CN218722506U - Multi-temperature combined intelligent cabinet - Google Patents

Abstract

The embodiment of the present disclosure discloses an intelligent cabinet of multi-temperature combination, this intelligent cabinet includes: a cabinet body; the low-temperature box is positioned in the cabinet body and comprises at least one freezing box and/or at least one refrigerating box, the low-temperature box comprises an independent box body placed in the cabinet body, or a box body formed by the low-temperature shelf and the cabinet body, and the temperature in the low-temperature box is lower than the normal temperature; wherein, the internal except that the object space of putting of at least one cryogenic tank forms normal warm district, normal warm district is provided with at least one normal temperature case, normal temperature case is including placing the internal independent box of cabinet, perhaps, by the outer wall of at least one cryogenic tank with the box that the cabinet body formed, the temperature in the normal temperature case is normal atmospheric temperature. According to the technical scheme, three functions of refrigeration, freezing and normal temperature keeping can be provided for the user according to the user requirement, the functions are flexible and changeable, and the application scene is wider.

Description

Multi-temperature combined intelligent cabinet

Technical Field

The utility model relates to an intelligence cabinet technical field, concretely relates to intelligence cabinet of many temperature combinations.

Background

Current intelligent cabinet all has the accuse temperature function, can the internal temperature of switch board keep at invariable low temperature state, and for example say that some intelligent cabinets have cold-stored function, can let the internal food of cabinet or other article keep the low temperature like the temperature of beverage etc. reach the fresh-keeping effect of food, in order to increase the freshness date of food, some intelligent cabinets still can have the freezing function. These intelligent cabinets are very common and can be found in all places where people move, such as refrigerators used at home, beverage cabinets and freezers used by merchants, vending cabinets used in public places, and the like.

SUMMERY OF THE UTILITY MODEL

The embodiment of the disclosure provides an intelligent cabinet with multiple temperature combinations, and solves the problems of single temperature control function and few applicable scenes of the existing intelligent cabinet.

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

Specifically, the intelligent cabinet of many temperature combinations includes:

a cabinet body;

the low-temperature box is positioned in the cabinet body and comprises at least one freezing box and/or at least one refrigerating box, the low-temperature box comprises an independent box body placed in the cabinet body, or a box body formed by the low-temperature shelf and the cabinet body, and the temperature in the low-temperature box is lower than the normal temperature;

the cabinet is characterized in that the storage space in the cabinet body except the at least one low-temperature box forms a normal-temperature area, the normal-temperature area is provided with the at least one normal-temperature box, the normal-temperature box comprises an independent box body placed in the cabinet body, or the outer wall of the at least one low-temperature box and a box body formed by the cabinet body, and the temperature in the normal-temperature box is normal temperature.

In a possible embodiment, for each cryogenic tank, the cryogenic tank further comprises a first refrigeration module for refrigerating such that the temperature inside the cryogenic tank is within a respective cryogenic range.

In a possible embodiment, a freezer and a refrigerator are arranged in the cabinet body, the low-temperature box is a box body formed by a low-temperature shelf and the cabinet body, and the freezer and the refrigerator share one shared low-temperature shelf;

the refrigerating box comprises a first refrigerating module and a second refrigerating module, wherein the first refrigerating module is used for refrigerating to enable the temperature in the refrigerating box to be within a corresponding refrigerating temperature range; the shared low-temperature shelf is provided with an electric air door, the electric air door is communicated with the freezing box and the refrigerating box, and the valve size of the electric air door is adjusted to enable the temperature in the freezing box to be within a corresponding freezing temperature range and the temperature in the refrigerating box to be within a corresponding refrigerating temperature range.

In a possible implementation mode, the low-temperature box is provided with a box opening, sealing strips are arranged on the periphery of the box opening, and when a cabinet door on the cabinet body is closed, the sealing strips on the low-temperature box are extruded to seal the box opening of the low-temperature box.

In a possible implementation mode, each low-temperature box is provided with a box opening and a box door located at the box opening, the box opening is provided with a sealing strip, and after the box door is closed, the box door at the box opening is attached to the sealing strip to seal the box opening of the low-temperature box.

