DE10053422A1 - Refrigeration device with automatic defrost - Google Patents

Abstract

The invention relates to a refrigerating device comprising a refrigeratory (3) arranged on a refrigerating chamber (2), a first sensor (5) for detecting the temperature of the refrigerating chamber (3), a second sensor (6) for detecting the temperature(Tv) of the refrigerating agent, a third sensor (7) for detecting the external temperature (Te), a heating device (9) for the refrigeratory (3) and a control device (8) for operating the heating device (9) according to the temperatures (Ti, Tv) measured by the first and second sensors (5,6). The control device (8) activates the heating device (9) if the temperature (Tv) measured by the second sensor (5,6) falls below a threshold value (Tlim) which is set according to the temperatures (Ti, Te) measured by the first and third sensors (5, 7).

Description

The present invention relates to a refrigerator with automatic defrost, also as a no-frost Refrigeration device. Such refrigerators are such. B. as household refrigerators or -freezers used. The evaporators of such refrigeration devices are equipped with heating devices gen equipped, which are operated from time to time to the evaporator on a Warming the temperature above 0 ° C and thus melting the frost condenses on the evaporator during operation and its cooling capacity impaired.

In order to operate such a refrigerator economically, a compromise must be made between conflicting requirements can be found. For one, it is for high cooling performance of the evaporator cheap if there is as little frost on it as possible, on the other hand, considerable energy is required for the evaporator for the defrost cycle heat above freezing, defrost the frost and then the ver cool the steamer back to its operating temperature. In addition, during the Do not cool evaporator defrost.

Measure the thickness of a layer of frost on an evaporator directly, using it as a criterion Raising the need for defrosting is difficult and has so far no practical application found. In most practical applications the operating time of the refrigerator is therefore measured to control the automatic defrost, and defrosting is initiated when a predetermined period of time has passed. A control based purely on the operating time can of course differ Do not take into account the application conditions of a refrigerator. So it can Amount of frost that accumulates in a household refrigerator in a given time, vary greatly depending on how often and for how long the refrigerator door is opened and how high the moisture content of the outside air entering the refrigerator is. It is therefore proposed in US-A-4 251 988 an adaptive method for defrost control propose a control device from the duration of a defrost the amount of frost or layer thickness, which at the beginning of the defrosting process on Evaporator must have been present, and the period between two ab thaws are shortened if this amount has been greater than a limit, and the  if the amount has been less than a limit, the period is extended by to be achieved in such a way that defrosting always takes place at a specified layer thickness det. The disadvantage of such control is that it is necessarily behind long-term lagging behind changes in the operating conditions of a refrigerator. How it got there z. B. in summer, at relatively high outside temperatures and when in an apartment, in such a refrigerator is generally not heated, with everyone Open a relatively large amount of moisture in the device. The well-known adaptive defrost Automatic thus sets itself to relatively short intervals between two over time Defrosting. When the apartments are heated again in winter and that The ambient temperature of such a refrigerator is typically lower and the air moisture is lower, so the moisture input is lower, and the automatic gradually changes to longer time intervals between two defrosts. In the Transition times, however, are not optimally controlled.

With larger refrigeration systems, temperature-dependent control of the defrost Automatic used. So it is z. B. known, the evaporation temperature and the air temperature at the evaporator inlet or outlet of an evaporator through which air flows measure and trigger a defrost whenever the difference between these two Temperatures around an initial value measured immediately after a defrost exceeds a predetermined percentage.

This technique avoids misregistration in the event that over time the refrigeration unit changes the amount of moisture entered, but it has the disadvantage that it is not able to change the ambient temperature and thus the Cooling needs to be considered. If the temperature in the environment is one in this Regulated refrigeration device increases, so does the heat input in its cooling space and thus the difference between the evaporation temperature and air temperature. In In such a case, the automatic system triggers a defrosting process even before it did is actually necessary. When the ambient temperature drops, the defrost process delayed beyond what is economically reasonable.

A similar problem arises when changing the controller position. If this on if a lower target temperature is set in the refrigerator's refrigerator, this leads also an increase in the temperature difference, with the result that a defrosting process  and thus heating of the cold room is brought about when the user actually wanted to cool down more.

The object of the present invention is to provide a refrigerator with automatic defrost, even if the outside temperature changes or is set by a user target temperature of the refrigerator compartment a favorable time interval of the defrosting processes preserves.

This task is performed in a refrigerator with a cold room, one on the cold room arranged evaporator for a refrigerant, a first sensor for detecting a Temperature of the cold room and a second sensor for detecting a temperature of the refrigerant, a heater for the evaporator and a control device to operate the heater depending on the ge of the two sensors Measured temperatures achieved in that a third sensor for detection an outside temperature is provided and that the control circuit is set up, activate the heating device when the temperature measured by the second sensor temperature falls below a limit value, which is dependent on that of the first and third Sensor measured temperatures is set.

