CN112902537A - Beauty refrigerator and temperature control method thereof - Google Patents

Abstract

The application provides a beauty refrigerator and a temperature control method thereof. The beauty refrigerator comprises a box body and a plurality of compartments, wherein a cold air circulating system is arranged in the box body, and the compartments can be opened and installed in the box body. Each compartment is provided with a temperature control system which is matched with the cold air circulating system to control the cold air supply amount of the cold air circulating system to the compartment. By applying the technical scheme of the invention, each compartment is provided with the temperature control system, the temperature of each compartment can be adjusted by controlling the cold air supply amount of the cold air circulating system to the compartment through the cooperation of the temperature control system and the cold air circulating system, the control of a plurality of temperature areas of a plurality of compartments is realized, the compartments with different temperatures can be conveniently set based on different low-temperature storage requirements, and the requirement that different articles are at the optimal storage temperature in the same refrigerator is met.

Description

Beauty refrigerator and temperature control method thereof

Technical Field

The invention relates to the technical field of refrigerators, in particular to a beauty refrigerator and a temperature control method thereof.

Background

Since the market of beauty refrigerators, the beauty refrigerators are popular with modern women due to their compactness, portability and fine appearance, and users of beauty refrigerators also consider storing some proprietary articles such as medicines, snacks, drinks, etc. in addition to storing them. The optimal storage temperature of different cosmetics, medicines, snacks and the like is different. However, most of cosmetic refrigerators in the market can only realize the adjustment of a single temperature, and although a temperature control system is set on the refrigerator, various articles stored in the refrigerator are always in a temperature range, so that the optimal storage temperature of different types cannot be met.

Disclosure of Invention

The embodiment of the invention provides a beauty refrigerator and a temperature control method thereof, and aims to solve the technical problem that different temperature intervals cannot be provided in the beauty refrigerator in the prior art.

The application embodiment provides a beauty refrigerator which comprises a refrigerator body, wherein a cold air circulating system is arranged in the refrigerator body; the cold air supply device comprises a plurality of compartments, the compartments can be installed in a box body in an opening mode, a temperature control system is arranged on each compartment, and the temperature control systems and the cold air circulating systems are matched to control the cold air supply amount of the cold air circulating systems to the compartments.

In one embodiment, the cold air circulation system comprises an air outlet duct, an air return duct and a refrigeration cycle component, the air outlet duct and the air return duct are respectively connected with the refrigeration cycle component, the air outlet duct is provided with a plurality of air outlets respectively corresponding to the plurality of compartments, the air return duct is provided with a plurality of air return inlets respectively corresponding to the plurality of compartments, and the temperature control system controls the air outlets and/or the air return inlets.

In one embodiment, the refrigeration cycle component comprises a refrigeration element and a wind power element, wherein the wind power element drives airflow to flow from the return air duct to the outlet air duct, so that the airflow is cooled by the refrigeration element.

In one embodiment, the refrigeration element is a semiconductor refrigeration module, and the refrigeration surface of the semiconductor refrigeration module is opposite to the wind power element.

In one embodiment, the air outlet duct and the air return duct are arranged in the duct structure in the box body together, and the air outlet duct and the air return duct are separated by a partition plate.

In one embodiment, the temperature control system includes an electronic control module and a damper door electrically connected to the electronic control module, the damper door being mounted on the compartment for controlling a supply of cold air to the compartment from the cold air circulation system.

In one embodiment, the temperature control system further comprises an interaction module, the interaction module is installed outside the compartment and connected with the electronic control module, and the interaction module is used for controlling the temperature of the compartment and/or displaying the temperature of the compartment.

In one embodiment, an electronic control box is arranged in the compartment, and the electronic control module is arranged in the electronic control box.

In one embodiment, the box body is a first cylinder, the compartment is a second cylinder matched with the box body in shape, an eccentric rotating shaft is arranged in the direction deviating from the axial lead in the box body, and the compartment is arranged in a manner of being capable of rotating around the eccentric rotating shaft.

In one embodiment, the air duct structure is formed within the eccentric shaft, and the air outlet and the air return opening are formed in the eccentric shaft.

In one embodiment, the box body comprises a base and a top cover, the eccentric rotating shaft is connected between the base and the top cover, a plurality of partition layers are arranged on the eccentric rotating shaft at intervals, and the plurality of compartments are respectively arranged on the upper parts of the plurality of partition layers.