In one possible embodiment, the door of the cryostat is a incubator door.

In a possible embodiment, the normal temperature box is provided with a box opening and a box door positioned at the box opening, and the box door of the normal temperature box is provided with a ventilation opening.

In a possible embodiment, a ventilation fan is arranged at the ventilation opening.

In one possible embodiment, the housing material of the cryostat comprises a thermally insulating material.

In a second aspect, an embodiment of the present disclosure provides a multiple temperature combined intelligent cabinet, including:

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

the low-temperature box is positioned in the cabinet body, is placed on a corresponding supporting structure and comprises at least one refrigerating box and/or at least one freezing box, and comprises an independent box body placed in the cabinet body or a box body formed by a low-temperature layer rack and the cabinet body; the low-temperature box also comprises a first refrigeration module, and the first refrigeration module is used for refrigerating to enable the temperature in the low-temperature box to be in a corresponding low-temperature range; each low-temperature box is provided with a box opening and a box door positioned at the box opening, the box opening is provided with a sealing strip, after the box door is closed, the box door at the box opening is attached to the sealing strip to seal the box opening of the low-temperature box, and the box door of the low-temperature box is a heat preservation box door; the height of each low-temperature box is 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 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 more than or equal to the total number of the low-temperature boxes placed in the intelligent cabinet;

the cabinet body is internally provided with at least one low-temperature box, wherein the storage space except the at least one low-temperature box in the cabinet body forms a normal-temperature area, the normal-temperature area is provided with at least one normal-temperature box, the normal-temperature box comprises an independent box body placed in the cabinet body, or a box body formed by the outer wall of the at least one low-temperature box and the cabinet body, and the temperature in the normal-temperature box is normal-temperature; the normal temperature box is provided with a box opening and a box door located at the box opening, the box door of the normal temperature box is provided with a ventilation opening, and the ventilation opening is provided with a ventilation fan.

Above-mentioned technical scheme can be according to user's needs, set up fridge, freezer in the cabinet body, do the normal atmospheric temperature case with the internal surplus object space of cabinet, so, for can providing for the user according to user's needs and refrigerate, freeze, keep the three kinds of functions of normal atmospheric temperature, for the user provides and refrigerate, freeze, three kinds of tastes of normal atmospheric temperature, the function is more complete, can place corresponding fridge, freezer in the cabinet body in a flexible way like this to be applicable to various needs and refrigerate, the hot storage, the multiple article storage scene of normal atmospheric temperature storage.

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 a multi-temperature combined intelligent cabinet according to an embodiment of the present disclosure;

FIG. 2 illustrates a schematic structural diagram of another multi-temperature combined intelligent cabinet according to an embodiment of the present disclosure;

FIG. 3 illustrates a schematic structural diagram of yet another multi-temperature combined intelligent cabinet according to an embodiment of the present disclosure;

fig. 4 shows a schematic diagram of a connection between a power module and a cryostat according to an embodiment of the present disclosure;

fig. 5 shows a block diagram of a refrigeration 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.

In the above, the existing intelligent cabinet has a temperature control function, and can control the temperature in the cabinet body to be kept in a constant low-temperature state, for example, some intelligent cabinets have a refrigeration function, so that the temperature of food or other articles in the cabinet body, such as beverages, can be kept at a low temperature, and a food fresh-keeping effect is achieved. These intelligent cabinets are very common and can be found in all places where people move, such as refrigerators used at home, beverage cabinets and freezers used by merchants, vending cabinets used in public places, and the like.

