CN113465272A

CN113465272A - Refrigeration control method of refrigerator, computer device and computer readable storage medium

Info

Publication number: CN113465272A
Application number: CN202110809129.7A
Authority: CN
Inventors: 汪涛; 宋有兵; 张咏
Original assignee: Gree Electric Appliances Inc of Zhuhai
Current assignee: Gree Electric Appliances Inc of Zhuhai
Priority date: 2021-07-16
Filing date: 2021-07-16
Publication date: 2021-10-01
Anticipated expiration: 2041-07-16
Also published as: CN113465272B

Abstract

The invention provides a refrigerator, a refrigeration control method of the refrigerator, a computer device and a computer readable storage medium, wherein the refrigeration control method comprises the steps of judging whether a compressor is in a defrosting state at the current moment when the compressor meets a starting condition, and determining a first target rotating speed of the compressor according to the obtained outer ring temperature value if the compressor does not meet the starting condition; and if so, determining a second target rotating speed of the compressor according to the latest defrosting time. The refrigerator, the computer device and the computer readable storage medium can realize the refrigeration control method. According to the invention, the starting and stopping time of the starting operation of the compressor is set, the rotating speed of the specific compressor is matched, the temperature change of the freezing chamber meets the refrigeration requirement, the operating rotating speed and the starting and stopping time of the compressor are met, the problem of the heat load of the box body is solved, the operation logic and the rotating speed control of the compressor after defrosting are optimized, and the energy consumption is saved.

Description

Refrigeration control method of refrigerator, computer device and computer readable storage medium

Technical Field

The invention relates to the technical field of refrigeration equipment, in particular to a refrigeration control method of a refrigerator, the refrigerator, a computer device and a computer readable storage medium.

Background

The frequency conversion air-cooled refrigerator can meet the refrigerating capacity requirements of a plurality of refrigerating compartments by regulating and controlling the running rotating speed of the compressor. The existing refrigeration control method of the refrigerator judges the refrigerating capacity requirement of each refrigerating chamber according to the temperature difference value between the detected temperature of each refrigerating chamber and the corresponding preset temperature, and adjusts the running rotating speed gear of a compressor.

However, the control method is not considered from the aspects of the thermal load of the box body and the service life of the compressor, although the operating rotating speed of the compressor meets the requirement of the refrigerating capacity, the control method can cause larger thermal load and larger energy consumption to the box body, for example, after defrosting work is finished, based on the compartment refrigerating requirement, when the compressor is restarted, if the operating rotating speed and the operating duration of the compressor are adjusted only according to the compartment temperature difference, the problems of large thermal load, high energy consumption and the like of the box body exist, and in addition, the problem that the starting failure of the compressor is easily caused due to overhigh system pressure exists.

Disclosure of Invention

The first purpose of the invention is to provide a refrigeration control method of a refrigerator, which meets the compartment refrigeration requirement, solves the heat load and energy consumption of a box body and solves the running problem after defrosting.

The second purpose of the invention is to provide a refrigerator capable of realizing the refrigeration control method.

A third object of the present invention is to provide a computer device capable of implementing the above refrigeration control method.

A fourth object of the present invention is to provide a computer-readable storage medium that can implement the above-described refrigeration control method.

The first purpose of the invention provides a refrigeration control method of a refrigerator, which comprises the steps that when a compressor meets a starting condition, whether the compressor is in a defrosting state at the current moment is judged, if not, a first target rotating speed of the compressor is determined according to an obtained outer ring temperature value; if yes, determining a second target rotating speed of the compressor according to the latest defrosting time.

According to the scheme, when the compressor meets the starting condition, the system judges the state of the compressor at the current moment, and if the compressor does not enter the defrosting state, the system judges whether the compressor is started at the second rotating speed or the third rotating speed by combining the comparison structure of the outer ring temperature value and the first preset value; if the defrosting state is entered firstly, the target rotating speed is selected to be set to be the fourth rotating speed or the second rotating speed according to the latest defrosting time, the starting and stopping time of the compressor is set and matched with the rotating speed of the specific compressor, the temperature change of the freezing chamber meets the refrigeration requirement and functional logic, the running rotating speed and the starting and stopping time of the compressor are also met, the problem of thermal load of a box body is solved, the problem that the compressor cannot be started due to overhigh system pressure after defrosting is finished is solved, the running logic and the rotating speed control of the compressor after defrosting are optimized, the running power of the compressor is ensured to be constant during defrosting, and energy consumption is saved.

