WO2023035998A1

WO2023035998A1 - Refrigerator control method

Info

Publication number: WO2023035998A1
Application number: PCT/CN2022/115370
Authority: WO
Inventors: 赵斌堂; 薛文超; 左立华; 张方友; 陈庆; 张延庆
Original assignee: 青岛海尔电冰箱有限公司; 海尔智家股份有限公司
Priority date: 2021-09-08
Filing date: 2022-08-29
Publication date: 2023-03-16
Also published as: CN115773618A

Abstract

Provided in the present invention are a refrigerator control method, a storage medium and a refrigerator. The refrigerator control method comprises: collecting an operation parameter of an ice-making system; when the operation parameter meets a defrosting condition of an ice-making evaporator, and the current operating state of an ice-making apparatus is an ice-overturning state, continuing to monitor the operation state; and when the operation parameter meets the defrosting condition of the ice-making evaporator, and the current operation state of the ice-making apparatus is a non-ice-overturning state, sending a starting signal to a defrosting unit corresponding to the ice-making evaporator.

Description

Refrigerator Control Method

technical field

The invention relates to the field of home appliances, in particular to a refrigerator control method, a storage medium and a refrigerator.

Background technique

At present, in family life, a refrigerator has become an indispensable household appliance. The refrigerator is equipped with a refrigeration system for refrigeration. The refrigeration system includes an evaporator. When the refrigeration system is used for a period of time, frost will form on the surface of the evaporator. Therefore, in order to ensure the refrigeration effect of the refrigeration system, it is necessary to defrost the evaporator regularly. When the evaporator defrosts, the temperature in the refrigerator compartment will rise.

In order to meet the needs of users, ice making devices are also installed in some refrigerators. The ice making device can be installed on the box body or the door body of the refrigerator, and the ice making device can include an ice storage box for storing ice. However, when the current refrigerator defrosts the evaporator, it often only judges whether to defrost according to the running time of the compressor, and ignores the working status of the ice making device. Therefore, the temperature rise caused by defrosting often affects the ice production. The device has a negative impact.

Contents of the invention

In order to solve the above problems, the present invention proposes a refrigerator control method, a storage medium and a refrigerator. When the ice-making device is in the ice-turning state, the ice-making evaporator is not defrosted.

In order to achieve one of the objectives of the above invention, an embodiment of the present invention provides a refrigerator control method, including:

Collect the working parameters of the ice making system;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is the ice-turning state, continue to monitor the working state;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is the non-ice-turning state, a start signal is sent to the defrosting unit corresponding to the ice-making evaporator.

As a further improvement of an embodiment of the present invention, the non-ice turning state includes an ice storage state and an ice making state.

As a further improvement of an embodiment of the present invention, if the current working state is the ice making state, a start signal is sent to the defrosting unit corresponding to the ice making evaporator and the ice making device is controlled to stop the ice making operation.

As a further improvement of an embodiment of the present invention, if the current working state of the ice-making device is the ice-making state, the ice-making operation is restarted after receiving a defrosting end signal of the ice-making evaporator.

To achieve one of the objectives of the above invention, another embodiment of the present invention provides a refrigerator control method, including:

Collect the working parameters of the ice making system;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is the ice-over state, then continue to monitor the working state of the ice-making device;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is a non-ice-turning state, the refrigeration system is controlled to refrigerate the ice-making compartment;

When it is detected that the temperature of the ice-making compartment reaches the corresponding pre-cooling temperature, a defrosting start signal is sent to the defrosting unit corresponding to the ice-making evaporator.

As a further improvement of an embodiment of the present invention, the corresponding pre-cooling temperature is matched according to the current ice volume information of the ice storage box.

As a further improvement of an embodiment of the present invention, if the current working state is the ice-making state, the defrosting unit corresponding to the ice-making evaporator is controlled to start the defrosting operation and stop the ice-making operation.

Collect the working parameters of the ice making system;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is the non-ice-turning state, then judge whether to pre-cool the ice-making compartment according to the ice volume information of the ice storage box;

If so, match the pre-cooling temperature according to the ice volume information, and send a defrosting start signal to the defrosting unit corresponding to the ice-making evaporator when it is detected that the temperature of the ice-making compartment reaches the corresponding pre-cooling temperature;

If not, send a defrosting start signal to the defrosting unit corresponding to the ice-making evaporator.

As a further improvement of an embodiment of the present invention, "judging whether to pre-cool the ice-making compartment according to the ice volume information of the ice storage box" includes:

It is judged whether the amount of ice in the ice storage box is less than a first preset value.

