KR20010030294A - Refrigerator - Google Patents

Abstract

PURPOSE: To maintain the average temperature of a refrigerating chamber at a target temperature even when temperature changes. CONSTITUTION: In the winter season having low temperature, before the temperature of a refrigerating chamber does rise to an ON-temperature. an F-cooling mode is finished. As a result, when the average temperature of the refrigerating chamber is lower than a target temperature, OFF-temperature is raised. Then, since an R-cooling mode is finished at an OFF-temperature higher than a previously set temperature, the average temperature of the refrigerating chamber rises to effectively prevent food from being frozen. On the contrary, when temperature is high, even if the temperature of the refrigerating chamber rises to the ON-temperature or higher, the F-cooling mode may not be completed. As a result, the average temperature of the refrigerating chamber may be higher than the target temperature. In this case, the OFF-temperature is lowered. Thus, since the R-cooling mode is finished at the OFF-temperature lower than the previouslyset OFF-temperature, the average temperature of the refrigerating chamber is lowered to preserve freshness of the food.

Description

Refrigerator {REFRIGERATOR}

The present invention relates to a refrigerator having a configuration in which coolant is alternately supplied to a refrigerating cooler and a freezing cooler to alternately cool the refrigerating compartment side and the freezing compartment side.

Conventional refrigerators are generally configured to cool the refrigerating compartment, the vegetable compartment and the freezer compartment lower than them by a cooling system consisting of one cooler and one cold air circulation fan, and the air cooled by the cooler is cooled by a cold air circulation fan. Each chamber is blown through a cold air circulation duct or an electric damper to cool each chamber.

However, in the refrigerator having this configuration, since the temperature of the cold air supplied to the refrigerating compartment or the vegetable compartment is extremely low as the temperature of the cold air supplied to the freezer compartment, the cold air circulation duct or the electric damper that supplies cold air to the refrigerating compartment or the vegetable compartment must be insulated. As a result, the volume of a cold air circulation duct and an electric damper became large, and this became an impediment factor in the case of aiming at the improvement of a volume ratio (content of the external dimension of a refrigerator).

In order to solve this problem, a cooler is arranged on the refrigerating compartment side and the freezing compartment side, respectively, and the coolant is alternately supplied to the refrigerating cooler and the freezing cooler to alternately cool the refrigerating compartment side and the freezing compartment side, and the compressor or cold air circulation is performed. A refrigerator is provided in which the rotation speed of the fan is changed so that each cooler is controlled to a temperature suitable for the temperature range of the refrigerating chamber and the freezing chamber.

Referring to the switching control method for alternate cooling of the refrigerator, first, an off temperature lower than the target temperature and an on temperature higher than the target temperature are set in the refrigerating chamber and the freezing chamber, respectively. Basically, when the temperature sensor for the refrigerating compartment and the temperature sensor for the freezing compartment detect the off temperature, the state of supplying the refrigerant to the refrigerator cooler (hereinafter referred to as R cooling mode) and the state of supplying the refrigerant to the refrigerator cooler (hereinafter referred to as , F cooling mode). By such alternating cooling, the temperatures of the refrigerating compartment and the freezing compartment change up and down respectively between the on temperature and the off temperature, so that the refrigerating compartment and the freezing compartment are maintained at respective target temperatures as their average temperatures.

However, in the above-described switching control method, for example, in winter, when the temperature decreases, the heat transfer between the inside of the refrigerator and the outside of the refrigerator decreases, so that the temperature rise of the refrigerating compartment is slow, and the F cooling mode is not carried out until the temperature rises. Is terminated and enters the R cooling mode, resulting in a problem that the average temperature of the refrigerating chamber is lower than the target temperature.