Further scheme is that after the step of determining the second target rotating speed according to the latest defrosting time: the compressor operates at a second target rotating speed for a first preset time period; the compressor operates at a second target rotating speed for a second preset time period, and the detection temperature value of the freezing chamber is obtained in real time within the second preset time period; and adjusting the rotating speed of the compressor according to the comparison result of the detected temperature value of the freezing chamber and the second preset value.

Therefore, the rotation speed of the compressor is adjusted and the compressor is operated for the first preset time length under the comprehensive consideration of defrosting requirements, energy consumption and heat load by judging whether the compressor is restarted and judging the current stage of the defrosting state according to the latest defrosting time length after entering the defrosting state, and the rotation speed of the compressor is increased according to the room temperature difference. For example, at the later stage of the defrosting state or after defrosting is finished, the compressor operates at a lower rotating speed within the dripping time, and the rotating speed of the compressor is increased according to the room temperature difference after the dripping time is finished. For another example, the defrosting operation is carried out at a lower rotating speed to increase the frosting amount and enter the defrosting operation in advance, so that the defrosting time is prolonged; and after the frosting state is finished, the rotating speed of the compressor is increased according to the room temperature difference. And when the temperature difference value meets the judgment condition, the system jumps out of the operation logic of the scheme and adjusts the rotating speed of the compressor according to the normal operation logic of the system.

According to a further scheme, in the step of adjusting the rotating speed of the compressor according to the comparison result of the detected temperature value of the freezing chamber and the second preset value, the rotating speed after the adjustment of the compressor is positively related to the latest defrosting time.

Therefore, the longer the defrosting time is last, the larger the temperature difference value between the detected temperature value of the defrosting rear compartment and the preset value is, the larger the refrigerating demand is, and the rotating speed of the compressor is increased, so that the refrigerating efficiency is improved.

In a further scheme, the second target rotating speed is positively related to the last defrosting time length, and the second target rotating speed is negatively related to the second preset time length.

Therefore, the longer the defrosting time is, the closer the defrosting state is to be finished or is finished, so that the energy consumption of the heater is lower, the compressor can operate at a higher rotating speed, and the higher the rotating speed of the compressor is, the shorter the required refrigerating time is, so that the second preset time is shortened. The arrangement can improve the compartment refrigeration efficiency under the conditions of energy consumption and heat load.

The further scheme is that the method comprises the following steps of determining a second target rotating speed according to the latest defrosting time, starting a compressor and operating for a first preset time: if the last defrosting time is longer than or equal to a third preset value, determining the second target rotating speed as a fourth rotating speed; if the last defrosting time is shorter than a third preset value, determining the second target rotating speed as a second rotating speed; the fourth rotational speed is higher than the second rotational speed.

In a further aspect, the step of operating the compressor at the second target speed for a first preset time period comprises: if the defrosting time of the last time is more than or equal to a third preset value, taking the value of the first preset time as a first value; if the last defrosting time is less than a third preset value, the value of the first preset time is a second value; the first value is greater than the second value.

Therefore, the current stage is judged according to the comparison result of the latest defrosting time and the third preset value, if the water dropping time is long, the rotating speed of the compressor can be increased to a fourth higher rotating speed and the compressor can operate for a longer time, and if the water dropping time is long, the compressor can be increased to a second lower rotating speed and the compressor can operate for a shorter time, so that the refrigerating efficiency after defrosting can be improved on the premise of avoiding over-high energy consumption.

The further scheme is that in the step that the compressor runs at a second target rotating speed for a second preset time period: if the defrosting time of the last time is more than or equal to a third preset value, taking the value of the second preset time as a third value; if the last defrosting time is shorter than a third preset value, the value of the second preset time is a fourth value; the third value is less than the fourth value.

As can be seen from the above, under the same refrigeration requirement, the higher the rotation speed of the compressor is, the shorter the required refrigeration time is, and therefore the second preset time is shortened. The arrangement can improve the compartment refrigeration efficiency under the conditions of energy consumption and heat load.