To achieve one of the objectives of the above invention, one embodiment of the present invention provides a computer-readable storage medium, on which a computer program is stored, and when the computer program is executed by a processor, the refrigerator control described in any one of the above-mentioned embodiments is realized. steps in the method,

In order to achieve one of the objectives of the above invention, an embodiment of the present invention provides a refrigerator, which includes a box body, the storage compartment formed in the box body includes a refrigerator compartment and a freezer compartment, and the box body is equipped with a Close the refrigerating door of the refrigerating room, the refrigerating door is provided with an ice-making room, and an ice-making device is installed in the ice-making room, and the refrigerator includes an ice-making evaporator room and a box evaporator An ice-making evaporator is installed in the ice-making evaporator room, and the ice-making evaporator room is connected with the ice-making room, and a box evaporator is installed in the box evaporator room , the evaporator compartment of the box communicates with the box, the refrigerator also includes a memory and a processor, the memory stores a computer program that can run on the processor, and the processor executes the In the case of a computer program, the steps in the refrigerator control method described in any one of the above-mentioned embodiments are realized.

In the refrigerator control method provided by the present invention, when the ice-making evaporator meets the defrosting conditions, it is judged whether to defrost the ice-making evaporator according to the current working state of the ice-making device. In this case, the ice-making evaporator is not defrosted, so as to avoid the melting of the ice cubes in the ice-making tray and the formation of ice lumps in the ice storage box due to the defrosting of the ice-making evaporator.

Description of drawings

Fig. 1 is a schematic diagram of a refrigerator according to an embodiment of the present invention;

Fig. 2 is another schematic diagram of the refrigerator shown in Fig. 1;

Fig. 3 is a flow chart of the refrigerator control method according to the first embodiment of the present invention;

Fig. 4 is a detailed flow chart of the refrigerator control method according to the first embodiment of the present invention;

5 is a flowchart of a refrigerator control method according to a second embodiment of the present invention;

6 is a detailed flowchart of a refrigerator control method according to a second embodiment of the present invention;

7 is a flowchart of a refrigerator control method according to a third embodiment of the present invention;

8 is a detailed flowchart of a refrigerator control method according to a third embodiment of the present invention;

Fig. 9 is a schematic diagram of another refrigerator according to an embodiment of the present invention.

Detailed ways

In order to enable those skilled in the art to better understand the technical solutions in the present invention, the technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the drawings in the embodiments of the present invention. Obviously, the described The embodiments are only some of the embodiments of the present invention, not all of them. Based on the embodiments of the present invention, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts shall fall within the protection scope of the present invention.

Referring to Fig. 1 and Fig. 2, one embodiment of the present invention provides a refrigerator 100, the refrigerator 100 may include a box body 110, and the storage space formed in the box body 110 may include a refrigerated compartment 111 and a freezer compartment 112, on the box body 110 A refrigerator door 121 for opening and closing the refrigerator compartment 111 and a freezer door 122 for opening and closing the freezer compartment 112 may be connected. An ice making device 150 is installed in the refrigerator 100, and an ice making compartment 113 may be arranged on the refrigerating door body 121. The small ice-making door of the ice-making compartment 113, and the dispenser communicated with the ice-making compartment 113. The ice-making device 150 may include an ice-making tray and an ice storage box 151 placed under the ice-making tray. The user may open the small ice-making door to take out the ice storage box 151 inside the ice-making compartment 113. The ice cubes in the ice storage box 151 are directly taken out under the premise of opening the refrigeration door body 121 and the small ice making door.

The refrigerator 100 may also include a water supply device for supplying water to the ice making tray. When the ice making starts, the water supply device injects liquid water into the ice making tray. When the liquid water in the ice making tray is completely frozen, the ice making device 150 turns over the ice. operation, the ice cubes in the ice making tray are discharged to the ice storage box 151 for storage. The ice-making device 150 can use a flexible ice-making tray to turn over the ice by twisting the ice-making tray, or install an ice-turning structure such as an ice rake 152 to turn over the ice.

The ice making device 150 can also include an ice volume detection component, which can be used to detect the ice volume information in the ice storage box 151. The ice volume detection component can be an ice detection rod installed on one side of the ice making tray, or can be Infrared sensors, ultrasonic sensors, pressure sensors, etc. installed in the ice storage box 151 or other locations may be used to detect the height or weight of ice in the ice storage box 151 .

