KR100368944B1 - Multi-room refrigerator and control method thereof - Google Patents

Abstract

Multi-room refrigerator according to the present invention is to stabilize the cooling cycle and to reduce the operating time of the compressor to save energy, a plurality of storage chambers installed with a sensor for sensing the temperature, a plurality of installed to cool each storage chamber Compressor for supplying the refrigerant to the plurality of evaporators through the evaporator of the evaporator, branched refrigerant pipe, the on-off valve installed in the inlet side flow path of the evaporator to selectively control the supply of refrigerant to each evaporator, the storage chamber of any one of the plurality of storage chambers Reference chamber setting means for setting the reference chamber for the operation control of the control unit; and control means for controlling the starting of the compressor according to the temperature change of the reference chamber determined through the reference chamber setting means.

Description

Multi-room refrigerator and its control method {MULTI-ROOM REFRIGERATOR AND CONTROL METHOD THEREOF}

The present invention relates to a refrigerator, and more particularly, to a refrigerator having a plurality of storage compartments and a control of the multi-room refrigerator which can save energy while simultaneously stabilizing a cycle by controlling a driving time of a compressor employed in a multi-room refrigerator having a plurality of storage rooms. It is about a method.

In general, a multi-room refrigerator having a plurality of storage compartments is provided with a separate evaporator for supplying cold air to each storage compartment, and refrigerant supplied from one compressor is supplied to the evaporator of each storage compartment through a branched refrigerant pipe. . This is especially the case for special purpose refrigerators in which the refrigerant pipe of the evaporator is installed on the wall of the storage room to store kimchi and the cold air is transferred into the storage room through the wall of the storage room.

The multi-room refrigerator is configured to detect each internal temperature through a temperature sensor separately provided in each storage compartment, and the temperature information detected in each storage compartment is transmitted to a control unit for controlling the operation of the refrigerator to control the start of the compressor. . In addition, an opening / closing valve which is opened and closed by a control signal of a control unit is installed in the refrigerant pipe connected to each evaporator so that the refrigerant supplied from the compressor is supplied to the corresponding evaporator.

Therefore, the refrigerator detects this when the temperature of the storage compartment rises above the set range by means of a temperature sensor, and the controller opens the refrigerant pipe connected to the evaporator of the corresponding storage compartment through the control of the opening / closing valve and starts the compressor. Allow the storage compartment to cool.

However, in the conventional multi-room refrigerator having such a configuration, the compressor stops when the temperature of each storage chamber is lowered below the set range, and the compressor is controlled to be driven immediately when any storage chamber rises above the set range. Therefore, the operation of the compressor is frequent, the cycle is not stabilized, and there is a big problem of energy loss.

The present invention has been made in view of the above problems, and an object of the present invention is to control the start of the compressor relative to the storage compartment in which the cooling load is relatively large, so that the cycle is stabilized by preventing frequent starting and stopping of the compressor. In addition, the present invention provides a multi-stage refrigerator and a control method thereof, which can reduce the driving time of the compressor as a whole and reduce the required energy.

1 is a cycle configuration diagram of a multi-chamber refrigerator according to the present invention.

2 is a view showing the configuration of a reference room selector switch applied to a multi-chamber refrigerator according to the present invention.

3 is a flow chart showing the overall control process of the multi-fridge refrigerator according to the present invention.

Figure 4 is a flow chart showing a control process of the multi-type refrigerator according to the present invention, showing an independent control process.

5 is a flowchart showing a control process of the multi-room refrigerator according to the present invention, and shows a reference room determination process.

6 is a flowchart illustrating a control process of a multi-room refrigerator according to the present invention, and shows a reference room control process.

Explanation of symbols on the main parts of the drawings

1: first storeroom, 2: second storeroom,

3: compressor, 4: condenser,

5a, 5b: refrigerant expansion device, 6a: first evaporator,

6b: second evaporator, 9a: first temperature sensor,

9b: second temperature sensor, 10a: first opening and closing valve,

10b: second open / close valve, 11: microcomputer,

12: selector switch, 13a: first door sensor,

13b: second door sensor.

A multi-room refrigerator according to the present invention for achieving the above object is a compressor for supplying refrigerant to the plurality of evaporators through a plurality of storage compartments, a plurality of evaporators provided to cool each of the storage compartments, and a branched refrigerant pipe. And an opening / closing valve installed in an inlet flow path of the evaporator so as to selectively control the supply of refrigerant to each evaporator, and a reference room setting which sets any one of the plurality of storage chambers as a reference chamber for operation control of the compressor. Means and control means for controlling the starting of the compressor according to the temperature change of the reference chamber determined by the reference chamber setting means.