The further scheme is that the step of adjusting the rotating speed of the compressor according to the comparison result of the detected temperature value of the freezing chamber and the second preset value is as follows: when the last defrosting time is longer than or equal to a third preset value, and the difference value between the detected temperature value of the freezing chamber and the second preset value is longer than or equal to a fourth preset value, increasing the rotating speed of the compressor to an eighth rotating speed; when the last defrosting time is shorter than a third preset value and the difference value between the detected temperature value of the freezing chamber and the second preset value is larger than or equal to a fifth preset value, the rotating speed of the compressor is increased to a seventh rotating speed; the fourth preset value is larger than the fifth preset value, and the eighth rotating speed is higher than the seventh rotating speed.

As can be seen from the above, according to the difference of the last defrosting time, the preset values used for comparing the detected temperature value of the freezing chamber with the second preset value are different, and the correspondingly increased gear selection of the rotating speed is also different, so that the temperature change of the freezing chamber can be better judged to match the corresponding rotating speed of the compressor.

The further scheme is that the step of adjusting the rotating speed of the compressor according to the comparison result of the detected temperature value of the freezing chamber and the second preset value is as follows: when the last defrosting time is longer than or equal to a third preset value and the difference value between the detected temperature value of the freezing chamber and the second preset value is smaller than a fourth preset value, the rotating speed of the compressor is kept at a fourth rotating speed; and when the last defrosting time is less than a third preset value and the difference value between the detected temperature value of the freezing chamber and the second preset value is less than a fifth preset value, the rotating speed of the compressor is kept at the second rotating speed.

Therefore, if the difference value between the detected temperature value of the freezing chamber and the second preset value is smaller than the corresponding preset value, the current rotating speed of the compressor is judged to meet the refrigeration requirement, and therefore the rotating speed is not increased so as to reduce energy consumption and heat load of the box body.

After the step of increasing the rotating speed of the compressor to the eighth rotating speed, if the difference value between the detected temperature value of the freezing chamber and the second preset value is greater than or equal to the sixth preset value, adjusting the rotating speed of the compressor according to the initial refrigeration requirement; after the step of increasing the rotating speed of the compressor to the seventh rotating speed, if the difference value between the detected temperature value of the freezing chamber and the second preset value is larger than or equal to the seventh preset value, the rotating speed of the compressor is adjusted according to the initial refrigeration requirement. The sixth preset value is smaller than the fourth preset value, and the seventh preset value is smaller than the fifth preset value.

Therefore, whether the temperature of the intermediate room meets the requirement after the rotating speed of the compressor is increased and operates for a certain time is judged by setting the second temperature difference value judging step, and if yes, the rotating speed of the compressor is reduced according to the required rotating speed of the initial refrigeration state.

Further, the step of determining the first target rotation speed according to the obtained outer ring temperature value comprises: if the temperature value of the outer ring is greater than or equal to the first preset value, the first target rotating speed is determined as a second rotating speed; if the temperature value of the outer ring is smaller than the first preset value, the first target rotating speed is determined as a third rotating speed; the third rotational speed is higher than the second rotational speed.

According to a further scheme, the first target rotating speed is determined to be a third preset time after the second rotating speed is operated; the first target rotating speed is determined to be a fourth preset time after the third rotating speed is reached; the third preset duration is greater than the fourth preset duration.

Therefore, if the compressor is not started after entering the defrosting state, the heat load condition of the current box body is judged according to the difference value between the outer ring temperature value and the first preset value, if the heat load of the box body is large, the compressor runs for a long time at a low rotating speed to meet the refrigerating capacity requirement, if the heat load of the box body is small, the compressor runs for a long time at a high rotating speed to meet the refrigerating requirement, and therefore the situation that the heat load of the box body is too high is avoided.

A second object of the present invention is to provide a refrigerator including a processor for implementing the above-mentioned cooling control method when executing a computer program stored in a memory.

A third object of the present invention is to provide a computer device comprising a processor for implementing the above-mentioned refrigeration control method when executing a computer program stored in a memory.

A fourth object of the present invention is to provide a computer-readable storage medium having a computer program stored thereon, the computer program, when executed by a processor, implementing the above-described refrigeration control method.

Drawings

Fig. 1 is a first flowchart of a refrigeration control method of a refrigerator according to an embodiment of the present invention.