The ice amount detection component can work according to a predetermined program to detect the ice amount information in the ice storage box 151 . For example, when the water in the ice making tray is completely frozen and an ice turning signal is sent, the ice volume detection component can be controlled to detect the ice volume information in the ice storage box 151, and if the ice volume information of the ice storage box 151 is not full of ice, then it can be The ice making device 150 is controlled to turn over ice, and if the ice volume information of the ice storage box 151 is full of ice, the ice making device 150 can be prevented from turning over ice. The ice amount detection component can also detect the ice amount information in the ice storage box 151 after each ice extraction is completed, or detect the ice amount information in the ice storage box 151 when the small ice making door is detected to be opened and then closed.

The refrigerator 100 also includes a refrigeration system, which may include a compressor, a condenser, an ice-making evaporator 131 , an ice-making capillary, an ice-making return air pipe, a box evaporator 141 , a box capillary, and a box return air pipe. After flowing through the condenser, the refrigerant flowing out of the compressor can flow through the ice-making capillary, the ice-making evaporator 131, the ice-making return air pipe, and then flow back to the compressor, or it can also flow through the box capillary and the box evaporator in sequence. 141. The air return pipe of the box body flows back to the compressor.

The refrigerator 100 can also be provided with an ice-making evaporator compartment 130 and a box evaporator compartment 140. The ice-making evaporator 131 can be installed inside the ice-making evaporator compartment 130, and the ice-making evaporator compartment 130 can be blown by the wind. The channel communicates with the ice-making compartment 113 , and an ice-making fan can be installed inside the ice-making evaporator compartment 130 , and the ice-making fan can supply cold air generated by the ice-making evaporator 131 to the interior of the ice-making compartment 113 . The box evaporator 141 can be installed inside the box evaporator compartment 140, and the box evaporator compartment 140 can communicate with the refrigerated compartment 111 and the freezer compartment 112 to supply cold air to the refrigerated compartment 111 and the freezer compartment 112. .

The ice-making evaporator 131 also has a corresponding defrosting unit. The defrosting unit may include a defrosting heating wire arranged on the ice-making evaporator 131. In the defrosting condition, the defrosting heating wire can be turned on to defrost the ice-making evaporator 131 . A temperature sensor can also be installed inside the ice-making compartment 113 , and the temperature sensor can detect the temperature change inside the ice-making compartment 113 .

Referring to Fig. 3, the first embodiment of the present invention provides a method for controlling a refrigerator 100, including:

Collect the working parameters of the ice making system;

When the working parameters meet the defrosting conditions of the ice-making evaporator 131 and the current working state of the ice-making device 150 is the ice-turning state, continue to monitor the working state;

When the working parameters meet the defrosting conditions of the ice making evaporator 131 and the current working state of the ice making device 150 is the non-ice turning state, a start signal is sent to the defrosting unit corresponding to the ice making evaporator 131 .

In this embodiment, the ice making system may include an ice making device 150 and a refrigeration system corresponding to the ice making compartment 113, such as a compressor, an ice making evaporator 131, and an ice making fan. When there is too much frost on the ice-making evaporator 131 , in order not to affect the operation of the ice-making evaporator 131 , it is necessary to activate the defrosting unit corresponding to the ice-making evaporator 131 to defrost the ice-making evaporator 131 .

When the working parameters of the ice-making system meet the defrosting conditions, it may be determined that the ice-making evaporator 131 needs to defrost. The working parameters of the ice-making system may include the cumulative running time of the compressor after the last defrosting of the ice-making evaporator 131 or the number of ice-making times of the ice-making device 150 .

"The working parameter satisfies the defrosting condition of the ice-making evaporator 131" may include: the cumulative operating time of the compressor after the last defrosting of the ice-making evaporator 131 is greater than or equal to the preset defrosting of the ice-making evaporator 131 The cycle, or the number of ice-making times of the ice-making device 150 is greater than or equal to the preset number of defrosting and ice-making times of the ice-making evaporator 131 .

The operating parameters of the ice making system may also include the temperature of the ice making evaporator compartment 130, the speed and current of the ice making fan. "The working parameters meet the defrosting conditions of the ice-making evaporator 131" may also include: the temperature of the ice-making evaporator compartment 130 is less than a preset value, or the current of the ice-making fan is greater than the preset current and the speed is lower than the preset speed . At this time, if the temperature of the ice-making evaporator compartment 130 is too low, or the ice-making fan is blocked, it can be determined that the ice-making evaporator 131 or the ice-making fan is blocked, even if the defrosting of the ice-making evaporator 131 has not been reached at this time. Period, it is also necessary to defrost the ice-making evaporator 131, otherwise, it will affect the normal operation of the refrigeration system of the ice-making system.