The reference chamber setting means may be a selection switch for selecting one of the plurality of storage chambers as the reference chamber in advance.

In addition, the reference chamber setting means is to allow the independent cooling of each of the storage compartment to be performed for a predetermined time, and then the storage compartment of the larger storage cumulative opening time of the on-off valve by comparing the opening cumulative time of each of the opening and closing valves associated with each of the storage compartment Characterized in that the reference chamber to be determined.

In addition, the present invention provides a plurality of storage chambers having a temperature sensor for sensing the internal temperature, a plurality of evaporators provided to cool each of the storage chambers, and a compressor for supplying refrigerant to the plurality of evaporators through branched refrigerant pipes; And a shut-off valve installed in an inlet side flow path of the evaporator to selectively control the supply of refrigerant to each evaporator, the control method of a multi-room refrigerator comprising: controlling any one of the plurality of storage compartments for operation control of the compressor; And a reference room control step of controlling the start of the compressor according to the temperature of the reference room set through the reference room setting step.

And the reference room setting step is characterized in that the reference room is determined by the user's selection through the operation of the selection switch.

The reference chamber setting step may include an independent control step of controlling the compressor to operate by opening / closing a valve of a corresponding storage compartment when cooling of any one of the storage compartments is required, and during the predetermined time of performing the independent control. Accumulating the opening times of each of the plurality of on / off valves, and comparing the accumulated cumulative opening times of the on / off valves to determine one storage chamber associated with the on / off valve having the largest open accumulation time as the reference chamber. do.

And the reference chamber control step is controlled to start the operation of the compressor by opening and closing the valve related to the reference chamber only when the temperature of the reference chamber is more than the set range, and when the compressor is operated other than the reference chamber Sensing each storage room temperature; controlling opening and closing valves of the corresponding storage room when each storage room temperature other than the reference room is above the setting range and maintaining the closed state when the storage room temperature is below the setting range; And controlling the operation of the compressor to be stopped when the internal temperature of the storage chamber other than the reference chamber is less than the set range.

In addition, the control method of the multi-room refrigerator according to the present invention is to be re-executed from the reference room setting step when the door for opening and closing the respective storage rooms in the process of performing the reference room setting step and the reference room control step. It is characterized by.

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

As shown in FIG. 1, the multi-room refrigerator according to the present invention includes a first storage compartment 1 and a second storage compartment 2 which are mutually partitioned, and each storage compartment 1, 2 is configured to accommodate storage. Each of the doors 1a and 2a that can be opened and closed is provided. In addition, the multi-room refrigerator constitutes a cooling device for cooling each of the storage compartments 1 and 2, and uses a conventional compressor 3, a condenser 4, a refrigerant expansion device 5a, 5b, and an evaporator 6a, 6b. Equipped.

The evaporator includes a separate first evaporator 6a and a second evaporator 6b to cool the internal spaces of the first storage chamber 1 and the second storage chamber 2, respectively. The refrigerant pipes 7 and 8 are connected between the compressor 3, the condenser 4, the refrigerant expansion devices 5a and 5b, and the two evaporators 6a and 6b to enable refrigerant circulation. At this time, the refrigerant pipe 7 connected from the outlet of the condenser 4 to the inlet of each evaporator 6a, 6b is branched in the middle, and the refrigerant pipe connected to the compressor 3 from the outlet of each evaporator 6a, 6b. (8) merges into one halfway. The refrigerant expansion devices 5a and 5b are constituted by ordinary capillary tubes and are provided in the middle of the refrigerant pipe 7 connected to the inlets of the respective evaporators 6a and 6b.

In addition, the present invention is to control the temperature of each storage compartment (1, 2) and the operation of the compressor (3), the first temperature sensor for sensing the temperature of the first storage compartment (1) and the second storage compartment (2) ( 9a) and the second temperature sensor 9b, the first door sensor 13a and the second door sensor 13b for detecting opening and closing of the doors 1a and 2a of the storage chambers 1 and 2, and the respective evaporators 6a, A first open / close valve (10a) and a second open / close valve (10b) for controlling the supply of the refrigerant to 6b), and a control device for controlling the operation of these devices includes a conventional microcomputer (11).

The first temperature sensor 9a and the second temperature sensor 9b are respectively installed in the first storage chamber 1 and the second storage chamber 2, and each door sensor 13a, 13b is provided with a door 1a, It is provided in the part adjacent to 2a). The first opening / closing valve 10a and the second opening / closing valve 10b are respectively installed in the middle of the refrigerant pipe 7 connected to the inlets of the respective evaporators 6a, 6b. (The compressor is driven by the control signal of the microcomputer. Since the compressor driving unit and the driving unit of each on-off valve driving the on-off valve are conventional in constructing a control circuit, description thereof will be omitted.) In the present embodiment, the refrigerator is divided into two compartments. Even if the storage compartment is divided into three or more, the quantity of the evaporator, the temperature sensor, the door sensor, the opening / closing valve is different, and the basic configuration may be the same as the case described above.

