WO2022148089A1

WO2022148089A1 - Refrigerator control method and apparatus, and storage medium and refrigerator

Info

Publication number: WO2022148089A1
Application number: PCT/CN2021/124945
Authority: WO
Inventors: 杨华伟; 韩鹏; 明开云; 胡浩然; 张南佑; 李子鑫
Original assignee: 珠海格力电器股份有限公司
Priority date: 2021-01-08
Filing date: 2021-10-20
Publication date: 2022-07-14
Also published as: CN112815615A

Abstract

Provided are a refrigerator control method and apparatus, and a storage medium and a refrigerator. The refrigerator control method comprises: detecting and determining whether a refrigerator enters a defrosting period; when the refrigerator enters the defrosting period, acquiring a real-time environment temperature T0 of an environment where the refrigerator is located; and according to a relationship between the real-time environment temperature T0 and a preset environment temperature interval, setting the running time of forced refrigeration, and controlling the refrigerator to execute forced refrigeration according to the set running time of forced refrigeration, wherein the running time of forced refrigeration corresponds to the preset environment temperature interval that corresponds to the real-time environment temperature. According to the present application, when a real-time environment temperature is in different preset environment temperature intervals, different running times of forced refrigeration are respectively matched, and unlike in traditional technology, the running time of forced refrigeration with a fixed duration is utilized regardless of the level of the real-time environment temperature, thereby shortening the running time of a forced refrigeration stage, and thus reducing the consumption of electric energy insofar as performance requirements are met.

Description

Refrigerator control method, device, storage medium and refrigerator

Related applications

This application claims the priority of the Chinese patent application filed on January 08, 2021, with the application number of 202110022575.3 and entitled "Refrigerator Control Method, Device, Storage Medium, and Refrigerator", which is hereby incorporated by reference in its entirety.

technical field

The application belongs to the technical field of household appliances, and in particular relates to a refrigerator control method, a device, a storage medium and a refrigerator.

Background technique

Refrigerator, as a home appliance for storing food at low temperature or keeping items at a constant temperature, has entered thousands of households. With the acceleration of the pace of life, refrigerators are used more and more frequently.

Generally, in the defrosting operation stage of the refrigerator, the smaller the temperature rise of the freezing compartment is, the better the preservation of the food is. Therefore, in the initial stage of defrosting, forced refrigeration is required to lower the temperature of the freezing compartment. Most of the traditional control methods run for a fixed duration. However, if the ambient temperature or operating mode of the refrigerator changes, such as at a lower ambient temperature or operating in an energy-saving mode, appropriately shortening the forced cooling time can not only meet the temperature rise requirements of the freezer, but also reduce the energy consumption of the refrigerator.

SUMMARY OF THE INVENTION

Therefore, the technical problem to be solved by the present application is to provide a refrigerator control method, device, storage medium and refrigerator, so as to solve the problem that the refrigerator in the conventional technology has a fixed operation time for forced cooling before defrosting operation, resulting in high energy consumption of the refrigerator.

In order to solve the above problems, the present application provides a refrigerator control method, including:

Detect to determine whether the refrigerator has entered the defrosting cycle;

When the refrigerator enters the defrosting cycle, obtain the real-time ambient temperature T0 of the environment where the refrigerator is located;

According to the relationship between the real-time ambient temperature T0 and the preset ambient temperature interval, the operation time of the forced cooling is set and the refrigerator is controlled to operate the forced cooling with the set operation time of the forced cooling, wherein the operation time of the forced cooling and the real-time ambient temperature The corresponding preset ambient temperature interval corresponds.

In one embodiment, the preset ambient temperature interval includes at least a first preset ambient temperature interval (Ta, T1) and a second preset ambient temperature interval [T1, T2), where Ta is a preset ambient temperature interval The lower limit value, T1 is the first preset temperature, T2 is the second preset temperature and T1<T2, when T0∈(Ta, T1), the operation time of controlling the refrigerator to operate forced cooling is t1, when T0∈[T1 , T2), the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2.

In one embodiment, the preset ambient temperature interval further includes a third preset ambient temperature interval [T2, T3), where T3 is the third preset temperature and T2<T3, when T0∈[T2, T3) , the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2; or,

The preset ambient temperature interval also includes a fourth preset ambient temperature interval [T3, T4), where T3 is the third preset temperature, T4 is the fourth preset temperature and T2<T3<T4, when T0∈[T3 , T4), the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2; or,

The preset ambient temperature interval also includes a fifth preset ambient temperature interval [T4, Tb), where Tb is the preset upper limit value of the ambient temperature, T4 is the fourth preset temperature and T2<T4, when T0∈[T4 , Tb), the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2.

