CN115111844B - Refrigerator with a refrigerator body - Google Patents

Abstract

The embodiment of the application discloses a refrigerator, and belongs to the technical field of refrigerators. The refrigerator comprises a refrigerator body, a cooked mounting box, a refrigerating and humidifying device and an air door assembly; the refrigerating and humidifying device is communicated with the ripening installation box and forms a circulating air channel, the air door assembly is configured to be opened when the refrigerating and humidifying device is in a refrigerating state, the refrigerating and humidifying device is configured to be closed for refrigerating treatment and starting defrosting treatment after the refrigerating and humidifying device is refrigerated for a preset time, and the air door assembly is configured to be closed. According to the application, a water source is not required to be added into the water storage box regularly, so that on one hand, the problem that the refrigerator needs to be frequently opened to be unfavorable for the stability of the humidity in the ripening area is avoided; on the other hand, the problem that the effective control of humidity cannot be realized by only relying on the natural evaporation of water can be avoided, so that the weight loss and the spoilage risk of foods in the dry ripening process are reduced obviously, and the quality of the dry ripening foods is further improved.

Description

Refrigerator with a refrigerator body

Technical Field

The application relates to the technical field of refrigerators, in particular to a refrigerator.

Background

The dry ripening process of food is a process of slowly improving the quality of the food during the sterilization and acid discharge process under the constant temperature, humidity and ventilation conditions, and the dry ripening food has a unique flavor compared with fresh food.

In general, a ripening area is provided in a refrigerator, through which a user can make dry-ripened foods, for example, dry-ripened beef, etc. Among them, the moisture, quality, etc. of the dry cooked food are of great importance in the process of making. In the related art, in order to avoid excessive evaporation of food moisture, a water storage tank is often provided in a ripening zone, and a water source is periodically added to the water storage tank, so that the humidity of the ripening zone is increased by evaporation of water in the water storage tank.

However, the above-described manner is disadvantageous in stabilizing the humidity inside the ripening zone.

Disclosure of Invention

In view of the above problems, the present application provides a refrigerator, which does not need to add a water source to a water storage box regularly, on one hand, avoids the problem that the refrigerator needs to be frequently opened to be unfavorable for the stability of the humidity in a ripening area; on the other hand, the problem that the effective control of humidity cannot be realized by only relying on the natural evaporation of water can be avoided, so that the weight loss and the spoilage risk of foods in the dry ripening process are reduced obviously, and the quality of the dry ripening foods is further improved.

In order to achieve the above object, the present application provides the following technical solutions:

the embodiment of the application provides a refrigerator, which is at least partially used for placing cooked food, and comprises the following components:

The box body, the maturing installation box, the refrigerating and humidifying device and the air door component;

the ripening installation box is provided with a storage cavity, and the storage cavity is used for placing the ripening food;

a refrigerating and humidifying cavity is arranged between the box body and the ripening installation box, the refrigerating and humidifying device is arranged in the refrigerating and humidifying cavity, the refrigerating and humidifying device is communicated with the ripening installation box and forms a circulating air channel, and the air door assembly is arranged on the refrigerating and humidifying device;

the air door assembly is configured to be opened when the refrigerating and humidifying device is in a refrigerating state, air flow in the storage cavity enters the refrigerating and humidifying cavity and is converted into cold air flow after being refrigerated by the refrigerating and humidifying device, and the cold air flow flows back into the storage cavity;

when the refrigerating and humidifying device is refrigerated for a preset time, the refrigerating and humidifying device is configured to close the refrigerating process and start the defrosting process, the air door assembly is configured to close, the cold air flow is converted into hot air flow after the defrosting process, the hot air flow is converted into cold air flow again after the humidifying process of the refrigerating and humidifying device, and the cold air flow flows back into the storage cavity.

In one implementation, the refrigerator further comprises a sterilization device, wherein the sterilization device is arranged on the refrigeration and humidification device and is close to the communication end of the refrigeration and humidification device and the ripening installation box, and the sterilization device is configured to be started when the refrigeration and humidification device is in a working state;

when the refrigeration and humidification device is in a refrigeration state, the starting frequency of the sterilization device is a first frequency, and when the refrigeration and humidification device is in a defrosting state, the starting frequency of the sterilization device is a second frequency;

and the first frequency is less than the second frequency.

In an implementation manner, the box body is provided with an air inlet and an air outlet, the air outlet is higher than the air inlet, and the refrigeration and humidification device is communicated with the ripening installation box through the air inlet and the air outlet and forms the circulating air duct;

the air door assembly comprises a first air door and a second air door, the first air door is arranged on the refrigerating and humidifying device close to the air inlet, and the second air door is arranged on the refrigerating and humidifying device close to the air outlet;

the first damper and the second damper are both configured to be opened when the cooling and humidifying device is in a cooling state, and the first damper and the second damper are both configured to be closed when the cooling and humidifying device is in a defrosting state.

In one implementation manner, the refrigeration and humidification device comprises a refrigeration and humidification assembly, a first connection main pipeline and a second connection main pipeline, wherein the refrigeration and humidification assembly is positioned between the first connection main pipeline and the second connection main pipeline;

one end of the first connecting main pipeline is communicated with the ripening installation box through the air inlet, and the other end of the first connecting main pipeline is communicated with the refrigeration and humidification assembly;

one end of the second connecting main pipeline is communicated with the ripening installation box through the air outlet, and the other end of the second connecting main pipeline is communicated with the refrigeration and humidification assembly;

the first air door is arranged on the first connecting main pipeline close to the air inlet, and the second air door is arranged on the second connecting main pipeline close to the air outlet;

the degerming device is arranged on the second connecting main pipeline close to the air outlet and is positioned between the second air door and the air outlet.

