KR20090079676A - Refrigerator and control method - Google Patents

Abstract

A refrigerator and a control method of the refrigerator for controlling the temperature of at least one storage room are provided to respectively control temperatures of divided spaces of a single storage room to store articles having different storage temperatures together. A refrigerator includes a heating part(140), a temperature sensor(120) and a controller(130). The heating part is located in at least one storage room and heat the air of the storage room. The temperature sensor senses the storage room temperature around the heating part. The controller controls the operation of the heating part according to the temperature sensed by the temperature sensor to respectively control temperatures of divided spaces of the storage room.

Description

Refrigerator and its control method {Refrigerator and control method}

The present invention relates to a refrigerator and a control method thereof, and more particularly, to a refrigerator and a control method thereof for controlling a temperature in at least one storage compartment provided in the refrigerator.

The refrigerator includes a main body in which at least one storage compartment is formed, and a cooling system for cooling food stored in the storage compartment.

Such a cooling system includes a compressor for compressing a refrigerant, a condenser for condensing the refrigerant in a high temperature and high pressure state compressed by the compressor, and a cooling operation for absorbing latent heat while the refrigerant is evaporated by the refrigerant from the condenser. It includes at least one evaporator for cooling the ambient air.

The storage compartment of the refrigerator further includes a blowing fan for blowing air that has passed through the evaporator to the storage compartment, and a temperature sensor for detecting the temperature of the storage compartment.

In addition, the refrigerator is provided with a temperature control unit for controlling the degree of cooling of each storage compartment, and a control unit for controlling the load including the compressor and the blowing fan according to the temperature level selected by the temperature control unit.

Among these refrigerators, the kimchi refrigerator is a refrigerator made for the purpose of storing kimchi, and the temperature of the inside of the storage room is controlled to be 0 ° C. to 5 ° C. so that the kimchi can be aged and stored.

Recently, the temperature of a plurality of storage spaces formed inside the kimchi refrigerator can be controlled, so that it is used not only for kimchi but also for storing various foods such as vegetables, fruits, and meat.

Such a kimchi refrigerator has a lid type that opens and closes the lid of the upper surface according to the opening and closing method, a drawer type that draws in and draws out a storage space of a drawer shape, and a combination type that mixes a lid type and a drawer type. Kimchi refrigerator of the type has the advantage of excellent ability to control the cold compared to the normal refrigerator opening and closing the front.

However, the Kimchi refrigerator controls the temperature of each storage room by the set temperature of each storage room. When the temperature of the storage room is controlled by the set temperature, the total temperature of one storage room is controlled to be the same so that the set temperature is used to store a specific storage. If the temperature is not appropriate, problems such as decay or freezing of specific storage may occur.

That is, when the storage room stores kimchi at the bottom and the storage room at the top stores vegetables or fruits, if the storage room is set to a temperature for storing kimchi, the vegetables or fruits stored together are frozen. If the temperature is set to kimchi stored together, the problem of rapid ripening occurs.

Conventionally, since the entire space in the storage compartment of the refrigerator is controlled to one set temperature, there is a problem that the storage is corrupted or frozen when the storage is not suitable for storage at the set temperature.

Accordingly, it is an object of the present invention to provide a refrigerator and a method of controlling the same, which allow storage of different storage temperatures in one storage compartment by separately controlling the storage compartment temperature in the refrigerator.

Technical means of the present invention for achieving the above object is provided in at least one storage compartment, the heating unit for heating the air in the storage compartment; A temperature sensing unit sensing a temperature of a storage compartment around the heating unit; And a control unit controlling the temperature of the storage compartment by controlling the operation of the heating unit according to the temperature sensed by the temperature sensing unit.

In addition, the input unit for instructing the separation control of the temperature in the storage compartment; And a display unit displaying the separation control mode according to the instruction of the controller when the separation control mode is selected through the input unit.

The controller controls the heating unit when the cooling cycle is turned off, and controls the heating unit by comparing the temperature detected by the temperature sensing unit with a preset heating unit off-set temperature.

In addition, a heating unit is provided above the storage chamber, and a temperature sensing unit is provided at a position adjacent to the heating unit.

The technical method of the present invention for achieving the above object comprises the steps of determining whether the operation mode of the storage compartment is the temperature separation control mode; Determining whether a temperature in the storage compartment exceeds an off-point temperature of a cooling cycle in the temperature separation control mode; Heating the air in the storage compartment by turning on a heating part when the off point temperature of the cooling cycle is exceeded; After the heating unit senses the temperature in the adjacent reservoir, the step of controlling the off operation of the heating unit is compared with the heating unit off set temperature.