In contrast, when the target temperature of the refrigerating chamber is set at 2 ° C, if the off temperature is set at 1.5 ° C and the on-temperature is set to 2.5 ° C, the average temperature of the refrigerating chamber is not lowered to such an extent even in winter. By the way, in recent years, it is considered to keep food more freshly by setting the target temperature of a refrigerator compartment to 1 degreeC. In this case, the off temperature of the refrigerating chamber is set to 0.6 ° C and the on temperature of 1.4 ° C, for example, so that the average temperature is controlled to 1 ° C. However, in this case, the F cooling mode ends and the R cooling mode is started before the refrigerating compartment temperature rises to 1.4 ° C. in winter, and as a result, the average temperature of the refrigerating compartment is lower than the target temperature (1 ° C.) to partially freeze the food. I might do it.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a refrigerator capable of maintaining the average temperature of the refrigerating chamber close to the target temperature even when the temperature changes.

1 is a temperature change diagram of a refrigerating chamber for explaining the operation in one embodiment of the present invention.

Fig. 2 is a diagram showing temperature changes of the refrigerating chamber and the freezing chamber in normal times.

3 is a configuration of a refrigeration cycle.

4 is a block diagram showing an electrical configuration.

5 is a cross-sectional view of the refrigerator.

Figure 6 corresponds to Figure 3 showing another embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

3: cold storage room

4: Vegetable Room

5: specification switching room

6: freezer

13: refrigeration cooler

14: refrigerating circulation fan

20: refrigeration cooler

21: freezing circulation fan

23: compressor

26: three-way valve (euro switching means)

30: temperature sensor for the refrigerator compartment (temperature sensor for the refrigerator)

31: freezing chamber temperature sensor (freezing temperature sensor)

38, 39: solenoid valve (euro switching means)

In order to achieve the above object, the present invention,

A refrigerator for cooling the refrigerator compartment side,

A freezer for cooling the freezer compartment side,

A refrigeration temperature sensor for detecting a temperature on the refrigerating chamber side;

A freezing temperature sensor detecting a temperature at the freezing compartment side;

Flow path switching means for switching a coolant flow path between a first flow path for supplying a coolant from a condenser to the refrigeration cooler and a second flow path for supplying the cooler for cooling;

In order to cool the refrigerating compartment side and the freezing compartment side alternately, when the refrigerating temperature sensor and the refrigerating temperature sensor detect an off temperature set lower than a target temperature, respectively, the flow path switching means is controlled to control the first flow path and the first flow path. It is provided with the control means which alternately switches to 2 flow paths,

When the average of the detected temperature of the refrigerating temperature sensor is lower or higher than the target temperature, the off temperature on the refrigerating compartment side is configured to be higher or lower.

According to this configuration, in the winter or the like when the temperature decreases, the F cooling mode ends and the R cooling mode is started while the refrigerator compartment does not rise to the on temperature, and as a result, when the average temperature of the refrigerator compartment becomes lower than the target temperature, the off temperature Becomes higher. Then, the R cooling mode ends when cooled to the corrected off temperature higher than the previous off temperature, so that the average temperature of the refrigerating chamber rises and approaches the target temperature.

On the contrary, when the air temperature is high, the refrigerating chamber becomes a higher temperature than usual at the end of the F cooling mode, and as a result, the average temperature of the refrigerating chamber may be higher than the target temperature. In this way, the off temperature of the refrigerating chamber is lowered. Then, since the R cooling mode is cooled down to the corrected off temperature lower than the previous off temperature, the average temperature of the refrigerating chamber is lowered to approach the target temperature.

In this case, on the refrigerating chamber side, an on temperature higher than the target temperature is also set in addition to the off temperature, and when the average of the detected temperature of the refrigerating temperature sensor is lower or higher than the target temperature, both the off temperature and the on temperature on the refrigerating chamber side are high or You may comprise so that all may be made low.

The temperature on the refrigerator compartment side is used for estimating the load on the refrigerator compartment side, for example, by comparison with the detected temperature of the refrigerator temperature sensor. For this reason, when the average of the detected temperature of the refrigerating temperature sensor is lower or higher than the target temperature, the one with the higher or lower temperature as well as the off temperature on the refrigerating chamber side is smaller or larger. It is estimated as (large) and quickly approaches the target temperature.