In one embodiment, the temperature control system further comprises a position detector electrically connected with the electronic control module, the position detector is used for detecting whether the compartment is opened, and after the position detector detects that the compartment is opened, the electronic control module controls the damper to block the cold air circulation system from being communicated with the compartment.

In one embodiment, the compartment is mounted on the eccentric rotating shaft through a sleeve structure, the sleeve structure is provided with a vent corresponding to the air return opening and the air outlet, when the compartment is located in the box body, the vent is communicated with the air return opening and the air outlet, and when the compartment is opened relative to the box body, the vent is staggered with the air return opening and the air outlet, so that the cold air circulating system is blocked from being communicated with the compartment.

In one embodiment, a damper flap is installed between the vent opening and the air outlet opening, and the damper flap controls the amount of cold air supplied to the compartment by the cold air circulation system by changing the communication area between the vent opening and the air outlet opening.

In one embodiment, the damper flap is movable between the vent opening and the outlet opening in a liftable manner.

The embodiment of the application also provides a temperature control method, which is applied to the beauty refrigerator and comprises the following steps:

acquiring the information of stored objects in each compartment;

determining the optimal storage temperature of each chamber according to the information of the storage object in each chamber;

adjusting the temperature of each compartment to the optimal storage temperature.

In one embodiment, the stock information includes at least one of:

the type of the stored material, the quantity of the stored material and the storage life of the stored material.

In one embodiment, adjusting the temperature of the compartments to the optimal storage temperature comprises:

according to the optimal storage temperature, adjusting the position of an air door baffle of each chamber, and changing the communication area of the vent and the air outlet so as to adjust the cold air supply amount of the cold air circulation system to the chambers, so that the temperature in each chamber reaches the optimal storage temperature; wherein, the air door baffle is movably arranged between the ventilation opening and the air outlet.

In one embodiment, adjusting the position of the damper flap of each compartment according to the optimal storage temperature to change the communication area between the vent and the air outlet includes:

acquiring a difference value between the current indoor temperature and the optimal storage temperature;

if the difference value is larger than zero, controlling the air door baffle to move, so that the communication area between the vent and the air outlet is increased;

and if the difference value is smaller than zero, controlling the damper baffle to move so as to reduce the communication area between the vent and the air outlet.

The present embodiments also provide a computer-readable storage medium having a computer program stored thereon, which when executed by a processor implements the above-described temperature control method.

In the embodiment, each compartment is provided with the temperature control system, the temperature control system is matched with the cold air circulating system to control the cold air supply amount of the cold air circulating system to the compartments, so that the temperature of each compartment can be adjusted, the control of a plurality of temperature areas of a plurality of compartments is realized, the compartments with different temperatures can be conveniently set based on different low-temperature storage requirements, and the requirement that different articles are at the optimal storage temperature in the same refrigerator is met.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic overall structure diagram of an embodiment of a beauty refrigerator according to the present invention;

fig. 2 is a schematic cross-sectional structure and a schematic partial enlarged structure of the beauty refrigerator of fig. 1;

FIG. 3 is a schematic view of a partial structure of the beauty refrigerator of FIG. 1;

FIG. 4 is a schematic structural view of the beauty refrigerator of FIG. 3 with the compartment in an open state;

FIG. 5 is a schematic view of a partial cross-sectional structure of a compartment of the beauty refrigerator of FIG. 1;

FIG. 6 is a schematic view of the disassembled compartment of the beauty refrigerator of FIG. 1;

fig. 7 is a schematic structural view of a vent of the beauty refrigerator compartment of fig. 4 in an open state;

FIG. 8 is a schematic view of the construction of the make-up refrigerator compartment of FIG. 7 with the damper door in a closed position;

FIG. 9 is a schematic view of the damper flap of the compartment of the beauty freezer of FIG. 7 in a fully open position;

fig. 10 is a flowchart of a temperature control method according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the following embodiments and accompanying drawings. The exemplary embodiments and descriptions of the present invention are provided to explain the present invention, but not to limit the present invention.

