CN217604469U - Intelligent cabinet - Google Patents

Abstract

The embodiment of the present disclosure discloses an intelligent cabinet, which includes: the cabinet body comprises a normal temperature zone and a refrigeration zone isolated from the normal temperature zone; the cabinet door is connected with the cabinet body and comprises an outer cabinet door and an inner cabinet door, the inner cabinet door is used for sealing the refrigerating area, the inner cabinet door is smaller than the outer cabinet door, a gap between the inner cabinet door and the outer cabinet door forms an air passage, one end of the air passage is communicated with the outside of the intelligent cabinet, and the other end of the air passage is communicated with the normal temperature area; the outer cabinet door comprises a single-layer glass door, and the inner cabinet door comprises a single-layer glass door; and the driving device is positioned on the cabinet door and used for driving the air in the air passage to circulate between the normal temperature zone and the outside of the intelligent cabinet. The technical scheme can achieve the effects of low demisting cost and low power consumption.

Description

Intelligent cabinet

Technical Field

The utility model relates to a put thing cabinet technical field, concretely relates to intelligence cabinet.

Background

The intelligent cabinet is an electronic device which can intelligently control the temperature in the cabinet body or automatically settle accounts, the intelligent cabinet can be a refrigeration cabinet, the refrigeration cabinet has a refrigeration function, and the temperature of food or other objects in the cabinet body, such as beverages and the like, can be kept low through controlling the low-temperature state of the temperature in the refrigerator by refrigeration, so that the effect of keeping the food fresh or iced is achieved. The refrigerator is very common, and various refrigerators can be seen in all places where people move, such as a refrigerator used at home, a beverage cabinet and a refrigerator used by a merchant, an automatic vending cabinet in a public place and the like.

SUMMERY OF THE UTILITY MODEL

The embodiment of the disclosure provides an intelligent cabinet, which solves the problem that the existing intelligent cabinet is high in anti-fog cost.

In a first aspect, an embodiment of the present disclosure provides an intelligent cabinet.

Specifically, the intelligence cabinet includes:

the refrigerator comprises a cabinet body and a refrigerator, wherein the cabinet body comprises a normal-temperature area and a refrigerating area isolated from the normal-temperature area;

the cabinet door is connected with the cabinet body and comprises an outer cabinet door and an inner cabinet door, the inner cabinet door is used for sealing the refrigerating area, the inner cabinet door is smaller than the outer cabinet door, a gap between the inner cabinet door and the outer cabinet door forms an air passage, one end of the air passage is communicated with the outside of the intelligent cabinet, and the other end of the air passage is communicated with the normal temperature area; the outer cabinet door comprises a single-layer glass door, and the inner cabinet door comprises a single-layer glass door;

and the driving device is positioned on the cabinet door and used for driving the air in the air passage to circulate between the normal temperature zone and the outside of the intelligent cabinet.

In one implementation of the present disclosure, the driving device includes a fan, and the fan is connected to the controller.

In one implementation of the present disclosure, the location of the refrigeration zone within the cabinet body is variable, and the inner cabinet door is slidably connected to the outer cabinet door;

the inner cabinet door slides along with the change of the position of the refrigeration area in the cabinet body, so that the refrigeration area is sealed.

In one implementation of the present disclosure, the inner cabinet door is slidably connected to the outer cabinet door through a sliding structure; wherein:

the sliding structure comprises a sliding block and a guide piece, the sliding block is fixedly connected with the inner cabinet door, the guide piece is fixedly connected with the outer cabinet door, and the sliding block slides along the direction limited by the guide rail.

In one implementation manner of the present disclosure, the method further includes: a limiting structure;

when the sliding block slides to a preset position along the direction limited by the guide piece, the limiting structure is used for limiting the position relation between the sliding block and the guide piece and preventing the sliding block from continuously sliding relative to the guide piece.

In one implementation of the present disclosure, the driving device is fixed at the bottom end and/or the top end of the inner cabinet door.

In one implementation of the present disclosure, a support structure is disposed on a side wall inside the cabinet body;

the intelligent cabinet is provided with at least one low-temperature box, the low-temperature box is placed on corresponding bearing structure, the low-temperature box includes low temperature box and refrigeration module, the refrigeration module is used for the refrigeration to make first temperature in the low-temperature box is less than normal atmospheric temperature, at least one low-temperature box place region is the refrigeration district, the internal except that the object space formation normal temperature region of at least one low-temperature box of cabinet.

In one implementation manner of the present disclosure, the cabinet body further includes a heating area isolated from the normal temperature area and the cooling area;

the intelligent cabinet comprises a cabinet body, a support structure, a heating module, at least one high-temperature box and a heating module, wherein the intelligent cabinet is internally provided with the at least one high-temperature box, the high-temperature box is placed on the corresponding support structure, the high-temperature box comprises a high-temperature box body and the heating module, the heating module is used for heating to enable the second temperature in the low-temperature box body to be higher than the normal temperature, and the region where the at least one high-temperature box is located is a heating region.

In one implementation manner of the present disclosure, the method further includes:

the power supply module is arranged on the cabinet body and comprises at least one power supply interface;

the low-temperature box or the high-temperature box further comprises a joint, and the joint is connected with the power supply interface;

the power supply module supplies power to the low-temperature box or the high-temperature box through the power supply interface and the joint which are communicated.

In a second aspect, an intelligent cabinet is provided in the disclosed embodiments.