In one embodiment, the method further includes:

Detect whether the refrigerator is in energy saving mode;

When the refrigerator is in the energy saving mode, the operation time of controlling the refrigerator to operate forced cooling is t3, t1<t3<t2.

In one embodiment, detecting and judging whether the refrigerator enters a defrosting cycle includes:

Determining the magnitude relationship between the accumulative running time tls of the compressor and the first preset accumulative running time tly, and when tls≥tly, it is judged that the refrigerator has entered a defrosting cycle; and/or,

Determine the magnitude relationship between the first cumulative power-on time tts1 and the first preset cumulative power-on time tty, and when tts1 ≥ tty, determine that the refrigerator has entered a defrosting cycle; and/or,

Determine the relationship between the second accumulative power-on time tts2 of the refrigerator and the first preset accumulative power-on time tty, and the compressor single-on time tds and the first preset single-on time tdy, when tts2 ≥ tty and tds ≥ tdy , judging that the refrigerator has entered the defrosting cycle.

The application also provides a refrigerator control device, comprising:

a detection unit for detecting and judging whether the refrigerator has entered a defrosting cycle;

a judging unit, configured to acquire the real-time ambient temperature T0 of the environment where the refrigerator is located when the refrigerator enters the defrosting cycle;

The execution unit is configured to set the operation time of the forced cooling according to the relationship between the real-time ambient temperature T0 and the preset ambient temperature interval, and control the refrigerator to run the forced cooling with the set operation time of the forced cooling, wherein the operation time of the forced cooling is the same as the The preset ambient temperature interval corresponding to the real-time ambient temperature corresponds to.

In one embodiment, the detection unit is further configured to detect whether the refrigerator is in an energy saving mode;

The execution unit is further configured to, when the refrigerator is in the energy-saving mode, control the operation time of the refrigerator to operate forced cooling to be t3, and t1<t3<t2.

Determine the magnitude relationship between the first cumulative power-on time tts1 of the refrigerator and the first preset cumulative power-on time tty, and when tts1 ≥ tty, determine that the refrigerator has entered a defrost cycle; and/or,

Determine the relationship between the second cumulative power-on time tts2 of the refrigerator and the first preset cumulative power-on time tty, as well as the relationship between the compressor single-on time tds and the first preset single-on time tdy, when tts≥tty and tds≥tdy , judging that the refrigerator has entered the defrosting cycle.

The present application also provides a storage medium on which a computer program is stored, and when the program is executed by a processor, the steps of the above method are implemented.

The present application also provides a refrigerator, which includes a processor, a memory, and a computer program stored in the memory and executable on the processor, and the processor implements the steps of the above method when the processor executes the program.

In a refrigerator control method, device, storage medium and refrigerator provided by the present application, when the real-time ambient temperature T0 is in different preset ambient temperature ranges, different operating times of forced refrigeration are respectively matched, rather than regardless of the traditional technology. The high and low real-time ambient temperature all use the fixed-length forced cooling operation time, thereby reducing the operation time of the forced cooling stage, and reducing the consumption of electric energy under the premise of meeting the performance requirements.

Description of drawings

FIG. 1 is a schematic diagram of steps of a refrigerator control method according to an embodiment of the present application.

FIG. 2 is a structural block diagram of a refrigerator control device according to an embodiment of the application.

FIG. 3 is a schematic control flow diagram of the first embodiment of the application.

Detailed ways

Referring to FIGS. 1 to 3 in combination, according to an embodiment of the present application, a method for controlling a refrigerator is provided, including:

Detect to determine whether the refrigerator has entered the defrosting cycle;

According to the relationship between the real-time ambient temperature T0 and the preset ambient temperature interval, the operation time of the forced cooling is set and the refrigerator is controlled to operate the forced cooling with the set operation time of the forced cooling; wherein, the operation time of the forced cooling and the real-time ambient temperature The corresponding preset ambient temperature intervals correspond, that is, when the real-time ambient temperature T0 is in a different preset ambient temperature interval, the operation time of the forced cooling is set to be different. It can be understood that when the refrigerator operates the forced cooling The defrost phase will be entered after the operating time as described above.