Fig. 1, 2 and 3 show an embodiment of a beauty refrigerator according to the present invention, which includes a cabinet 10 and a plurality of compartments 20, wherein a cool air circulation system 40 is provided in the cabinet 10, and the compartments 20 are openably installed in the cabinet 10. Each compartment 20 is provided with a temperature control system 30, and the temperature control system 30 cooperates with the cold air circulating system 40 to control the amount of cold air supplied to the compartment 20 by the cold air circulating system 40.

By applying the technical scheme of the invention, each compartment 20 is provided with the temperature control system 30, the temperature of each compartment 20 can be regulated by controlling the cold air supply amount of the cold air circulating system 40 to the compartment 20 through the cooperation of the temperature control system 30 and the cold air circulating system 40, the control of a plurality of temperature areas of a plurality of compartments 20 is realized, the compartments 20 with different temperatures can be conveniently set based on different low-temperature storage requirements, and the requirement that different articles are at the optimal storage temperature in the same refrigerator is met.

As shown in fig. 2, in the technical solution of this embodiment, the cold air circulation system 40 includes an air outlet duct 41, a return air duct 42 and a refrigeration cycle component, and the air outlet duct 41 and the return air duct 42 are respectively connected to the refrigeration cycle component. The air outlet duct 41 is provided with a plurality of air outlets 411 respectively corresponding to the plurality of compartments 20, the air return duct 42 is provided with a plurality of air return inlets 421 respectively corresponding to the plurality of compartments 20, and the temperature control system 30 controls the air outlets 411 and the air return inlets 421. When in use, under the action of the refrigeration cycle component, the air in the compartments 20 enters the return air duct 42 through the return air inlet 421, then is refrigerated when passing through the refrigeration cycle component, and then is sent into the outlet air duct 41, and finally enters the compartments 20 through the air outlets 411. In this process, the temperature control system 30 controls the air outlet 411 and the air return opening 421, so as to control the amount of cold air in each compartment 20, and thus control the temperature of each compartment 20. Preferably, as shown in fig. 3, the cool air forms a double circulation flow in the compartment 20 and circulates inside the compartment. The double-circulation airflow includes an airflow blown out from the air outlet 411 and an airflow sucked from the air return opening 421, and the airflow blown out from the air outlet 411 is sucked from the air return opening 421 after circulating for one circle through the circular compartment 20.

Optionally, in the technical solution of the present embodiment, the refrigeration cycle component includes a refrigeration element 43 and a wind power element 44. In use, the wind element 44 drives the airflow from the return air duct 42 to the outlet air duct 41, so that the airflow passes through the cooling element 43 to be cooled. More preferably, in the technical solution of this embodiment, the refrigeration element 43 is a semiconductor refrigeration module, and a refrigeration surface of the semiconductor refrigeration module is opposite to the wind power element 44. The semiconductor refrigeration module is used for refrigerating, so that the size of the refrigeration element 43 can be reduced, and the cosmetic refrigerator is miniaturized. Preferably, in the solution of the present embodiment, the wind power element 44 is an axial flow fan.

As shown in fig. 2 and 3, as a preferred embodiment, the air outlet duct 41 and the air return duct 42 are disposed together in a duct structure inside the casing 10, and the air outlet duct 41 and the air return duct 42 are separated by a partition 45. Thus, air outlet and air return can be realized only by one air duct structure, so that the air duct design is simplified, and the simplified design of the beauty refrigerator structure is facilitated.

More preferably, in the technical scheme of the present invention, each bent portion of the air duct structures such as the air outlet duct 41 and the air return duct 42 is processed by an arc angle, so that the air ducts are in smooth transition, and the on-way resistance inside the air ducts can be reduced.

As shown in fig. 2 and 5, in the solution of the present embodiment, the temperature control system 30 includes an electronic control module 31 and a damper 32 electrically connected to the electronic control module 31, and the damper 32 is mounted on the compartment 20 for controlling the amount of cold air supplied to the compartment 20 by the cold air circulation system 40. When in use, the air conditioner is used for cooling the electronic control module 31, so that the electronic control module 31 controls the damper 32 to move, and the cold air supply amount of each compartment 20 is adjusted.