In this embodiment, the working state of the ice making device 150 may include an ice turning state and a non-ice turning state, wherein the non-ice turning state may include an ice storage state and an ice making state. A control panel or control buttons can be set on the refrigerator 100, and the user can control the switch of the ice making mode. When the ice-making mode is turned on, the ice-making device 150 can operate to make ice, and when the ice-making mode is turned off, the ice-making device 150 can stop making ice. There are still ice cubes stored in the box 151, and the ice-making evaporator 131 continues to operate to supply cold air to the ice-making compartment 113. At this time, the working state of the ice-making device 150 can be defined as an ice storage state.

In a state where the ice making mode is turned on, the working state of the ice making device 150 may include an ice turning state and an ice making state. The ice turning state may be a state when the ice in the ice making tray is discharged into the ice storage box 151 after the liquid water in the ice making tray is frozen. An ice-making temperature sensor may be provided on the ice-making tray, and the ice-making device 150 is also provided with a preset ice-making cycle. When the ice making device 150 is running for an ice making period, an ice turning signal can be sent to control the ice making device 150 to turn ice.

The ice-making tray can be provided with an ice-turning heating wire, and when the ice-turning signal is received, the ice-turning heating wire can be activated to heat the ice-making tray, so that the ice cubes in the ice-making tray are separated from the ice-making tray. Therefore, when the current working state of the ice-making device 150 is the ice-turning state, the temperature in the ice-making compartment 113, especially the ice-making tray, is relatively high. If the ice-making evaporator 131 is defrosted at this time, due to the A further rise in temperature during the frosting process may lead to an overheating of the ice-making compartment 113, and the ice in the ice-making tray and ice storage box 151 may melt to produce more water, and the temperature of the ice-making compartment 113 will drop after defrosting. When the melted water freezes twice, it may cause the ice cubes in the ice storage box 151 to stick together and form ice lumps. And even if heating is not used when turning the ice, the temperature rise caused by the defrosting of the ice-making evaporator 131 will easily cause the unshed ice in the ice-making tray to melt.

Therefore, when it is detected that the current working parameters of the ice-making system meet the defrosting conditions of the ice-making evaporator 131, if the working state of the ice-making device 150 is the ice-turning state, the ice-making evaporator 131 will not be activated. defrosting unit to avoid the temperature of the ice-making compartment 113 being too high. At this time, the working state of the ice making device 150 can be continuously monitored, and the working parameters of the ice making system can be continuously monitored. When the working state is the non-ice turning state, the defrosting unit corresponding to the ice-making evaporator 131 is controlled to be turned on. Alternatively, it is also possible to only monitor the working state of the ice making device 150, for example, when it is detected that the ice turning state of the ice making device 150 is over, or when the ice turning end signal is received, the defrosting unit corresponding to the ice making evaporator 131 is directly controlled to open .

In this way, the defrosting of the ice-making evaporator 131 can reduce the impact on the ice-making compartment 113 and the ice cubes in the ice-making compartment 113 , and prevent the ice cubes in the ice storage box 151 from forming ice lumps.

In this embodiment, the control method of the refrigerator 100 further includes:

If the working parameters meet the defrosting conditions of the ice-making evaporator 131 and the current working state of the ice-making device 150 is the ice-turning state, then after the ice-turning is completed, the defrosting unit corresponding to the ice-making evaporator 131 is sent to start signal, and start the ice making operation of the ice making device 150 after receiving the defrosting end signal.

Wherein, the ice making operation of the ice making device 150 may include monitoring whether the current ice making time of the ice making device 150 reaches the preset ice making cycle and controlling ice turning, for example, when the ice making time reaches the preset ice making cycle, The ice making device 150 can be controlled to turn over ice. If the ice-making evaporator 131 meets the defrosting conditions, and the ice-making device 150 is in the ice-turning state at this time, the ice-making evaporator 131 can be defrosted after the ice-turning is completed, and after the ice-turning is completed, the water supply device will Start to supply water to the ice-making tray, but the temperature of the ice-making compartment 113 will be relatively high at this time. If the ice-making operation is started immediately to calculate the ice-making cycle, it may cause the liquid in the ice-making tray to The water is not completely frozen, so the ice making operation can be started after the defrost is complete.