In view of the above drawbacks, the present disclosure provides a multi-temperature combined intelligent cabinet, which includes a cabinet body and at least one low-temperature box located in the cabinet body, where the at least one low-temperature box includes at least one freezer and/or at least one refrigerator, and the low-temperature box includes a separate box body placed in the cabinet body, or a box body formed by a low-temperature shelf and the cabinet body, and a temperature in the low-temperature box is lower than a normal temperature; the internal except that of cabinet thing space formation normal temperature region outside at least one low-temperature box, normal temperature region is provided with at least one normal temperature box, normal temperature box is including placing the internal independent box of cabinet, perhaps, by the outer wall of at least one low-temperature box with the box that the cabinet body formed, the temperature in the normal temperature box is normal atmospheric temperature. Therefore, the refrigerator and the freezer can be arranged in the cabinet body according to the needs of users, the constant temperature area is formed by the residual storage space in the cabinet body, so that three functions of refrigeration, freezing and normal temperature keeping can be provided for the users according to the needs of the users, three tastes of refrigeration, freezing and normal temperature are provided for the users, the functions are complete, and the corresponding refrigerator and freezer can be flexibly arranged in the cabinet body so as to be suitable for various storage scenes of various articles needing refrigeration, freezing and normal temperature storage.

The embodiment of the present disclosure provides a multi-temperature combined intelligent cabinet, fig. 1 shows a schematic structural diagram of a multi-temperature combined intelligent cabinet according to an embodiment of the present disclosure, and fig. 2 shows a schematic structural diagram of a multi-temperature combined intelligent cabinet according to an embodiment of the present disclosure, and as shown in fig. 1 and fig. 2, the intelligent cabinet includes a cabinet body 11 and at least one cryogenic box 12.

In this embodiment, as shown in fig. 1, the cryoboxes 12 may be independent cryoboxes disposed in the cabinet, and the cryoboxes 12 are independent from each other, and the cryoboxes 12 may be inserted into the cabinet as required. Alternatively, as shown in fig. 2, the cryogenic box 12 may be a box body formed by the cryogenic shelves 120 and the cabinet body 11, one cryogenic shelf may be shared between adjacent cryogenic boxes 12, and if necessary, the cryogenic shelves 120 may be inserted into the cabinet body, and the plurality of cryogenic boxes 12 may be partitioned in the cabinet body by the cryogenic shelves 120.

In this embodiment, the low temperature box 12 may be a freezer or a refrigerator, the low temperature box 12 is located in the cabinet 11, at least one low temperature box 12 is placed in the cabinet 11, and the at least one low temperature box 12 includes at least one freezer and/or at least one refrigerator.

In this embodiment, as shown in fig. 1, the storage space in the cabinet body except for the at least one low-temperature box forms a normal-temperature area 13, the normal-temperature area 13 is provided with at least one normal-temperature box 131, the normal-temperature box 131 may include an independent box body placed in the cabinet body as shown in fig. 1, or the normal-temperature box may be a box body formed by the outer wall of the at least one low-temperature box and the cabinet body as shown in fig. 2, and the temperature in the normal-temperature box is a normal-temperature.

For example, the low temperature box is an independent box placed in the cabinet body, in a scenario where refrigeration is required, one or more refrigeration boxes may be placed one by one in the cabinet body 11 as shown in fig. 1 according to the number and volume of items to be refrigerated, in this case, the cabinet body 11 of the intelligent cabinet includes one or more refrigeration boxes, an operator may place items to be refrigerated in the refrigeration boxes, and in a scenario where refrigeration and preservation are required, items to be preserved at normal temperature may be placed in a storage space in the cabinet body 11 except for the refrigeration boxes. In a scenario where freezing is required, one or more freezers may be placed inside the cabinet 11, one after the other, depending on the number and volume of items to be frozen. In a scenario requiring refrigeration and freezing, one or more refrigeration cases may be placed in the cabinet 11 according to the quantity and volume of the articles to be refrigerated, and one or more freezing cases may be placed in the cabinet 11 according to the quantity and volume of the articles to be frozen, for example, the refrigeration cases may be placed one by one at the bottom of the cabinet 11, the freezing cases may be placed one by one on the refrigeration cases, an operator may place the articles to be refrigerated in the refrigeration case, place the articles to be frozen in the freezing cases, and in a scenario requiring refrigeration, freezing and ambient temperature preservation, the articles to be ambient temperature preserved may be placed in an ambient temperature region other than the refrigeration cases and the freezing cases in the cabinet 11.