In one implementation, the refrigeration and humidification assembly includes a refrigeration member, a humidification member, and a barrier member;

the refrigerating and humidifying cavity is provided with a refrigerating cavity and a humidifying cavity which are communicated, the refrigerating piece is positioned in the refrigerating cavity, the humidifying piece is positioned in the humidifying cavity, the refrigerating piece is positioned on one side of the humidifying piece far away from the ground, and the baffle piece is arranged between at least part of the refrigerating piece and at least part of the humidifying piece;

The cooling element is configured to cool the air flow entering the cooling cavity, and the humidifying element is configured to humidify the air flow after defrosting.

In one possible implementation, the cooling element includes a cooling element body and a first heating element disposed on the cooling element body, the first heating element configured to be activated when the cooling element body activates a defrosting process;

the humidifying piece comprises a humidifying base and a second heating piece, the second heating piece is arranged on one side of the humidifying base, which is close to the baffle piece, and the second heating piece is configured to be started when the humidifying piece starts humidifying treatment;

the humidifying base is provided with a middle humidifying area and two end humidifying areas, the surfaces of the two end humidifying areas protrude out of the middle humidifying area along the direction from the humidifying base to the baffle piece, and the second heating piece is arranged on the middle humidifying area;

the barrier is provided with a middle barrier region and two end barrier regions, and the surface of the middle barrier region protrudes out of the surfaces of the two end barrier regions along the direction from the humidifying base to the barrier;

A water outlet is arranged between the refrigerating part and the humidifying part, and penetrates through the baffle part.

In one implementation manner, the first connecting main pipeline comprises an air inlet channel, and the air inlet connecting pipeline is arranged close to the air inlet and is positioned between the air inlet and the first air door;

the air inlet duct comprises a first air inlet section, a second air inlet section and an air inlet connecting section, the first air inlet section is arranged close to the air inlet, the second air inlet section is arranged far away from the air inlet, and the air inlet connecting section is connected between the first air inlet section and the second air inlet section;

the first air inlet section and the second air inlet section are both straight-line sections, the air inlet connecting section is an air inlet arc section, the cambered surface of the air inlet arc section is a concave surface facing the first air door, and the extending direction of the first air inlet section is perpendicular to the extending direction of the second air inlet section.

In an implementation manner, the second connecting main pipeline comprises an air outlet channel, and the air outlet channel is arranged close to the air outlet and is positioned between the air outlet and the second air door;

the air outlet duct comprises a first air outlet section, a second air outlet section and an air outlet connecting section, the first air outlet section is close to the air outlet, the second air outlet section is far away from the air outlet, and the air outlet connecting section is connected between the first air outlet section and the second air outlet section;

The first air outlet section and the second air outlet section are both straight-line sections, the air outlet connecting section is an air outlet arc section, the cambered surface of the air outlet arc section is a concave surface facing the second air door, and the extending direction of the first air outlet section is vertical to the extending direction of the second air outlet section.

In one embodiment, the first connecting manifold includes a first connecting sub-line, a second connecting sub-line, and a third connecting sub-line, which is connected between the first connecting sub-line and the second connecting sub-line;

one end of the first connecting branch pipeline is communicated with a humidifying piece of the refrigerating and humidifying assembly, the other end of the first connecting branch pipeline is communicated with the air inlet duct and one end of the third connecting branch pipeline, one end of the second connecting branch pipeline is communicated with a refrigerating piece of the refrigerating and humidifying assembly, the other end of the second connecting branch pipeline is communicated with the other end of the third connecting branch pipeline, and the first air door is arranged on the third connecting branch pipeline;

the second connecting main pipeline comprises a fourth connecting sub-pipeline, a fifth connecting sub-pipeline and a sixth connecting sub-pipeline, and the sixth connecting sub-pipeline is connected between the fourth connecting sub-pipeline and the fifth connecting sub-pipeline;

One end of the fourth connecting branch pipeline is communicated with the humidifying piece, the other end of the fourth connecting branch pipeline is communicated with one end of the fifth connecting branch pipeline, one end of the sixth connecting branch pipeline is communicated with the refrigerating piece, and the other end of the sixth connecting branch pipeline is communicated with the other end of the fifth connecting branch pipeline and the air outlet connecting air duct;

the second air door is arranged on the sixth connecting sub-pipeline, and the sterilizing device is arranged on the fifth connecting sub-pipeline.

In one implementation, the air inlet includes a first air inlet and a second air inlet, and the air outlet includes a first air outlet and a second air outlet;

one of the first air inlet and the second air inlet is arranged on the refrigerating and humidifying device, the other one of the first air inlet and the second air inlet is arranged on the cooked mounting box, the first air inlet and the second air inlet are through holes, and the first air inlet and the second air inlet are correspondingly arranged and are mutually communicated;

one of the first air outlet and the second air outlet is arranged on the refrigerating and humidifying device, the other of the first air outlet and the second air outlet is arranged on the cooked mounting box, the first air outlet and the second air outlet are through holes, and the first air outlet and the second air outlet are correspondingly arranged and are mutually communicated;

The refrigerator further comprises a storage rack, wherein the storage rack is arranged in the storage cavity and is detachably connected with the mounting box.