Further, referring to FIG. 4 , in this embodiment, the method for controlling the refrigerator 100 further includes:

If the current working state of the ice making device 150 is the ice making state, a start signal is sent to the defrosting unit corresponding to the ice making evaporator 131 and the ice making device 150 is controlled to stop the ice making operation.

When the ice-making device 150 is in the ice-making state, the ice-making evaporator 131 is defrosted. Since the water in the ice-making tray is not completely frozen, it is greatly affected by the temperature of the ice-making compartment 113, and the ice-making evaporator 131 The temperature rise of the ice-making compartment 113 caused by defrosting may cause the partially frozen ice cubes in the ice-making tray to melt. Therefore, when the defrosting unit corresponding to the ice-making evaporator 131 is controlled to start the defrosting operation, the ice-making operation is stopped, and the parameters such as the ice-making time of the ice-making device 150 in the current ice-making cycle are no longer monitored, so as to avoid the The invalid ice-making time during the defrosting process of the ice evaporator 131 is included in the calculation, so that when the ice-making cycle is reached, the ice cubes are not completely frozen.

Further, in this implementation manner, the control method of the refrigerator 100 further includes:

If the current working state of the ice-making device 150 is the ice-making state, the ice-making operation will be restarted after receiving the defrosting end signal from the ice-making evaporator 131 .

In this embodiment, when the ice-making evaporator 131 is defrosted in the ice-making state, the ice-making operation can be cleared after the ice-making operation is stopped, and the stored ice-making parameters in the current ice-making cycle, such as the recorded ice-making duration, The temperature sensed by the temperature sensor, etc., restarts the ice making operation after the defrosting of the ice making evaporator 131 is completed, such as recalculating the ice making cycle, etc.

In this way, it can be ensured that the ice-making device 150 continues to operate normally after the defrosting of the ice-making evaporator 131 is completed, and the temperature of the compartment will not rise due to the defrosting of the ice-making evaporator 131 , thereby causing errors in the ice-making system.

Referring to FIG. 5 , it is a method for controlling the refrigerator 100 provided in the second embodiment of the present invention. The control method of the refrigerator 100 includes:

Collect the working parameters of the ice making system;

When the working parameters meet the defrosting conditions of the ice-making evaporator 131 and the current working state of the ice-making device 150 is the ice-turning state, continue to monitor the working state of the ice-making device 150;

When the working parameters meet the defrosting conditions of the ice-making evaporator 131, and the current working state of the ice-making device 150 is the non-ice-turning state, the refrigeration system is controlled to cool the ice-making compartment 113 and monitor the ice-making compartment room temperature;

When it is monitored that the temperature of the ice-making compartment 113 is equal to or lower than the corresponding pre-cooling temperature, a signal to start defrosting is sent to the corresponding defrosting unit of the ice-making evaporator 131 .

The main difference between this embodiment and the refrigerator 100 control method in the first implementation is that when the working parameters meet the defrosting conditions of the ice-making evaporator 131 and the current working state of the ice-making device 150 is the non-ice-turning state, no direct control The defrosting unit corresponding to the ice-making evaporator 131 is turned on, but the refrigeration system is controlled to pre-cool the ice-making compartment 113, and the ice-making evaporator 131 is turned on when the temperature of the ice-making compartment 113 reaches the pre-cooling temperature. The defrost unit is switched on.

For example, when the working parameters meet the defrosting conditions of the ice-making evaporator 131 and the current working state of the ice-making device 150 is the non-ice-turning state, the pre-cooling temperature corresponding to the ice-making compartment 113 is obtained first, and the pre-cooling temperature can be for the pre-stored temperature. And monitor the temperature of the ice-making room, such as the temperature sensor in the ice-making room can be controlled to detect the temperature of the ice-making room, of course, the temperature sensor in the ice-making room can regularly detect the temperature in the ice-making room and the detected The temperature is uploaded and stored in the memory of the refrigerator. When the working parameters of the ice-making system meet the defrosting conditions of the ice-making evaporator, the stored temperature of the ice-making compartment can be directly recalled. If the pre-cooling temperature is -8°C, and the current temperature of the ice-making compartment 113 is -3°C, then the cooling system is controlled to refrigerate the ice-making compartment 113, and when the temperature of the ice-making compartment 113 drops to the pre-cooling temperature- When the temperature is 8°C, the defrosting unit corresponding to the ice-making evaporator 131 is controlled to be turned on to defrost the ice-making evaporator 131 . Of course, if the current temperature of the ice-making compartment is lower than -8°C, such as -9°C, there is no need to cool the ice-making compartment, and the defrosting unit corresponding to the ice-making evaporator can be directly turned on.