It is preferable to obtain | require the average of the detected temperature of the said refrigerating temperature sensor every predetermined time, and to compare it with a target temperature.

The temperature of the room where the refrigerator is installed does not change so much in a short time, for example, about 1 hour. For this reason, it is wasteful to reset off temperature on the refrigerator compartment side every short time. From this point of view, it is reasonable to obtain the average of the detected temperatures of the refrigerating temperature sensor every relatively long time and change the off temperature in comparison with the target temperature.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS.

5 shows a schematic of an overall configuration of a refrigerator. In Fig. 5, the refrigerator main body 1 has a housing shape with an open front face, and is formed by filling a foamable heat insulating material between a resin inner housing and a steel plate outer housing. The heat insulation partition wall 2 is integrally formed in the internal middle part of this refrigerator main body 1, and the inside of the refrigerator main body 1 is set to a different temperature space by the upper part and the lower part of the heat insulation partition wall 2 here. .

In the refrigerator main body 1, the refrigerating chamber 3 and the vegetable chamber 4 are formed up and down in the upper space of the heat insulation partition wall 2, and the ice-making room (shown in the lower space of the heat insulation partition wall 2). And the specification switching chamber 5 are arranged side by side to the left and right, and the freezing chamber 6 is formed below the ice making chamber and the specification switching chamber 5. The front face portions of these chambers 3 to 6 are opened and closed by doors 8 to 11. In addition, although the ice-making chamber and the freezing chamber 6 communicate with each other, the specification switching chamber 5 is partitioned from the ice-making chamber and the freezing chamber 6 by the heat insulation wall 7, and is formed as an independent space.

The refrigeration cooler chamber 12 is formed in the rear part of the said vegetable chamber 4, The refrigeration cooler 13 is arrange | positioned in this refrigeration cooler chamber 12. As shown in FIG. And the air cooled by this refrigeration cooler 13 is conveyed to the cold air duct 15 by the variable speed refrigeration circulation fan 14 by an inverter. The cold air duct 15 is provided from the rear surface of the refrigerating chamber 3 to the ceiling surface, and cold air is blown to the whole inside the refrigerating chamber 3 from the blowout port 15a formed in this cold air duct 15. The cold air blown into the refrigerating compartment 3 from the cold air duct 13 is blown into the vegetable compartment 4 through the communication port 17 formed in the partition plate 16 partitioning the refrigerating compartment 3 and the vegetable compartment 4. After that, the suction port 18 formed in the front face of the refrigerating cooler chamber 12 is sucked into the refrigerating cooler chamber 12.

On the other hand, a freezing cooler chamber 19 is formed in the rear portion of the freezing chamber 6. The refrigeration cooler 20 is arrange | positioned in this refrigeration cooler chamber 19, The cold air cooled by this refrigeration cooler 20 is controlled by the variable speed refrigeration circulation fan 21 by an inverter. It blows into the ice chamber, the specification switching chamber 5, and the freezing chamber 6. The cold air blown through the ice making chamber, the specification switching chamber 5 and the freezing chamber 6 is finally sucked into the freezing cooler chamber 19 from the suction port 22 formed in the front surface of the freezing cooler chamber 19. It is.

In addition, the specification switching chamber 5 is controlled at the set temperature by receiving the supply of cold air in accordance with the opening and closing of the electric damper (not shown). In this case, the set temperature can be switched according to the use desired by the user. As the use purpose, the freezing chamber (about -18 ° C), partial chamber (about -3 ° C), chilled chamber (about 0 ° C), and refrigerating chamber ( About 1 degreeC), a vegetable room (about 3 degreeC), and a wine cooling room (about 8 degreeC) are set.