In this technical solution, when the real-time ambient temperature T0 is in different preset ambient temperature ranges, different forced cooling operating times are matched respectively, instead of using a fixed duration of forced cooling regardless of the level of the real-time ambient temperature as in the traditional technology The operation time of refrigeration is reduced, thereby reducing the operation time of the forced refrigeration stage, and reducing the consumption of electric energy under the premise of meeting the performance requirements.

Specifically, the preset ambient temperature interval includes at least a first preset ambient temperature interval (Ta, T1) and a second preset ambient temperature interval [T1, T2), where Ta is a preset lower limit value of the ambient temperature, T1 is the first preset temperature, T2 is the second preset temperature, and T1<T2. When T0∈(Ta, T1), the operation time of controlling the refrigerator to operate forced cooling is t1; when T0∈[T1, T2), the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2. In other words, when the ambient temperature in which the refrigerator is located is low, the corresponding operation time of forced cooling is set to be short. This can not only prevent the food freezing effect from decreasing due to the temperature rise of the refrigerator during the defrosting stage, but also effectively reduce the consumption of electric energy.

In one embodiment, the preset ambient temperature interval further includes a third preset ambient temperature interval [T2, T3), where T3 is the third preset temperature and T2<T3, when T0∈[T2, T3) , the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2; or, the preset ambient temperature interval further includes a fourth preset ambient temperature interval [T3, T4), where T3 is the third preset temperature, T4 is the fourth preset temperature and T2<T3<T4, when T0∈[T3, T4), the operating time for controlling the forced cooling of the refrigerator is t2, t1<t2; or, the preset ambient temperature interval further includes the first Five preset ambient temperature intervals [T4, Tb), where Tb is the preset upper limit of ambient temperature, T4 is the fourth preset temperature and T2 < T4, when T0∈[T4, Tb), control the refrigerator to operate forced cooling The running time of t2 is t1<t2.

In some embodiments, the method further includes: detecting whether the refrigerator is in an energy saving mode;

When the refrigerator is in the energy saving mode, the operation time of controlling the refrigerator to operate forced cooling is t3, t1<t3<t2. In this technical solution, the operation time of forced cooling is further adjusted by determining whether the refrigerator is in the energy-saving mode. When in the energy-saving mode, t3 is adjusted to be between t1 and t2, so as to prevent the operation time from being too long. The room temperature is too low, thereby further reducing the consumption of electricity.

Detecting and judging whether the refrigerator has entered the defrosting cycle includes:

Determine the magnitude relationship between the second cumulative power-on time tts2 and the first preset cumulative power-on time tty, and the compressor single-on time tds and the first preset single-on time tdy, when tts2 ≥ tty and tds ≥ tdy, It is judged that the refrigerator enters the defrosting cycle, generally tts1>tts2. In the technical solution, whether the refrigerator enters the defrosting cycle is detected through a variety of preset conditions, so that the operation of the forced refrigeration stage can be more reasonable and accurate.

In some embodiments, T1=12°C, T2=18°C, T3=27°C, T4=34°C, t1=1h, t2=4h, t3=2h, Ta=-50°C; Tb=73°C.

According to an embodiment of the present application, a refrigerator control device is provided, including:

The execution unit is configured to set the operation time of the forced cooling according to the relationship between the real-time ambient temperature T0 and the preset ambient temperature interval, and control the refrigerator to operate the forced cooling with the set operation time of the forced cooling, wherein the operation time of the forced cooling is the same as the The preset ambient temperature intervals corresponding to the real-time ambient temperature correspond to each other, that is, when the real-time ambient temperature T0 is in different preset ambient temperature intervals, the operation time of the forced cooling is set differently. It can be understood that when the The refrigerator will enter the defrosting stage after the operation time as described above in forced cooling.

Specifically, the preset ambient temperature interval includes at least a first preset ambient temperature interval (Ta, T1) and a second preset ambient temperature interval [T1, T2), where Ta is a preset lower limit value of the ambient temperature, T1 is the first preset temperature, T2 is the second preset temperature and T1<T2, when T0∈(Ta, T1), the operating time for controlling the forced cooling of the refrigerator is t1, when T0∈[T1, T2) , the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2. In other words, when the ambient temperature in which the refrigerator is located is low, the corresponding operation time of forced cooling is set to be short. In this way, it can not only prevent the food freezing effect from decreasing due to the temperature rise of the refrigerator during the defrosting stage, but also effectively reduce the consumption of electric energy.