The broken line shown in FIG. 1 is between each temperature sensor 9a, 9b and the microcomputer 11, between each door sensor 13a, 13b and the microcomputer 11, and each open / close valve 10a, 10b and the microcomputer 11 In the meantime, the connection for the transmission of the control signal between the compressor 3 and the microcomputer 11 is shown. The temperature information of each of the storage compartments 1 and 2 through the temperature sensors 9a and 9b and the door opening and closing information of each of the storage compartments 1 and 2 through the door sensors 13a and 13b are transferred to the microcomputer 11. It was made possible. In addition, the microcomputer 11 determines the conditions of the storage chambers 1 and 2 based on the information so as to control the operation of the compressor 3 and the opening / closing operations of the on / off valves 10a and 10b.

On the other hand, according to the present invention, a storage chamber in which a relatively large amount of storage material is stored among the storage chambers 1 and 2 or a low internal temperature setting range is applied as a reference chamber is selected as a reference chamber, and the compressor ( By controlling the start of 3), not only the stabilization of the cycle but also the operation time of the entire compressor 3 can be reduced to save energy.

To this end, the refrigerator according to the present invention is to allow the user to directly select the reference room or to automatically determine the reference room at the discretion of the microcomputer. A selection switch 12 as shown in FIG. 2 is provided. The selection switch 12 is configured to allow a user to directly select either the first storage chamber 1 or the second storage chamber 2 as a reference chamber or to select an automatic control mode through a dial operation of the selection switch 12. . As shown in FIG. 1, the selection switch 12 is associated with the microcomputer 11 so that the selected information is transmitted to the microcomputer 11. On the other hand, although the selection switch 12 is not shown in the figure can be configured as a plurality of ordinary buttons.

The following describes the control operation of the multi-fridge refrigerator according to the present invention having such a configuration.

As shown in FIG. 3, when the refrigerator is operated, the microcomputer 11 detects a signal of the selection switch 12 in order to know reference room selection information through the selection switch 12 (S101). Then, it is determined whether the selection information of the selection switch 12 (see FIG. 2) is the automatic mode or the manual mode (selected as the first storage chamber and the second storage chamber) (S102). At this time, when it is determined that the information of the selection switch 12 is not in the automatic mode, it is determined whether the selected reference chamber is the first storage chamber 1 or the second storage chamber 2 (S103), and the selection switch 12 The reference room control step (S400) is immediately performed based on the determined information. When it is determined in step 102 that the automatic mode is selected, the microcomputer 11 performs an independent control step S200 for determining a reference room by itself.

Independent control step (S200), as shown in Figure 4, after measuring the temperature of the first storage chamber 1 and the second storage chamber 2 through the temperature sensor (9a, 9b) of each storage chamber (S201, S202), it is determined whether the temperature of the first storage chamber 1 has risen above the set range (S203). After determining whether the temperature of the first storage chamber 1 rises, it is determined whether the temperature of the second storage chamber 2 has risen above the set range (S204, S206). At this time, when the temperature of the first storage chamber (1) and the second storage chamber (2) are both above the set range, the first opening and closing valve (10a) and the second opening and closing valve (10b) to be opened (S205), the compressor (3) ) Is driven (S213). When the temperature of the first storage chamber 1 is within the setting range and only the temperature of the second storage chamber 2 rises above the setting range, the first opening / closing valve 10a is closed (S207) and the second opening / closing valve 10b is closed. After opening (S208), the compressor 3 is driven (S213). If the temperatures of both storage chambers 1 and 2 are within the set range, after the first opening / closing valve 10a and the second opening / closing valve 10b are closed (S209), the compressor 3 is stopped. To maintain (S210). When the temperature of the first storage chamber 1 rises above the setting range and the temperature of the second storage chamber 2 is within the setting range, the first opening / closing valve 10a is opened (S211) and the second opening / closing valve 10b is opened. After closing (S212), the compressor 3 is driven (S213). When the compressor 3 is driven, the first opening / closing valve 10a and the first opening chamber 10 may be used as a reference chamber for starting the compressor 3 later. The opening time of the two open / close valves 10b is accumulated (S214). This control is to allow the compressor (3) to be started when the cooling of any one of the storage compartments (1, 2) is required to cool the corresponding storage compartments (1, 2), each of the opening and closing valves (10a, 10b) Through the cumulative opening time (S214) of the cooling load of each storage compartment (1,2) to be able to determine.

