PL201063B1 - Air-temperature regulated refrigerator - Google Patents

Abstract

Disclosed is a refrigerator comprising a heat-insulating housing (2), one evaporator (6), two spaces (3, 4) which are surrounded by the housing and are cooled by said one evaporator (6) to different set-point temperatures, a source (10-12) supplying the evaporator (6) with fluid cooling means, a temperature sensor (17), and a control unit (13) controlling the operation of the source (10-12) in relation to a temperature detected by said first temperature sensor (17). The temperature sensor is positioned in such a way that the air temperature in the warmer (3) of the two spaces (3, 4) is detected.

Description

(12) PATENT DESCRIPTION (19) PL (11) 201063 (21) Filing number: 369369 ^{(13) B1} (22) Filing date: 10.01.2003 ^{(51) Int.Cl.}

F25D 11/02 (2006.01) (86) Date and number of the international application: F25D 29/00 (2006.01)

2003-01-10, PCT / EP03 / 00185 G05D 23/19 (2006.01) (87) International application publication date and number:

24.07.2003, WO03 / 060402 PCT Gazette No. 30/03 (54)

Refrigerator with a heat-insulating casing

(30) Priority: 01/21/2002, DE, 10202134.1 (73) The right holder of the patent: BSH BOSCH UND SIEMENS HAUSGERATE GMBH, Munich, DE (43) Application was announced: April 18, 2005 BUP 08/05 (72) Inventor (s): Helmut Konopa, Leipheim, DE (45) The grant of the patent was announced: March 31, 2009 WUP 03/09 (74) Representative: Dziarnowska Monika, POLSERVICE, Kancelaria Rzeczników Patentowych Sp. z o.o.

(57) Refrigerator with a thermally insulating casing (2), an evaporator (6) and two chambers (3, 4), surrounded by the casing cooled by the evaporator to different desired temperatures, a source for supplying the evaporator (6) with a liquid refrigerant, the first temperature sensor (17) and a control unit (13) for controlling the operation of the evaporator power source (6), depending on the temperature measured by the first temperature sensor (17), measuring the air temperature in the warmer of the two chambers (3) and the second temperature sensor (18). ), characterized in that the second temperature sensor (18) measures the temperature of the chamber (4), the cooler of the two chambers (3, 4), the control unit (13) maintaining the first operating mode by means of a power source for the evaporator (6), such as for a long time, the temperature measured by the second temperature sensor (18) is below a predetermined threshold, so that the temperature measured by the first temperature sensor (17) remains in the desired range.

PL 201 063 B1

Description of the invention

The subject of the invention is a refrigerator with a thermally insulating casing, an evaporator and two chambers surrounded by the casing and cooled by the evaporator to different desired temperatures.

Known refrigerators of this type are, for example, refrigerated cabinets with a freezer compartment arranged inside, the walls of which are usually formed by an evaporator. Since heat can only penetrate from the outside through a small part of its surface into this freezer compartment, which is surrounded by an evaporator for a large part of its surface, it achieves much lower storage temperatures than the main refrigeration compartment of such a refrigerator.

Usually, the temperature in both chambers of such a refrigerator is regulated by a temperature sensor which is placed on the evaporator and measures its temperature. If the evaporator temperatures must be below 0 ° C for the operation of the freezer compartment, a layer of frost or ice will form on the surface of the evaporator when the refrigerator is operated for a long time. This layer leads to the thermal isolation of the evaporator from the main cooling chamber of the refrigerator, causing that with increasing icing, the evaporator takes less and less heat. As a result, the run times of the source of the liquid refrigerant supply to the evaporator are shorter than, for example, the evaporator requires, in order to maintain the temperature measured by the sensor within the predetermined range desired. However, the decreasing cooling capacity of the evaporator with increasing icing leads to higher temperatures in the refrigerating chambers of the refrigerator. The refrigerator can no longer perform its function well and there is a risk that the foodstuffs stored there will deteriorate prematurely. If the user perceives this situation and at the same time determines that the evaporator is hardly working, then it can easily come to the wrong assumption that the refrigerator is damaged.

The aim of the invention is to provide a refrigerator of the type mentioned at the outset, in which the increasing icing of the evaporator cannot cause an undesirable increase in temperatures inside the chambers and the way of operating with excessive icing does not lead the user to believe that it is damaged, but allows him to intuitively understand that it is necessary to defrosting.