Next, in FIG. 3 which shows the structure of a refrigeration cycle, the compressor 23 is comprised by the inverter apparatus 24 (refer FIG. 4) by rotation speed variable (capacity variable). The discharge port of this condenser 23 is connected to the inlet of the condenser 25, and the outlet of the condenser 25 is connected to the inlet of the electromagnetically driven three-way valve 26 as a flow path switching means. One outlet of the three-way valve 26 is connected to the inlet of the refrigerator 20 for cooling through a capillary tube 27, and the other outlet is connected to the inlet of the refrigerator 13 for cooling through a capillary tube 28. . The outlets of the refrigeration cooler 20 and the refrigeration cooler 13 are connected to the suction port of the compressor 23. Further, reference numeral 29 denotes a check valve connected between an outlet of the refrigeration cooler 20 and an outlet of the refrigerating cooler 13.

The electrical configuration of the refrigerator is shown in FIG. In Fig. 4, the input part of the microcomputer 30 as a control means is provided in the freezer compartment 6 as a refrigerating compartment temperature sensor 31 and a freezing compartment temperature sensor provided to detect the temperature in the refrigerating compartment 3 as the refrigerating side temperature sensor. The freezing chamber temperature sensor 32 provided to detect the temperature is connected. In addition, the inverter device 24 of the compressor 23, the refrigerating circulation fan 14, and the inverter devices 33 and 34 of the refrigerating circulation fan 21 are connected to the output of the microcomputer 30. At the same time, the drive circuit 35 of the three-way valve 26 is connected.

Then, the microcomputer 30 is based on the detection signals (hereinafter referred to as detection temperature) of the temperature sensor 31 for the refrigerating chamber and the temperature sensor 32 for the freezer compartment, and the inverter devices 24, 33, and the like. The compressor 23, the refrigeration circulation fan 14 and the refrigeration circulation fan 21 are controlled via the 34, and the three-way valve 26 is controlled via the drive circuit 35.

In the state where the three-way valve 26 communicates the inlet to one outlet, a first flow passage 36 (shown by arrows in FIG. 3 for convenience) is formed to communicate the condenser 25 to the freezing cooler 20. The refrigerant compressed by 23 and condensed in the condenser 25 is supplied to the freezing cooler 20 to cool the ice making chamber, the specification switching chamber 5 and the freezing chamber 6 (F cooling mode). do. In addition, in the state where the three-way valve 26 communicates the inlet to the other outlet, a second flow passage 37 (shown by an arrow in FIG. 3 for convenience) that connects the condenser 25 to the refrigerating cooler 13 is provided. The refrigerant formed, compressed by the compressor 23, and condensed by the condenser 25 is supplied to the refrigerating cooler 13 to be in a mode of cooling the refrigerating chamber 3 and the vegetable chamber 4 (R cooling mode).

In this embodiment, the compressor 23 is based on continuous operation without stopping. The refrigerant 23 is alternately supplied to the refrigerating cooler 13 and the refrigerating cooler 19, and the refrigerating chamber 3 and the freezing chamber 6 ) Alternately cool. In the control of the compressor 23, the refrigerating circulation fan 14, and the refrigerating circulation fan 21, the microcomputer 30 detects the refrigerating compartment temperature sensor 31 and the freezing compartment temperature sensor 32. From the temperature, the on-temperature (higher than the target temperature) and the off-temperature (lower than the target temperature) set for the refrigerating chamber 3 and the freezing chamber 6, the thermal load on the refrigerating chamber 3 side and the freezing chamber 6 side is reduced. The compressor 23 and the refrigerating circulation fan so that the refrigerant flow rate and the airflow amount supplied to the refrigerating cooler 13 and the refrigerating cooler 20 become amounts corresponding to the thermal loads on the refrigerating compartment 3 side and the freezing compartment 6 side. The rotation speeds of the 14 and the freezing circulation fan 21 are controlled to control the average temperatures of the refrigerating chamber 3 and the freezing chamber 6 to be the target temperatures, respectively.

In this case, the microcomputer 30 alternately switches between the R cooling mode and the F cooling mode, such that the temperature sensor 31 for the refrigerating chamber is turned off at the temperature of the refrigerating chamber 3 and the temperature sensor 32 for the freezing chamber is freezer 6. Is performed when the off temperature is detected.