The control circuit can be implemented in a simple manner with a memory that Limit values for different pairs of outside and cold room temperature takes. In order to keep the amount of this memory small and still one The control circuit can also achieve sensitive control of the time of defrosting an interpolation unit for calculating the limit for pairs of from the first and third sensor measured temperatures based on those recorded in the memory Include values.

The limits are preferably the same for all pairs of outside and cold room temperatures chosen so that they correspond to a predetermined frost layer thickness on the evaporator. the These values can e.g. B. on a prototype of the refrigerator under standardized A rate conditions are measured, and the limit values thus obtained are in the tax set up the refrigeration units supplied by the manufacturer.  

According to a simple embodiment, these limit values can be predefined. However, it is also conceivable to design the control device in such a way that it is able to to change these limits.

The control device is preferably capable of moving from the heating device to the heater the evaporator to measure the time required and thus draw a conclusion about the deed to actually obtain the amount or layer thickness of frost present on the evaporator. If the time required for defrosting one of the optimal amount of frost If the setpoint deviates, the control device changes the limit values of the second sensor so that the time required for dismantling converges to the setpoint. That is, if defrosting takes too long, the limit of the temperature difference is reduced, if it doesn't last long enough, it will be raised.

Such an adjustment of the limit values is preferably carried out selectively only for those Limit values that are assigned to pairs of outside and cold room temperature, which only have a small distance from the outside temperature-cold room temperature pair which the defrost time was measured. Through this selective rain In the course of its operation, a refrigeration device according to the invention acquires a set of Limit values of the second temperature sensor, which is absolutely flexible to the specific Operating conditions of the refrigerator is adapted.

Further features and advantages of the invention result from the following description description of an embodiment with reference to the accompanying figures. Show it:

Figure 1 is a highly schematic representation of a refrigerator according to the invention. and

Fig. 2 is a flowchart of a control process executed by the control means of the refrigeration device.

Fig. 1 shows a highly schematic representation of a refrigerator with an isolate the housing 1 , which encloses a cooling room 2 . From a refrigerant circuit of the refrigerator, an evaporator 3 in the interior of the refrigerator and a compressor 4 are shown in the figure, which supplies the evaporator 3 with liquefied refrigerant and sucks evaporated refrigerant therefrom. A first sensor 5 is arranged in the cold room for detecting its temperature Ti. A second temperature sensor 6 is located on the evaporator 3 in the vicinity of the refrigerant inlet in order to measure the evaporating temperature T _{v of} the refrigerant. A third sensor 7 for measuring the outside temperature T _e is arranged outside the housing 1 . All three sensors are connected to a control device, here a microprocessor 8 . The microprocessor 8 regulates the operation of the compressor 4 on the basis of the temperature T _i measured by the first sensor 5 , and it controls the operation of a heating element 9 arranged on the evaporator 3 on the basis of the temperatures measured by all three sensors 5 , 6 , 7 and a set of limits value, the memory 10 connected in another microprocessor 8 is stored.

The method performed by the microprocessor 8 to control the operation of the heater 9 is described with the flow chart of FIG. 2.

In a first step S1, the microprocessor 8 detects the temperatures T _{i of} the interior, T _e of the interior and T _{v of} the evaporator measured by the sensors 5 , 6 , 7 . In step S2, he determines a limit value T _{lim of} the evaporator temperature assigned to the measured values of T _i , T _e . This determination can, for. B. done by the microprocessor 8 among the pairs of indoor and outdoor temperature to which a limit value is stored in the memory 10 , which determines the measured pair of indoor and outdoor temperature closest and assumes its limit as the assigned limit , It is also conceivable to round the measured temperature values to the next higher or lower temperature value, for which a limit value is present in the memory 10 .

An alternative is that the microprocessor 8, for a pair (T _i , T _e ) of measured inside and outside temperatures, those four pairs (T _i- , T _e- ), (T _i- , T _{e +} ), (T _{i +} , T _e- ) and (T _{i +} , T _{e +} ) are determined, for the T _i- (T _e- ) the one closest to T _i (T _e ) and T _{i +} (T _{e +} ) the one smaller than T _i (T _e ) is the next higher temperature value, to which a limit value is stored in the memory 10 , and that the microprocessor sets the limit value for (T _i , T _e ) by interpolating the limit values to (T _i- , T _e- ), (T _i- , T _{e +} ), (T _{i +} , T _e- ) and (T _{i +} , T _{e +} ).

In step S3, the found limit value T _{lim is} compared with the evaporator temperature T _v . If the evaporator temperature is higher than the limit, it is concluded that defrosting is not yet necessary and the process returns to the beginning. If the evaporator temperature T _{v is} lower than the limit value, it is assumed that a frost layer has formed on the evaporator which must be defrosted. As a result, the microprocessor 8 sets a timer to 0 in step S4 and starts supplying the heater 9 with power to defrost the evaporator 3 . As soon as the temperature T _v measured by the second sensor rises above 0 ° C., it is assumed that the evaporator has been defrosted, the power supply to the heating device 9 is interrupted and the microprocessor 8 reads out the timer in order to find out the duration t of the defrosting process (Step S5). In step S6, the duration t is compared with a first limit value. If the duration t is greater than this limit value lim1, the limit value read from the memory 10 in step S2 is reduced in step S7. All other limit values in the memory remain unchanged. If t is smaller than the target value lim1, a comparison of the time period t with a smaller target value lim2 follows in step S8. If the time period t falls below this target value, the limit value T _lim determined in step S2 is increased in the memory 8 in step S9.