Refrigerator with a heat-insulating casing, an evaporator and two compartments surrounded by the casing and cooled by the evaporator to different desired temperatures, a source for supplying the evaporator with liquid refrigerant, a first temperature sensor and a control unit for controlling the operation of the evaporator supply source depending on the temperature measured by the first temperature sensor measuring the air temperature in the warmer of the two chambers and the second temperature sensor, characterized according to the invention in that the second temperature sensor measures the temperature of the cooler of the two chambers, the control unit maintaining the first operating mode by means of an evaporator power source as long as the temperature measured by the second temperature sensor is below a predetermined threshold, such that the temperature measured by the first temperature sensor remains within the desired range.

Preferably, the evaporator forms a wall delimiting the two chambers from one another, and the control unit changes the operating mode from the first operating mode to the second operating mode if the temperature measured by the second temperature sensor exceeds a first predetermined threshold, it regulates the average output of the evaporator feed. in the second mode of operation to a higher value than in the first mode of operation.

The control unit also preferably changes the second operating mode to the first operating mode if the temperature measured by the second temperature sensor lies below a second predetermined threshold, the second threshold being lower than the first, the control unit continuously energizing the source in particular in the second operating mode. evaporator feed.

Preferably, the control unit has a third user-settable mode of operation in which it does not feed the evaporator power source and the refrigerator has a heating device for heating the evaporator, and the control unit is arranged to drive the heating device in the third mode of operation, the control unit being set up. alternating the third mode of operation to the first or second mode of operation, if the temperature measured by the second temperature sensor exceeds the third threshold.

Due to the fact that the first temperature sensor in the refrigerator according to the invention is arranged in such a way that it measures the air temperature in the warmer of the two refrigerated chambers of the refrigerator, it is ruled out that excessive icing of the evaporator may lead to an undesirable temperature rise in this chamber. Instead, the operating phases of the refrigerant source are necessary

Due to icing, they are getting longer and longer to maintain the desired temperature in the chamber controlled by the sensor. The user can therefore hear that the refrigerator is running and make no false conclusions as to its operating state.

A refrigerator provided with a second temperature sensor to measure the temperature of the colder of the two compartments has a second temperature sensor not used as usual temperature sensors are placed e.g. on the evaporator for the purpose of keeping the evaporator temperature constantly within the desired range, but this serves essentially as a precautionary measure against control errors which could result from the exclusive use of the first temperature sensor at extremely low ambient temperatures or with very low cooling settings. Namely, if very low cooling is set or the ambient temperature in which the refrigerator is placed is slightly higher than the desired temperature in the warmer interior space, then this leads to very short operating phases of the refrigerant source, which may not be sufficient to keep the temperature value low enough. in the cooler of the two chambers. In order to avoid this problem, it is provided that the control unit which controls the operation of the refrigerant source is set to change the first operating mode or normal operating mode as long as the evaporator temperature measured by the second temperature sensor or in the second compartment is below a predetermined threshold and the first operating mode controls the operation of the temperature source such that the temperature measured by the first temperature sensor in the warmer chamber remains within the desired range. However, if the temperature measured by the second temperature sensor exceeds a first predetermined threshold, it is envisaged that the control unit will switch the first mode operation to the second mode operation, with the average output of the source in the second mode of operation being adjusted to a higher value than in the first mode. In the second mode of operation, the control unit preferably drives the source continuously.

If the temperature measured by the second temperature sensor does not reach a predetermined second threshold below the first, the control unit switches the second operating mode back to the first.

In order to defrost the evaporator if necessary, in a simple design of the refrigerator it is obviously sufficient to turn it off and then turn it on again after complete defrosting. The control unit, however, has a user-settable third mode of operation or a defrost mode in which it does not supply power to the source. If the refrigerator has a heating device for heating the evaporator, it can be provided that in this third operating mode the control unit is set to control the heating device in order to accelerate defrosting.

Moreover, the control unit is preferably set to automatically switch from the third mode of operation to the first or second mode of operation if the temperature measured by the second temperature sensor exceeds a third threshold which indicates complete defrosting of the evaporator. In this embodiment, it is therefore sufficient for the evaporator to defrost that the user gives the control unit an instruction relating thereto; after defrosting, the control unit returns to normal cooling operation without any user intervention.