Specifically, the intelligence cabinet includes:

the refrigerator comprises a cabinet body and a refrigerator body, wherein the cabinet body comprises a normal temperature zone and a refrigeration zone isolated from the normal temperature zone, and a supporting structure is arranged on the side wall in the cabinet body; the intelligent cabinet is internally provided with at least one low-temperature box, the low-temperature box is placed on a corresponding supporting structure and comprises a low-temperature box body and a refrigeration module, the refrigeration module is used for refrigerating to enable the first temperature in the low-temperature box body to be lower than the normal temperature, the area where the at least one low-temperature box is located is a refrigeration area, and an object placing space except the at least one low-temperature box in the cabinet body forms a normal-temperature area; each low-temperature box is provided with a box opening, and sealing strips are arranged around the box opening;

the cabinet door is connected with the cabinet body and comprises an outer cabinet door and an inner cabinet door, the inner cabinet door is used for sealing the refrigerating area, the inner cabinet door is smaller than the outer cabinet door, a gap between the inner cabinet door and the outer cabinet door forms an air passage, one end of the air passage is communicated with the outside of the intelligent cabinet, and the other end of the air passage is communicated with the normal temperature area; the outer cabinet door comprises a single-layer glass door, and the inner cabinet door comprises a single-layer glass door; the inner cabinet door is connected with the outer cabinet door in a sliding manner; the inner cabinet door slides along with the change of the position of the refrigeration area in the cabinet body, and when the cabinet door is closed, the inner cabinet door extrudes the sealing strip on the low-temperature box to seal the refrigeration area;

the fan is fixed at the bottom end of the inner cabinet door and used for driving air in the air passage to circulate between the normal temperature zone and the outside of the intelligent cabinet;

the power supply module is arranged on the cabinet body and comprises at least one power supply interface; the low-temperature box also comprises a joint, and the joint is connected with the power supply interface; the power supply module supplies power to the low-temperature box through the power supply interface and the joint which are communicated; the number of the power supply interfaces is larger than or equal to the total number of the low-temperature boxes placed in the intelligent cabinet.

Among the above-mentioned technical scheme, this outer cabinet door of intelligence cabinet adopts single-layer glass, increases the single-layer glass that the one deck is used for sealing this refrigeration district in refrigeration district department and does interior cabinet door, then through set up drive arrangement drive this interior cabinet door and outer cabinet door in the air flue air between the normal temperature region with circulate between the outside of intelligence cabinet, accelerated the circulation of air of interior cabinet door department to reduce the possibility of condensation fog, simultaneously, by drive arrangement driven circulation of air to the normal temperature district, can play the effect of giving the normal temperature district cooling. This disclosed cabinet door adopts single-deck glass, has reduced the cost by a wide margin, and this drive arrangement is that drive circulation of air in this air flue compares with the heating consumption of heater strip, has also reduced the consumption by a wide margin.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

Other features, objects, and advantages of the present disclosure will become more apparent from the following detailed description of non-limiting embodiments when taken in conjunction with the accompanying drawings. In the drawings:

fig. 1 shows a schematic structural diagram of an intelligent cabinet according to an embodiment of the present disclosure;

fig. 2 shows a schematic structural view of a cabinet door according to an embodiment of the present disclosure;

FIG. 3 illustrates a schematic structural view of a sliding structure according to an embodiment of the present disclosure;

FIG. 4 shows a schematic structural diagram of another intelligent cabinet according to an embodiment of the present disclosure;

fig. 5 shows a schematic diagram of a connection between a power module and a cryostat/hot box according to an embodiment of the present disclosure;

fig. 6 shows a block diagram of a refrigeration module or a heating module according to an embodiment of the present disclosure.

Detailed Description

Hereinafter, exemplary embodiments of the present disclosure will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement them. Also, for the sake of clarity, parts not relevant to the description of the exemplary embodiments are omitted in the drawings.

In the present disclosure, it is to be understood that terms such as "including" or "having," etc., are intended to indicate the presence of the disclosed features, numbers, steps, actions, components, parts, or combinations thereof, and do not preclude the possibility that one or more other features, numbers, steps, actions, components, parts, or combinations thereof are present or added.

In the present disclosure, it is to be understood that the terms "upper", "lower", "vertical", "horizontal", "inner", "outer", "top", "bottom", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

In the present disclosure, it is to be understood that the plurality means two or more, that is, more than, less than, more than, etc. are understood as excluding the present number, and that more than, less than, etc. are understood as including the present number. If the first and second are described for the purpose of distinguishing technical features, they are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

It should be further noted that the embodiments and features of the embodiments in the present disclosure may be combined with each other without conflict. The present disclosure will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

The intelligent cabinet is an electronic device capable of regulating the temperature in the cabinet body or automatically settling, and can be a refrigeration cabinet, the refrigeration cabinet has a refrigeration function, and the temperature of food or other objects in the cabinet body, such as beverages and the like, can be kept low through controlling the low-temperature state of the temperature in the refrigeration cabinet through refrigeration, so that the effect of keeping the food fresh or iced is achieved. The refrigerator is very common, and various refrigerators can be seen in all places where people move, such as a refrigerator used at home, a beverage cabinet and a refrigerator used by a merchant, an automatic vending cabinet in a public place and the like. Because the inside of refrigerator-freezer and the humiture environment nonconformity of outside can lead to appearing atomizing phenomenon on the glass face of refrigerator-freezer cabinet door, in order to prevent glass door atomizing, current scheme adopts double-deck vacuum glass, increases the heater strip between two-layer glass, gives the heating of glass surface to realize the defogging effect on glass surface. However, this solution is costly and consumes a lot of power.

In view of the above defects, the present disclosure provides an intelligent cabinet, where an outer cabinet door of the intelligent cabinet is made of single-layer glass, a layer of single-layer glass for sealing the refrigeration area is added at the refrigeration area to form an inner cabinet door, and then a driving device is arranged on the cabinet door to drive air in an air passage between the inner cabinet door and the outer cabinet door to circulate between the normal temperature area and the outside of the intelligent cabinet, so as to accelerate air circulation at the inner cabinet door, thereby reducing the possibility of condensation, and meanwhile, the air driven by the driving device circulates to the normal temperature area, thereby playing a role of cooling the normal temperature area. This disclosed cabinet door adopts single-layer glass, has reduced the cost by a wide margin, and this drive arrangement is that the circulation of air in this air flue of drive compares with the heating consumption of heater strip, has also reduced the consumption by a wide margin.

The embodiment of the present disclosure provides an intelligent cabinet, and fig. 1 shows a schematic structural diagram of an intelligent cabinet according to an embodiment of the present disclosure, and as shown in fig. 1, the intelligent cabinet includes a cabinet body 11, a cabinet door 12 and a driving device 13.

In this embodiment, the cabinet 11 is used for placing articles, the storage space inside the cabinet 11 may be divided into a normal temperature zone 111 and a refrigeration zone 112 isolated from the normal temperature zone 111, and the normal temperature zone 111 and the refrigeration zone 112 are two zones with different temperatures. The temperature in the normal temperature zone 111 is the normal temperature, and the temperature in the refrigeration zone 112 is lower than the normal temperature, so that the refrigeration zone 112 and the normal temperature zone 111 need to be separated by using a thermal insulation material, and the temperatures in the two zones are prevented from influencing each other.