More preferably, as shown in fig. 1 and 3, the temperature control system 30 further includes an interaction module 33, the interaction module 33 is installed outside the compartment 20, and the interaction module 33 is connected to the electronic control module 31. In use, a user may control the temperature of compartment 20 via interactive module 33, or may feedback the temperature of compartment 20 via interactive module 33. When the user controls the temperature of the compartment 20 through the interactive module 33, the electronic control module 31 controls the movement of the damper baffle 32, and adjusts the opening size of the damper baffle 32, so as to control the cold quantity entering the compartment, thereby achieving the purpose of adjusting the temperature.

Preferably, in the technical solution of this embodiment, the interactive module 33 is a temperature display and adjustment integrated control board, and as another optional implementation, the interactive module 33 may also be a touch display screen.

As shown in fig. 5, in the solution of the present embodiment, an electronic control box 21 is disposed in the compartment 20, and an electronic control module 31 is disposed in the electronic control box 21. Preferably, as shown in fig. 3, the interaction module 33 is located at the electronic control box 21 so that the interaction module 33 is connected with the electronic control module 31 in the electronic control box 21.

As shown in fig. 3 and 4, in the solution of the present embodiment, the casing 10 is of a first cylindrical shape, the compartment 20 is of a second cylindrical shape adapted to the shape of the casing 10, the eccentric rotating shaft 13 is provided in the casing 10 in a direction deviating from the axial center line, and the compartment 20 is provided so as to be rotatable around the eccentric rotating shaft 13. When the refrigerator is used, the compartment 20 eccentrically rotates around the eccentric rotating shaft 13, the compartment 20 can rotate out relative to the refrigerator body 10, and due to the structural design, a door opening and closing structure does not need to be additionally designed on the compartment 20, so that the structure of the beauty refrigerator is simpler. Preferably, the air duct structure is formed in the eccentric rotating shaft 13, and the air outlet 411 and the air return opening 421 are formed in the eccentric rotating shaft 13, so that the eccentric rotating shaft 13 can be used as a supporting structure main body of the beauty makeup refrigerator and also used as a base body of the air duct structure, and the whole structure of the beauty makeup refrigerator is simpler.

Optionally, as shown in fig. 6, in the technical solution of this embodiment, the box 10 includes a base 11 and a top cover 12, the eccentric rotating shaft 13 is connected between the base 11 and the top cover 12, a plurality of partition layers 14 are arranged on the eccentric rotating shaft 13 at intervals, and the plurality of compartments 20 are respectively installed on the plurality of partition layers 14. In the present embodiment, the plurality of compartments 20 are stacked in the height direction.

As an alternative embodiment, the temperature control system 30 further comprises a position detector electrically connected to the electronic control module 31, and the position detector is used for detecting whether the compartment 20 is opened. When the position detector detects that the compartment 20 is opened, the electronic control module 31 controls the damper 32 to block the cold air circulation system 40 from communicating with the compartment 20. Specifically, as shown in fig. 4, when the articles need to be taken out from the compartment 20, the compartment 20 can be opened to take out the articles by rotating the compartment 20 by 180 °. Through the cooperation of the position detector and the electric control module 31, the air door baffle 32 blocks the communication between the cold air circulating system 40 and the compartment 20, at the moment, the compartment is in a state of being separated from the air duct, no cold quantity is leaked, and other compartments which are not opened still refrigerate normally. When the compartment 20 is in a closed state and normally performs refrigeration, the ventilation opening 221 of the compartment 20 nested on the air duct structure is consistent with the openings of the air return opening 421 and the air outlet 411, and one is above the other. When the compartment 20 is opened for taking out, the damper 32 is lifted to the upper limit position rapidly, and after the compartment rotates 180 degrees, the air return opening 421 and the air outlet 411 are both blocked by the parts nested in the air return opening.

As another alternative embodiment not shown in the drawings, as shown in fig. 7, the compartment 20 may also be mounted on the eccentric rotating shaft 13 through a sleeve structure 22, and the sleeve structure 22 is provided with a vent 221 corresponding to the air return opening 421 and the air outlet 411. When the compartment 20 is located in the box 10, the vent 221 is communicated with the air return opening 421 and the air outlet 411, and when the compartment 20 is opened relative to the box 10, the vent 221 is staggered with the air return opening 421 and the air outlet 411 to block the communication between the cold air circulating system 40 and the compartment 20. Specifically, in this embodiment, the air return opening 421 and the air outlet 411 and the air vent 221 on the sleeve structure 22 can be designed in a fence shape, and when the refrigerator compartment 20 is closed, the cool air can normally circulate in the loop. When the compartment 20 is opened, as long as the vent 221 is staggered with the air return opening 421 and the air outlet 411, the communication between the cold air circulating system 40 and the compartment 20 can be blocked, and at the moment, even if the rotation angle of the compartment 20 is less than 180 degrees, the cold quantity leakage can be avoided.

