DE112018007426T5 - Air-cooled refrigerator and control method, control system and control for defrosting the same - Google Patents

Abstract

An air-cooled refrigerator and a control method, control system, and controller for defrosting the same are provided. The high temperature air of the air-cooled refrigerator exchanges heat with the evaporator in the air duct and is sent into a refrigerator compartment by the operation of a fan; If the evaporator is gradually iced up, the heat exchanged air experiences the resistance from the frost deposits on the evaporator during the flow and the fan slows down. Based on this principle, the fan speed can directly correspond to the frost accumulation mass of the evaporator. The actual frost accumulation mass of the evaporator can be determined directly by determining the fan speed. If the fan speed is reduced to a certain low speed, it means that there is a lot of frost on the evaporator and defrosting must be started in good time. As a result, the problems of high energy consumption and poor freshness caused by the conventional control method of early or delayed defrost can be solved, and the energy consumption and freshness of the air-cooled refrigerator can be improved.

Description

CROSS REFERENCE TO RELATED APPLICATION

The present application claims priority from Chinese Patent Application No. 2018102824146 entitled "Air-cooled refrigerator and Control Method, Control System and Controller for Defrosting thereof," which is incorporated herein by reference in its entirety.

STATE OF THE ART

Technical area

The embodiments of the present application relate to the field of defrost control, particularly a control method for defrosting an air-cooled refrigerator, a control system and controller for defrosting an air-cooled refrigerator and an air-cooled refrigerator.

Description of the prior art

Air-cooled refrigerators, also known as frost-free refrigerators, are configured to be cooled with air. When high-temperature air passes through a built-in evaporator, the high-temperature air directly exchanges heat with the low-temperature evaporator, the temperature of the air is lowered, and the cooled air is blown into the refrigerator by a fan for cooling.

• 1. Abtauen wird vorzeitig ausgeführt. Wenn die tatsächliche Frostakkumulationsmasse nicht groß ist (z.B. wenn der Benutzer die Tür für eine lange Zeit öffnet, kann die tatsächliche Frostakkumulationsmasse nicht zu viel sein, da keine Lebensmittel hineingelegt werden, wenn die Tür geöffnet wird), wird Bestimmen der Frostakkumulationsmasse basierend auf der Öffnungsdauer unweigerlich vorzeitiges Abtauen und Anstieg des Stromverbrauchs bewirken. Dabei steigt die Temperatur innerhalb des Kühlschranks aufgrund von Erwärmung, wenn das Abtauen ausgeführt wird, sodass die Temperatur der Lebensmittel im Kühlschrank ansteigt und der Frischhalteeffekt geschwächt wird.
• 2. Abtauen wird verzögert. Wenn die tatsächliche Frostakkumulationsmasse groß ist (z.B. wenn der Benutzer die Tür für eine kurze Zeit öffnet, zu viele Lebensmittel mit hohem Feuchtigkeitsgehalt hineingelegt werden, wird die tatsächliche Frostakkumulationsmasse zu viel sein), wird bestimmt, dass die Abtaubedingung nicht erfüllt ist und noch mehr Türöffnungszeit, Laufzeit oder andere Bedingungen abgewartet. Dies erhöht die Frostakkumulationsmasse und schwächt die Kühlwirkung ab und löst außerdem ernste Beschwerden von Benutzern aus, dass der Kühlschrank nicht kühlt. Aufgrund der schwachen Kühlwirkung und der geringen Effizienz steigt außerdem der Energieverbrauch. Der Frischhalteeffekt ist ebenfalls in hohem Maße herabgesetzt.

Since there is always water vapor in the air, the water vapor condenses when it becomes cold. During the process of continuous heat exchange, the water vapor is gradually frozen on the evaporator. In order to promote the functional operation of the evaporator, it is necessary to defrost the evaporator. Currently, there are numerous conditions for starting defrosting: a control method for defrosting a refrigerator that by CN106288613A is provided, determines whether defrost is required based on the cumulative operating time of a compressor operating multiple times; Fan control methods that are carried out by CN106091566A and CN107477973A determine if defrost is required based on temperature; CN106403487A determines whether defrosting is required based on door opening times and other factors. In other technologies, the combination of ambient temperature and humidity is used as the defrost determining condition. In all of the determination schemes given above, the frost accumulation mass is estimated based on empirical values and defrosting is started based on the estimated amount. However, these estimation methods are not suitable for the actual use of refrigerators in many cases. For example, different usage habits of users, unknown types of food that users put in each time the door is opened, and unknown amounts of food can result in a completely different actual moisture content, and therefore the icing of the evaporator varies greatly. The determination conditions in the field often have the following shortcomings.