In this embodiment, the cabinet door 12 is connected to the cabinet body 11, and the cabinet door 12 may be rotatably connected to the cabinet body 11, or may be connected to the cabinet body 11 by pushing and pulling, as long as the cabinet door 12 is closed, the cabinet opening of the cabinet body 11 can be completely sealed. The cabinet door 12 includes an outer cabinet door 121 and an inner cabinet door 122, the inner cabinet door 122 is used for sealing the refrigeration area 112, the outer cabinet door 121 is used for sealing the opening of the whole cabinet body 11 in cooperation with the inner cabinet door 122, the inner cabinet door 122 is smaller than the outer cabinet door 121, the outer cabinet door 121 covers the inner cabinet door 122, for example, as shown in fig. 1, the refrigeration area 112 is located in the lower half area of the intelligent cabinet, the inner cabinet door 122 is correspondingly located at the lower part of the outer cabinet door 121, the height of the inner cabinet door 122 is greater than the height of the refrigeration area 112, is smaller than the height of the outer cabinet door 121, and is 2/3 of the height of the outer cabinet door 121.

In this embodiment, the outer cabinet door 121 comprises a single-layer glass door, and the inner cabinet door 122 comprises a single-layer glass door; the gap between the inner cabinet door 122 and the outer cabinet door 121 forms an air passage, one end of the air passage is communicated with the outside of the intelligent cabinet, the other end of the air passage is communicated with the normal temperature region 111, the driving device 13 positioned on the cabinet door 12 can drive the air in the air passage to circulate between the normal temperature region 111 and the outside of the intelligent cabinet, for example, the driving device 13 can drive the air in the air passage to flow from the outside of the intelligent cabinet to the normal temperature region 111 as shown by an arrow direction in fig. 1. Like this, normal atmospheric temperature district 111 circulates with the outside air, and normal atmospheric temperature district 111 is the same with outside humiture, and the glass door of normal atmospheric temperature district 111 department can not produce atomizing phenomenon, and only sealed this refrigerating zone 112's interior cabinet door 122 can produce atomizing phenomenon, and this embodiment adopts drive arrangement 13 drive this interior cabinet door 122 and the interior air of the air flue of outer cabinet door 121 be in normal atmospheric temperature district 111 with circulate between the outside of intelligence cabinet, accelerated the circulation of air of interior cabinet door 122 department to reduce the possibility of condensation fog. Meanwhile, the air driven by the driving device 13 circulates to the normal temperature zone 111, and may play a role of cooling the normal temperature zone 111.

The outer cabinet door 121 in this embodiment is made of single-layer glass, a layer of single-layer glass for sealing the refrigerating area 112 is added to the refrigerating area 112 to form the inner cabinet door 122, then the driving device 13 is arranged on the cabinet door 12 to drive air in an air passage between the inner cabinet door 122 and the outer cabinet door 121 to circulate between the normal temperature area 111 and the outside of the intelligent cabinet, so that air circulation at the position of the inner cabinet door 122 is accelerated, the possibility of condensation mist is reduced, meanwhile, air driven by the driving device 13 circulates to the normal temperature area 111, and the effect of cooling the normal temperature area 111 can be achieved. Moreover, the cabinet door 12 in this embodiment adopts single-layer glass, so that the cost is greatly reduced, and the driving device 13 drives the air circulation in the air passage, so that the power consumption is greatly reduced compared with the heating of a heating wire.

In a possible embodiment, the drive means 13 comprise a fan, which is connected to the controller.

In this embodiment, the fan includes a motor and a fan blade connected to the motor, the motor is connected to the controller, the controller can be powered on by the motor, the motor can convert electrical energy into mechanical energy to drive the fan blade to rotate, and the rotation of the fan blade can drive air in the air passage to circulate between the normal temperature region 111 and the outside of the intelligent cabinet.

In a possible embodiment, the location of the refrigeration zone 112 inside the cabinet 11 is variable, and the inner cabinet door 122 is slidably connected to the outer cabinet door 121; the inner cabinet door 122 slides along with the change of the position of the refrigeration area 112 in the cabinet body 11, so as to seal the refrigeration area 112.

In this embodiment, the position of the refrigeration area 112 in the cabinet 11 may be changed according to different needs of users, for example, in hot seasons such as summer, the food in the refrigeration area 112 is often purchased or taken by users, at this time, the refrigeration area 112 may be disposed in the upper half area in the cabinet 11, which is convenient for users to take articles, in winter, due to the cold weather, the users who purchase or take cold products may be few, the food in the normal temperature area 111 may be frequently purchased or taken by users, at this time, the refrigeration area 112 may be disposed in the lower half area in the cabinet 11, and the normal temperature area 111 may be disposed in the upper half area in the cabinet 11.

In this embodiment, the inner cabinet door 122 may be slidably connected to the outer cabinet door 121 for sealing the refrigeration compartment 112, so that the inner cabinet door 122 may be slid to a corresponding position to seal the refrigeration compartment 112 with the change of the position of the refrigeration compartment 112 in the cabinet 11.

It should be noted that, in some other embodiments, the position of the refrigeration area 112 in the cabinet 11 may be fixed, and the inner cabinet door 122 is correspondingly fixedly connected to the outer cabinet door 121.

In a possible embodiment, as shown in fig. 2, the inner cabinet door 122 is slidably connected to the cabinet 11 through a sliding structure 14; the sliding structure 14 includes a sliding block and a guiding member, the sliding block is fixedly connected to the inner cabinet door 122, the guiding member is fixedly connected to the outer cabinet door 121, and the sliding block slides along the direction defined by the guiding rail.

For example, as shown in fig. 3, the sliding block 141 may be a block structure with a through hole in the middle, the guiding element 142 may be a sliding rod, and the guiding element 142 may pass through the through hole of the sliding block 141, such that the sliding block 141 is sleeved on the guiding element 142, and thus the sliding block 141 may slide along the direction defined by the guiding element 142. When the sliding block 141 slides along the guiding member 142, the inner cabinet door 122 fixedly connected to the sliding block 141 is driven to slide to a corresponding position, so as to seal the refrigeration area 112. Of course, the sliding block and the guiding element may be in other forms, for example, the sliding block may be a protrusion, the guiding element is a guide rail, the sliding block is clamped in the rail groove of the guide rail and slides along the direction defined by the rail groove; and the like, as long as the sliding block can slide along the direction defined by the guide rail to drive the inner cabinet door 122 to slide to the corresponding position, which is not limited herein.