The embodiment of the application provides a refrigerator, which comprises a cooked mounting box, wherein cooked food can be placed in a storage cavity, and the refrigerator comprises a refrigeration and humidification device which can perform refrigeration treatment and humidification treatment on air flow in the mounting box; the air door assembly is arranged on the refrigerating and humidifying device, wherein the opening or closing of the air door assembly is controlled, so that the refrigerating function and the humidifying function of the refrigerating and humidifying device can be correspondingly controlled, the functions of the device can be guaranteed to be completed in the refrigerator, meanwhile, the moisture of the cooked food can be supplied at any time, and a water source is not required to be added into the water storage box regularly, so that the problem that the refrigerator needs to be frequently opened to be unfavorable for stabilizing the humidity in the cooked area is avoided; on the other hand, the problem that the effective control of humidity cannot be realized by only relying on the natural evaporation of the water in the water storage box can be avoided, so that the weight loss and the spoilage risk of food in the dry ripening process are reduced remarkably, and the quality of the dry ripening food is further improved.

Drawings

Fig. 1 is a schematic structural view of a refrigerator according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a cooked mounting case of a refrigerator according to an embodiment of the present application;

fig. 3 is a schematic diagram II of a structure of a cooked mounting case of a refrigerator according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of a refrigeration and humidification assembly of a refrigerator according to an embodiment of the present application;

fig. 5 is a schematic structural view of a first damper of a refrigerator according to an embodiment of the present application disposed on a first connecting main duct;

fig. 6 is a schematic structural view of a second damper of the refrigerator according to an embodiment of the present application disposed on a second connecting main duct;

fig. 7 is a schematic structural diagram of an air inlet duct of a refrigerator according to an embodiment of the present application;

fig. 8 is a sectional view of an air inlet duct of a refrigerator according to an embodiment of the present application;

fig. 9 is a schematic structural diagram of an air outlet duct of a refrigerator according to an embodiment of the present application;

fig. 10 is a cross-sectional view of an air outlet duct of a refrigerator according to an embodiment of the present disclosure.

Reference numerals illustrate:

100-refrigerator; 110-a box body; 111-cavity;

112-refrigerating and humidifying cavity; 1121-a refrigeration cavity; 1122-humidification chamber;

120-curing into an installation box; 121-a storage cavity; 122-a first air inlet;

123-a first air outlet; 124-shelf; 125-snap;

130-a refrigeration and humidification device; 131-a refrigeration humidification assembly; 1311—a refrigeration member;

13111—a refrigeration member body; 13112—a first heating element; 1312—humidifying member;

13121—a humidification mount; 131211-intermediate humidification zone; 131212-end humidification zone;

13122-a second heating element; 1313-a barrier; 13131-mid-gap stops;

13132-end baffles; 1314-drain; 132—a first connecting mains;

1321-first connecting branch pipe; 1322-a second connecting sub-pipe; 1323-third connecting sub-pipe;

1324-an air inlet duct; 13241-a first air inlet section; 13242-a second air intake section;

13243-an air inlet connection section; 1325-a second air inlet; 133-a second connecting mains;

1331-fourth connecting sub-pipeline; 1332-fifth connecting sub-pipe; 1333-sixth connecting sub-pipe;

1334-an air outlet duct; 13341-a first air outlet section; 13342-a second air outlet section;

13343-an air outlet connection section; 1335-a second air outlet; 140-damper assembly;

141-a first damper; 142-a second damper; 150-a sterilization device.

Detailed Description

The dry ripening process of food is a process of slowly improving the quality of the food during the sterilization and acid discharge process under the constant temperature, humidity and ventilation conditions, and the dry ripening food has a unique flavor compared with fresh food. In general, a ripening zone is provided in a refrigerator, through which a user can prepare dry-type ripening foods, for example, dry-type ripening beef, etc., wherein dry-type ripening beef refers to a process of remarkably increasing tenderness, flavor, and juiciness of meat under controlled environments (temperature, humidity, microorganisms, wind speed) without packaging beef.

In the dry ripening process, the weight loss caused by evaporation of the water on the surface and in the beef is about 30% of the weight of the beef before ripening, and in the ripening process of the beef placed in the ripening area, most of the water evaporated and scattered by the beef frosts on the surface of the evaporator due to the action of vapor pressure difference, and then the water is discharged out of the cabinet along with defrosting of the evaporator, the refrigeration and defrosting process of the evaporator is continuously circulated, so that the humidity in the ripening area is gradually reduced, and the furniture is air-dried, and meanwhile, the waste of the water source is also caused.

In the related art, in order to avoid excessive evaporation of food moisture, a water storage tank is often provided in a ripening zone, and a water source is periodically added to the water storage tank, so that the humidity of the ripening zone is increased by evaporation of water in the water storage tank. However, in the above arrangement, on one hand, the refrigerator needs to be frequently opened to add a water source into the water storage box, so that the problem of stability of the humidity in the ripening area is not facilitated; on the other hand, the problem that the effective control of humidity cannot be realized by only relying on the natural evaporation of moisture can be avoided; on the other hand, when the refrigerator is frequently opened, external air microorganisms are easily introduced, thereby increasing the spoilage risk of the cooked food.