Fig. 2 is a second flowchart of the refrigeration control method of the refrigerator according to the embodiment of the present invention.

Fig. 3 is a third flowchart of a refrigeration control method of a refrigerator according to an embodiment of the present invention.

Detailed Description

Refrigerator and refrigeration control method embodiment of refrigerator

The refrigerator of the embodiment is a cold air frequency conversion refrigerator comprising a freezing chamber and a refrigerating chamber, wherein the freezing chamber, the temperature changing chamber and the refrigerating chamber are mutually independent refrigerating spaces, the freezing chamber is used for refrigerating at a low temperature below 0 ℃, the freezing chamber can meet the requirement of three-star and four-star storage temperature at a low temperature below-18 ℃, and the refrigerating chamber is used for refrigerating at a low temperature above 0 ℃. In other embodiments, the refrigerator further comprises a temperature-changing chamber, and the adjustable refrigerating temperature range of the temperature-changing chamber is-15 ℃ to 6 ℃.

The refrigerator has a first room temperature sensor and a second room temperature sensor respectively provided corresponding to the freezing chamber and the refrigerating chamber, wherein the system can acquire a freezing chamber detection temperature value in real time through the first room temperature sensor. The whole refrigerator is provided with an ambient temperature detection sensor, and the system can detect and obtain an outer ring temperature value in real time through the ambient temperature detection sensor. In addition, the refrigerator also comprises a defrosting control device, the defrosting control device comprises a defrosting temperature sensor, a defrosting heater and a defrosting timer, the system can obtain the latest defrosting time length from the beginning of entering the defrosting state through the defrosting time timer, and the defrosting time length is the working time length of the defrosting heater.

The refrigerating system of the refrigerator comprises a compressor, wherein the rotating speed of the compressor can be controlled, 8 levels of rotating speeds such as L1-L8 are preset for the rotating speed of the compressor, the rotating speeds are sequentially increased from the level L1 to the level L8, and the rotating speeds from the level L1 to the level L8, L1, L2 and L3, … … and L8 correspond to a first rotating speed, a second rotating speed and an eighth rotating speed of a third rotating speed … … of the invention respectively.

A processor is provided in the housing of the refrigerator for implementing the refrigeration control method when executing the computer program stored in the memory.

Referring to fig. 1, a refrigeration control method of a refrigerator is as follows:

after the refrigerator is powered on, the system first performs a determination step S1 to determine whether the compressor satisfies the power-on condition, and a determination step S1 is used to determine whether the compressor satisfies the basic condition for restarting. If the judgment result of the step S1 is negative, the step S20 is executed to control the operation of the compressor according to the initial cooling state requirement. If the determination result in the step S1 is yes, a determination step S2 is executed to determine whether the compressor enters the defrosting state before the current time point of restarting the compressor after determining whether the compressor enters the defrosting state at the current time point. Since whether the defrosting state is entered before the current time affects the energy consumption and the heat load condition of the system, different target rotating speeds of the compressor need to be set as the judgment conditions.

If the judgment result in the step S2 is no, executing step S16, obtaining an outer ring temperature value t10 in real time, and then executing a judgment step S17, judging whether the outer ring temperature value t10 is greater than a first preset value t1, where t1 is 16 ℃ in this embodiment, if the judgment result in the step S17 is yes, executing step S18, where the compressor determines that the rotation speed of the L2 is the target rotation speed, starts and operates for 60 seconds, and 60 seconds is a third preset duration of the present invention; if the judgment result in the step S17 is negative, step S19 is executed, and the compressor determines that the L3 rotation speed is started as the target rotation speed, and the operation is performed for 40 seconds, where 40 seconds is a fourth preset time length of the present invention. Because the outer ring temperature value can reflect the heat load condition of the box body, different target rotating speeds of the compressor are set according to the difference value of the outer ring temperature value and the first preset value, and the heat load of the box body is reduced.

If the determination result in the determination step S2 is yes, then a determination step S3 is executed to determine whether the latest defrosting time period a from the time of entering the defrosting state is greater than or equal to 30 minutes, where 30 minutes is the third preset value of the present invention.