It should be noted here that the temperatures in different cryogenic boxes may be the same or different, and may specifically be set according to user needs, and an independent first refrigeration module may be provided in each cryogenic box, and the first refrigeration module is used to refrigerate so that the temperature in the cryogenic box is within a set low temperature range.

According to the above example, various cryogenic boxes 12 can be flexibly placed in the intelligent cabinet as required, three functions of refrigeration, freezing and maintaining normal temperature are provided for users, richer mouthfeel (refrigeration/freezing/normal temperature) is provided for users, for example, the number of the cryogenic boxes can be increased in winter and the number of the cryogenic boxes can be increased in summer, the functions are complete, and the applicable scenes are wide.

In a possible embodiment, for each cryogenic tank, the cryogenic tank further comprises a first refrigeration module for refrigerating such that the temperature inside the cryogenic tank is within a respective cryogenic range.

In this embodiment, each of the cryoboxes includes a first refrigeration module, and when the cryobox is a refrigerator, the first refrigeration module in the cryobox can refrigerate to make the temperature in the cryobox be within a corresponding refrigeration temperature range, and when the cryobox is a freezer, the first refrigeration module in the cryobox can refrigerate to make the temperature in the cryobox be within a corresponding refrigeration temperature range.

In this embodiment, this first refrigeration module's refrigeration mode can be forced air cooling or direct cooling, and direct cooling adopts the cooling mode of air natural convection, and the evaporimeter absorbs the heat in food and the air through heat-conduction and realizes the cooling, and the cooling tube snap-on is around the low-temperature cabinet to realize whole refrigeration. The air cooling is to cool by air, when high temperature air flows in the built-in evaporator, the temperature of the evaporator is low due to high air temperature, the two directly exchange heat, and the air temperature is gradually reduced. Meanwhile, cool air is blown into the cold box by the blower, thereby reducing the temperature.

In this embodiment, if the low temperature box is an independent box placed in the cabinet, the first refrigeration module is fixedly connected to the box of the low temperature box, and if the low temperature box is a box formed by a low temperature shelf and the cabinet body, the first refrigeration module is fixedly connected to the low temperature shelf.

For example, the first refrigeration module may be fixed at the upper end of the low-temperature shelf, and may refrigerate the upper side of the low-temperature shelf, and place the low-temperature shelf in the cabinet, and the low-temperature shelf and the cabinet part above the low-temperature shelf form a low-temperature box, or the low-temperature shelf, the bottom of the upper low-temperature box and the cabinet part between the low-temperature shelf and the upper low-temperature box form a low-temperature box, and the first refrigeration module on the low-temperature shelf may refrigerate to preserve the articles placed on the low-temperature shelf at a low temperature. Or, for example, the first refrigeration module may be fixed below the low-temperature shelf, and may refrigerate the lower part of the low-temperature shelf, and place the low-temperature shelf in the cabinet, and the low-temperature shelf and the part of the cabinet below the low-temperature shelf form a low-temperature box, or the low-temperature shelf, the top of the lower-layer low-temperature box, and the part of the cabinet between the low-temperature shelf and the top of the lower-layer low-temperature box form a low-temperature box, and the first refrigeration module below the low-temperature shelf may refrigerate to preserve the articles placed at the bottom of the cabinet or at the top of the lower-layer low-temperature box at a low temperature.