As shown in fig. 8 and 9, the damper flap 32 is installed between the air vent 221 and the air outlet 411, and the damper flap 32 controls the amount of cold air supplied to the compartment 20 by the cold air circulation system 40 by changing the communication area of the air vent 221 and the air outlet 411. Preferably, the movement of the damper flap 32 is controlled by a microswitch or a motorized push rod.

In a preferred embodiment, the damper flap 32 is movable between the air inlet 221 and the air outlet 411 in a liftable manner. As another alternative embodiment, the damper flap 32 may be rotatably movable between the air outlet 221 and the air outlet 411.

According to the technical scheme of the invention, under the cooperative control of the temperature control system 30 and the cold air circulating system 40, the interior of the beauty refrigerator is divided into different control areas through the cooperative work of the internal circulating air duct and the air door baffle 32, so that multi-area temperature control is realized, and different temperature regulation in a refrigeration temperature range can be realized in each area. In addition, the design of the rotary closing air channel can realize that the middle chamber is separated from the air channel in the process of taking out the objects, and the cold quantity leakage when the objects are taken out through opening the door is effectively avoided.

The present invention further provides a temperature control method applied to the beauty refrigerator, and fig. 10 is a flowchart of the temperature control method according to the embodiment of the present invention, as shown in fig. 10, the method includes:

s101, storage object information in each compartment is obtained.

In a specific implementation, the stored material information includes a type of the stored material, a quantity of the stored material, and a shelf life of the stored material. If the temperature requirement in the storage compartment is different according to the type of the lipstick to be stored, for example, the lipstick is stored in the makeup refrigerator to avoid melting, therefore, the temperature of the compartment for storing the lipstick does not need to be too low, and the essence is put into the makeup refrigerator to avoid the active ingredients from losing efficacy, therefore, the temperature required is lower, that is, the temperature for ensuring the optimal use effect of different makeup products is different.

In addition, if the number of stored materials is different, the required temperature is also different, and in the case where the number of stored materials is large, for example, if the entire compartment is filled, the temperature in the compartment needs to be low, and if the number of stored materials is reduced, the temperature in the compartment can be appropriately high, and therefore, the number of stored materials can also be a factor for determining the optimum storage temperature of the compartment. In specific implementation, the quantity of the stored objects can be judged by arranging a weight sensor at the bottom of the chamber and detecting the weight, or an image acquisition device is arranged in the chamber, and the quantity of the stored objects is judged by automatically identifying the space occupied by the stored objects according to the images in the chamber.

In practical applications, if the storage material has a short shelf life and a fast deterioration, and is generally required to be stored at a lower temperature, and if the storage material has a long shelf life and a slow deterioration, the storage temperature can be appropriately increased to save energy, and thus the shelf life of the storage material is also a factor in determining the optimal storage temperature of the compartment.

And S102, determining the optimal storage temperature of each chamber according to the information of the storage object in each chamber.

The optimum storage temperature of each compartment can be determined by the type of the stored material stored in each compartment, the number of the stored materials, and the shelf life of the stored materials.

S103, adjusting the temperature of each chamber to the optimal storage temperature.

By the temperature control method, the temperature in each chamber can be controlled to reach different temperatures according to the actual conditions of the stored objects stored in each chamber, so that the storage state of the stored objects in each chamber is optimal, and energy is saved.

In order to accurately determine the optimal storage temperature, step S102 includes: determining the optimal storage temperature of each chamber according to the types of the stored materials in each chamber; the optimum storage temperature of the corresponding compartments is different depending on the kind of the storage material. In the concrete implementation, the most storage temperature can be set by inquiring the product characteristics and the storage temperature requirement of each cosmetic product, and the most storage temperature is stored in a system of a cosmetic refrigerator. When in use, the data of the optimal storage temperature of different types of cosmetic products can be called.