If the judgment result in the step S3 is yes, step S4 is executed, and the compressor determines that the L4 rotation speed is the target rotation speed, starts and operates for 10 minutes, where 10 minutes is the first value of the first preset time duration of the present invention. Since the last defrosting time period a exceeds 30 minutes, the defrosting state may have been exited or the heater may be in the dripping time and the defrosting state is about to exit, and the heater has stopped operating, the compressor may be started at the higher L4 speed and 10 minutes may be set as the dripping time period.

With reference to fig. 1 and 2, after the step S4 is completed, step S5 is executed, the rotation speed of the compressor is maintained at L4, the compressor is operated for 60 minutes, and meanwhile, the detected temperature value t11 of the freezing chamber is obtained in real time, and the 60 minutes is a third value of a second preset time period of the present invention. In the step, the compressor is maintained at a lower rotating speed and runs for a longer time to defrost, and then the compressor is recovered, so that the problem that the compressor cannot be started due to direct starting at a high rotating speed after the defrosting state is finished can be solved.

Then, executing a judgment step S6, judging whether the difference between the detected freezing chamber temperature value t11 and the second preset value t2 is greater than or equal to a fourth preset value t4, where the fourth preset value t4 is 4 ℃ in this embodiment, if not, the current L4 rotating speed meets the refrigeration requirement, executing a step S9, and keeping the rotating speed of the compressor at L4 and continuing to operate; if yes, the current L4 speed does not match the cooling demand, step S7 is executed, and the compressor speed is increased to the L8 speed and operated.

And executing a circulating judgment step S8 after the rotating speed is increased, judging whether the difference value between the detected freezing chamber temperature value t11 and the second preset value t2 is greater than or equal to a sixth preset value t6, wherein the sixth preset value t6 is-1 ℃ in the embodiment, if not, executing a step S8 in a circulating mode, if so, meeting the refrigeration requirement, and then executing a step S20, and controlling the compressor to operate according to the initial refrigeration state requirement.

Referring to fig. 1, if the determination result in the step S3 is negative, step S10 is executed, and the compressor determines that L2 is the target rotation speed, starts to operate for 8 minutes, where 8 minutes is the second value of the first preset time period of the present invention. Because the defrosting time length A of the last defrosting does not exceed 30 minutes, the defrosting state is not exited and the pre-cooling stage is in, the compressor is started at a low L2 rotating speed, 8 minutes are set as the pre-cooling time length, the defrosting amount of the upper surface and the lower surface of the fin evaporator is increased, the defrosting program is started in advance, and the working time length of the heater is prolonged.

With reference to fig. 1 and 3, after the step S10 is completed, step S11 is executed, the rotation speed of the compressor is maintained at L2, the compressor is operated for 80 minutes, and meanwhile, the detected temperature value t11 of the freezing chamber is obtained in real time, and the 80 minutes is a fourth value of a second preset time period of the present invention. In the step, the compressor is maintained at a lower rotating speed and operates for a longer time to defrost, and then the compressor is recovered, so that the problem that the compressor is started again at a high rotating speed to be failed due to the increase of the refrigerating capacity after the defrosting process is finished is solved.

Then, executing a judgment step S12, judging whether the difference between the detected freezing chamber temperature value t11 and the second preset value t2 is greater than or equal to a fifth preset value t5, where the fourth preset value t5 is 3 ℃ in this embodiment, and if not, the current L2 rotating speed meets the refrigeration requirement, executing a step S15, and keeping the compressor rotating speed at L2 and continuing to operate; if yes, the current L2 speed does not match the cooling demand, step S13 is executed, and the compressor speed is increased to the L7 speed and operated.

And executing a circulating judgment step S14 after the rotating speed is increased, judging whether the difference value between the detected freezing chamber temperature value t11 and the second preset value t2 is greater than or equal to an eighth preset value t8, wherein the eighth preset value t8 is-2 ℃ in the embodiment, if not, executing a step S14 in a circulating mode, if so, meeting the refrigeration requirement, and then executing a step S20, and controlling the compressor to operate according to the initial refrigeration state requirement.