Here, the target temperature of the refrigerating chamber 3 is 1 degreeC, the on temperature is set to 1.4 degreeC, and the off temperature is set to 0.6 degreeC, the target temperature of the freezer compartment 6 is -18 degreeC, the on temperature is -17 degreeC, and the off temperature is It is assumed that is set to -16 ° C.

Assume that the freezing chamber temperature sensor 32 has detected the off temperature (-19 ° C). Then, the microcomputer 30 switches the three-way valve 26 to allow the condenser 25 to communicate with the refrigerating cooler 13, stops the freezing circulation fan 20, and 21). As a result, the cooling mode is switched from the F cooling mode to the R cooling mode.

In this R cooling mode, the air cooled by the refrigerating cooler 13 is blown into the refrigerating chamber 3 and the vegetable chamber 4 to cool both chambers. By this cooling, the detection temperature of the refrigerating compartment temperature sensor 31 gradually decreases as shown by the solid line in FIG. On the other hand, in this R cooling mode, since cold air is not supplied to the ice making chamber, the specification switching chamber 5 and the freezing chamber 6, the detected temperature of the freezing chamber temperature sensor 32 gradually rises as shown in FIG. Going.

When the refrigerating chamber temperature sensor 31 detects the off temperature (0.6 ° C.), the microcomputer 30 switches the three-way valve 26 to communicate the condenser 25 with the freezing cooler 20. At the same time, the refrigeration circulation fan 20 is stopped and the refrigeration circulation fan 21 is driven. As a result, the cooling mode is switched from the R cooling mode to the F cooling mode.

In this F cooling mode, the air cooled by the freezer cooler 20 is blown into the ice making chamber, the specification switching chamber 5, and the freezing chamber 6 to cool each of them. By this cooling, the detection temperature of the freezer compartment temperature sensor 32 gradually decreases as shown by the solid line in FIG. On the other hand, in this F cooling mode, since cold air is not supplied to the refrigerating chamber 3 and the vegetable chamber 4, the detected temperature of the refrigerating chamber temperature sensor 31 gradually rises as shown in FIG.

In this way, the F cooling mode and the R cooling mode are alternately performed. In this case, in the operation of the F cooling mode, the rotation speed of the compressor 23 and the refrigerating circulation fan 21 is selected so that the temperature in the refrigerating chamber 3 is almost at the end of the F cooling mode. And the operation of the R cooling mode is similarly performed at the end of the R cooling mode, when the temperature in the freezer compartment 6 rises to almost the temperature (-17 ° C.). It is supposed to be done at the same time. Thereby, the refrigerator compartment 3 and the vegetable compartment 4 hold | maintain 1 degreeC which is an average temperature and target temperature, and the ice-making chamber and the freezing compartment 6 hold | maintain -18 degreeC which is an average temperature and target temperature.

By the way, in the winter etc. when temperature becomes low, since the temperature rise of the refrigerating compartment 3 becomes slow as shown by the broken line in FIG. 2, F cooling mode will be complete | finished while it does not rise to temperature, and as a result, the refrigerating compartment 3 The average temperature of the c) is lower than 1 ° C, and some of the food may freeze. In this embodiment, the occurrence of such a problem is prevented by the following configuration.

In other words, the microcomputer 30 reads the detected temperature of the refrigerating chamber temperature sensor 31 every fixed short time and stores it in a memory (memory means) such as RAM or EEPROM. Then, the microcomputer 30 reads the detected temperature of the refrigerating compartment temperature sensor 31 stored in the memory every predetermined time, for example, every 5 hours, and calculates the average temperature T thereof (average temperature calculating means). When this average temperature T is lower than the target temperature T0, the microcomputer 30 moves the off temperature and the on temperature by the correction temperature t obtained by the following equation (1) (on-off temperature change Way).

t = (T0-T) / 8

Then, as shown in FIG. 1, the operation of the R cooling mode is then terminated at an off temperature set higher by t ° C than before, and consequently the temperature of the refrigerating chamber 3 rising during the operation of the F cooling mode. Even higher than then. For this reason, as an average temperature of the refrigerating chamber 3, it will become higher than the mean temperature up to that time, and will approach 1 degreeC which is a target temperature.