If t lies between the two limit values lim1 and lim2, this means that the defrosting time is within the desired, predetermined range, and T _lim remains unchanged. The reduction or increase in T _lim in steps S7 or S9 can be carried out by subtracting or adding a fixed, small positive value or by subtracting or adding a value proportional to the difference between t and the target value lim1 or lim2. A reduction or enlargement by multiplying or dividing by a predetermined fixed factor or a factor proportional to the difference is also possible. Alternatively, it is also possible to use a single setpoint instead of the two setpoints lim1 and lim2, and to carry out step S7 if t exceeds the setpoint and to carry out step S9 if t falls below the setpoint.

If the limit value T _{lim has} been determined by interpolation as indicated above, all limit values in the memory 10 that have been included in the interpolation are adapted in the manner described above. The extent to which a limit value is adapted is expediently proportional to the weight with which the limit value was included in the interpolation.

With the method described above, a limit value Tiim for the evaporator temperature is obtained over time for each operating condition of the refrigeration device defined by a pair (from an outside temperature T _e and an inside or cold room temperature T _i ), which is exactly a predetermined target thickness of a frost layer corresponds to the evaporator 3 . Changes in the operating conditions, be it due to fluctuations in the outside temperature T _e or because a user sets a changed refrigerator compartment temperature T _i between two defrosting processes, can no longer lead to disturbances in the rhythm of the defrosting processes, since the appropriate evaporator for all combinations of these temperatures Limit temperature T _v is stored as a limit in the memory 10 . The defrosting is therefore completely independent of time. It does not perform superfluous defrosting if, e.g. B. due to a temporary absence of the user, the door of the refrigerator is not opened and no moisture can penetrate inside and form frost on the evaporator. If the door remains open for a longer period of time and accordingly more moisture than usual gets into the device, defrosting is accordingly more frequent. A change in the behavior of the control, which could lead to an inappropriate control in subsequent normal operation, is not connected to this.

Claims (8)

1. Refrigeration device with a cooling space ( 2 ), a arranged on the cooling space ( 2 ) Ver evaporator ( 3 ) for a refrigerant, a first sensor ( 5 ) for detecting a temperature (T _i ) of the cooling space ( 2 ) and a second sensor ( 6 ) for detecting a temperature (T _v ) of the refrigerant, a heating device ( 9 ) for the evaporator ( 3 ) and a control device ( 8 ) for operating the heating device ( 9 ) as a function of that of the first ( 5 ) and second sensor ( 6 ) ge measured temperatures (T _i , T _v ), characterized in that it further comprises a third sensor ( 7 ) for detecting an outside temperature (T _e ), and that the control device ( 8 ) is set up, the heating device ( 9 ) to be activated when the temperature (T _v ) measured by the second sensor ( 6 ) falls below a limit value which is dependent on the temperatures (T _i , T.) Measured by the first ( 5 ) and third sensor ( 7 ) _e ) is fixed. 2. Refrigerating appliance according to claim 1, characterized in that the Steuereinrich device ( 8 ) comprises a memory ( 10 ) which records values of the limit value (T _lim ) for different pairs of outside and cold room temperature. 3. Refrigerating appliance according to claim 2, characterized in that the Steuereinrich device ( 8 ) has an interpolation unit for calculating the limit value for pairs of temperatures (T _i , T _e ) measured by the first ( 5 ) and third sensor ( 7 ) on the basis of those in FIGS Memory ( 10 ) includes recorded values. 4. Refrigerating appliance according to one of the preceding claims, characterized in that the limit values (T _lim ) for all pairs of outside and cold room temperature (T _i , T _e ) are chosen such that they have a predetermined thickness on the evaporator ( 3 ) correspond. 5. Refrigerating appliance according to one of the preceding claims, characterized in that the limit values (T _lim ) of the second temperature sensor ( 6 ) are fixed ben. 6. Refrigerating appliance according to one of claims 1 to 4, characterized in that the limit values (T _lim ) of the second temperature sensor ( 6 ) can be changed by the control device ( 8 ). 7. Refrigerating appliance according to claim 6, characterized in that the Steuereinrich device ( 8 ) is able to measure the time (t) required by the heating device ( 9 ) for defrosting the evaporator ( 3 ) and if this time deviates from a setpoint (lim1, lim2) to change the limit values (T _lim ) of the second sensor ( 6 ) so that the time (t) required for defrosting converges to the setpoint. 8. Refrigerating appliance according to claim 7, characterized in that when the given time (t) deviates from the target value (lim1, lim2) for a given pair of outside and cold room temperature (T _i , T _e ), the control device ( 8 ) the limits of the given pair of adjacent temperature pairs changed more than those of more distant ones.