In view of the above technical problems, an embodiment of the present application provides a refrigerator, which includes a cooked mounting box, in which cooked food can be placed in a storage cavity, and a cooling and humidifying device, which is capable of performing cooling and humidifying treatment on an air flow in the mounting box; the air door assembly is arranged on the refrigerating and humidifying device, wherein the opening or closing of the air door assembly is controlled, so that the refrigerating function and the humidifying function of the refrigerating and humidifying device can be correspondingly controlled, the functions of the device can be guaranteed to be completed in the refrigerator, meanwhile, the moisture of the cooked food can be supplied at any time, and a water source is not required to be added into the water storage box regularly, so that the problem that the refrigerator needs to be frequently opened to be unfavorable for stabilizing the humidity in the cooked area is avoided; on the other hand, the problem that the effective control of humidity cannot be realized by only relying on the natural evaporation of the water in the water storage box can be avoided, so that the weight loss and the spoilage risk of food in the dry ripening process are reduced remarkably, and the quality of the dry ripening food is further improved.

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions in the embodiments of the present application will be described in more detail below with reference to the accompanying drawings in the embodiments of the present application. In the drawings, the same or similar reference numerals refer to the same or similar components or components having the same or similar functions throughout. The described embodiments are some, but not all, embodiments of the application.

The embodiments described below by referring to the drawings are illustrative and intended to explain the present application and should not be construed as limiting the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

A refrigerator provided by an embodiment of the present application will be described with reference to fig. 1 to 10.

Referring to fig. 1 to 3, an embodiment of the present application provides a refrigerator 100 at least partially for placing cooked food, wherein the refrigerator 100 includes a case body 110, a cooked mounting case 120, a cooling and humidifying device 130, and an air door assembly 140, and it should be noted that at least partially the cooked food may be placed in the case body 110 entirely or partially the cooked food may be placed, and in this embodiment, the cooked food is mainly placed under the refrigerating chamber.

The ripening installation box 120 is arranged in the cavity 111, the storage cavity 121 is formed in the ripening installation box 120, the storage cavity 121 is used for storing ripening food, a refrigeration and humidification cavity 112 is formed between the box body 110 and the ripening installation box 120, the refrigeration and humidification device 130 is arranged in the refrigeration and humidification cavity 112, the refrigeration and humidification device 130 is communicated with the ripening installation box 120 and forms a circulating air channel, and the air door assembly 140 is arranged on the refrigeration and humidification device 130.

The damper assembly 140 is configured to be opened when the cooling and humidifying device 130 is in a cooling state, so that the air flow in the storage chamber 121 enters the cooling and humidifying chamber 112, is converted into a cold air flow after being cooled by the cooling and humidifying device 130, and the cold air flow flows back into the storage chamber 121, thereby realizing the cooling function of the mature mounting case 120.

When the cooling and humidifying device 130 cools to a preset time, the cooling and humidifying device 130 is configured to close the cooling process and start the defrosting process, the air door assembly 140 is configured to close, the cold air flow is converted into the hot air flow after the defrosting process, the hot air flow is humidified by the cooling and humidifying device 130 and is converted into the cold air flow again, and the cold air flow flows back into the storage cavity 121. In the defrosting process, the air door assembly 140 is closed, and at this time, the storage cavity 121 and the refrigerating and humidifying device 130 are not communicated, so that heat generated by defrosting can be reduced to the greatest extent and enter the storage cavity 121, and the problem of fluctuation of humidity inside the storage cavity 121 is caused.

In one implementation, referring to fig. 2 and 3, the sterilization device 150 is further included, where the sterilization device 150 is disposed on the cooling and humidification device 130 and is near a communication end of the cooling and humidification device 130 and the curing installation box 120, and the sterilization device 150 is configured to be started when the cooling and humidification device 130 is in an operating state.

By including the sterilizing device 150, a large amount of positive and negative ions, hydroxyl radicals, singlet oxygen, etc. having oxidation and sterilization functions are carried when the gas flows out from the air outlet, so that the foreign odor and bacteria causing the spoilage of beef in the storage chamber 121 can be removed.

When the cooling and humidifying device 130 is in the cooling state, the starting frequency of the sterilizing device 150 is a first frequency, and when the cooling and humidifying device 130 is in the defrosting state, the starting frequency of the sterilizing device 150 is a second frequency, and the first frequency is smaller than the second frequency.

When the cooling and humidifying device 130 is in the cooling state, the humidity and temperature of the air flow flowing out through the air outlet are both low, and therefore, the sterilizing device 150 is turned on at a low frequency; when the cooling and humidifying device 130 is in the frosted state, since the air humidity is high, the proliferation of microorganisms is easily caused, and thus the sterilizing device 150 is turned on at a high frequency.

In one implementation manner, the box body 110 is provided with an air inlet and an air outlet, the air outlet is higher than the air inlet, and the refrigeration and humidification device 130 is communicated with the curing installation box 120 through the air inlet and the air outlet, and forms a circulation air channel.

By including the air inlet and the air outlet, the air flow in the storage cavity 121 firstly enters the refrigerating and humidifying cavity 112 through the air inlet, is converted into cold air flow after being refrigerated and humidified by the refrigerating and humidifying device 130, and flows back into the storage cavity 121 through the air outlet, so that the refrigerating function of the mature mounting box 120 can be realized.

By setting the air outlet higher than the air inlet, the design is such that the refrigerating wind flowing out of the air outlet naturally sinks due to the higher density, and is finally sucked in the position of the air inlet, so that uniform refrigeration is realized in the whole storage cavity 121.