In addition, the on / off control of the cooling cycle is controlled according to the temperature sensed in the lower part of the storage compartment, and the on / off control of the heating part is controlled in accordance with the sensed temperature in the upper part of the storage compartment.

Moreover, the off set temperature of a heating part is below the hot point temperature of a cooling cycle.

In addition, after a predetermined time has elapsed since the cooling cycle is turned off, the heating unit is turned on.

As described above, according to the present invention by controlling the temperature of the space in one storage compartment, it is possible to store the storage having different storage temperatures together to increase the space utilization, which is stored together in one storage compartment Since different stores can be stored at appropriate temperatures, the storage efficiency and reliability can be improved.

In addition, the food can be prevented from spoiling or freezing due to a slight temperature difference, which has a great effect on improving the quality of the kimchi refrigerator.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a kimchi refrigerator according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the kimchi refrigerator, and further includes a plurality of temperature sensors and heaters. This will be explained in more detail.

Kimchi refrigerator according to the present embodiment, the main body 1 having an input opening that is upwardly open and formed into a rectangular parallelepiped shape, and a door rotating about one side of the upper surface of the main body 1 to open and close the input opening of the main body 1 ( Not shown).

The main body 1 has a plurality of separate housings 30 for separating the outer case 30 to form an appearance, and a storage container 40 spaced apart by a predetermined interval into the inner side of the outer case and having an upward input opening and storing kimchi and other foods and the like. The inner case which forms the storage chambers 10 and 20 is provided.

The storage compartments 10 and 20 are divided into a left compartment storage compartment 10 and a right compartment storage compartment 20 so that separate storage spaces are formed, and each storage space can be adjusted to different temperatures, and thus have different storage characteristics. Can effectively store them.

In addition, the main body 1 is filled between the outer case 30 and the inner case to block heat transfer between the storage space inside the inner case and the outside of the outer case to prevent the loss of cold air and the lower region of the inner case There is provided an equipment parts chamber (not shown) provided in the housing to accommodate a plurality of equipment parts such as a compressor.

In addition, a condenser (not shown) for receiving a refrigerant compressed from a compressor (not shown) between the outer walls of the storage compartments 10 and 20 of the refrigerator body 1, that is, between the outer case 30 and the inner case and condensing it into a liquid phase. An evaporator (not shown) is provided to cool the inside of the storage chambers 10 and 20 by absorbing heat in the storage chambers 10 and 20 using the condensed refrigerant.

In addition, the upper surface of the main body 1 is provided with an input unit 110 composed of a plurality of operation buttons for selecting the type of storage contained in the storage compartments 10 and 20, the ripening time of food, the temperature condition, the operation mode, and the like. A display unit 150 for displaying the type of the stock stored in 10 and 20, the ripening time of the food, the temperature condition, the operation mode, and the like are provided.

Here, the operation button is a user's operation to control the operation of the kimchi refrigerator, it is possible to form a variety of forms such as push button (Push button) type or dial knob (Dial nob) type.

In addition, first and third temperature sensors 11 and 21 are provided at an outer lower portion of each of the storage compartments 10 and 20 of the refrigerator main body, and the first and third temperature sensors 11 and 21 are provided in the storage compartments 10 and 20. The temperature of the lower part of the storage compartments 10 and 20 is sensed so that the cooling cycle is controlled.

In addition, first and second heaters 13 and 23 are provided at an outer upper portion of each storage chamber to heat the upper air in the storage chambers 10 and 20 to raise the temperature of the upper storage chamber, and the first and second heaters 13 and 23 are provided. Second and fourth temperature sensors 12 and 22 are provided to sense a temperature of an upper portion of the storage compartments 10 and 20, which are adjacent to each other.

Here, the first heater 13 is controlled on and off in accordance with the temperature of the upper side of the storage compartment 10 detected by the second temperature sensor 12, the second heater 23 through the fourth temperature sensor 22 On-off control is performed according to the sensed temperature above the storage compartment 20.

A coil heater (not shown) is provided along the lower outer surface of the inner case. This heater heats the inside of the inner case when the ripening mode of kimchi is input to ripen kimchi.

3 is a control block diagram of a refrigerator according to an embodiment of the present invention, and includes an input unit 110, a temperature sensing unit 120, a control unit 130, a heating unit 140, and a display unit 150.

The input unit 110 is provided on the upper front surface of the main body 1, and consists of a plurality of operation buttons for selecting the type of storage contained in the storage compartments (10, 20), the ripening time of food, temperature conditions, operation mode, etc., The signal selected by the user is transmitted to the controller 130.