• 1. Defrosting is carried out early. If the actual frost accumulation mass is not large (e.g. if the user opens the door for a long time, the actual frost accumulation mass cannot be too much because no food is put in when the door is opened), the frost accumulation mass is determined based on the opening time inevitably cause premature defrosting and increase in power consumption. At this time, the temperature inside the refrigerator rises due to heating when defrosting is carried out, so that the temperature of the food in the refrigerator rises and the freshness effect is weakened.
• 2. Defrosting is delayed. If the actual frost accumulation mass is large (e.g. if the user opens the door for a short time, too much high moisture food is put in it, the actual frost accumulation mass will be too much), it is determined that the defrost condition is not met and there is more door open time , Duration or other conditions awaited. This increases the frost accumulation mass and weakens the cooling effect and also causes serious complaints from users that the refrigerator is not cooling. Due to the weak cooling effect and the low efficiency, the energy consumption also increases. The freshness effect is also greatly reduced.

ABSTRACT

Technical problems to be solved

The embodiments of the application serve to provide a control method for defrosting an air-cooled refrigerator, a control system and a controller for defrosting an air-cooled refrigerator and an air-cooled refrigerator, which at least solve the problem that the defrosting time of the air-cooled refrigerator does not correspond to the actual icing of an evaporator.

Technical solutions

In order to solve at least the above technical problem, the present application provides a control method for defrosting an air-cooled refrigerator, which includes: detecting a fan speed R during stable operation of a refrigerator; Determining whether the fan speed R is less than or equal to a preset speed Rmin; Performing a defrost when the fan speed R is less than or equal to a preset speed Rmin.

In this technical solution, the actual frost accumulation mass is derived from the fan speed based on the principle that the icing of the evaporator creates resistance to airflow and the fan speed decreases, and whether defrosting is required is determined according to the frost accumulation mass, and defrosting can occur in time . The icing process is also avoided when there is no need to defrost, and the consumption of energy is saved.

In some embodiments, a heater is used for defrosting during the defrosting process.

In this technical solution, the heater is placed at the bottom of the evaporator, and the evaporator is directly defrosted by heat, and the molten frost is drained through a drain pipe to improve the defrosting efficiency.

In some embodiments, a method of sensing fan speed includes allowing the fan to operate at a rated voltage and determining the fan speed by detecting feedback signals from an electrical control circuit where the fan is located.

In this technical solution, the fan speed is determined according to the operating information of the fan, and therefore the actual operation of the fan is effectively controlled and the accuracy of the frost accumulation mass determination of the evaporator is improved.

In some embodiments, after the defrosting process is performed, the control method further includes: sensing the temperature of the evaporator; Determining whether the temperature of the evaporator reaches a preset defrost temperature; and stopping the defrost when the temperature of the evaporator reaches a preset defrost temperature.

In this technical solution, it is determined whether the evaporator has completely defrosted, based on whether the evaporator has no frost or is at a temperature above a certain temperature after the defrosting is completed, and the defrosting is ended in time to save energy consumption.

In some embodiments, prior to detecting the fan speed R during stable operation of the refrigerator, the control method further includes: detecting a fan speed R _before and a fan speed R _{after of} the refrigerator before and after a preset period of time; Determining whether the absolute value of the difference between the fan speed R _before and the fan speed R _{after is} less than or equal to ΔR; when the absolute value of the difference between the fan speed R _before and the fan speed R _{after is} less than or equal to ΔR, determining that the refrigerator is operating stably.