This independent control step (S200) is to continue for a predetermined time, as shown in Figure 3 (S220). In this case, a predetermined time for performing independent control may be determined as a time until the cooling cycle is stabilized after the refrigerator is initially operated. After the predetermined time elapses and the independent control step S200 is completed as described above, either the first storage room 1 or the second storage room 2 in the process of performing the independent control step S200. It is determined whether the cooling load is large and the reference chamber determination step (S300) of determining the side where the cooling load is large is performed.

As shown in FIG. 5, the reference chamber determination step S300 may include a first opening / closing valve in order to determine which of the storage chambers 1 and 2 has a large cooling load in the independent control step S200 described above. 10a) It is determined whether the accumulated open time is longer than the accumulated open time of the second open / close valve 10b (S301). In this case, when it is determined that the opening accumulation time of the first opening / closing valve 10a related to the first storage chamber 1 is longer than the opening accumulation time of the second opening / closing valve 10b related to the second storage chamber 2, the first storage chamber ( 1) is set as a reference chamber for starting control of the compressor 3 (S302), and the second storage chamber 2 is set as a slave chamber (S303). On the contrary, the second storage chamber 2 is set as the reference chamber (S304) and the first storage chamber 1 is set as the slave chamber (S305). After the reference room is set in the reference room determination step (S300), the reference room control step (S400) is performed (see FIG. 3).

As shown in FIG. 6, the reference room control step (S400) first detects the temperature of the reference room determined in the reference room determination step (S300) among the storage rooms 1 and 2 (S401). It is determined whether the temperature is above the set range (S402). For example, when the first storage chamber 1 is set as the reference chamber and the second storage chamber 2 is set as the dependent chamber in the reference chamber determination step S300, the first temperature sensor 9a of the first storage chamber 1 is used. After sensing the internal temperature of the first storage chamber 1, it is determined whether the temperature of the first storage chamber 1 is greater than or equal to a set range.

At this time, when it is determined that the internal temperature of the reference chamber is higher than the set range, after opening the reference chamber open / close valve associated with the reference chamber (S404), the compressor 3 is operated (S405), and in the opposite case, the compressor 3 is stopped. To maintain (S403). This allows the compressor 3 to be started in accordance with the conditions of the storage compartment designated as the reference chamber. That is, when the first storage chamber 1 is the reference chamber, the compressor 3 is started only when the temperature of the first storage chamber 1 rises above the set range.

After the compressor 3 is operated (S405), the temperature of the storage compartment designated as the slave compartment is sensed (S406), and it is determined whether the temperature of the slave compartment is greater than or equal to the set range (S407). At this time, when it is determined that the internal temperature of the subordinate chamber is greater than the set range, the refrigerant is supplied toward the evaporator of the subordinate chamber to open the on / off valve associated with the subordinate chamber to cool the subordinate chamber (S409). On the contrary, when it is determined that the internal temperature of the subordinate chamber is lower than the set range, the on / off valve associated with the subordinate chamber is kept closed and the process returns to step 401 (S408). In this case, only the reference room is cooled. This type of control is to determine whether or not the subsidiary chamber is cooled after the compressor is operated to cool the reference chamber and to perform the cooling of the subordinate chamber only when the subsidiary chamber is required to be cooled.

After the on / off valve associated with the subordinate chamber is opened and cooling of the subordinate chamber proceeds (S409), the temperature of the reference chamber is sensed again (S410), and it is determined whether the temperature of the reference chamber is greater than the set range (S411). At this time, if it is determined that the internal temperature of the reference chamber is more than the set range, the process returns to step 406 to continue cooling the reference chamber. When it is determined that the internal temperature of the reference chamber is lower than the set range, the closing of the shutoff valve associated with the reference chamber is stopped to stop the cooling of the reference chamber and return to step 406 to continue the cooling of the dependent chamber (S412).

This control allows the operation to be stopped after the compressor 3 has been started once after the internal temperatures of the reference chamber and the slave chamber both fall below the set range. That is, the start of the compressor 3 depends on the temperature conditions of the reference chamber, but the operation of the compressor 3 is made possible when the temperatures of the reference chamber and the dependent chamber both fall below the set range. This allows the cycle to be stabilized by allowing the compressor 3 to be operated as continuously as possible once the compressor 3 is started, and prevents frequent starting of the compressor 3, thereby reducing the operating time of the compressor 3 as a whole. In order to save energy.