Some intelligent cabinets are horizontal cabinet bodies 11, the refrigeration area 112 is in a left half area or a right half area in the intelligent cabinet body 11, an operator slides the inner cabinet door 122 to the corresponding left half area or right half area, some intelligent cabinets are vertical cabinet bodies 11 shown in fig. 1, the refrigeration area 112 is in an upper half area or a lower half area in the intelligent cabinet body 11, and after the operator slides the inner cabinet door 122 to the corresponding upper half area or lower half area, in order to prevent the inner cabinet door 122 from continuously sliding downwards under the action of gravity, in one possible embodiment, as shown in fig. 3, a limiting structure 143 is further provided, and when the sliding block 141 slides to a preset position along the direction defined by the guide piece 142, the limiting structure 143 is used for limiting the position relationship between the sliding block and the guide piece, so as to prevent the sliding block from continuously sliding relative to the guide piece.

In this embodiment, still taking the above-mentioned sliding block as a block-shaped structure with a through hole in the middle, the guiding element is a sliding rod as an example for explanation, the limiting structure 143 may be a locking structure located on the sliding block 141, when an operator needs to adjust the position of the inner cabinet door 122, the locking structure may be twisted to enable the sliding block 141 to slide on the guiding element 142, and when the sliding block drives the inner cabinet door 122 to slide to a corresponding position capable of sealing the refrigeration area 112, the locking structure may be twisted to enable the sliding block 141 to be locked with the guiding element 142, and cannot slide on the guiding element 142 continuously. Or, the limiting structure 142 may be a screw hole and a corresponding screw on both sides of the sliding block 141, when the sliding block drives the inner cabinet door 122 to slide to a corresponding position where the inner cabinet door can seal the refrigeration area 112, an operator may screw the screw, and the screws on both sides may clamp the guide member in the through hole, so as to fix the position relationship between the sliding block and the guide member, and prevent the sliding block from continuously sliding relative to the guide member. Or, the limiting structure may also be a plurality of screw holes located on the sliding rod, and when the sliding block drives the inner cabinet door 122 to slide to a corresponding position where the refrigeration area 112 can be sealed, an operator may screw a screw into the screw hole below the sliding block, so as to prevent the sliding block from sliding downward relative to the guiding member. Of course, the limiting structure may be other structures, and is not limited herein.

In a possible embodiment, the driving device 13 is fixed at the bottom end and/or the top end of the inner cabinet door 122.

In this embodiment, the driving device 13 may be fixed at the bottom end of the inner cabinet door 122 as shown in fig. 1, or the driving device 13 may be fixed at the top end of the inner cabinet door 122, or a driving device 13 may be disposed at both the bottom end and the top end of the inner cabinet door 122. Therefore, when the inner cabinet door 122 slides, the driving device 13 is also moved, and the driving device 13 is always at the bottom and/or the top of the air passage between the inner cabinet door 122 and the outer cabinet door 121, so as to drive the air in the air passage to circulate between the normal temperature zone 111 and the outside of the intelligent cabinet.

It should be noted that, in some other embodiments, the position of the inner cabinet door 122 may be fixed, and in this case, the driving device 13 may also be fixed on the outer cabinet door 121.

In a possible embodiment, the location of the refrigeration zone may vary, as shown in fig. 4, the side walls inside the cabinet 11 are provided with support structures 113; be provided with at least one cryobox 14 in the intelligence cabinet, cryobox 14 places on corresponding bearing structure 113, cryobox 14 includes low temperature box and refrigeration module, the refrigeration module is used for the refrigeration to make first temperature in the low temperature box is less than ambient temperature, at least one cryobox 14 place region is refrigeration district 112, except that the storage space of at least one cryobox 14 forms normal atmospheric temperature region 111 in the cabinet body 11.

In this embodiment, the supporting structure 113 may include supporting bars on the left and right side walls of the cabinet 11 as shown in fig. 4, and a pair of supporting bars on the left and right side walls form a supporting structure 113 to support an intelligent cabinet, or the supporting structure 113 may also include supporting bars on the left and right side walls of the cabinet 11 and a supporting bar on the rear side wall of the cabinet 11 opposite to the cabinet door 12, and the pair of supporting bars on the left and right side walls and the supporting bar on the rear side wall form a supporting structure 113 to support a low temperature box 14. The support structure 113 may be a support bar as shown in fig. 4, or may be a support groove, in which a protrusion needs to be disposed at the bottom of the cryogenic box 14 to be engaged in the support groove, so as to support the cryogenic box 14 by the support structure 113. The position and shape of the support structure 113 are not limited, and it is only necessary that the support structure 113 be capable of supporting the cryobox 14 placed thereon.

In this embodiment, one or more cryogenic boxes 14 may be placed according to the quantity and volume of the items to be refrigerated by the user, and the operator may also place the cryogenic box 14 in the appropriate area of the cabinet 11 according to the convenience of the user in picking up the items, thus effecting a change in the location of the refrigerated area 112.

In one possible embodiment, the height of each cryogenic tank 14 is the same.

In this embodiment, each of the cryoboxes 14 has the same height, so that the corresponding support structures 113 can be disposed at the same distance in the cabinet 11, and each of the support structures 113 can accommodate a cryobox 14, so that the cryoboxes can be flexibly disposed in the cabinet 11 according to the user's needs. And the volume of each low-temperature box 14 is standard, so that the uniform production is convenient.

In one possible embodiment, a ventilation opening is provided in the rear side wall of the cabinet body, and the low-temperature box 14 is located at the ventilation opening.

In this embodiment, a ventilation net or a ventilation fence may be disposed at the vent, and when the low-temperature box is located at the vent, heat generated by the refrigeration module of the low-temperature box can be dissipated.