During the cooling operation of the refrigerator, which is provided by the technical solution, the process determination from the start-up of the refrigerator to its stable operation provides a more precise determination environment for the subsequent determination of the frost accumulation mass of the evaporator according to the fan speed and improves the determination accuracy.

The embodiment of the present application also provides a controller that executes the control method for defrosting an air-cooled refrigerator, including: a data receiver configured to detect the temperature of an evaporator and fan speeds of the refrigerator in various states; determining means configured to execute the above control method and determine whether the refrigerator needs to be defrosted according to the fan speed or to determine whether the refrigerator stops defrosting according to the temperature of the evaporator; a signal transmitter configured to send determination results made by the determination device to a defrost assembly of the refrigerator, the determination results including start defrost, start without defrost, continue defrost, and stop defrost.

In this technical solution, several function modules are provided for carrying out corresponding processes of the control method for defrosting an air-cooled refrigerator. The actual frost accumulation mass of the evaporator is derived from the fan speed based on the principle that the Freezing of the evaporator creates resistance to air flow and the fan speed decreases, and whether defrosting is necessary is determined according to the frost accumulation mass, and defrosting can be timely. The icing process is also avoided when there is no need to defrost, and the consumption of energy is saved.

The embodiment of the present application also provides a control system for defrosting an air-cooled refrigerator, which includes: a fan, a defrosting assembly and the controller, the fan being arranged in an air duct of a refrigerator body, the controller with the fan and the defrosting assembly each via a electrical control circuit is connected and the controller detects the fan speed and determines whether the defrosting assembly is activated according to the fan speed.

This technical solution corresponds to the control method given above for defrosting the air-cooled refrigerator. The fan runs in the air duct, the defrost assembly is arranged on the evaporator or provides defrost heat for the evaporator, and the controller is configured to control the fan and the defrost assembly. Through the effective control of the control system, the actual frost accumulation mass of the evaporator is derived from the fan speed, and whether defrosting is required is determined according to the frost accumulation mass, and defrosting can be performed in time. The icing process is also avoided when there is no need to defrost, and the consumption of energy is saved.

In some embodiments, the control system for defrosting the air-cooled refrigerator further includes: an evaporator sensor electrically connected to the controller and configured to sense the temperature of the evaporator. During the defrosting operation being performed by the defrosting assembly, the controller determines whether the defrosting assembly is stopping the defrosting operation according to the temperature of the evaporator detected by the evaporator sensor.

With this technical solution, the temperature of the evaporator is detected by the evaporator sensor during and after defrosting, and the defrosting process is ended in good time. It is determined whether the evaporator has completely defrosted based on whether the evaporator is free from frost or at a temperature above a certain temperature after the defrosting is completed, and the defrosting is ended in time to save energy consumption.

In some embodiments, the defrost assembly includes a heater located at the bottom of the evaporator.

The present application also provides a computer apparatus including a memory, a processor, and computer programs stored in the memory and capable of running on the processor, and wherein the processor performs the control method when the computer programs are executed.

The present application also provides a computer readable storage medium on which computer programs are stored, and the control method is implemented when computer programs are executed by the processor.

The present application also provides an air-cooled refrigerator including an air duct of a refrigerator body, a compressor, a condenser, a capillary tube, an evaporator and the control system, the compressor, the condenser, the capillary tube and the evaporator forming a refrigerant circulation circuit; wherein the evaporator is arranged in the air duct of the refrigerator body and the evaporator is located upstream of the blower in the air flow path of the air duct of the refrigerator body.

With this technical solution, a refrigerator incorporating any of the above control systems can defrost the refrigerator's evaporator at a more optimized freezing time under refrigeration conditions, i.e. to avoid delay in defrosting and starting defrosting when there is little frost accumulation mass or no icing, which reduces energy consumption and is more suitable for the actual use of the refrigerator.