With continued reference to fig. 2 and 3, the damper assembly 140 includes a first damper 141 disposed on the refrigeration and humidification device 130 proximate the air intake and a second damper 142 disposed on the refrigeration and humidification device 130 proximate the air outlet.

The first and second dampers 141 and 142 are each configured to be opened when the cooling and humidifying device 130 is in a cooling state, and the first and second dampers 141 and 142 are each configured to be closed when the cooling and humidifying device 130 is in a defrosting state.

By providing the first air door 141 and the second air door 142, and disposing the first air door 141 and the second air door 142 at positions near the air inlet and the air outlet, respectively, it is convenient to control the air inlet and the air outlet, respectively.

In one implementation, referring to fig. 2 and 3, the cooling and humidifying device 130 includes a cooling and humidifying assembly 131, a first connecting header 132, and a second connecting header 133, and the cooling and humidifying assembly 131 is located between the first connecting header 132 and the second connecting header 133.

One end of the first connecting main pipe 132 is communicated with the curing installation box 120 through an air inlet, and the other end of the first connecting main pipe 132 is communicated with the refrigeration and humidification assembly 131; one end of the second connecting main pipe 133 is communicated with the ripening installation case 120 through an air outlet, and the other end of the second connecting main pipe 133 is communicated with the refrigerating and humidifying assembly 131.

The first air door 141 is arranged on the first connecting main pipeline 132 near the air inlet, and the second air door 142 is arranged on the second connecting main pipeline 133 near the air outlet;

the sterilizing device 150 is disposed on the second connecting main pipe 133 near the air outlet, and the sterilizing device 150 is disposed between the second damper 142 and the air outlet.

By including the first connecting header 132 and the second connecting header 133, communication between the mature box 120 and the cooling and humidifying module 131 can be achieved, thereby facilitating the flow of air.

In one manner of implementation, referring to fig. 4, the refrigeration and humidification assembly 131 includes a refrigeration member 1311, a humidification member 1312, and a barrier member 1313.

Wherein, referring to fig. 4, the refrigerating and humidifying cavity 112 has a refrigerating cavity 1121 and a humidifying cavity 1222 which are communicated, the refrigerating element 1311 is positioned in the refrigerating cavity 1121, the humidifying element 1312 is positioned in the humidifying cavity 1222, the refrigerating element 1311 is higher than the humidifying element 1312, and the barrier 1313 is disposed between at least part of the refrigerating element 1311 and at least part of the humidifying element 1312.

By including the refrigerating member 1311, the refrigerating member 1311 is capable of refrigerating the air flow entering the refrigerating chamber 1121, and when the refrigerating member 1311 is refrigerated for a predetermined time, the refrigerating member 1311 is closed and the defrosting process is started, at this time, both the first damper 141 and the second damper 142 are closed, and the humidifying member 1312 humidifies the defrosted air flow and converts it into a cool air flow again.

By including the baffle 1313, the baffle 1313 may function to separate the cooling member 1311 and the humidifying member 1312, so that when the first damper 141 is opened, most of the air flow enters the cooling chamber 1121, flows out of the air outlet after the cooling process by the cooling member 1311, wherein a small part of the air flow passes through the humidifying chamber 1222 and then flows out of the air outlet after being mixed with the cold air flow flowing out of the cooling chamber 1121, so as to raise the humidity of the cold air flow, thereby preventing the problem that the cold air flow with too low humidity flowing out of the air outlet accelerates the air drying of cooked food during the cooling process.

In one possible implementation, referring to fig. 4, the refrigeration member 1311 includes a refrigeration member body 13111 and a first heating member 13112, where the first heating member 13112 is disposed on the refrigeration member body 13111, and the refrigeration member body 13111 is configured to perform refrigeration on an air flow flowing into the refrigeration cavity 1121, and when the refrigeration member body 13111 is refrigerated for a preset time, the refrigeration member body 13111 is turned off and starts defrosting, and at the same time, the first heating member 13112 is started to heat the refrigeration member body 13111, so as to implement defrosting operation on the surface of the refrigeration member body 13111, thereby avoiding the problem of excessive frosting on the surface of the refrigeration member body 13111, and further being beneficial to improving the heat exchange effect.

The humidifying part 1312 includes a humidifying base 13121 and a second heating part 13122, the second heating part 13122 is disposed on one side of the humidifying base 13121 close to the barrier 1313, when the refrigerating part body 13111 starts defrosting treatment, the humidifying base 13121 is used for gathering defrosting water after defrosting, and the second heating part 13122 heats the gathered defrosting water, so that the defrosting water temperature is increased, the water vapor pressure of the defrosting water surface is increased, and then the water evaporation is accelerated.

With continued reference to fig. 4, the humidifying base 13121 has a middle humidifying region 131211 and two end humidifying regions 131212, both surfaces of the two end humidifying regions 131212 protruding from the middle humidifying region 131211 in the direction of the humidifying base 13121 to the barrier 1313, and the second heating member 13122 is disposed on the middle humidifying region 131211. By providing the humidifying base 13121 in a shape with both ends high and middle low, it is convenient to collect the defrost water at the lowest.

The barrier 1313 has a middle barrier 13131 and two end barriers 13132, and the surface of the middle barrier 13131 protrudes from the surface of the two end barriers 13132 in the direction from the humidifying base 13121 to the barrier 1313; a water outlet 1314 is arranged between the refrigerating member 1311 and the humidifying member 1312, the water outlet 1314 is arranged near the middle separation baffle 13131, and the water outlet 1314 penetrates through the separation baffle 1313.