Here, the normal mode is an operation mode for equally controlling the temperature of the entire space in one storage room in the case of storing a plurality of the same storage in one storage room, and in the temperature separation control mode, different storages are stacked up and down in one storage room. In this case, the storage mode is divided into up and down space in one storage room to control the storage room up and down at different temperatures.

Temperature sensing unit 120 is composed of a plurality of temperature sensors (11, 12, 21, 22), a plurality of temperature sensors are installed on the upper and lower portions of each storage chamber (10, 20) to the upper and lower portions of each storage chamber The detected temperature is transmitted to the controller 130.

That is, since the first temperature sensor 11 is located under the storage compartment 10, the first temperature sensor 11 detects a temperature of the lower portion of the storage compartment 10 and transmits the temperature to the controller 130. At this time, the cooling cycle of the storage compartment 10 is controlled according to the temperature sensed under the storage compartment 10.

The second temperature sensor 12 is positioned above the storage compartment 10, and senses a temperature of the upper portion of the storage compartment 10 and transmits the temperature to the controller 130. At this time, the on-off operation of the first heater 13, which is the heating unit 140, is controlled according to the temperature sensed at the upper part of the storage compartment 10.

 The third temperature sensor 21 is located under the storage compartment 20 and senses a temperature of the lower portion of the storage compartment 20 and transmits it to the controller 130. At this time, the cooling cycle of the storage compartment 20 is controlled according to the temperature sensed under the storage compartment 20.

The fourth temperature sensor 22 is positioned above the storage compartment 20, and senses a temperature of the upper portion of the storage compartment 20 and transmits the temperature to the controller 130. At this time, the on-off operation of the second heater 23, which is the heating unit 140, is controlled according to the temperature sensed at the upper part of the storage chamber 20.

The controller 130 controls operations of various loads for performing cooling cycles of each of the plurality of storage compartments provided in the refrigerator.

That is, when the operation mode of the at least one storage compartment is selected as the normal mode, the controller 130 controls the general mode selection signal to be input through the input unit 110 and maintains the temperature of the entire space in the storage compartment at the set temperature.

In addition, when the operation mode of the at least one storage compartment is selected as the temperature separation control mode, the control unit 130 receives a temperature separation control mode selection signal through the input unit 110, and controls the heater of the heater 140, which is provided in the storage compartment. The operation is controlled so that the upper and lower reservoirs are kept at different temperatures.

That is, the controller 130 turns off the cooling cycle when the temperature of the lower part of the storage compartment becomes the off point temperature of the cooling cycle during the operation of the cooling cycle in the temperature separation control mode, and heats the heating unit 140 when a predetermined time elapses after the cooling cycle is turned off. The phosphorus heater is controlled to turn on to increase the space temperature of the upper part of the storage compartment.

In addition, the controller 130 senses the temperature of the upper part of the storage compartment to determine whether the temperature exceeds the preset temperature of the heater, and controls the heater 140 to be turned off when the temperature of the upper part of the storage compartment exceeds the off temperature of the heater.

The heating unit 140 is respectively installed in the upper portion of the plurality of storage compartments, and the on or off operation according to the instructions of the controller 130 to increase the upper temperature in the storage compartment to maintain a constant temperature suitable for storage of the storage stored in the upper storage compartment. do.

Here, the first heater 13, which is the heating unit 140, is installed at the upper portion of the storage compartment 10 to increase the upper temperature in the storage compartment 10, and the second heater 23 is installed at the upper portion of the storage compartment 20. The upper temperature in the storage compartment 20 is raised.

The display unit 150 displays the type of the stock stored in each of the storage rooms 10 and 20, the ripening time of the food, the temperature condition, and the currently selected operating mode according to the instructions of the controller 130.

Here, the display unit 150 is connected to each of the plurality of storage compartments and is installed, and each display unit connected to the storage compartment displays storage conditions and the like stored in the storage compartment.

4 is a control flowchart of a refrigerator according to an embodiment of the present invention, a method of controlling a temperature of a storage compartment 10 among a plurality of storage compartments will be described with reference to FIGS. 1, 3, and 5.

5 is a graph illustrating a temperature control graph of a storage room in a temperature separation control mode, in which <A> is a graph showing temperature changes of upper and lower parts of a storage room, and <B> is a graph illustrating on and off cycles of a cooling cycle and a heater on / off period. It is a graph.

First, when the storage compartment of the refrigerator operates in the normal mode, the cooling cycle is turned on and off according to the temperature sensed by the first temperature sensor as in the cooling cycle of FIG. 5.