Favorable effects

According to the technical solutions provided by the embodiments of this application, the high-temperature air of the air-cooled refrigerator exchanges heat with the evaporator in the air duct and is sent to a cooling compartment by the operation of the fan; If the evaporator is gradually iced up, the heat exchanged air experiences the resistance from the frost deposits on the evaporator during the flow and the fan slows down. Based on this principle, the fan speed can directly reflect the frost accumulation mass of the evaporator. The actual frost accumulation mass of the evaporator can be determined directly by determining the fan speed. When the fan speed is reduced to a certain low speed, it means that there is a lot of frost on the evaporator and that defrosting must be started in good time. As a result, the problems of high energy consumption and poor freshness caused by the conventional control method of early or delayed defrost can be solved, and the energy consumption and freshness of the air-cooled refrigerator can be improved.

Figure list

• 1 Figure 13 is a schematic flow diagram showing a process for determining evaporator defrost based on fan speed according to an embodiment of the application;
• 2 Figure 3 is a schematic flow diagram of a control method for defrosting an air-cooled refrigerator according to an embodiment of the application;
• 3 Fig. 3 is a schematic structural diagram of a controller according to an embodiment of the application; and
• 4th Fig. 13 is a schematic structural diagram of a control system for defrosting an air-cooled refrigerator according to an embodiment of the application.

DETAILED DESCRIPTION

The specific embodiments of the present application are further described in detail below with reference to the drawings and embodiments. The following examples are intended to illustrate the application, but are not intended to limit the scope of the application.

In the description of embodiments of the present application, it should be noted that, unless expressly stated and defined otherwise, the terms “set up”, “connected to” and “connected” are to be understood generally; for example it can be either permanently connected or releasably connected, or it can be incorporated; it can be mechanically connected or electrically connected; it can be directly connected or indirectly connected through an intermediate medium and the communication between the interior of two elements. "First / r / s", "second / r / s", "third / r / s" and "fourth / r / s" do not represent any sequential relationship, but only serve the convenience of description. The specific meanings of the above terms in embodiments of the present application are understood by those skilled in the art according to specific conditions. “Present” means a moment when a certain operation is being performed, multiple present moments appearing in the text, all of which are recorded in real time over time.

To solve the problem that the timing of the defrosting of the air-cooled refrigerator does not correspond to the actual freezing of an evaporator, the embodiments of the application are directed to a control method for defrosting an air-cooled refrigerator, a control system and a controller for defrosting an air-cooled refrigerator and an air-cooled refrigerator.

The products and methods are detailed below through basic designs, advanced designs, and substitute designs.

During the cooling process of the air-cooled refrigerator, the evaporator maintains a low temperature to provide cooling capacity. In the initial phase, the evaporator has less icing and therefore offers less resistance to the flow of air, the air flows evenly in the air duct and the fan maintains a certain speed. If the cooling time extends or the moisture load of the food increases, the icing builds up on the evaporator, the evaporator becomes severely clogged, the wind resistance of the air duct increases and the fan speed decreases because the voltage supplied to the fan by the main board remains unchanged remains. From this principle it can be deduced that the fan speed reflects the actual frost accumulation mass of the evaporator during cooling.

Based on the above principles, one embodiment of the present application provides a control method for defrosting an air-cooled refrigerator that determines the frost accumulation mass of an evaporator according to a fan speed and then determines whether the evaporator needs to be defrosted, as in FIG 1 shown, including:

Step 01: Detect the fan speed R during stable operation of the refrigerator;

The corresponding relationship between the fan speed and the frost accumulation mass of the evaporator must be established under the condition of the stable operation of the refrigerator, and the influence of any abnormal operation on the fan speed and the frost accumulation mass of the evaporator should be excluded;

Step 02: Determine whether the fan speed R is less than or equal to the preset speed Rmin;

After the evaporator is frozen, the evaporator creates resistance to the flow of air and the fan speed is affected. As the frost accumulation mass increases, the fan speed will gradually decrease. When a preset speed Rmin is reached, it indicates that the evaporator has sufficient frost accumulation mass. Defrosting needs to be carried out in time, that is, if the determination result is Yes (less than or equal to), defrosting is carried out; when the determination result is no (greater than), the process returns to step 01.

Step 01 and 02 provide the operation method for effective defrosting based on the frost accumulation mass of the evaporator, which effectively solves the problems of high energy consumption and poor freshness caused by the conventional early or delayed defrost control method, and the energy saving and freshness effects of the air-cooled refrigerator improved.