By arranging the barrier 1313 in a shape with both ends low and middle high, the defrost water flows from high to low and is discharged through the drain port 1314 onto the middle humidification region 131211 of the humidification chamber 1222; the baffle 1313 in this embodiment is a baffle, and the inclination angle of the baffle 1313 may be between 10 ° and 30 ° in the direction from the middle baffle 13131 to the end baffle 13132.

In one implementation, referring to fig. 5, 7 and 8, the first connection main 132 may include an air intake duct 1324, where the air intake duct 1324 is disposed near the air intake and between the air intake and the first damper 141.

As shown in fig. 7, the air inlet duct 1324 includes a first air inlet section 13241, a second air inlet section 13242, and an air inlet connection section 13243, where the first air inlet section 13241 is disposed near the air inlet, the second air inlet section 13242 is disposed far from the air inlet, and the air inlet connection section 13243 is connected between the first air inlet section 13241 and the second air inlet section 13242.

The first air inlet section 13241 and the second air inlet section 13242 are both straight-line sections, the air inlet connecting section 13243 is an air inlet arc section, the cambered surface of the air inlet arc section is a concave surface facing the first air door 141, and the extending direction of the first air inlet section 13241 is perpendicular to the extending direction of the second air inlet section 13242.

Through including the inlet wind channel 1324, the extending direction of first inlet section 13241 is perpendicular with the extending direction of second inlet section 13242, and inlet connection section 13243 is the arc section, like this, when the air current enters into in the refrigeration humidification device 130, inlet wind channel 1324 can play the effect of direction, and the direction of inlet wind stream changes 90, in addition, steerable the amount of wind ratio that flows through refrigeration chamber 1121 and humidification chamber 1222 prevents that a large amount of high humidity air current that passes through humidification chamber 1222 from mixing with the low temperature air current that passes through refrigeration chamber 1121, and then avoids producing the condensation in the wind channel junction.

In one implementation, referring to fig. 6, 9 and 10, the second connecting manifold 133 may include an air outlet air duct 1334, where the air outlet air duct 1334 is disposed adjacent to the air outlet and between the air outlet and the second damper 142.

The air outlet air duct 1334 includes a first air outlet section 13341, a second air outlet section 13342 and an air outlet connection section 13343, the first air outlet section 13341 is close to the air outlet, the second air outlet section 13342 is far away from the air outlet, and the air outlet connection section 13343 is connected between the first air outlet section 13341 and the second air outlet section 13342.

The first air outlet section 13341 and the second air outlet section 13342 are both straight-line sections, the air outlet connecting section 13343 is an air outlet arc section, the cambered surface of the air outlet arc section is a concave surface which is sunken towards the second air door 142, and the extending direction of the first air outlet section 13341 is perpendicular to the extending direction of the second air outlet section 13342.

By including the air outlet duct 1334, the extending direction of the first air outlet section 13341 is perpendicular to the extending direction of the second air outlet section 13342, and the air outlet connecting section 13343 is an arc section, so that the air flow after the cooling treatment or the humidifying treatment flows back into the storage cavity 121 from the air outlet duct 1334, and the shape of the air outlet duct 1334 can change the flowing back direction of the air flow.

In one implementation, as shown with reference to fig. 7 and 8, the first connecting manifold 132 includes a first connecting sub-line 1321, a second connecting sub-line 1322, and a third connecting sub-line 1323, the third connecting sub-line 1323 being connected between the first connecting sub-line 1321 and the second connecting sub-line 1322.

Wherein, one end of the first connecting branch pipe 1321 is communicated with the humidifying part 1312 of the refrigeration humidifying assembly 131, the other end of the first connecting branch pipe 1321 is communicated with the air inlet duct 1324 and one end of the third connecting branch pipe 1323, one end of the second connecting branch pipe 1322 is communicated with the refrigerating part 1311 of the refrigeration humidifying assembly 131, the other end of the second connecting branch pipe 1322 is communicated with the other end of the third connecting branch pipe 1323, and the first air door 141 is arranged on the third connecting branch pipe 1323.

Referring to fig. 9 and 10, the second connecting header 133 includes a fourth connecting sub-pipe 1331, a fifth connecting sub-pipe 1332, and a sixth connecting sub-pipe 1333, the sixth connecting sub-pipe 1333 being connected between the fourth connecting sub-pipe 1331 and the fifth connecting sub-pipe 1332.

One end of a fourth connecting sub-pipeline 1331 is communicated with the humidifying piece 1312, the other end of the fourth connecting sub-pipeline 1331 is communicated with one end of a fifth connecting sub-pipeline 1332, one end of a sixth connecting sub-pipeline 1333 is communicated with the refrigerating piece 1311, and the other end of the sixth connecting sub-pipeline 1333 is communicated with the other end of the fifth connecting sub-pipeline 1332 and an air outlet air duct 1334;

the second damper 142 is provided on the sixth connecting sub-pipe 1333, and the sterilizing device 150 is provided on the fifth connecting sub-pipe 1332.

In one manner of implementation, referring to fig. 1 and 2, the air intake includes a first air intake 122 and a second air intake 1325, and the air outlet includes a first air outlet 123 and a second air outlet 1335.