In a possible embodiment, the material of the cabinet 11 includes a metal material, and the cabinet may be a sheet metal cabinet, where the sheet metal cabinet refers to a cabinet made by a sheet metal process, and the sheet metal refers to a sheet metal (generally below 6 mm) that is a comprehensive cold processing process, including shearing, punching/cutting/combining, folding, riveting, splicing, forming (such as an automobile body), and the like. The electromagnetic shielding part has the remarkable characteristics of consistent thickness of the same part, light weight, high strength, electric conduction (capable of being used for electromagnetic shielding), low cost, good large-scale mass production performance and the like. The material of the low-temperature box 14 includes a heat insulating material, so that heat transfer between the low-temperature boxes 14 is prevented and the temperature inside the low-temperature box 14 is maintained. Preferably, the thermal insulation material may be a foamed material, and the foamed material may be, for example, polyurethane rigid foam or the like. In the embodiment, the temperature control cabinet does not need to be made of foaming materials, the cabinet body 11 is made of metal materials, and the box body of the low-temperature box 14 is made of foaming materials, so that the cost of the intelligent cabinet is greatly reduced.

In a possible embodiment, as shown in fig. 4, the cabinet body further includes a heating area isolated from the normal-temperature area and the cooling area; be provided with at least one high-temperature cabinet 15 in the intelligence cabinet, high-temperature cabinet 15 is placed on corresponding bearing structure 113, high-temperature cabinet 15 includes the high-temperature box and heats the module, it is used for heating the messenger to heat the second temperature in the low-temperature box is greater than normal atmospheric temperature, at least one high-temperature cabinet 15 place region is the heating area.

In this embodiment, this accuse temperature case not only provides cold-stored function for the user through setting up the low temperature box 14, can also set up high temperature box 15 and provide the heat preservation function for the user, can put into various low temperature boxes 14 or high temperature box 15 in this intelligence cabinet in a flexible way according to user's needs, three kinds of functions of cold-stored, warm-stored, the normal atmospheric temperature preservation that provide needs for the user, provide abundanter taste (cold/hot/normal atmospheric temperature) for the user, for example can increase the quantity of high temperature box 15 in winter, increase the quantity of low temperature cabinet in summer, it is multiple functional, applicable scene is extensive.

In some other embodiments, the high temperature box may further include a box body formed by a shelf and the cabinet body and a heating module fixedly connected to the shelf, in which the heating module is fixedly connected to the shelf, for example, the heating module may be an electric heating wire, the shelf may be a flat shelf fixed below the electric heating wire layer, the shelf is placed in the cabinet body, the shelf and the cabinet body portion above the shelf form a high temperature box body, or the shelf, the bottom of the upper temperature control box and the cabinet body portion therebetween form a high temperature box body, and heat generated by the electric heating wire layer on the shelf after being electrified can heat and preserve articles placed on the shelf. Or for example, the layer of rack is a flat plate rack fixed on the electric heating wire layer, the layer of rack is placed in the cabinet body, the layer of rack and the part of the cabinet body below the layer of rack form a high-temperature box body, or the layer of rack, the top of the lower temperature control box and the part of the cabinet body between the layer of rack and the top of the lower temperature control box form a high-temperature box body, and heat generated after the electric heating wire layer below the layer of rack is electrified can heat and preserve heat of the objects placed at the bottom of the cabinet body or the top of the lower temperature control box below the layer of rack.

Here, when the high temperature box 15 is a separate box body independent from the cabinet body, the box body material of the high temperature box 15 is a thermal insulation material, and when the high temperature box includes a box body formed by a shelf and the cabinet body, the material of the shelf belongs to the thermal insulation material, so that the heat generated by the heating module on or under the shelf can be prevented from being transferred to the adjacent box body.

In one possible embodiment, as shown in fig. 5, the intelligent cabinet further comprises:

the power supply module 16 is arranged on the cabinet 11 and comprises at least one power supply interface 161;

the low temperature box 14 or the high temperature box 15 further comprises a connector 162, and the connector 162 is connected to the power supply interface 161;

the power supply module 16 supplies power to the low temperature box 14 or the high temperature box 15 through the power supply interface 161 and the connector 162 which are connected.

In this embodiment, the power module 16 may be disposed at the top or the bottom of the cabinet 11, one end of the power module 16 may be connected to the power line of the intelligent cabinet, and the other end is at least one power interface 161, before the operator places the low temperature box 14 or the high temperature box 15 on the supporting structure 113 of the intelligent cabinet, the operator may insert the connector 162 of the low temperature box 14 or the high temperature box 15 into one power interface 161, so that when the power line is powered on, the power module 16 can supply power to the low temperature box 14 or the high temperature box 15 through the connected power interface 161 and connector 162.

It should be noted here that the number of the power supply interfaces 161 may be the total number of the low temperature boxes 14 and the high temperature boxes 15 that can be placed in the intelligent cabinet, and of course, the number of the power supply interfaces 161 may also be greater than the total number, so that when some power supply interfaces 161 have problems such as non-energization, other spare power supply interfaces 161 may be used.

The present disclosure also provides an intelligent cabinet, which includes:

the cabinet body 11 comprises a normal-temperature area 111 and a refrigeration area 112 isolated from the normal-temperature area 111, and a support structure 113 is arranged on the side wall in the cabinet body 11; at least one low-temperature box 14 is arranged in the intelligent cabinet, the low-temperature box 14 is placed on a corresponding supporting structure 113, the low-temperature box 14 comprises a low-temperature box body and a refrigeration module, the refrigeration module is used for refrigerating to enable the first temperature in the low-temperature box body to be lower than the normal temperature, the area where the at least one low-temperature box 14 is located is a refrigeration area 112, and an object placing space except the at least one low-temperature box 14 in the cabinet body 11 forms a normal-temperature area 111; each low-temperature box 14 is provided with a box opening, sealing strips are arranged on the periphery of the box opening, the sealing strips on the low-temperature boxes are extruded when the cabinet doors on the cabinet body are closed, and the heights of the low-temperature boxes are the same; a ventilation opening is formed in the rear side wall in the cabinet body, the low-temperature box is located at the ventilation opening, and a ventilation net or a ventilation fence is arranged at the ventilation opening; the box body material of the low-temperature box comprises a thermal insulation foaming material;