A more specific control method is given below in connection with the overall process for defrosting the air-cooled refrigerator, as in FIG 2 shown.

The control method includes step 110: detecting a fan speed R _before and a fan speed R _{after of} the refrigerator before and after a preset time period;

Determining whether the refrigerator is operating normally and stably based on the change in fan speed in a short period of time; where a few seconds, such as 5 seconds, can be selected as a preset time period, and,
since the refrigerator may be in various working states (e.g., an unstable operating state, a defrosting state, a state of determining whether defrosting is required, etc.), the fan speed is detected in real time. The operation of the blower is controlled by the main control board (also called the controller) of the refrigerator. Both the fan and the main control board are connected to the electrical control circuit. The fan works at the nominal voltage. The fan operating signal is transmitted back to the main control board via the electrical control circuit and the fan speed is determined after it has been analyzed by the main control board. This embodiment provides only one method for detecting the fan speed. In other embodiments, various methods known in the art can be used to sense fan speed.

The control method includes step 112: determining whether the absolute value of the difference between the fan speed R _before and the fan speed R _{after is} less than or equal to ΔR;
if the determination result is Yes (less than or equal to), determining that the refrigerator is operating stably; and
if the determination result is no (greater than), proceed to repeating step 110.

Steps 110 and 112 are used to determine whether the refrigerator is operating stably. Once it is determined that the refrigerator is operating stably, the process proceeds to determine the frost accumulation mass of the evaporator.

The control process includes step 114: detecting the fan speed R during stable operation of the refrigerator;
Step 116: Determine whether the fan speed is less than or equal to the preset speed Rmin;
if the determination result is yes (less than or equal to), performing defrosting, activating the defrosting assembly to defrost the evaporator, and the molten frost is drained through a drain pipe; and
if the determination result is no (greater than), return to step 114 and continue detecting the fan speed in real time.

There are various defrosting treatment methods such as reverse air defrosting and heating defrosting. In this embodiment, a heater, which is arranged on the evaporator, is used for defrosting.

It should be noted that steps 114 and 116 are specific steps for determining the frost accumulation mass of the evaporator and for determining whether the evaporator needs to be defrosted. These steps can be performed in real time in the cooling mode of the air-cooled refrigerator, or they can be recorded and determined at a preset frequency.

The control procedure includes step 118, in the defrost mode, for detecting the temperature T of the evaporator;
Step 120: if the temperature T of the evaporator _preset reached determining a preset defrost temperature T;
Stopping defrosting when the determination result is yes (achieved); and
Resuming defrosting when the determination result is no (not reached).

The temperature of the non-iced or defrosted evaporator is usually higher than a certain temperature, so that it is determined whether the evaporator has completely defrosted and the defrosting is ended in time to save energy consumption. Therefore, the question of whether to stop defrosting the evaporator is determined by the change in the temperature of the evaporator. On the other hand, it should be noted that the temperature of the evaporator drops after freezing and can be detected in real time by the evaporator temperature sensor, but the change in the temperature of the evaporator cannot reflect the frost accumulation mass and the strength of the frost accumulation.

This technology provides a control method for determining the evaporator freeze accumulation mass based on the fan speed and then controlling the defrosting process. This method may also be configured to determine defrost in combination with a number of times and the length of time the door is opened and closed, a number and type of food stored in the refrigerator, and the change in temperature of the refrigerator compartment.

Furthermore, a controller is provided which carries out the above control method for defrosting the air-cooled refrigerator. As in 3 As shown, the controller may be incorporated into an electrical control board of the refrigerator in the form of a software program or a hardware device.

The controller includes: a data receiver, a determination device and a signal transmitter, the data receiver and the signal transmitter all being connected to the determination device. The data receiver is configured to sense the temperature of an evaporator and fan speeds of the refrigerator in various states; determining means configured, according to the above control method, to determine whether the refrigerator needs to be defrosted according to the fan speed and to determine whether the refrigerator stops defrosting according to the temperature of the evaporator; a signal transmitter configured to send determination results made by the determination device to a defrost assembly of the refrigerator, the determination results including start defrost, start without defrost, continue defrost, and stop defrost.