In this way, when the temperature of the ice-making compartment is -8°C, defrost the ice-making evaporator. If the temperature of the ice-making compartment rises by 5°C during the defrosting process, After the frost is over, the temperature of the ice-making compartment is still -3°C.

In this way, even if the temperature of the ice-making compartment 113 increases during the defrosting process of the ice-making evaporator 131, the temperature of the ice-making compartment 113 will not be too high, and will not affect the ice cubes and ice cubes stored in the ice storage box 151. Subsequent ice making process.

Further, referring to FIG. 6 , in this embodiment, the method for controlling the refrigerator 100 further includes:

The corresponding pre-cooling temperature is matched according to the current ice volume information of the ice storage box 151 .

In this embodiment, the pre-cooling temperature may be positively correlated with the amount of ice in the ice storage box 151 . The more ice there is in the ice storage box 151, the more cold the ice cubes in the ice storage box 151 can release, and the higher the temperature of the ice-making compartment 113 may be during the defrosting process of the ice-making evaporator 131. Therefore, the more ice in the ice storage box 151, the lower the corresponding pre-cooling temperature can be, so that the corresponding pre-cooling temperature can be matched according to the ice volume information of the ice storage box, so as to save energy consumption and improve the defrosting efficiency .

Further, in this embodiment, "matching the corresponding pre-cooling temperature according to the current ice volume information of the ice storage bin 151" may include:

If the current amount of ice in the ice storage box 151 is greater than or equal to the preset value, the pre-cooling temperature is the first pre-cooling temperature;

Otherwise, the pre-cooling temperature is a second pre-cooling temperature, wherein the first pre-cooling temperature is greater than the second pre-cooling temperature.

As a specific example, if the ice storage box 151 is full of ice volume Q, then the preset value can be 0.5Q, when the current ice volume of the ice storage box 151 is greater than or equal to 0.5Q, it can match the first pre-cooling temperature T1, And obtain the current temperature of the ice-making compartment 113, if the current temperature of the ice-making compartment 113 is greater than T1, then turn on the refrigeration system to pre-cool the ice-making compartment 113 until the temperature of the ice-making compartment 113 drops to T1, The defrosting unit corresponding to the ice-making evaporator 131 can be turned on to defrost the ice-making evaporator 131 . And when the current ice volume of the ice storage box 151 is less than 0.5Q, it can match the second pre-cooling temperature T2, because the ice volume in the ice storage box 151 is less, the second pre-cooling temperature T2 can be lower than the first pre-cooling temperature T1, If the temperature of the ice-making compartment 113 is greater than T2 at this time, the refrigeration system can be turned on to pre-cool the ice-making compartment 113 until the temperature of the ice-making compartment 113 drops to T2, and the corresponding ice-making evaporator 131 can be turned on. The defrosting unit defrosts the ice-making evaporator 131 .

In this way, the pre-cooling temperature of the ice-making compartment 113 is directly matched according to the ice volume information, and the ice-making evaporator 131 is defrosted when it is confirmed that the temperature of the ice-making compartment 113 reaches the pre-cooling temperature, so that the ice-making compartment 113 can be avoided Excessive temperature will have a negative impact on the ice making device 150, and at the same time, the pre-cooling operation can be reasonably controlled to avoid excessive pre-cooling and reduce energy consumption.

As shown in FIG. 7 , it is a control method of the refrigerator 100 according to the third embodiment of the present invention. The control method of the refrigerator 100 includes:

Collect the working parameters of the ice making system;

When the working parameters meet the defrosting conditions of the ice-making evaporator 131 and the current working state of the ice-making device 150 is the non-ice-turning state, it is judged according to the ice volume information of the ice storage box 151 whether to use ice-making compartment 113 Pre-cooling;

If so, match the pre-cooling temperature according to the ice volume information, and when the temperature of the ice-making compartment 113 is monitored to be equal to or lower than the corresponding pre-cooling temperature, send a defrosting message to the corresponding defrosting unit of the ice-making evaporator 131. start signal;

If not, send a defrosting start signal to the defrosting unit corresponding to the ice-making evaporator 131 .

The difference between the control method of the refrigerator 100 in this embodiment and the control method of the refrigerator 100 in the second implementation is that when the working parameters meet the defrosting conditions of the ice-making evaporator 131 and the current working state of the ice-making device 150 is non-ice turning state, judge whether to pre-cool the ice-making compartment 113 according to the ice volume information of the ice storage box 151, and then match the corresponding pre-cooling temperature according to the ice volume information of the ice storage box 151 , control the refrigeration system to pre-cool the ice-making compartment 113 .