Further, the preset ambient temperature interval also includes a third preset ambient temperature interval [T2, T3), where T3 is the third preset temperature and T2<T3, when T0∈[T2, T3), control The operating time for the forced cooling of the refrigerator is t2, t1<t2; or, the preset ambient temperature interval further includes a fourth preset ambient temperature interval [T3, T4), where T3 is the third preset temperature and T4 is the third preset temperature. 4. The preset temperature and T2<T3<T4, when T0∈[T3, T4), the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2; or, the preset ambient temperature interval further includes a fifth preset temperature range. Set the ambient temperature interval [T4, Tb), where Tb is the preset upper limit of ambient temperature, T4 is the fourth preset temperature and T2 < T4, when T0∈[T4, Tb), control the operation of the refrigerator to operate forced cooling The time is t2, and t1<t2.

In some embodiments, the detection unit is further configured to detect whether the refrigerator is in an energy saving mode;

The execution unit is further configured to, when the refrigerator is in the energy-saving mode, control the operation time of the refrigerator to operate forced cooling to be t3, and t1<t3<t2. In this technical solution, the operation time of forced cooling is further adjusted by determining whether the refrigerator is in the energy-saving mode. When in the energy-saving mode, t3 is adjusted to be between t1 and t2, so as to prevent the operation time from being too long. The room temperature is too low, thereby further reducing the consumption of electricity.

Determine the relationship between the second accumulative power-on time tts2 of the refrigerator and the first preset accumulative power-on time tty, and the compressor single-on time tds and the first preset single-on time tdy, when tts2 ≥ tty and tds ≥ tdy , judging that the refrigerator enters the defrosting cycle, generally tts1>tts2. In the technical solution, whether the refrigerator enters the defrosting cycle is detected through a variety of preset conditions, so that the operation of the forced refrigeration stage can be more reasonable and accurate.

According to an embodiment of the present application, there is also provided a storage medium on which a computer program is stored, and when the program is executed by a processor, the steps of the above method are implemented.

According to an embodiment of the present application, a refrigerator is also provided, including a processor, a memory, and a computer program stored in the memory and executable on the processor, and the processor implements the steps of the above method when the processor executes the program; or, Including devices as described above.

It can be easily understood by those skilled in the art that, on the premise of no conflict, the above advantageous manners can be freely combined and superimposed.

The above are only preferred embodiments of the present application and are not intended to limit the present application. Any modifications, equivalent replacements and improvements made within the spirit and principles of the present application shall be included in the protection scope of the present application. Inside. The above are only some embodiments of the present application. It should be pointed out that for those skilled in the art, without departing from the technical principles of the present application, several improvements and modifications can also be made, and these improvements and modifications should also be It is regarded as the protection scope of this application.

Claims

A refrigerator control method, comprising:

Detect to determine whether the refrigerator has entered the defrosting cycle;

When the refrigerator enters the defrosting cycle, obtain the real-time ambient temperature T0 of the environment where the refrigerator is located;

According to the relationship between the real-time ambient temperature T0 and the preset ambient temperature interval, the operation time of the forced cooling is set and the refrigerator is controlled to operate the forced cooling with the set operation time of the forced cooling, wherein the operation time of the forced cooling and the real-time ambient temperature The corresponding preset ambient temperature interval corresponds.
The refrigerator control method according to claim 1, wherein,

The preset ambient temperature interval includes at least a first preset ambient temperature interval (Ta, T1) and a second preset ambient temperature interval [T1, T2), where Ta is the preset lower limit of the ambient temperature, and T1 is the first ambient temperature. A preset temperature, T2 is the second preset temperature and T1<T2, when T0∈(Ta, T1), control the refrigerator to operate the forced cooling operation time t1, when T0∈[T1, T2), control the refrigerator The operation time of the forced cooling operation is t2, and t1<t2.
The refrigerator control method according to claim 2, wherein,

The preset ambient temperature interval further includes a third preset ambient temperature interval [T2, T3), where T3 is the third preset temperature and T2<T3, when T0∈[T2, T3), the refrigerator is controlled to operate for forced cooling The running time of is t2, t1 < t2; or,

The preset ambient temperature interval also includes a fourth preset ambient temperature interval [T3, T4), where T3 is the third preset temperature, T4 is the fourth preset temperature and T2<T3<T4, when T0∈[T3 , T4), the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2; or,

The preset ambient temperature interval also includes a fifth preset ambient temperature interval [T4, Tb), where Tb is the preset upper limit value of the ambient temperature, T4 is the fourth preset temperature and T2<T4, when T0∈[T4 , Tb), the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2.
The refrigerator control method according to claim 2 or 3, wherein the method further comprises:

Detect whether the refrigerator is in energy saving mode;

When the refrigerator is in the energy saving mode, the operation time of controlling the refrigerator to operate forced cooling is t3, t1<t3<t2.
The refrigerator control method according to claim 1, wherein detecting and judging whether the refrigerator enters a defrosting cycle comprises:

Determining the magnitude relationship between the accumulative running time tls of the compressor and the first preset accumulative running time tly, and when tls≥tly, it is judged that the refrigerator has entered a defrosting cycle; and/or,

Determine the magnitude relationship between the first cumulative power-on time tts1 of the refrigerator and the first preset cumulative power-on time tty, and when tts1 ≥ tty, determine that the refrigerator has entered a defrost cycle; and/or,

Determine the relationship between the second accumulative power-on time tts2 of the refrigerator and the first preset accumulative power-on time tty, and the compressor single-on time tds and the first preset single-on time tdy, when tts2 ≥ tty and tds ≥ tdy , judging that the refrigerator has entered the defrosting cycle.
A refrigerator control device, comprising:

a detection unit for detecting and judging whether the refrigerator has entered a defrosting cycle;

a judging unit, configured to acquire the real-time ambient temperature T0 of the environment where the refrigerator is located when the refrigerator enters the defrosting cycle;

The execution unit is configured to set the operation time of the forced cooling according to the relationship between the real-time ambient temperature T0 and the preset ambient temperature interval, and control the refrigerator to operate the forced cooling with the set operation time of the forced cooling, wherein the operation time of the forced cooling is the same as the The preset ambient temperature interval corresponding to the real-time ambient temperature corresponds to.
The refrigerator control device according to claim 6, wherein,

The preset ambient temperature interval includes at least a first preset ambient temperature interval (Ta, T1) and a second preset ambient temperature interval [T1, T2), wherein T1 is the first preset temperature and T2 is the second preset temperature. Set the temperature and T1<T2, when T0∈(Ta, T1), the operating time of controlling the forced cooling of the refrigerator is t1, and when T0∈[T1, T2), the operating time of controlling the forced cooling of the refrigerator is t2, t1 <t2.
The refrigerator control device according to claim 7, wherein,

The preset ambient temperature interval further includes a third preset ambient temperature interval [T2, T3), where T3 is the third preset temperature and T2<T3, when T0∈[T2, T3), the refrigerator is controlled to operate for forced cooling The running time of is t2, t1 < t2; or,

The preset ambient temperature interval also includes a fourth preset ambient temperature interval [T3, T4), where T3 is the third preset temperature, T4 is the fourth preset temperature and T2<T3<T4, when T0∈[T3 , T4), the operation time of controlling the refrigerator to operate forced cooling is t2, t1<t2; or,

The preset ambient temperature interval also includes a fifth preset ambient temperature interval [T4, Tb), where T4 is the fourth preset temperature and T2 < T4, when T0∈[T4, Tb), the refrigerator is controlled to operate forced cooling The running time of t2 is t1<t2.
The refrigerator control device according to claim 7 or 8, wherein,

The detection unit is also used to detect whether the refrigerator is in the energy-saving mode;

The execution unit is further configured to, when the refrigerator is in the energy-saving mode, control the operation time of the refrigerator to operate forced cooling to be t3, and t1<t3<t2.
The refrigerator control device according to claim 6, wherein detecting and judging whether the refrigerator enters a defrosting cycle comprises:

Determining the magnitude relationship between the accumulative running time tls of the compressor and the first preset accumulative running time tly, and when tls≥tly, it is judged that the refrigerator has entered a defrosting cycle; and/or,

Judging the magnitude relationship between the accumulative power-on time tts of the refrigerator and the first preset accumulative power-on time tty, and when tts ≥ tty, it is judged that the refrigerator has entered a defrosting cycle; and/or,

Determine the relationship between the accumulative power-on time tts of the refrigerator and the first preset accumulative power-on time tty, as well as the relationship between the compressor single-on time tds and the first preset single-on time tdy, when tts≥tty and tds≥tdy, judge The refrigerator enters the defrost cycle.
A storage medium on which a computer program is stored, wherein when the program is executed by a processor, the method of any one of claims 1-5 is implemented.
A refrigerator includes a processor, a memory, and a computer program stored in the memory and executable on the processor, wherein the processor implements the method of any one of claims 1-5 when the processor executes the program.