The fan speed includes the speed values that are recorded in real time in various states in steps 110 to 112.

In some embodiments, the data receiver, the determining device, and the signal transmitter may be divided into smaller unit components, according to function or structural design to refine the function of each unit component. In some embodiments, the determining device may be implemented as part of a control circuit or on-board computer of the main control board or by the controller or processor of a refrigerator.

The embodiment of the present application also provides a control system for defrosting an air-cooled refrigerator, as in FIG 4th which includes: a fan which is arranged in an air duct of a refrigerator body, a defrosting assembly and the controller, the controller being connected to the fan and the defrosting assembly in each case via an electrical control circuit, and the controller detects the fan speed and determines whether the Defrost assembly is activated according to the fan speed.

In one embodiment of the present application, an evaporator sensor for detecting the temperature of the evaporator is electrically connected to the controller; during the defrosting operation of the defrosting assembly, the controller determines whether the defrosting assembly is stopping the defrosting operation according to the temperature of the evaporator detected by the evaporator sensor.

The defrost assembly includes a heater located at the bottom of the evaporator, and the molten frost from the evaporator flows into the water receiver box below the evaporator and is then drained with a drain pipe.

The embodiment of the present application also provides a computer apparatus including a memory, a processor, and computer programs stored in the memory and capable of running on the processor, and wherein the processor executes the control method when the computer programs are executed.

In this technical solution, the computer programs that execute the control method described above for defrosting an air-cooled refrigerator are stored in the memory. If the processor runs the computer programs, it can precisely determine the icing of the evaporator and defrost it in good time.

The embodiment of the present application also provides a computer readable storage medium on which computer programs are stored and the control method becomes implemented when computer programs are executed by the processor.

In this technical solution, the processor must use computer programs to implement the control method for defrosting the air-cooled refrigerator, and these computer programs must be stored in a computer-readable medium. This computer-readable medium ensures that the computer programs can be executed by the processor, thereby accurately determining the degree of icing of the evaporator in the refrigerator and avoiding the situation of freeze-free or delayed defrosting.

An embodiment of the application also provides an air-cooled refrigerator that includes an air duct of a refrigerator body, a compressor, a condenser, a capillary tube, an evaporator, and a control system.

The compressor, the condenser, the capillary tube and the evaporator form a refrigerant circulation circuit; the evaporator is arranged in the air duct of the refrigerator body, and the evaporator is located upstream of the blower in the air flow path of the air duct of the refrigerator body.

When the compartment is refrigerated, the compressor runs. After the refrigerant is condensed, it becomes a low temperature and low pressure refrigerant by the throttling of the capillary tube and then flows through the evaporator for heat exchange, and therefore the temperature of the evaporator is lowered, the fan in the air duct also works and becomes the cooling capacity of the evaporator in the Brought fridge. The evaporator simultaneously absorbs the moisture in the refrigerator to form frost during the cooling process, and the frost adheres to the surface of the fins and tubes of the evaporator. During the cooling process, the evaporator maintains low temperature to provide cooling capacity and the cooling fan operates and rotates at a rated voltage supplied through the main control board, allowing the return air to pass through the evaporator for heat exchange and send it through the air outlet in the refrigirator. In the initial phase the evaporator has less frost and therefore offers less resistance and there is less wind resistance in the air duct and the fan maintains a certain speed. If the cooling time extends or the moisture load of the food increases, the icing on the evaporator increases, the evaporator becomes heavily clogged, the wind resistance of the air duct increases and the fan speed decreases, since the voltage supplied to the fan by the main board remains unchanged remains. The fan speed is fed back to the main board via the electrical control circuit and it means that defrosting is required when the main board detects that the fan speed has dropped to a certain speed. When the timed defrost coordination is reached, the defrost heater at the bottom of the evaporator starts to heat, so that the frost on the evaporator is melted into water and flows out through the drain pipe to the outside of the refrigerator for evaporation. When the defrosting sensor detects the defrosting end temperature, defrosting by heating is ended and defrosting is completed.