That is, when the storage compartment of the refrigerator operates in the normal mode, the temperature of the lower portion of the storage compartment is sensed by the first temperature sensor 11.

Next, the detected temperature of the lower part of the storage compartment is compared with the temperature of the hot spot of the cooling cycle, and when the temperature of the lower part of the storage compartment exceeds the temperature of the cooling point of the cooling cycle, the cooling cycle is turned on (t5-t6, t9-t10) to store the storage compartment 10. Cool down.

While performing the operation of the cooling cycle in the normal mode, the temperature of the lower portion of the storage compartment 10 is sensed through the first temperature sensor 11 and then compared with the off point temperature of the cooling cycle.

At this time, when the temperature of the lower part of the storage chamber is lower than the off point temperature of the cooling cycle, the cooling cycle is turned off (t1-t5, t6-t9), and the cooling cycle operation of the normal mode is performed until the operation mode is changed by the user.

As such, when the cooling cycle is turned on during the cooling cycle control, the temperature of the storage compartment becomes low, and the temperature of the storage compartment becomes lower than the temperature of the cooling cycle off point. Thus, even if the cooling cycle is turned off, the temperature of the storage compartment is reduced due to the cold air remaining in the evaporator. Conduction cooling occurs which will be lower than the off point temperature of the cooling cycle.

Thereafter, when the temperature of the storage compartment increases due to the opening of the door, a cooling cycle is performed to periodically maintain the temperature of the lower portion of the storage compartment by periodically detecting the temperature of the storage compartment bottom through the first temperature sensor in order to control the temperature of the storage compartment again. .

During the cooling cycle in the normal mode, the temperature separation control mode is selected by the user to determine whether a signal is input through the input unit 110 (210).

In this case, when the temperature separation control mode signal is input through the input unit 110, the user may identify that the selected operation mode is operating by displaying the operation mode input through the display unit 150.

In addition, when the temperature separation control mode signal is input through the input unit 110, the temperature of the lower portion of the storage compartment 10 is sensed through the first temperature sensor 11, and then the cooling cycle is compared with the off point temperature (211).

In this case, when the detected temperature of the lower part of the storage compartment 10 is lower than the off point temperature of the cooling cycle, it is determined whether the detected temperature of the lower part of the storage compartment 10 exceeds the on-point temperature of the cooling cycle (217). At this time, when the detected temperature of the lower part of the storage compartment 10 exceeds the hot point temperature of the cooling cycle, the cooling cycle is turned on 218.

If the detected temperature of the lower part of the storage compartment 10 is less than the off point temperature of the cooling cycle, the cooling cycle is turned off (212) t1.

Next, the time elapsed since the off point of the cooling cycle is counted, and it is determined whether the counted time has elapsed for a predetermined time (t1-t2) (213).

At this time, conduction cooling (t1-t3) is generated in the lower part of the storage chamber for a predetermined time, so that the temperature of the storage chamber is lower than the off-point temperature of the cooling cycle due to the cold air remaining in the evaporator even when the cooling cycle is turned off.

Next, when the cooling cycle is turned off, the temperature of the lower part of the storage compartment becomes lower due to the conduction cooling, and after a certain time has elapsed since the off point of the cooling cycle, the first heater 13 installed on the upper part of the storage compartment 10 is turned on (214: t2). When the temperature in the upper part of the storage compartment is canceled by the first heater 13, the temperature of the upper part of the storage compartment rapidly rises (t2-t5).

At this time, the temperature of the lower part of the storage compartment 10 is gradually increased (t3-t5) by heat exchange with the upper temperature of the storage compartment 10.

In addition, the operation of the first heater after a predetermined time delay is a function considered for cooling performance, and there is no delay without affecting the cooling performance.

Next, while the first heater 13 is turned on to raise the temperature of the upper part of the storage chamber, the upper temperature of the upper part of the storage chamber 10 is sensed by the second temperature sensor 12 installed at a portion adjacent to the first heater 13. .

Next, the detected temperature of the upper portion of the storage compartment 10 and the preset off-set temperature of the first heater 13 are compared 215.

At this time, the set temperature at which the first heater is turned off must be lower than or equal to the on-point temperature of the cooling cycle for cooling performance.

Next, when the temperature of the upper portion of the storage chamber 10 exceeds the off set temperature of the first heater 13, the operation of the first heater 13 is turned off (t4).

After the first heater 13 is turned off, the temperature of the upper portion of the storage compartment 10 gradually rises (t4-t5) due to heat exchange with the external temperature when the door is opened.

