooled interior, with a control device and with a refrigerant circuit, which comprises an evaporator, a compressor and a condenser, wherein a temperature sensor is provided, which is arranged, the temperature in the cooled To measure the interior, and wherein a controller is provided which is designed to regulate the temperature in the cooled interior to a desired value or to a desired value range of the temperature in the cooling mode of the device, and wherein a blocking element is provided which is designed in to prevent or restrict the activated state of the operation of the compressor, the blocking element being designed in such a way that the period of time in which the blocking element is in its activated state does not depend on the measured temperature in the cooled interior space or on the evaporator temperature.

Description

The present invention relates to a refrigerator and / or freezer with a cooled interior, with a control device and with a refrigerant circuit, which comprises an evaporator, a compressor and a condenser, wherein a temperature sensor is provided, which is arranged, the temperature in the cooled To measure interior space, and wherein a controller is provided which is designed to regulate the temperature in the cooled interior to a desired value or to a desired value range in the cooling mode of the device, and wherein a blocking element is provided which is designed to be activated Condition to prevent or restrict the operation of the compressor.

Such a refrigerator and / or freezer is from the DE 196 13 859 A1 known. The device known from this document has a first temperature sensor in the cooled interior, the value measured by this being used to regulate the temperature in the cooled interior by this temperature sensor providing the actual temperature value required for the regulation.

Furthermore, a second temperature sensor is arranged on the evaporator, but this is irrelevant for the temperature control during normal operation of the device.

That from the DE 196 13 859 A1 Known devices furthermore have a blocking element, referred to as a timer, which prevents the compressor from operating in the activated state.

This timer is activated according to specified criteria, e.g. when it is determined that 100 door openings have been registered. The evaporator is then defrosted, the compressor not being put into operation due to the activated timer even if the temperature measured by the first temperature sensor reaches or exceeds the switch-on temperature in the cooled interior during the defrosting process.

The current temperature of the evaporator is measured by means of a further sensor arranged on the evaporator during this defrosting phase. The defrost time can thus be controlled so that the evaporator defrosts safely.

If this increases disproportionately quickly, for example because warm refrigerated goods have been stored, a correction element deactivates the time element again during the defrosting phase and the system switches to normal control mode. Since the temperature measured by the first temperature sensor in the cooled interior exceeds the switch-on temperature, the compressor is put into operation again.

The duration of the defrosting phase and thus also the duration in which the timer is activated thus depends on the temperature measured on the evaporator in the known device.

The present invention is based on the object of developing a refrigerator and / or freezer of the type mentioned at the outset such that it has a simplified structure compared to the known device.

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

According to this, it is provided that the blocking element is designed in such a way that the time period in which the blocking element is in its activated state does not depend on the measured temperature in the cooled interior space nor on the evaporator temperature. The blocking element of the present invention is designed to completely prevent or at least restrict the operation of the compressor in its activated state. Such a restricted operation is to be understood to mean that the compressor is operated, but with an output which is lower than that in normal cooling operation.

The defrost phase is therefore in contrast to that from the DE 196 13 859 A1 known procedure regardless of the evaporator temperature.

Rather, the defrost phase is preferably carried out exclusively according to the time, i.e. for a certain period of time, which is independent of the temperature measured in the cooled interior and also independent of the evaporator temperature.

Thus, in a preferred embodiment, a temperature sensor, which is arranged on the evaporator, is dispensed with. Rather, a temperature sensor, which is arranged in the cooled interior and is used for temperature control in normal operation, is sufficient. “Normal operation” or “cooling operation” means the operation of the device in which the controller regulates the temperature in the cooled interior to a setpoint or to a setpoint range.

Furthermore, the device can be operated in a defrost mode in which this regulation is not carried out and in which the evaporator of the refrigerant circuit and / or other parts of the device are defrosted.

The locking element can be designed in such a way that the time period in which the locking element is in its activated state depends on the creation of the rule, ie on the temperature setpoint and / or on the room temperature and / or on the number of openings in the cooled interior from a reference point in time , e.g. depends on the last defrost.

The lower the controller position, i.e. the smaller the temperature setpoint and / or the higher the room temperature, the greater the amount of ice to be defrosted. The same applies to the number of openings in the door or another locking element. The more of these opening processes are recorded, the more moisture is introduced into the cooled interior and the more ice has to be defrosted.

Basically, the invention also includes the dependence of the time period on one or more further or alternative parameters.

As stated, a preferred embodiment of the invention is that the device does not have a temperature sensor for measuring the evaporator temperature. Such a temperature measurement is also not necessary because the evaporator temperature has no influence on the blocking element and thus on the defrosting duration.

Furthermore, there is preferably no correction element which is designed to shorten the defrosting phase or the compressor standing time when a high evaporator temperature is measured.

The device according to the invention is preferably designed such that during the defrosting phase there is no change at all in the predetermined duration of the defrost. A correction element for changing this time period can therefore be dispensed with.

The control device is preferably designed to deactivate the blocking element after the time period has elapsed and to operate the compressor at the end of the defrosting phase at a power level which depends on the temperature in the cooled interior when the defrosting phase is complete.

Should the temperature in the cooled interior rise very strongly during the defrosting phase, for example because warm goods have been inserted, this is detected by the temperature sensor, which measures the temperature of the air in the cooled interior. The compressor is then operated with a comparatively high output after the end of the defrost phase in order to achieve rapid cooling of the interior. The higher the measured temperature, the higher the performance.