the cabinet door 12 is connected with the cabinet body 11 and comprises an outer cabinet door 121 and an inner cabinet door 122, the inner cabinet door 122 is used for sealing the refrigeration area 112, the inner cabinet door 122 is smaller than the outer cabinet door 121, a gap between the inner cabinet door 122 and the outer cabinet door 121 forms an air passage, one end of the air passage is communicated with the outside of the intelligent cabinet, and the other end of the air passage is communicated with the normal temperature area 111; the outer cabinet door 121 comprises a single-layer glass door, and the inner cabinet door 122 comprises a single-layer glass door; the inner cabinet door 122 is slidably connected with the outer cabinet door 121; the inner cabinet door 122 slides along with the change of the position of the refrigeration area 112 in the cabinet body 11, and when the cabinet door 12 is closed, the inner cabinet door 122 presses the sealing strip on the low-temperature box 14 to seal the refrigeration area 112;

the fan is fixed at the bottom end of the inner cabinet door 122 and is used for driving air in the air flue to circulate between the normal temperature zone 111 and the outside of the intelligent cabinet;

the power supply module 16 is arranged on the cabinet 11 and comprises at least one power supply interface 161; the cryogenic box 14 further comprises a connector 162, and the connector 162 is connected with the power supply interface 161; the power supply module 16 supplies power to the cryogenic box 14 through the power supply interface 161 and the connector 162 which are connected; the number of the power supply interfaces 161 is greater than or equal to the total number of the cryoboxes 14 placed in the intelligent cabinet.

The intelligent cabinet provided by the present disclosure is described in detail below by several embodiments.

Example 1:

the refrigerator comprises a cabinet body 11 and a refrigerator, wherein the cabinet body 11 comprises a normal temperature zone 111 and a refrigeration zone 112 isolated from the normal temperature zone 111, and a supporting structure 113 is arranged on the side wall in the cabinet body 11;

be provided with at least one cryobox 14 in the intelligence cabinet, cryobox 14 places on corresponding bearing structure 113, cryobox 14 includes low temperature box and refrigeration module, the refrigeration module is used for the refrigeration to make first temperature in the low temperature box is less than ambient temperature, at least one cryobox 14 place region is refrigeration district 112, except that the storage space of at least one cryobox 14 forms normal atmospheric temperature region 111 in the cabinet body 11. Be provided with at least one high-temperature cabinet 15 in the intelligence cabinet, high-temperature cabinet 15 is placed on corresponding bearing structure 113, high-temperature cabinet 15 includes the high-temperature box and heats the module, it is used for heating the messenger to heat the second temperature in the low temperature box is greater than normal atmospheric temperature, at least one high-temperature cabinet 15 place region is the heating area.

The cabinet door 12 is connected with the cabinet body 11, and includes an outer cabinet door 121 and an inner cabinet door 122, the inner cabinet door 122 is used for sealing the refrigeration area 112, the inner cabinet door 122 is smaller than the outer cabinet door 121, a gap between the inner cabinet door 122 and the outer cabinet door 121 forms an air passage, one end of the air passage is communicated with the outside of the intelligent cabinet, and the other end of the air passage is communicated with the normal temperature area 111; the outer cabinet door 121 comprises a single-layer glass door, and the inner cabinet door 122 comprises a single-layer glass door;

and the driving device 13 is located on the cabinet door 12 and is used for driving the air in the air passage to circulate between the normal temperature zone 111 and the outside of the intelligent cabinet, the driving device 13 comprises a fan, the fan is connected with a controller, and the driving device 13 is fixed at the bottom end and/or the top end of the inner cabinet door 122.

The position of the refrigeration area 112 in the cabinet body 11 is variable, and the inner cabinet door 122 is slidably connected with the outer cabinet door 121; the inner cabinet door 122 slides along with the change of the position of the refrigeration area 112 in the cabinet body 11, so as to seal the refrigeration area 112. The inner cabinet door 122 is slidably connected with the outer cabinet door 121 through a sliding structure 14; wherein: the sliding structure 14 includes a sliding block and a guiding member, the sliding block is fixedly connected to the inner cabinet door 122, the guiding member is fixedly connected to the outer cabinet door 121, and the sliding block slides along the direction defined by the guiding rail. A limiting structure is arranged between the sliding block and the guide piece, and when the sliding block slides to a preset position along the direction limited by the guide piece, the limiting structure is used for limiting the position relation between the sliding block and the guide piece and preventing the sliding block from continuously sliding relative to the guide piece.

The power supply module 16 is arranged on the cabinet 11 and comprises at least one power supply interface 161; the low temperature box 14 or the high temperature box 15 further comprises a connector 162, and the connector 162 is connected with the power supply interface 161; the power supply module 16 supplies power to the low temperature box 14 or the high temperature box 15 through the power supply interface 161 and the connector 162 which are connected.

Example 2:

a cabinet body 11, wherein a heat insulation plate is fixed in the cabinet body 11, and the heat insulation plate divides the cabinet body 11 into a normal temperature zone 111 and a refrigeration zone 112 isolated from the normal temperature zone 111;

the cabinet door 12 is connected with the cabinet body 11 and comprises an outer cabinet door 121 and an inner cabinet door 122, the inner cabinet door 122 is used for sealing the refrigeration area 112, the inner cabinet door 122 is smaller than the outer cabinet door 121, a gap between the inner cabinet door 122 and the outer cabinet door 121 forms an air passage, one end of the air passage is communicated with the outside of the intelligent cabinet, and the other end of the air passage is communicated with the normal temperature area 111; the outer cabinet door 121 comprises a single-layer glass door, and the inner cabinet door 122 comprises a single-layer glass door;

the driving device 13 is located in the cabinet door 12 and is used for driving the air in the air passage to circulate between the normal temperature zone 111 and the outside of the intelligent cabinet, the driving device 13 includes a fan, the fan is connected with the controller, the driving device 13 is fixed at the bottom end and/or the top end of the inner cabinet door 122, or the driving device 13 is fixed at the outer cabinet door 121.

In the above embodiments, the refrigeration module may include a semiconductor refrigeration sheet, the refrigeration module performs refrigeration by using a semiconductor refrigeration technology, and the heating module starts to include an electric heating wire, and can generate heat when being powered on; or the refrigeration module or the heating module may be a compressor for refrigeration or heating, as shown in fig. 6, the refrigeration module or the heating module includes a compressor 61, a condenser 62, a throttling element 63, and an evaporator 64, wherein the compressor 61, the condenser 62, the throttling element 63, and the evaporator 64 are connected through a pipe filled with a refrigerant to form a closed pipeline, so as to form a refrigeration module or a heating module capable of circulating the refrigerant.