In the embodiment of the application, the actual frost accumulation mass of the evaporator in the refrigerator is determined by the control rule, and defrosting is only started in good time when the actual frost accumulation mass is large, thereby eliminating the problems of high energy consumption and poor freshness caused by the conventional control method early or delayed defrosting can be effectively solved, and the energy saving and freshness-keeping effects of the air-cooled refrigerator are improved.

The above embodiments are only the preferred embodiments of the present application and are not intended to limit the application. All modifications, equivalent substitutions, improvements, etc. that come within the spirit and principles of the present application are intended to be included within the scope of the present application.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• CN 2018102824146 [0001]
• CN 106288613 A [0004]
• CN 106091566 A [0004]
• CN 107477973 A [0004]
• CN 106403487 A [0004]

Claims (12)

A control method for defrosting an air-cooled refrigerator, comprising: Detecting a fan speed R during stable operation of the refrigerator; Determining whether the fan speed R is less than or equal to a preset speed Rmin; and Run a defrost when the fan speed R is less than or equal to the preset speed Rmin. Control procedure for defrosting the air-cooled refrigerator according to Claim 1 , characterized in that a heater is used for defrosting during the defrosting process. Control procedure for defrosting the air-cooled refrigerator according to Claim 1 characterized in that detecting the fan speed includes allowing the fan to operate at a nominal voltage and determining the fan speed by detecting feedback signals from an electrical control circuit of the fan. Control procedure for defrosting the air-cooled refrigerator according to Claim 1 characterized in that, after the defrosting operation is carried out, the control method further comprises: detecting the temperature of an evaporator; Determining whether the temperature of the evaporator reaches a preset defrost temperature; and stopping the defrost when the temperature of the evaporator reaches the preset defrost temperature. Control method for defrosting the air-cooled refrigerator according to one of the Claims 1 to 4th characterized in that, prior to detecting the fan speed R during the stable operation of the refrigerator, the control method further comprises: detecting a fan speed R _before and a fan speed R _{after of} the refrigerator before and after a preset time period; Determining whether the absolute value of the difference between the fan speed R _before and the fan speed R _{after is} less than or equal to ΔR; and determining that the refrigerator is operating stably when the absolute value of the difference between the fan speed R _before and the fan speed R _{after is} less than or equal to ΔR. Control that the control method for defrosting an air-cooled refrigerator according to one of the Claims 1 to 5 comprising: a data receiver configured to sense the temperature of an evaporator and fan speeds of the refrigerator; a determining means for carrying out the control method according to one of the Claims 1 to 5 is configured; and a signal transmitter configured to send determination results made by the determining means to a defrosting assembly of the refrigerator, the determination results including starting defrosting, not starting defrosting, continuing defrosting, and stopping defrosting. A control system for defrosting an air-cooled refrigerator comprising: a fan, a defrost assembly and the controller Claim 6 wherein the fan is arranged in an air duct of a refrigerator body; and wherein the controller is connected to the fan and the defrost assembly in each case via an electrical control circuit and the controller detects the fan speed and determines whether the defrost assembly is activated according to the fan speed. Control system for defrosting an air-cooled refrigerator according to Claim 7 , further comprising an evaporator sensor electrically connected to the controller and configured to detect the temperature of an evaporator; wherein during the defrosting operation performed by the defrosting assembly, the controller determines whether the defrosting assembly stops the defrosting operation according to the temperature of the evaporator detected by the evaporator sensor. Control system for defrosting the air-cooled refrigerator after Claim 7 , characterized in that the defrost assembly includes a heater which is arranged at the bottom of the evaporator. Computer device, comprising a memory, a processor and computer programs which are stored in the memory and can be executed by the processor, the processor for executing the control method according to one of the Claims 1 to 5 configured when executing the computer programs. Computer-readable storage medium on which computer programs are stored, the control method according to one of the Claims 1 to 5 is implemented when the computer programs are executed by a processor. An air-cooled refrigerator comprising an air duct of a refrigerator body, a compressor, a condenser, a capillary tube, an evaporator and the control system according to one of the Claims 7 to 9 wherein the compressor, the condenser, the capillary tube and the evaporator form a refrigerant circulation circuit; and wherein the evaporator is arranged in the air duct of the refrigerator body.

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