And when the alternating operation of F cooling mode and R cooling mode is performed for 5 hours in this state, the microcomputer 30 of the refrigerating chamber 3 of the past 5 hours performed in the state which moved off temperature and on temperature by t was performed. An average temperature is calculated | required and the same process as the above is performed. As a result of the correction of the off temperature and the on temperature, when the average temperature of the refrigerating chamber 3 exceeds the target temperature, the correction temperature t obtained by Equation 1 becomes negative, so the on temperature and the off temperature are It is set low, so that the average temperature of the refrigerating chamber 3 is also controlled to approach the target temperature.

Figure 6 shows another embodiment of the present invention. This is configured such that the switching of the refrigerant passage is performed by two first and second solenoid valves 38 and 39. That is, the outlet side of the condenser 25 is divided into two, one branch is connected to the refrigeration cooler 20 via the first solenoid valve 38, and the other branch is connected to the second solenoid valve 39. It is connected to the refrigeration cooler 13 via. Reference numeral 40 denotes a receiver for storing excess liquid refrigerant.

According to this configuration, in the F cooling mode, the first solenoid valve 35 is energized to be in an open state, whereby a first flow path 41 (indicated by an arrow for convenience) is formed to cool the coolant 20 in the refrigerating cooler 20. Is supplied. In addition, in the R cooling mode, the second solenoid valve 36 is energized to be in an open state, whereby a second flow path 42 (shown by an arrow for convenience) is formed to supply a refrigerant to the refrigerating cooler 13. do.

In addition, the present invention is not limited to the embodiments described above and shown in the drawings, and can be expanded or changed as follows.

The moving temperature is not limited to that according to equation (1).

The temperature does not have to move.

The refrigerating temperature sensor is not limited to the refrigerating chamber temperature sensor 31, and may detect the temperature of the vegetable chamber 4, and the refrigerating temperature sensor is not limited to the freezing chamber temperature sensor, and detects the temperature of the ice making chamber. It may be done.

As described above, according to the present invention, the F cooling mode does not end even if the F cooling mode ends or exceeds the on-temperature temperature while the refrigerating chamber does not rise to the on-temperature in winter or when the temperature increases. As a result, when the average temperature of the refrigerating compartment becomes lower or higher than the target temperature, the off temperature becomes high or low. Therefore, the average temperature of the refrigerating compartment is controlled to be close to the target temperature, so that the food can be kept fresh.

Claims (3)

A refrigerator for cooling the refrigerator compartment side, A freezer for cooling the freezer compartment side, A refrigeration temperature sensor for detecting a temperature on the refrigerating chamber side; A freezing temperature sensor detecting a temperature at the freezing compartment side; Flow path switching means for switching a coolant flow path between a first flow path for supplying a coolant from a condenser to the refrigeration cooler and a second flow path for supplying the cooler for cooling; In order to cool the refrigerating compartment side and the freezing compartment side alternately, when the refrigerating temperature sensor and the refrigerating temperature sensor detect an off temperature set lower than a target temperature, respectively, the flow path switching means is controlled to control the first flow path and the first flow path. It is provided with the control means which alternately switches to 2 flow paths, And the off temperature at the side of the refrigerating compartment is increased or decreased when the average of the detected temperatures of the refrigerating temperature sensor is lower or higher than the target temperature. The refrigerating compartment side according to claim 1, wherein an on-temperature temperature higher than the target temperature is also set for the refrigerating compartment side, and when the average of the detected temperatures of the refrigerating temperature sensor is lower or higher than the target temperature. A refrigerator characterized in that both the off temperature and on temperature of the high or low temperature is configured to be low. The refrigerator according to claim 1 or 2, wherein the average of the detected temperatures of the refrigerating temperature sensor is obtained every predetermined time and compared with the target temperature.