The compressor 61 is a driven fluid machine for lifting a low-pressure refrigerant into a high-pressure refrigerant, the compressor 61 can suck a low-temperature low-pressure gaseous refrigerant, and the compressor 61 can drive a piston to compress the refrigerant by the operation of a motor, and then discharge the high-temperature high-pressure gaseous refrigerant to provide power for a refrigeration cycle, the compressor 61 can include a reciprocating compressor 61, a screw compressor 61, a rotary compressor 61, a scroll compressor 61, a centrifugal compressor 61 and the like, and the specific type of the compressor 61 is not limited in the embodiment of the present application.

The condenser 62 is a heat exchanger for exchanging heat between the refrigerant in the condenser 62 and the air outside the condenser 62 to release heat. In particular, the condenser 62 may include a long length of tubing for containing the refrigerant, which may be made of a thermally conductive metal material, typically copper, and which may be coiled into a generally helical shape. In addition, in order to improve the heat exchange efficiency of the condenser 62, a heat radiation fin having excellent heat conductivity may be provided on the pipe to increase a heat radiation area, thereby accelerating the speed of heat exchange and improving the heat exchange efficiency. The fan or fan matched with the condenser 62 can be arranged to accelerate the flow speed of air around the condenser 62, so that the heat exchange speed is accelerated, and the heat exchange efficiency is improved.

The throttling element 63 is used for throttling the liquid refrigerant at normal temperature and high pressure by the throttling element 63 to become a gas refrigerant at low temperature and low pressure, wherein the throttling element 63 may also be referred to as the throttling element 63 or a regulating valve, and the throttling element 63 may include an expansion valve, a capillary tube, and the like. In addition, the throttling element 63 can also control the flow rate of the refrigerant flowing through the throttling element 63, so that the flow rate of the refrigerant flowing through the throttling element 63 is prevented from being too large or too small. If the flow rate of the refrigerant flowing through the throttling element 63 is too large, the refrigerant flowing out of the throttling element 63 still includes liquid refrigerant, and the liquid refrigerant entering the compressor 61 may generate liquid impact to damage the compressor 61; if the flow rate of the refrigerant flowing through the throttling element 63 is too small, the refrigerant entering the compressor 61 is too small, and the operating efficiency of the compressor 61 is reduced.

The evaporator 64 is a heat exchanger for exchanging heat between the refrigerant in the evaporator 64 and the air outside the condenser 62 to absorb heat. Specifically, the evaporator 64 may include a long length of tubing for receiving the refrigerant, which may be made of a generally thermally conductive metal material such as copper, and which may be coiled in a generally helical shape. In addition, in order to improve the heat exchange efficiency of the condenser 62, a heat radiation fin having excellent heat conductivity may be provided on the pipe to increase a heat radiation area, thereby accelerating the heat exchange speed and improving the heat exchange efficiency. In some embodiments, a fan or a fan matched with the evaporator 64 may be further provided, and the flow speed of the air around the evaporator 64 is increased by the wind generated by the fan or the fan, so as to increase the speed of heat exchange and improve the heat exchange efficiency.

The refrigerant may also be called as refrigerant, refrigerant or snow, and refers to a medium substance for performing energy conversion in a refrigeration system or a heating system. The refrigerant is generally a substance that is susceptible to reversible phase change (e.g., absorbing heat to become gas, releasing heat to become liquid), and the refrigerant can transfer heat through the reversible phase change. The coolant may include ammonia, air, water, brine, freons (also referred to as chlorofluorocarbons, chlorofluorocarbons), etc., wherein freons may include monochlorotrifluoromethane, chlorodifluoromethane, trifluoromethane, tetrafluoroethane, trifluorodichloroethane, etc.

In the low-temperature box, low-temperature and low-pressure vapor-state refrigerant flows into the compressor 61 from the evaporator 64, the low-temperature and low-pressure vapor-state refrigerant is compressed by the compressor 61, and high-temperature and high-pressure gaseous-state refrigerant flows into the condenser 62; the high-temperature high-pressure gaseous refrigerant exchanges heat with air outside the condenser 62 through the condenser 62, so that the high-temperature high-pressure gaseous refrigerant is cooled in the condenser 62 to be a normal-temperature high-pressure liquid refrigerant, and then the normal-temperature high-pressure liquid refrigerant flows into the throttling element 63, and the throttling element 63 throttles the normal-temperature high-pressure liquid refrigerant, so that the refrigerant flowing out of the throttling element 63 is converted into a low-temperature low-pressure liquid refrigerant; the low-temperature low-pressure liquid refrigerant flows into the evaporator 64, and exchanges heat with air outside the evaporator 64 through the evaporator 64, and the low-temperature low-pressure liquid refrigerant is evaporated and vaporized into a low-temperature low-pressure gaseous refrigerant to absorb heat. The air outside the evaporator 64 can be guided into the box body of the low-temperature box, and the air outside the condenser 62 can be guided into the box body of the low-temperature box, so that the heat in the box body of the low-temperature box can be conveyed out of the box body, and the box body space of the low-temperature box can be refrigerated.

In the high temperature chamber, the low-temperature and low-pressure vapor refrigerant flows into the compressor 61 from the condenser 62, the low-temperature and low-pressure vapor refrigerant is compressed by the compressor 61, and the high-temperature and high-pressure vapor refrigerant flows into the evaporator 64; the high-temperature high-pressure gaseous refrigerant exchanges heat with the air outside the evaporator 64 through the evaporator 64, so that the high-temperature high-pressure gaseous refrigerant is cooled to be a normal-temperature high-pressure liquid refrigerant in the evaporator 64, then the normal-temperature high-pressure liquid refrigerant flows into the throttling element 63, and the throttling element 63 throttles the normal-temperature high-pressure liquid refrigerant, so that the refrigerant flowing out of the throttling element 63 is converted into a low-temperature low-pressure liquid refrigerant; the low-temperature and low-pressure liquid refrigerant flows into the condenser 62, and exchanges heat with air outside the condenser 62 through the condenser 62, and the low-temperature and low-pressure liquid refrigerant is evaporated and vaporized into a low-temperature and low-pressure gaseous refrigerant to absorb heat. Wherein, the air outside the evaporator 64 can be guided into the box body of the high-temperature box, and the air outside the condenser 62 can be guided into the box body outside the high-temperature box, so that the heat outside the box body of the high-temperature box is carried into the box body of the high-temperature box, and the space in the box body of the high-temperature box is heated.