Further, referring to FIG. 8 , "judging whether to pre-cool the ice-making compartment 113 according to the ice volume information of the ice storage box 151" includes:

It is judged whether the amount of ice in the ice storage box 151 is less than a first preset value.

For example, the first preset value may be the full ice volume Q of the ice storage bin 151 , or any other suitable ice volume, and the first preset value may be greater than 0.5Q. When the amount of ice in the ice storage box 151 is greater than the first preset value, the amount of ice in the ice storage box 151 is relatively large. At this time, the temperature rise generated during the defrosting process of the ice-making evaporator 131 will not make the ice-making compartment If the temperature of 113 rises too much, it will not cause the ice cubes in the ice storage box 151 to melt. Therefore, it is not necessary to pre-cool the ice-making compartment 113, and the defrosting unit corresponding to the ice-making evaporator 131 can be directly opened to make ice. The evaporator 131 performs defrosting, thereby saving energy consumption.

Because the more ice in the ice storage box 151, the more cold the ice cubes can dissipate, the smaller the temperature rise of the ice-making compartment 113 during the defrosting process of the ice-making evaporator 131 is. When the amount of ice is greater than a certain amount, the temperature generated during the defrosting process of the ice-making evaporator 131 may not cause the temperature of the ice-making compartment 113 to be too high. The ice-making compartment 113 needs to be pre-cooled. In this way, the pre-cooling time can be reduced, the noise generated by the compressor during the pre-cooling process can be avoided, and the defrosting efficiency can be improved to save energy consumption.

In this embodiment, the pre-cooling temperature may be positively correlated with the current amount of ice. "Matching the corresponding pre-cooling temperature based on ice volume information" may include:

If the current amount of ice is greater than or equal to the second preset value, the pre-cooling temperature is the first pre-cooling temperature;

Otherwise, the pre-cooling temperature is the second pre-cooling temperature;

Wherein, the second preset value is smaller than the first preset value, and the second pre-cooling temperature is lower than the first pre-cooling temperature.

For example, if the ice storage bin 151 is full of ice and the ice volume is Q, the first preset value can be 0.8Q, and the second preset value can be 0.5Q. When the current ice volume in the ice storage bin 151 is greater than or equal to When the first preset value is 0.8Q, there is no need to pre-cool the ice-making compartment 113, and the defrosting unit corresponding to the ice-making evaporator 131 can be directly turned on to defrost the ice-making evaporator 131; When the amount of ice is less than the first preset value 0.8Q and greater than or equal to the second preset value 0.5Q, the corresponding precooling temperature of the ice making compartment 113 can be T1. At this time, if the temperature of the ice making compartment 113 is greater than T1, then the refrigeration system can be turned on first to pre-cool the ice-making compartment 113, and when the temperature of the ice-making compartment 113 drops to T1, then the defrosting unit corresponding to the ice-making evaporator 131 is controlled to be turned on for the ice-making evaporator 131 Perform defrosting; if the current ice volume of the ice storage box 151 is less than the second preset value of 0.5Q, then the corresponding precooling temperature of the ice making compartment 113 can be T2, and T2 is less than T1 to ensure that the ice making compartment 113 The ice cubes in the ice storage box 151 will not be affected. At this time, if the temperature of the ice-making compartment 113 is greater than T2, the refrigeration system can be turned on to pre-cool the ice-making compartment 113. When the temperature of the ice-making compartment 113 When the temperature decreases to T2, the defrosting unit corresponding to the ice-making evaporator 131 is controlled to be turned on to defrost the ice-making evaporator 131 .

In this way, it can be judged according to the current amount of ice in the ice storage box 151 whether to pre-cool the ice-making compartment 113 and match the appropriate pre-cooling temperature, so as to reduce energy consumption and improve defrosting efficiency.

Referring to FIG. 9 , an embodiment of the present invention also provides a refrigerator 100 , including a memory 102 and a processor 101 , and the memory 102 and the processor 101 are communicatively connected through a communication bus 104 . A computer program that can run on the processor 101 is stored in the memory 102. When the processor 101 executes the computer program, the steps in the refrigerator control method in the above-mentioned embodiments are realized. The refrigerator 100 also includes a communication interface 103 connected to a communication bus 104 for communicating with other devices in the refrigerator 100 .