In addition, the temperature of the lower part of the storage compartment 10 is gradually increased (t4-t5) by heat exchange between the temperature of the outside of the storage compartment supplied from the outside when the door is opened and the temperature of the upper portion of the storage compartment 10.

Accordingly, when the temperature of the lower part of the storage compartment 10 rises to the hot point temperature of the cooling cycle, the cooling cycle is turned on (t5) so that the temperatures of the upper and lower parts of the storage compartment are simultaneously lowered at the same cooling rate (t5-t7). ).

Accordingly, after the operation of the first heater 13 is turned off (216: t4), the temperature of the lower part of the storage chamber that is changed by heat exchange is sensed through the first temperature sensor 11.

Next, the detected temperature of the lower part of the storage compartment is compared with the temperature of the hot spot of the cooling cycle, and when the temperature of the lower part of the storage compartment exceeds the temperature of the cooling point of the cooling cycle, the cooling cycle is turned on (t5) to cool the storage compartment 10.

Next, while performing a cooling cycle of the storage compartment 10, the temperature of the lower portion of the storage compartment 10 is sensed through the first temperature sensor 11 and then compared with the off point temperature of the cooling cycle.

Next, when the temperature of the lower part of the storage chamber is lower than the off point temperature of the cooling cycle, after the cooling cycle is turned off (t6), the on-off control of the first heater 13 is changed (t6-t10) until it is changed to another operation mode by the user. ) Again.

While the upper and lower spaces in the storage compartment are separated and the temperature is controlled, the inside of the storage compartment is a closed space with little circulation of air, and hot air rises and cold air descends. The upper temperature of the storage compartment and the lower temperature lowered by conduction cooling do not mix well with each other and maintain a temperature difference for a certain time, so that the upper and lower portions of one storage compartment can store different storage materials.

If the general mode is selected by the user, the operation mode input through the display unit 150 is displayed so that the user can identify that the selected operation mode is operating, and at the same time, the operation mode 219 is performed by the cooling cycle of the general mode. The entire temperature in the storage compartment 10 is controlled to be maintained at a preset temperature.

At this time, the set temperature is a temperature suitable for storing the storage of the storage compartment and is set by the user.

1 is a perspective view of a refrigerator according to an embodiment of the present invention.

2 is a cross-sectional view of a refrigerator according to an embodiment of the present invention.

3 is a block diagram of a refrigerator according to an embodiment of the present invention.

4 is a control flowchart of a refrigerator according to an embodiment of the present invention.

5 is a temperature control graph of a refrigerator according to an embodiment of the present invention.

* Description of symbols on the main parts of the drawings *

1: refrigerator 10, 20: storage room

11, 12, 21, 22: temperature sensor 13, 23: heater

30: outer case 40: storage container

110: input unit 120: temperature detection unit

130: control unit 140: heating unit

150: display unit

Claims (8)

A heating unit provided in at least one storage compartment and heating air in the storage compartment; A temperature sensing unit sensing a temperature of a storage compartment around the heating unit; And And a controller configured to control an operation of the heating unit according to the temperature sensed by the temperature sensing unit to separate and control the temperature in the storage compartment. The method of claim 1, An input unit for instructing separation control of the temperature in the storage compartment; And a display unit for displaying the separation control mode according to the instruction of the controller when the separation control mode is selected through the input unit. The method of claim 1, The control unit controls the heating unit when the cooling cycle is off, and controls the heating unit off by comparing the temperature detected by the temperature sensing unit with a preset heating unit off set temperature. The method of claim 1, The heating unit is provided above the storage compartment, And the temperature sensing unit is provided at a position adjacent to the heating unit. Determining whether an operation mode of the storage compartment is a temperature separation control mode; Determining whether a temperature in the storage compartment exceeds an off-point temperature of a cooling cycle in the temperature separation control mode; Heating the air in the storage compartment by turning on a heating part when the off point temperature of the cooling cycle is exceeded; And controlling the off operation of the heater by comparing the heater with a preset temperature of the heater off after sensing the temperature in the adjacent reservoir. The method of claim 5, On-off control of the cooling cycle is controlled according to the temperature sensed in the lower part of the storage compartment, On / Off control of the heating unit is a control method of the refrigerator, characterized in that controlled according to the temperature sensed in the upper part of the storage compartment. The method of claim 5, wherein The off set temperature of the heating unit is a control method of the refrigerator, characterized in that less than the hot point temperature of the cooling cycle. The method of claim 5, wherein the step of turning on the heating unit The control method of the refrigerator, characterized in that the heating unit is turned on after a predetermined time has elapsed since the cooling cycle is turned off.

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