Fig. 1 shows a perspective view of a refrigerator in which the present invention can be used, Fig. 2 is a diagram showing various functional elements of the refrigerator, and Figs. 3A to Fig. 3C show course of temperatures measured by refrigerator temperature sensors as a function of time and phase of operation of the refrigerator evaporator.

Fig. 1, as an embodiment of the present invention, shows a perspective view of a refrigerated cabinet with the door open 1. The heat-insulating casing 2 of the refrigerated cabinet contains an interior space that is divided into a basic refrigerating chamber, chamber 3 and a freezer chamber, chamber 4. Chamber 4. having a nearly square shape in cross section is placed in the upper corner of the inner space. On its front side facing the door 1 it has a closed, half-open cover 5 shown in FIG. 1. The four walls adjacent to the front side of the cuboid are formed by an evaporator 6, on the outer surface of which the refrigerant pipes 1 are visible.

Under the freezer compartment 4 there is a flat, pull-out container 8. It extends along the entire length of the bottom of the compartment 4 and serves to collect water from the melting frost which drips down from it when defrosting the evaporator 6.

The diagram in Fig. 2 shows the various functional elements of the refrigerator. Visible is the housing 2, shown here as a closed door 1, and a base chamber inside the housing

The refrigerant 3 and a freezer compartment 4 surrounded by an evaporator 6. A suction line 9 for the evaporated refrigerant extends from the evaporator 6 to the compressor 10. The pressure line 11 coming from the compressor 10 to the evaporated refrigerant passes through the evaporator 6 before reaching the evaporator 6. condenser 12 mounted on the rear side of the casing 2.

The control unit 13 for controlling the operation of the evaporator 6 is connected to the operating elements 15 or indicators 16 mounted on the front plate 14 of the housing 2 and to two temperature sensors 17, 18, the first 17 of which is mounted inside the primary refrigerating chamber of the chamber 3 or on its wall at a distance from the evaporator 6 for measuring the air temperature prevailing in the primary chamber 3. A second temperature sensor 18 is mounted on the evaporator 6 and measures the temperature of the chamber 4.

The control unit 13 has three operating modes. In the first operating mode, it switches on the compressor 10 depending on the temperature T _N measured by the temperature sensor 17 and switches it off in order to keep this temperature T _N within a predetermined tolerance range around a target value that is set by the user at one of the operating elements 15.

Fig. 3A shows the course of the temperature T _N in the primary refrigerating chamber 3 as measured by the temperature sensor 17 as a function of time t. If the temperature T _N lies at the upper end of the tolerance range, then the control unit 13 turns on the compressor 10 and keeps it running for as long as possible. until the temperature T _N reaches the lower limit of the tolerance range. The respective operating phases of the compressor 10 are shown in Fig. 3B.

Over time, due to the ingress of moisture when opening and closing the door 1 or due to water evaporating from the stored refrigerated goods, a layer of frost forms on the evaporator 6, which isolates it more and more from the primary refrigerating chamber 3. Therefore, the cooling speed the operating phases of the compressor 10 decrease with the passage of time and the operating phases of the compressor 10 become longer. As a result, undesirable heating of the refrigerated goods in the primary chamber 3 is ruled out.

As the frost layer on the evaporator 6 generally grows slower in the freezer compartment 4 than in the primary compartment 3, the increasing duration of the compressor 10 operating phases leads to a temperature course in the freezer compartment T _E shown in Fig. 3C. With the increasing duration of the operating phases of the compressor 10, it shows a downward trend which is not detrimental to the shelf life of the foodstuffs stored in the freezer compartment.

The lower the ambient temperature in which the refrigerator is set, the slower the increase in temperature T _{N is} and the greater the time interval between the two phases of its operation. If the control unit 12 had only a temperature sensor 17 for measuring the air temperature in the primary refrigerating chamber, this could lead to the temperature being undesirably high with sufficient cooling in the primary refrigerating chamber 3 of the freezer chamber 4. Prevents this second temperature sensor 18. FIG. 2 shows a second temperature sensor 18 mounted on the evaporator 6. More specifically, with such a placement of the second sensor 18, as measured by its temperature differs from the temperature T _E prevailing in the chamber 4 of the freezer compartment. This difference is small, however, as the evaporator 15 forms a large part of the surface of the freezer compartment 4 and the heat flow through the front and rear walls of the compartment 4 compared to the heat flow through its four walls formed by the evaporator 15 is small. Alternatively, in order to measure its temperature, the second sensor 18 could be placed in the freezer compartment 4 at a distance from the evaporator 6.