With reference to fig. 1 to 3, in the present invention, when the compressor meets the start condition, the system first determines the current state, and if the compressor does not enter the defrosting state, the system determines whether the compressor is started at the second rotation speed or the third rotation speed by combining the comparison structure between the outer ring temperature value and the first preset value; if the defrosting state is entered firstly, the target rotating speed is selected and set to be the fourth rotating speed or the second rotating speed according to the latest defrosting time, after the corresponding preset time is operated, whether the rotating speed of the compressor needs to be increased or not is judged according to the compartment detection temperature, and if the rotating speed of the compressor needs to be increased, the rotating speed of the compressor is correspondingly increased to be the eighth rotating speed or the seventh rotating speed.

According to the invention, by setting the on-off time of the compressor and matching the rotating speed of the specific compressor, the temperature change of the freezing chamber meets the refrigeration requirement and functional logic, and also meets the operating rotating speed and the on-off time of the compressor, the problem of thermal load of a box body is solved, the problem that the compressor cannot be started due to overhigh system pressure after defrosting is finished is solved, the operating logic and rotating speed control of the compressor after defrosting are optimized, the operating power of the compressor is ensured to be constant during defrosting, and the energy consumption is saved.

Embodiments of a computer device

The computer device of the present invention may be a device including a processor, a memory, and the like, for example, a single chip microcomputer including a central processing unit and the like. The processor is used for implementing the steps of the refrigeration control method of the refrigerator when executing the computer program stored in the memory.

The Processor may be a Central Processing Unit (CPU), other general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, etc. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

The memory may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required by at least one function (such as a sound playing function, an image playing function, etc.), and the like; the storage data area may store data (such as audio data, a phonebook, etc.) created according to the use of the cellular phone, and the like. In addition, the memory may include high speed random access memory, and may also include non-volatile memory, such as a hard disk, a memory, a plug-in hard disk, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), at least one magnetic disk storage device, a Flash memory device, or other volatile solid state storage device.

Computer-readable storage medium embodiments

The computer readable storage medium of the present invention may be any form of storage medium that is read by a processor of a computer device, including but not limited to a non-volatile memory, a ferroelectric memory, etc., and the computer readable storage medium has a computer program stored thereon, and when the processor of the computer device reads and executes the computer program stored in the memory, the steps of the above-described refrigeration control method of the refrigerator may be implemented.

The computer program comprises computer program code which may be in the form of source code, object code, an executable file or some intermediate form, etc. The computer-readable medium may include: any entity or device capable of carrying the computer program code, recording medium, usb disk, removable hard disk, magnetic disk, optical disk, computer Memory, Read-Only Memory (ROM), Random Access Memory (RAM), electrical carrier wave signals, telecommunications signals, software distribution medium, and the like. It should be noted that the computer readable medium may contain content that is subject to appropriate increase or decrease as required by legislation and patent practice in jurisdictions, for example, in some jurisdictions, computer readable media does not include electrical carrier signals and telecommunications signals as is required by legislation and patent practice.

Finally, it should be emphasized that the above-described preferred embodiments of the present invention are merely examples of implementations, rather than limitations, and that many variations and modifications of the invention are possible to those skilled in the art, without departing from the spirit and scope of the invention.

Claims

1. A refrigeration control method of a refrigerator, comprising:

when the compressor meets the starting condition, judging whether the current time is in the defrosting state,

if not, determining a first target rotating speed of the compressor according to the obtained outer ring temperature value;

and if so, determining a second target rotating speed of the compressor according to the latest defrosting time.

2. A cooling control method of a refrigerator according to claim 1, wherein:

after the step of determining the second target rotating speed according to the latest defrosting time:

the compressor operates at the second target rotating speed for a first preset time period;

the compressor operates at the second target rotating speed for a second preset time period, and a detection temperature value of the freezing chamber is obtained in real time within the second preset time period;

and adjusting the rotating speed of the compressor according to the comparison result of the detected temperature value of the freezing chamber and a second preset value.

3. A cooling control method of a refrigerator according to claim 2, wherein:

in the step of adjusting the rotating speed of the compressor according to the comparison result of the detected temperature value of the freezing chamber and a second preset value, the rotating speed after the adjustment of the compressor is positively related to the latest defrosting time.

4. A cooling control method of a refrigerator according to claim 2 or 3, wherein:

the second target rotating speed is positively related to the last defrosting time, and the second target rotating speed is negatively related to the second preset time.