As described above, since the number of stored materials may be a factor for determining the optimal storage temperature of each compartment, the step S102 of determining the optimal storage temperature of each compartment based on the stored material information in each compartment may further include: determining the optimal storage temperature of each chamber according to the number of the stored objects in each chamber; wherein the larger the number of stored items, the lower the optimum storage temperature.

Similarly, since the storage life of the stored material is also a factor affecting the optimal storage temperature, the step S102 further includes: determining the optimal storage temperature of each chamber according to the storage life of the storage materials in each chamber; wherein the shorter the shelf life, the lower the optimum storage temperature.

In particular, the optimal storage temperature may be determined according to any single factor, or may be determined by combining at least two factors, for example, the type and the number of stored materials, the number and the storage life of stored materials, the type and the storage life of stored materials, or by combining three factors, that is, the type, the number and the storage life of stored materials.

In the makeup refrigerator in the above-mentioned embodiment, the air door baffle is installed between vent and air outlet, and the air door baffle is through changing the intercommunication area control cold air circulation system of vent and air outlet to the cold air supply volume of compartment, based on above-mentioned structure, with the temperature adjustment of each compartment to the optimum storage temperature, include: according to the optimal storage temperature, the positions of air door baffles of the compartments are adjusted, the communication area between the ventilation opening and the air outlet is changed, and the cold air supply amount of the cold air circulating system to the compartments is adjusted, so that the temperature in the compartments reaches the optimal storage temperature. Specifically, according to the optimum storage temperature, adjust the position of the air door baffle of each compartment, change the area of intercommunication of vent and air outlet, include: acquiring a difference value between the current indoor temperature and the optimal storage temperature; if the difference value is larger than zero, the air door baffle is controlled to move, so that the communication area between the vent and the air outlet is increased; and if the difference value is smaller than zero, controlling the damper baffle to move so as to reduce the communication area between the vent and the air outlet. Wherein, the activity of above-mentioned air door baffle can be controlled through micro-gap switch or electric putter. In a preferred embodiment, the damper flap is movable between the ventilation opening and the air outlet in a liftable manner, and the increase or decrease of the communication area between the ventilation opening and the air outlet is controlled by the lifting. As other alternative embodiments, the damper flap may be rotatably movable between the ventilation opening and the air outlet, and the increase or decrease of the communication area between the ventilation opening and the air outlet is controlled by controlling the rotation angle of the damper flap.

The present embodiment also provides a computer-readable storage medium having stored thereon a computer program which, when executed by a processor, implements the above-described temperature control method.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes may be made to the embodiment of the present invention by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (20)

1. A cosmetic refrigerator is characterized by comprising

The refrigerator comprises a refrigerator body (10), wherein a cold air circulating system (40) is arranged in the refrigerator body (10);

the refrigerator comprises a plurality of compartments (20), the compartments (20) are arranged in the box body (10) in an openable mode, a temperature control system (30) is arranged on each compartment (20), and the temperature control system (30) is matched with the cold air circulating system (40) to control the cold air supply amount of the cold air circulating system (40) to the compartments (20).

2. The beauty makeup refrigerator according to claim 1, wherein said cold air circulation system (40) comprises an air outlet duct (41), a return air duct (42), and a refrigeration cycle component, said air outlet duct (41) and said return air duct (42) are respectively connected to said refrigeration cycle component, said air outlet duct (41) is provided with a plurality of air outlets (411) respectively corresponding to said compartments (20), said return air duct (42) is provided with a plurality of return air inlets (421) respectively corresponding to said compartments (20), and said temperature control system (30) controls said air outlets (411) and/or said return air inlets (421).

3. Cosmetic refrigerator according to claim 2, characterized in that the refrigeration cycle comprises a refrigeration element (43) and a wind element (44), the wind element (44) driving the air flow from the return air duct (42) to the outlet air duct (41) to cool the air flow passing through the refrigeration element (43).

4. Cosmetic refrigerator according to claim 3, characterized in that the refrigerating element (43) is a semiconductor refrigerating module, the refrigerating face of which is opposite to the wind element (44).

5. The beauty refrigerator according to claim 2, wherein the air outlet duct (41) and the air return duct (42) are jointly disposed in a duct structure in the box body (10), and the air outlet duct (41) and the air return duct (42) are separated by a partition (45).