An embodiment of the present invention further provides a computer-readable storage medium, on which a computer program is stored. When the computer program is executed by a processor, the steps in the method for controlling the refrigerator in the above-mentioned embodiment are implemented.

Therefore, in summary, the refrigerator control method and the refrigerator 100 provided by the present invention, when the ice-making evaporator 131 meets the defrosting conditions, further judge whether to defrost the ice-making evaporator according to the current working state of the ice-making device 150. When the current working state of the ice making device is turning over ice, defrost the ice making evaporator after turning over ice to avoid overheating of the ice making room due to defrosting of the ice making evaporator during turning over ice. High, the ice cubes in the ice maker tray or in the ice storage bin melt and form ice cubes.

It should be understood that although the description is described according to the embodiments, not each embodiment only includes an independent technical solution, and this description of the description is only for clarity, and those skilled in the art should take the description as a whole, and each The technical solutions in the embodiments can also be properly combined to form other embodiments that can be understood by those skilled in the art.

The series of detailed descriptions listed above are only specific descriptions of feasible embodiments of the present invention, and are not intended to limit the scope of protection of the present invention. All equivalent embodiments or changes made without departing from the technical spirit of the present invention All should be included within the protection scope of the present invention.

Claims

A refrigerator control method, characterized in that, comprising:

Collect the working parameters of the ice making system;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is the ice-turning state, continue to monitor the working state;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is the non-ice-turning state, a start signal is sent to the defrosting unit corresponding to the ice-making evaporator.
The refrigerator control method according to claim 1, wherein the non-ice turning state includes an ice storage state and an ice making state.
The refrigerator control method according to claim 2, further comprising:

If the current working state is the ice making state, a start signal is sent to the defrosting unit corresponding to the ice making evaporator and the ice making device is controlled to stop the ice making operation.
The refrigerator control method according to claim 3, further comprising:

If the current working state of the ice-making device is the ice-making state, restart the ice-making operation after receiving the defrosting end signal of the ice-making evaporator.
A method for controlling a refrigerator, comprising:

Collect the working parameters of the ice making system;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is the ice-turning state, continue to monitor the working state of the ice-making device;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is a non-ice-turning state, control the refrigeration system to cool the ice-making compartment and monitor the temperature of the ice-making compartment;

When the temperature of the ice-making compartment is equal to or lower than the corresponding pre-cooling temperature, a defrosting start signal is sent to the corresponding defrosting unit of the ice-making evaporator.
The refrigerator control method according to claim 5, further comprising:

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is a non-refrosting state, the corresponding pre-cooling temperature is matched according to the current ice volume information of the ice storage box.
The refrigerator control method according to claim 5, wherein the non-ice turning state includes an ice storage state and an ice making state.
The refrigerator control method according to claim 7, further comprising:

If the current working state is the ice-making state, control the defrosting unit corresponding to the ice-making evaporator to start the defrosting operation and stop the ice-making operation.
The refrigerator control method according to claim 8, further comprising:

If the current working state of the ice-making device is the ice-making state, restart the ice-making operation after receiving the defrosting end signal of the ice-making evaporator.
A method for controlling a refrigerator, comprising:

Collect the working parameters of the ice making system;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is the ice-turning state, continue to monitor the working state;

When the working parameters meet the defrosting conditions of the ice-making evaporator and the current working state of the ice-making device is the non-ice-turning state, then judge whether to pre-cool the ice-making compartment according to the ice volume information of the ice storage box;

If so, match the pre-cooling temperature according to the ice volume information, and send a defrosting start signal to the defrosting unit corresponding to the ice-making evaporator when the temperature of the ice-making compartment is monitored to be equal to or lower than the corresponding pre-cooling temperature ;

If not, send a defrosting start signal to the defrosting unit corresponding to the ice-making evaporator.
The refrigerator control method according to claim 10, wherein "judging whether to pre-cool the ice-making compartment according to the ice volume information of the ice storage box" includes:

It is judged whether the amount of ice in the ice storage box is less than a first preset value.
The refrigerator control method according to claim 10, wherein the non-ice turning state includes an ice storage state and an ice making state.
The refrigerator control method according to claim 12, further comprising:

If the current working state is the ice-making state, control the defrosting unit corresponding to the ice-making evaporator to start the defrosting operation and stop the ice-making operation.
The refrigerator control method according to claim 13, further comprising:

If the current working state of the ice-making device is the ice-making state, restart the ice-making operation after receiving the defrosting end signal of the ice-making evaporator.