5. A cooling control method of a refrigerator according to claim 2 or 3, wherein:

the step of determining the second target rotating speed according to the latest defrosting time, starting the compressor and operating for a first preset time comprises the following steps:

if the last defrosting time is longer than or equal to a third preset value, determining the second target rotating speed as a fourth rotating speed;

if the last defrosting time is shorter than the third preset value, determining the second target rotating speed as a second rotating speed;

the fourth rotational speed is higher than the second rotational speed.

6. The cooling control method of the refrigerator as claimed in claim 5, wherein:

the step of operating the compressor at the second target rotational speed for a first preset period of time:

if the last defrosting time is longer than or equal to the third preset value, the value of the first preset time is a first value;

if the last defrosting time is shorter than the third preset value, the value of the first preset time is a second value;

the first value is greater than the second value.

7. The cooling control method of the refrigerator as claimed in claim 5, wherein:

the step of operating the compressor at the second target speed for a second preset period of time:

if the last defrosting time is longer than or equal to the third preset value, the value of the second preset time is a third value;

if the last defrosting time is shorter than the third preset value, the value of the second preset time is a fourth value;

the third value is less than the fourth value.

8. The cooling control method of the refrigerator as claimed in claim 5, wherein:

the step of adjusting the rotating speed of the compressor according to the comparison result of the detected temperature value of the freezing chamber and a second preset value comprises the following steps:

when the last defrosting time is longer than or equal to the third preset value, and the difference value between the detected temperature value of the freezing chamber and the second preset value is longer than or equal to a fourth preset value, increasing the rotating speed of the compressor to an eighth rotating speed;

when the last defrosting time is shorter than the third preset value and the difference value between the detected temperature value of the freezing chamber and the second preset value is larger than or equal to a fifth preset value, the rotating speed of the compressor is increased to a seventh rotating speed;

the fourth preset value is larger than the fifth preset value, and the eighth rotating speed is higher than the seventh rotating speed.

9. The cooling control method of the refrigerator as claimed in claim 8, wherein:

when the last defrosting time is longer than or equal to the third preset value and the difference value between the detected temperature value of the freezing chamber and the second preset value is smaller than the fourth preset value, the rotating speed of the compressor is kept at the fourth rotating speed;

and when the last defrosting time is less than the third preset value and the difference value between the detected temperature value of the freezing chamber and the second preset value is less than the fifth preset value, the rotating speed of the compressor is kept at the second rotating speed.

10. The cooling control method of the refrigerator as claimed in claim 8, wherein:

after the step of increasing the rotating speed of the compressor to the eighth rotating speed, if the difference value between the detected temperature value of the freezing chamber and the second preset value is greater than or equal to a sixth preset value, adjusting the rotating speed of the compressor according to the initial refrigeration requirement;

after the step of increasing the rotating speed of the compressor to a seventh rotating speed, if the difference value between the detected temperature value of the freezing chamber and the second preset value is more than or equal to the seventh preset value, adjusting the rotating speed of the compressor according to the initial refrigeration requirement;

the sixth preset value is smaller than the fourth preset value, and the seventh preset value is smaller than the fifth preset value.

11. The cooling control method of a refrigerator according to any one of claims 1 to 3, wherein:

the step of determining the first target rotation speed according to the obtained outer ring temperature value comprises the following steps:

if the outer ring temperature value is larger than or equal to a first preset value, the first target rotating speed is determined as a second rotating speed;

if the outer ring temperature value is smaller than the first preset value, the first target rotating speed is determined as a third rotating speed;

the third rotational speed is higher than the second rotational speed.

12. The cooling control method of the refrigerator as claimed in claim 11, wherein:

the first target rotating speed is determined to be the second rotating speed and then operates for a third preset time;

the first target rotating speed is determined to be the fourth preset time after the third rotating speed is operated;

the third preset duration is longer than the fourth preset duration.

13. The refrigerator is characterized in that: the refrigerator includes a processor for implementing the cooling control method of the refrigerator according to any one of claims 1 to 12 when executing a computer program stored in a memory.

14. A computer device, characterized by: the computer device includes a processor for implementing the refrigeration control method of the refrigerator according to any one of claims 1 to 12 when executing a computer program stored in a memory.

15. A computer-readable storage medium having stored thereon a computer program, characterized in that: the computer program, when executed by a processor, implements the refrigeration control method of the refrigerator of any one of claims 1 to 12.