6. Cosmetic refrigerator according to claim 1, characterized in that the temperature control system (30) comprises an electronic control module (31) and a damper flap (32) electrically connected to the electronic control module (31), the damper flap (32) being mounted on the compartment (20) for controlling the cold air supply of the cold air circulation system (40) to the compartment (20).

7. Cosmetic refrigerator according to claim 6, characterized in that said temperature control system (30) further comprises an interaction module (33), said interaction module (33) being mounted outside said compartment (20), said interaction module (33) being connected to said electronic control module (31), said interaction module (33) being adapted to control the temperature of said compartment (20) and/or to display the temperature of said compartment (20).

8. Cosmetic refrigerator according to claim 6, characterized in that an electronic control box (21) is provided inside said compartment (20), said electronic control module (31) being provided in said electronic control box (21).

9. The makeup refrigerator according to claim 5, characterized in that said cabinet (10) is a first cylinder, said compartment (20) is a second cylinder adapted to the shape of said cabinet (10), an eccentric shaft (13) is provided in the direction deviating from the axial center line of said cabinet (10), and said compartment (20) is rotatably provided around said eccentric shaft (13).

10. Cosmetic refrigerator according to claim 9, characterized in that the air duct structure is formed inside the eccentric shaft (13), the air outlet (411) and the air return (421) opening onto the eccentric shaft (13).

11. The makeup refrigerator according to claim 9, characterized in that said cabinet (10) comprises a base (11) and a top cover (12), said eccentric shaft (13) is connected between said base (11) and said top cover (12), said eccentric shaft (13) is provided with a plurality of partitions (14) at intervals, and said compartments (20) are respectively mounted on said partitions (14).

12. The beauty refrigerator according to claim 6, wherein the temperature control system (30) further comprises a position detector electrically connected to the electronic control module (31), the position detector being configured to detect whether the compartment (20) is open, the electronic control module (31) controlling the damper flap (32) to block the cold air circulation system (40) from communicating with the compartment (20) after the position detector detects that the compartment (20) is open.

13. The makeup refrigerator according to claim 10, characterized in that said compartment (20) is mounted on said eccentric shaft (13) through a sleeve structure (22), said sleeve structure (22) being provided with a vent (221) corresponding to said air return opening (421) and said air outlet (411), when said compartment (20) is located in said cabinet (10), said vent (221) is in communication with said air return opening (421) and said air outlet (411), when said compartment (20) is opened with respect to said cabinet (10), said vent (221) is staggered from said air return opening (421) and said air outlet (411) to block said cold air circulation system (40) from communicating with said compartment (20).

14. The beauty refrigerator according to claim 13, wherein the damper flap (32) is installed between the ventilation opening (221) and the air outlet (411), and the damper flap (32) controls the amount of cold air supplied to the compartment (20) by the cold air circulation system (40) by changing a communication area of the ventilation opening (221) and the air outlet (411).

15. The cosmetic refrigerator according to claim 14, wherein the damper flap (32) is liftably movable between the air vent (221) and the air outlet (411).

16. A temperature control method applied to the beauty refrigerator of any one of claims 1 to 15, characterized in that the method comprises:

acquiring the information of stored objects in each compartment;

determining the optimal storage temperature of each chamber according to the information of the storage object in each chamber;

adjusting the temperature of each compartment to the optimal storage temperature.

17. The temperature control method according to claim 16, wherein the storage information includes at least one of:

the type of the stored material, the quantity of the stored material and the storage life of the stored material.

18. The method of claim 16, wherein adjusting the temperature of each compartment to the optimal storage temperature comprises:

according to the optimal storage temperature, adjusting the position of an air door baffle of each chamber, and changing the communication area of the vent and the air outlet so as to adjust the cold air supply amount of the cold air circulation system to the chambers, so that the temperature in each chamber reaches the optimal storage temperature; wherein, the air door baffle is movably arranged between the ventilation opening and the air outlet.

19. The method of claim 18, wherein adjusting the position of the damper flap of each compartment to change the area of communication between the vent and the outlet based on the optimal storage temperature comprises:

acquiring a difference value between the current indoor temperature and the optimal storage temperature;

if the difference value is larger than zero, controlling the air door baffle to move, so that the communication area between the vent and the air outlet is increased;

and if the difference value is smaller than zero, controlling the damper baffle to move so as to reduce the communication area between the vent and the air outlet.

20. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the method of any one of claims 16 to 19.

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