Wherein, one of the first air inlet 122 and the second air inlet 1325 may be disposed on the refrigeration and humidification device 130, the other of the first air inlet 122 and the second air inlet 1325 may be disposed on the curing installation box 120, the first air inlet 122 and the second air inlet 1325 are through holes, and the first air inlet 122 and the second air inlet 1325 are correspondingly disposed and are mutually communicated.

One of the first air outlet 123 and the second air outlet 1335 may be disposed on the refrigerating and humidifying device 130, the other of the first air outlet 123 and the second air outlet 1335 may be disposed on the curing installation box 120, the first air outlet 123 and the second air outlet 1335 are through holes, and the first air outlet 123 and the second air outlet 1335 are correspondingly disposed and mutually communicated.

By including the first air inlet 122, the second air inlet 1325, the first air outlet 123, and the second air outlet 1335, communication between the cooked mounting box 120 and the refrigeration and humidification assembly 131 can be achieved, thereby facilitating airflow.

In addition, in the present embodiment, referring to fig. 1, the refrigerator 100 may further include a shelf 124, the shelf 124 being disposed in the storage chamber 121, the shelf 124 being detachably connected to the curing installation case 120.

Wherein, the rack 124 and the curing installation box 120 may be connected by clamping, the rack 124 and the curing installation box 120 may be connected by matching with screw threads and screw holes, or the rack 124 and the curing installation box 120 may be further connected by fastening with a fastener, in this embodiment, a buckle 125 is specifically illustrated as being provided on an inner wall surface of the storage cavity 121, and the rack 124 is clamped on the buckle 125.

It should be noted that, in the description of the embodiments of the present application, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, communication between two elements or interaction between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to the specific circumstances.

In the description of the embodiments of the present application, the term "and/or" merely represents an association relationship describing an association object, and indicates that three relationships may exist, for example, a and/or B may indicate: a exists alone, A and B exist together, and B exists alone. In addition, the term "at least one" means any combination of any one or at least two of the plurality, e.g., including at least one of A, B, may mean any one or more elements selected from the set consisting of A, B and C communication.

In the description of the embodiments of the present application, the terms "upper", "lower", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application. Furthermore, the term "plurality" means two or more, unless specifically stated otherwise.

In describing embodiments of the present application, the terms "first," "second," "third," "fourth," and the like (if any) are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the application described herein may be implemented in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present application, and not for limiting the same; although the application has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the application.

Claims (9)

1. A refrigerator at least partially used for placing cooked food, which is characterized by comprising a refrigerator body, a cooked mounting box, a refrigerating and humidifying device and an air door assembly;

the ripening installation box is provided with a storage cavity, and the storage cavity is used for placing the ripening food;

a refrigerating and humidifying cavity is arranged between the box body and the ripening installation box, the refrigerating and humidifying device is arranged in the refrigerating and humidifying cavity, the refrigerating and humidifying device is communicated with the ripening installation box and forms a circulating air channel, and the air door assembly is arranged on the refrigerating and humidifying device;

the air door assembly is configured to be opened when the refrigerating and humidifying device is in a refrigerating state, air flow in the storage cavity enters the refrigerating and humidifying cavity and is converted into cold air flow after being refrigerated by the refrigerating and humidifying device, and the cold air flow flows back into the storage cavity;

when the refrigerating and humidifying device is refrigerated for a preset time, the refrigerating and humidifying device is configured to close the refrigerating process and start the defrosting process, the air door assembly is configured to close, the cold air flow is converted into hot air flow after the defrosting process, the hot air flow is converted into cold air flow again after the humidifying process of the refrigerating and humidifying device, and the cold air flow flows back into the storage cavity;

The refrigerating and humidifying device comprises a refrigerating and humidifying assembly, and the refrigerating and humidifying assembly comprises a refrigerating piece, a humidifying piece and a baffle piece;

the refrigerating and humidifying cavity is provided with a refrigerating cavity and a humidifying cavity which are communicated, the refrigerating piece is positioned in the refrigerating cavity, the humidifying piece is positioned in the humidifying cavity, the refrigerating piece is higher than the humidifying piece, and the baffle piece is arranged between at least part of the refrigerating piece and at least part of the humidifying piece;

the cooling element is configured to cool the air flow entering the cooling cavity, and the humidifying element is configured to humidify the air flow after defrosting.

2. The refrigerator of claim 1, further comprising a sterilization device disposed on the cooling and humidification device and proximate a communication end of the cooling and humidification device with the curing mounting box, the sterilization device configured to be activated when the cooling and humidification device is in an operational state;

when the refrigeration and humidification device is in a refrigeration state, the starting frequency of the sterilization device is a first frequency, and when the refrigeration and humidification device is in a defrosting state, the starting frequency of the sterilization device is a second frequency;

And the first frequency is less than the second frequency.

3. The refrigerator according to claim 2, wherein the refrigerator body is provided with an air inlet and an air outlet, the air outlet is higher than the air inlet, and the refrigerating and humidifying device is communicated with the ripening mounting box through the air inlet and the air outlet, and forms the circulating air duct;

the air door assembly comprises a first air door and a second air door, the first air door is arranged on the refrigerating and humidifying device close to the air inlet, and the second air door is arranged on the refrigerating and humidifying device close to the air outlet;

the first damper and the second damper are both configured to be opened when the cooling and humidifying device is in a cooling state, and the first damper and the second damper are both configured to be closed when the cooling and humidifying device is in a defrosting state.