The foregoing description is only exemplary of the preferred embodiments of the disclosure and is illustrative of the principles of the technology employed. It will be understood by those skilled in the art that the scope of the present invention is not limited to the specific combination of the above-mentioned features, but also covers other embodiments formed by any combination of the above-mentioned features or their equivalents without departing from the spirit of the present invention. For example, the above features and (but not limited to) the features disclosed in this disclosure having similar functions are replaced with each other to form the technical solution.

Claims (10)

1. An intelligent cabinet, comprising:

the refrigerator comprises a cabinet body and a refrigerator, wherein the cabinet body comprises a normal-temperature area and a refrigerating area isolated from the normal-temperature area;

the cabinet door is connected with the cabinet body and comprises an outer cabinet door and an inner cabinet door, the inner cabinet door is used for sealing the refrigerating area, the inner cabinet door is smaller than the outer cabinet door, a gap between the inner cabinet door and the outer cabinet door forms an air passage, one end of the air passage is communicated with the outside of the intelligent cabinet, and the other end of the air passage is communicated with the normal temperature area; the outer cabinet door comprises a single-layer glass door, and the inner cabinet door comprises a single-layer glass door;

and the driving device is positioned on the cabinet door and used for driving the air in the air passage to circulate between the normal temperature zone and the outside of the intelligent cabinet.

2. Intelligent cabinet according to claim 1, wherein the driving means comprise a fan connected to the controller.

3. The intelligent cabinet according to claim 1, wherein the location of the refrigeration zone within the cabinet body is variable, the inner cabinet door being slidably connected to the outer cabinet door;

the inner cabinet door slides along with the change of the position of the refrigeration area in the cabinet body, so that the refrigeration area is sealed.

4. The intelligent cabinet according to claim 3, wherein the inner cabinet door is slidably connected with the outer cabinet door by a sliding structure; wherein:

the sliding structure comprises a sliding block and a guide piece, the sliding block is fixedly connected with the inner cabinet door, the guide piece is fixedly connected with the outer cabinet door, and the sliding block slides along the direction limited by the guide piece.

5. The intelligent cabinet according to claim 4, further comprising: a limiting structure;

when the sliding block slides to a preset position along the direction limited by the guide piece, the limiting structure is used for limiting the position relation between the sliding block and the guide piece and preventing the sliding block from continuously sliding relative to the guide piece.

6. An intelligent cabinet according to claim 3, wherein the driving device is fixed at the bottom end and/or the top end of the inner cabinet door.

7. Intelligent cabinet according to claim 1,

a supporting structure is arranged on the side wall in the cabinet body;

the intelligent cabinet is provided with at least one low-temperature box, the low-temperature box is placed on corresponding bearing structure, the low-temperature box includes low temperature box and refrigeration module, the refrigeration module is used for the refrigeration to make first temperature in the low-temperature box is less than normal atmospheric temperature, at least one low-temperature box place region is the refrigeration district, the internal except that the object space formation normal temperature region of at least one low-temperature box of cabinet.

8. The intelligent cabinet according to claim 7, further comprising a heating zone isolated from the constant temperature zone and the cooling zone within the cabinet body;

the intelligent cabinet is characterized in that at least one high-temperature box is arranged in the intelligent cabinet, the high-temperature box is placed on a corresponding supporting structure and comprises a high-temperature box body and a heating module, the heating module is used for heating to enable the second temperature in the box body of the high-temperature box to be higher than the normal temperature, and the area where the at least one high-temperature box is located is a heating area.

9. The intelligent cabinet according to claim 8, further comprising:

the power supply module is arranged on the cabinet body and comprises at least one power supply interface;

the low-temperature box or the high-temperature box further comprises a joint, and the joint is connected with the power supply interface;

the power supply module supplies power to the low-temperature box or the high-temperature box through the power supply interface and the joint which are communicated.

10. An intelligent cabinet, comprising:

the refrigerator comprises a cabinet body and a refrigerator body, wherein the cabinet body comprises a normal temperature zone and a refrigeration zone isolated from the normal temperature zone, and a supporting structure is arranged on the side wall in the cabinet body; the intelligent cabinet is internally provided with at least one low-temperature box, the low-temperature box is placed on a corresponding supporting structure and comprises a low-temperature box body and a refrigeration module, the refrigeration module is used for refrigerating to enable the first temperature in the low-temperature box body to be lower than the normal temperature, the area where the at least one low-temperature box is located is a refrigeration area, and an object placing space except the at least one low-temperature box in the cabinet body forms a normal-temperature area; each low-temperature box is provided with a box opening, sealing strips are arranged on the periphery of the box opening, the sealing strips on the low-temperature boxes are extruded when the cabinet door on the cabinet body is closed, and the heights of the low-temperature boxes are the same; a ventilation opening is formed in the rear side wall in the cabinet body, the low-temperature box is located at the ventilation opening, and a ventilation net or a ventilation fence is arranged at the ventilation opening; the box body material of the low-temperature box comprises a thermal insulation foaming material;

the cabinet door is connected with the cabinet body and comprises an outer cabinet door and an inner cabinet door, the inner cabinet door is used for sealing the refrigerating area, the inner cabinet door is smaller than the outer cabinet door, a gap between the inner cabinet door and the outer cabinet door forms an air passage, one end of the air passage is communicated with the outside of the intelligent cabinet, and the other end of the air passage is communicated with the normal temperature area; the outer cabinet door comprises a single-layer glass door, and the inner cabinet door comprises a single-layer glass door; the inner cabinet door is connected with the outer cabinet door in a sliding manner; the inner cabinet door slides along with the change of the position of the refrigeration area in the cabinet body, and when the cabinet door is closed, the inner cabinet door extrudes the sealing strip on the low-temperature box to seal the refrigeration area;

the fan is fixed at the bottom end of the inner cabinet door and used for driving air in the air passage to circulate between the normal temperature zone and the outside of the intelligent cabinet;

the power supply module is arranged on the cabinet body and comprises at least one power supply interface; the low-temperature box also comprises a joint, and the joint is connected with the power supply interface; the power supply module supplies power to the low-temperature box through the power supply interface and the joint which are communicated; the number of the power supply interfaces is larger than or equal to the total number of the low-temperature boxes placed in the intelligent cabinet.

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