If the second temperature sensor 18 signals the control unit 12 a temperature below a critical first threshold, e.g. -5 ° C, then it switches to a second operating mode in which the compressor 10 is driven continuously, regardless of the temperature T _N measured by the temperature sensor 17. Only when the evaporator temperature drops below the second threshold, for example -10 ° C, and therefore sufficient cooling of the freezer compartment is guaranteed, the control unit returns to the first operating mode.

For simplicity, these two thresholds may be predetermined by the manufacturer of the refrigerator. Generally, there is no need for the user to define them himself. However, it may be advantageous if the control unit 13 provides the user with the possibility of completely locking the second mode of operation. As a result, energy can be saved when the freezer compartment is empty and the temperatures can be assumed at the first threshold such that the refrigerated goods are not spoiled.

Furthermore, by actuating the corresponding operating element 15, the control unit 13 is switched to the third operating mode, defrosting. This mode of operation simply can rely on

In that the control unit can turn off the compressor, but with the compressor off, it controls the temperature measured by the second temperature sensor 18, and if a positive Celsius temperature is reached, which indicates complete defrosting of the evaporator 6, the control unit returns to the first or second operating mode .

To speed up the defrosting process, the evaporator 6 may be provided with a heating device (not shown) which is controlled by the control unit 13 as long as it is in its third operating mode.

In order to defrost the refrigerator, it is therefore sufficient that the user once activates the corresponding operating element for activating the defrosting process. When defrosting is complete, the refrigerator automatically resumes normal cooling operation. The user, at a corresponding later point in time, only needs to remove the melted frost water collected in the container 8.

Claims (8)

Patent claims 1. Refrigerator with a heat-insulating casing, an evaporator and two compartments surrounded by a casing and cooled by the evaporator to different desired temperatures, a source for supplying the evaporator with liquid refrigerant, a first temperature sensor and a control unit for controlling the operation of the evaporator supply source, depending on temperature measured by the first temperature sensor measuring the air temperature in the warmer of the two chambers and the second temperature sensor, characterized in that the second temperature sensor (18) measures the temperature of the chamber (4), the cooler of the two chambers (3, 4), the control unit (13) maintains the first operating mode by means of the evaporator power supply (6) as long as the temperature measured by the second temperature sensor (18) is below a predetermined threshold, such that the temperature measured by the first temperature sensor (17) remains at a temperature. desired range. 2. A refrigerator according to claim 1 A wall as claimed in claim 1, characterized in that the evaporator (6) forms a wall delimiting the two chambers (3, 4) from one another. 3. Refrigerator according to claim 1 The method of claim 1, characterized in that the control unit (13) changes the operating mode from the first operating mode to the second operating mode if the temperature measured by the second temperature sensor (18) exceeds the first predetermined threshold, it regulates the average efficiency of the evaporator power source ( 6) in the second mode of operation to a higher value than in the first mode of operation. 4. Refrigerator according to claim 1 The method of claim 3, characterized in that the control unit (13) changes the second operating mode to the first operating mode, if the temperature measured by the second temperature sensor (18) is below a second predetermined threshold, the second threshold being lower than the first. 5. Refrigerator according to claim 1 3. The device according to claim 3 or 4, characterized in that in the second operating mode, the control unit (13) continuously supplies the power source for the evaporator (6). 6. Refrigerator according to claim 1 A device according to claim 3, characterized in that the control unit (13) has a third user-settable mode of operation in which it does not feed the evaporator (6) power. 7. Refrigerator according to claim 1 6. The refrigerator as claimed in claim 6, characterized in that the refrigerator has a heating device for heating the evaporator (6) and the control unit (13) is arranged to drive the heating device in the third operating mode. 8. Refrigerator according to claim 1 The method of claim 6 or 7, characterized in that the control unit (13) is set to change the third mode of operation to the first or second mode of operation, if the temperature measured by the second temperature sensor (18) exceeds the third threshold.