In addition, as shown in Figure 3, through all the process of performing the independent control step (S200), the reference room determination step (S300) and the reference room control step (S400) as described above through the door sensor (13a, 13b) When the doors 1a and 2a of the storage compartments 1 and 2 are detected to be open, a door interrupt is generated so that all the control processes are re-executed from the first step (S500). On the other hand, if the door (1a, 2a) does not open to maintain the reference room control step (S400).

This is a case in which a storage condition of each storage compartment 1 or 2 is changed by additionally storing the storage in each user storage compartment 1 or 2 or taking out the storage which is already stored. In other words, if the cooling conditions of each storage chamber 1, 2 change due to the change in the storage volume of each storage chamber 1, 2, the control unit re-executes from the independent control step for setting the reference chamber, and then, based on the newly determined reference chamber, The actual word is to be made. On the other hand, if the user has set the storage space of the first storage chamber 1 and the second storage chamber 2 of the first storage chamber 1 and the second storage chamber 2 through the operation of the direct selection switch 12 directly after the storage of the stored object as described above in the independent control step The reference room control step (S400) is performed immediately based on the selected reference room without going through the step S200 and the reference room determination step S300.

As described in detail above, in the multi-room refrigerator according to the present invention, since any one of the storage rooms with a relatively large cooling load is set as the reference room and the compressor is controlled according to the conditions of the storage room set as the reference room, The operation is prevented and the cycle is stabilized, and the driving time of the compressor as a whole is reduced, thereby saving energy.

Claims (9)

A plurality of storage chambers, a plurality of evaporators provided to cool each of the storage chambers, a compressor for supplying refrigerant to the plurality of evaporators through branched refrigerant pipes, and the evaporator to selectively control the supply of refrigerant to the respective evaporators. An opening / closing valve installed at an inlet side flow path of the control chamber, reference chamber setting means for setting any one of the plurality of storage chambers as a reference chamber for operation control of the compressor, and the reference chamber defined by the reference chamber setting means. And a control means for controlling the start of the compressor in response to a change in temperature. The method of claim 1, The reference room setting means is a multi-room refrigerator, characterized in that the selection switch that can select any one of the plurality of storage rooms to the reference room in advance. The method of claim 1, The reference chamber setting means performs independent cooling of each of the storage compartments for a predetermined time, and then compares the accumulated accumulation time of each of the opening / closing valves associated with each of the storage compartments, and the storage compartment having the larger opening accumulation time of the opening / closing valve is larger. The multi-room refrigerator, characterized in that to be determined as the reference room. A plurality of storage chambers provided with a temperature sensor for sensing an internal temperature, a plurality of evaporators installed to cool each of the storage chambers, a compressor for supplying refrigerant to the plurality of evaporators through branched refrigerant tubes, and each of the evaporators In the control method of the multi-room refrigerator comprising an opening and closing valve installed in the inlet side flow path of the evaporator to selectively control the supply of refrigerant to the furnace, A reference room control step of controlling any one of the plurality of storage rooms as a reference room for operation control of the compressor and controlling the starting of the compressor according to the temperature of the reference room set through the reference room setting step; Control method of a multi-room refrigerator comprising a. The method of claim 4, wherein The reference room setting step is a control method of a multi-room refrigerator, characterized in that the reference room is determined by the user's selection through the operation of the selection switch. The method of claim 4, wherein The reference chamber setting step includes an independent control step of controlling the compressor to operate by opening / closing a valve of a corresponding storage chamber when any one of the storage chambers requires cooling, and the plurality of the plurality of storage chambers during the predetermined time for performing the independent control. Accumulating the opening times of each of the on / off valves of the on / off valves, and comparing the accumulated cumulative opening times of the on / off valves to determine one storage chamber associated with the on / off valve having the largest open accumulation time as the reference chamber. Control method of multi-room refrigerator. The method of claim 4, wherein If there is an opening of the door for opening and closing the respective storage compartment in the process of performing the reference room setting step and the reference room control step, the control method of the multi-room refrigerator, characterized in that to execute again from the reference room setting step. The method of claim 4, wherein The reference chamber control step includes controlling the compressor to start with the opening / closing valve related to the reference chamber only when the temperature of the reference chamber is greater than or equal to a set range, and when the compressor is operated, Detecting a storage room temperature, and controlling opening and closing valves of the corresponding storage room when each storage room temperature other than the reference room is above a setting range and maintaining a closed state when the storage room temperature is below a setting range. Control method of multi-room refrigerator. The method of claim 8, The control method of the reference room control step further comprises the step of controlling to stop the operation of the compressor when both the temperature of the reference room and the internal temperature of the storage room other than the reference room is less than the set range.