4. The refrigerator of claim 3, wherein the cooling and humidifying device further comprises a first connecting main pipe and a second connecting main pipe, the cooling and humidifying assembly being located between the first connecting main pipe and the second connecting main pipe;

one end of the first connecting main pipeline is communicated with the ripening installation box through the air inlet, and the other end of the first connecting main pipeline is communicated with the refrigeration and humidification assembly;

One end of the second connecting main pipeline is communicated with the ripening installation box through the air outlet, and the other end of the second connecting main pipeline is communicated with the refrigeration and humidification assembly;

the first air door is arranged on the first connecting main pipeline close to the air inlet, and the second air door is arranged on the second connecting main pipeline close to the air outlet;

the degerming device is arranged on the second connecting main pipeline close to the air outlet and is positioned between the second air door and the air outlet.

5. The refrigerator of claim 4, wherein the cooling element comprises a cooling element body and a first heating element disposed on the cooling element body, the first heating element configured to be activated when the cooling element body activates a defrosting process;

the humidifying piece comprises a humidifying base and a second heating piece, the second heating piece is arranged on one side of the humidifying base, which is close to the baffle piece, and the second heating piece is configured to be started when the humidifying piece starts humidifying treatment;

the humidifying base is provided with a middle humidifying area and two end humidifying areas, the surfaces of the two end humidifying areas protrude out of the middle humidifying area along the direction from the humidifying base to the baffle piece, and the second heating piece is arranged on the middle humidifying area;

The barrier is provided with a middle barrier region and two end barrier regions, and the surface of the middle barrier region protrudes out of the surfaces of the two end barrier regions along the direction from the humidifying base to the barrier;

a water outlet is arranged between the refrigerating part and the humidifying part, the water outlet is arranged close to the middle baffle area, and the water outlet penetrates through the baffle part.

6. The refrigerator of any one of claims 4-5, wherein the first connecting header includes an air intake duct disposed proximate the air intake and between the air intake and the first damper;

the air inlet duct comprises a first air inlet section, a second air inlet section and an air inlet connecting section, the first air inlet section is arranged close to the air inlet, the second air inlet section is arranged far away from the air inlet, and the air inlet connecting section is connected between the first air inlet section and the second air inlet section;

the first air inlet section and the second air inlet section are both straight-line sections, the air inlet connecting section is an air inlet arc section, the cambered surface of the air inlet arc section is a concave surface facing the first air door, and the extending direction of the first air inlet section is perpendicular to the extending direction of the second air inlet section.

7. The refrigerator of claim 6, wherein the second connecting manifold includes an air outlet duct disposed proximate the air outlet and between the air outlet and the second damper;

the air outlet duct comprises a first air outlet section, a second air outlet section and an air outlet connecting section, the first air outlet section is close to the air outlet, the second air outlet section is far away from the air outlet, and the air outlet connecting section is connected between the first air outlet section and the second air outlet section;

the first air outlet section and the second air outlet section are both straight-line sections, the air outlet connecting section is an air outlet arc section, the cambered surface of the air outlet arc section is a concave surface facing the second air door, and the extending direction of the first air outlet section is vertical to the extending direction of the second air outlet section.

8. The refrigerator of claim 7, wherein the first connection header pipe includes a first connection sub-pipe, a second connection sub-pipe, and a third connection sub-pipe connected between the first connection sub-pipe and the second connection sub-pipe;

one end of the first connecting branch pipeline is communicated with a humidifying piece of the refrigerating and humidifying assembly, the other end of the first connecting branch pipeline is communicated with the air inlet duct and one end of the third connecting branch pipeline, one end of the second connecting branch pipeline is communicated with a refrigerating piece of the refrigerating and humidifying assembly, the other end of the second connecting branch pipeline is communicated with the other end of the third connecting branch pipeline, and the first air door is arranged on the third connecting branch pipeline;

The second connecting main pipeline comprises a fourth connecting sub-pipeline, a fifth connecting sub-pipeline and a sixth connecting sub-pipeline, and the sixth connecting sub-pipeline is connected between the fourth connecting sub-pipeline and the fifth connecting sub-pipeline;

one end of the fourth connecting branch pipeline is communicated with the humidifying piece, the other end of the fourth connecting branch pipeline is communicated with one end of the fifth connecting branch pipeline, one end of the sixth connecting branch pipeline is communicated with the refrigerating piece, and the other end of the sixth connecting branch pipeline is communicated with the other end of the fifth connecting branch pipeline and the air outlet duct;

the second air door is arranged at the communication part of the sixth connecting sub-pipeline and the fifth connecting sub-pipeline, and the sterilizing device is arranged on the fifth connecting sub-pipeline.

9. The refrigerator of any of claims 3-5, wherein the air inlet comprises a first air inlet and a second air inlet, and the air outlet comprises a first air outlet and a second air outlet;

one of the first air inlet and the second air inlet is arranged on the refrigerating and humidifying device, the other one of the first air inlet and the second air inlet is arranged on the cooked mounting box, the first air inlet and the second air inlet are through holes, and the first air inlet and the second air inlet are correspondingly arranged and are mutually communicated;

One of the first air outlet and the second air outlet is arranged on the refrigerating and humidifying device, the other of the first air outlet and the second air outlet is arranged on the cooked mounting box, the first air outlet and the second air outlet are through holes, and the first air outlet and the second air outlet are correspondingly arranged and are mutually communicated;

the refrigerator further comprises a storage rack, wherein the storage rack is arranged in the storage cavity and is detachably connected with the curing installation box.