It is preferably provided that the control device is designed to activate the compressor at a certain switch-on temperature in the cooling mode of the device and that the power level of the compressor depends on the value by which the temperature in the cooled interior exceeds the switch-on temperature when the defrosting phase is completed. The greater the difference between the switch-on temperature and the temperature measured after the defrost phase, the greater the power level at which the compressor is operated after the defrost phase has been completed.

The control device can be designed to initiate the defrosting phase after a certain accumulated compressor running time and / or after reaching a certain number of openings in the cooled interior and / or depending on other parameters.

The present invention further relates to a method for operating a refrigerator and / or freezer according to any one of the preceding claims, wherein the operation of the compressor is prevented during the defrosting phase of the evaporator for a certain period of time, which neither of the temperature in the cooled interior nor depends on the evaporator temperature.

It is preferably provided that the time period depends on the creation of the rule and / or on the room temperature and / or on the number of openings in the cooled interior from a reference point in time.

Provision can furthermore be made for the temperature in the cooled interior to be measured after the defrosting phase of the evaporator and for the compressor to be operated after the defrosting phase with a power level which depends on the difference between the temperature measured after the defrosting phase and the switch-on temperature mentioned. It is thus possible to achieve rapid cooling of the cooled interior even when the cooled interior heats up strongly during the defrosting phase by means of the compressor operated at high power.

At this point it is pointed out that the terms “a” and “an” do not necessarily refer to exactly one of the elements, although this is a possible embodiment, but can also denote a majority of the elements. Likewise, the use of the plural also includes the existence of the element in question in the singular form and, conversely, the singular also includes several of the elements in question.

Further details and advantages are explained in more detail using an exemplary embodiment explained below.

The exemplary embodiment relates to a refrigerator and / or freezer with a cooled interior, in which an air sensor is arranged, which measures the temperature in the cooled interior.

The device also has a refrigerant circuit that includes an evaporator, a compressor, a condenser, and a throttle, through which refrigerant flows in this order when the compressor is in operation. After the throttle, the refrigerant returns to the evaporator, which is used to cool the interior.

A controller compares the temperature determined by the temperature sensor with a setpoint specified by the user on the controller position and activates or deactivates the compressor in cooling mode of the device depending on the difference between the two values, in order to keep the actual temperature at a setpoint or in a setpoint range.

After a certain compressor running time or after a certain number of door openings, the cooling operation is interrupted and a defrost phase is initiated. This is done by activating a locking element that prevents the compressor from operating, i.e. the compressor is not in operation when the blocking element is activated. This state is maintained for a certain period of time.

This period of time is independent of temperature values measured in the cooled interior during the defrosting phase. An evaporator sensor for measuring the temperature of the evaporator is not provided, so that the evaporator temperature also has no influence on the period of the defrosting phase.

After the period has elapsed, the system switches back to cooling mode, in which conventional temperature control takes place.

If it is determined by the air sensor mentioned that the temperature in the cooled interior is a defined value above the specified switch-on value for the compressor, the compressor automatically switches to a higher level after the defrost phase, which has the advantage that the temperature in the cooled interior is lowered more quickly into the desired area than if the compressor is operated at a low power level.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 19613859 A1 [0002, 0004, 0012]

Claims (9)

A refrigerator and / or freezer with a cooled interior, with a control device and with a refrigerant circuit, which comprises an evaporator, a compressor and a condenser, a temperature sensor being provided, which is arranged to measure the temperature in the cooled interior, and wherein a controller is provided which is designed to regulate the temperature in the cooled interior to a desired value or to a desired value range of the temperature in the cooling mode of the device, and wherein a blocking element is provided which is designed to operate in its activated state to prevent or restrict the compressor, characterized in that the blocking element is designed such that the time period in which the blocking element is in its activated state does not depend on the measured temperature in the cooled interior space nor on the evaporator temperature. Refrigerator and / or freezer after Claim 1 , characterized in that the locking element is designed such that the period of time in which the locking element is in its activated state depends on the rule creation and / or on the room temperature and / or on the number of openings of the cooled interior from a reference time , Refrigerator and / or freezer after Claim 1 or 2 , characterized in that the device has no temperature sensor for measuring the evaporator temperature. Refrigerator and / or freezer according to one of the preceding claims, characterized in that the control device is designed to deactivate the blocking element and to operate the compressor after the end of the defrosting phase at a power level which depends on the temperature in the cooled interior when the defrosting phase is completed depends. Refrigerator and / or freezer after Claim 4 , characterized in that the control device is designed to activate the compressor during cooling operation of the compressor at a specific switch-on temperature and that the power level of the compressor depends on the value by which the temperature in the cooled interior exceeds the switch-on temperature when the defrosting phase is completed. Refrigerator and / or freezer according to one of the preceding claims, characterized in that the control device is provided to initiate the defrosting phase after a certain accumulated compressor runtime and / or after reaching a certain number of openings in the cooled interior. Method for operating a refrigerator and / or freezer according to one of the preceding claims, characterized in that the operation of the compressor is prevented during the defrosting phase of the evaporator for a certain period of time, which does not depend on the temperature in the cooled interior or on the evaporator temperature , Procedure according to Claim 7 , characterized in that the time period depends on the rule creation and / or on the room temperature and / or on the number of openings of the cooled interior from a reference time. Procedure according to Claim 7 or 8th , characterized in that in cooling operation the compressor is switched on when a switch-on temperature is reached in the cooled interior, that the temperature in the cooled interior is measured after the defrosting phase of the evaporator and that the compressor is operated after the defrosting phase with a power level which is operated by the Difference between the temperature measured after the defrost phase and the switch-on temperature mentioned.