For example, the low temperature box is a box body formed by low temperature shelves and the cabinet body, in a scene needing refrigeration, one or more low temperature shelves 120 can be placed in the cabinet body 11 as shown in fig. 2 according to the quantity and volume of articles needing refrigeration, one or more refrigeration boxes are formed in the cabinet body 11 of the intelligent cabinet, an operator can place the articles needing refrigeration in the refrigeration boxes, and in a scene needing refrigeration and normal temperature preservation, the articles needing normal temperature preservation can be placed in a storage space except the refrigeration boxes in the cabinet body 11. In a scenario requiring refrigeration, one or more low temperature shelves 120 may be placed inside the cabinet 11, forming one or more freezers inside the cabinet 11 of the smart cabinet, according to the number and volume of items to be refrigerated. Under the scene that needs to be refrigerated and frozen, can be according to the quantity and the volume of the article that need to be refrigerated, place one or more low temperature layer frame in this cabinet 11, form a plurality of cryogenic tanks, according to the quantity and the volume of the article that need to freeze, refrigerate the first refrigeration module refrigeration of the corresponding quantity cryogenic tank and make the temperature in this cryogenic tank be freezing temperature range, refrigerate the first refrigeration module refrigeration of the remaining quantity cryogenic tank and make the temperature in this cryogenic tank be cold-stored temperature range, under the scene that needs to be refrigerated, freeze and keep at room temperature, can also place the article that need to keep at room temperature in the normal atmospheric temperature district except that fridge and freezer in the cabinet 11.

In a possible embodiment, a freezing box and a refrigerating box are arranged in the cabinet body, the low-temperature box is a box body formed by a low-temperature shelf and the cabinet body, and the freezing box and the refrigerating box share one shared low-temperature shelf; the refrigerating box comprises a first refrigerating module and a second refrigerating module, wherein the first refrigerating module is used for refrigerating to enable the temperature in the refrigerating box to be within a corresponding refrigerating temperature range; the shared low-temperature shelf is provided with an electric air door, the electric air door is communicated with the freezing box and the refrigerating box, and the valve size of the electric air door is adjusted to enable the temperature in the freezing box to be within a corresponding freezing temperature range and the temperature in the refrigerating box to be within a corresponding refrigerating temperature range.

In this embodiment, the intelligent cabinet further includes a controller, wherein temperature sensors are respectively disposed in the freezer and the refrigerator, the temperature sensors are used for detecting the temperature in the freezer or the refrigerator, the controller is connected to the temperature sensors and the second refrigeration module, and the controller can control the second refrigeration module of the freezer to refrigerate according to the temperature detected by the temperature sensors in the freezer, so that the temperature in the freezer is within a corresponding freezing temperature range; meanwhile, the controller can also control the size of the valve of the electric air door according to the temperature detected by the temperature sensor in the refrigerating box, so that the temperature in the refrigerating box is in a corresponding refrigerating temperature range. For example, if the temperature in the refrigerating box is too high, the valve of the electric air door can be controlled to be opened to a large extent, so that the cold air in the refrigerating box can be quickly transferred into the refrigerating box; if the temperature in the refrigerating box is in the corresponding refrigerating temperature range, the valve of the electric air door can be controlled to be opened to a small point, so that the cold air in the refrigerating box is slowly transferred into the refrigerating box, and the refrigerating temperature is kept.

In this embodiment, in order to prevent the cold air in each low temperature box 12 from leaking out and affecting the temperature in the low temperature box 12 during the use of the intelligent cabinet, the low temperature box 12 may be sealed in the following two embodiments:

in a possible implementation manner, fig. 3 shows a schematic structural diagram of another multi-temperature combined intelligent cabinet according to an embodiment of the present disclosure, as shown in fig. 3, each cryogenic box 12 is provided with a box opening, the box opening is provided with a sealing strip 121, and after a cabinet door on the cabinet body 11 is closed, the sealing strip 121 on the cryogenic box 12 is attached to the cabinet body 11.

In this embodiment, a circle of sealing strips 121 may be disposed around the opening of each low temperature box 12, and when the cabinet door on the cabinet body 11 is closed, the sealing strips 121 on the low temperature box 12 may be pressed, and the sealing strips may deform under the pressing of the cabinet door, so as to seal the low temperature box 12 and prevent the cold air in the low temperature box 12 from leaking.

In another possible embodiment, each cryogenic box 12 comprises a box opening and a box door for closing the box opening, a sealing strip 121 is arranged around the box opening, and the box door presses the sealing strip 121 on the cryogenic box 12 when being closed, so that the box opening of the cryogenic box 12 is sealed.

In this embodiment, a circle of sealing strips may be disposed around the opening of each low temperature box 12, the sealing strips 121 on the low temperature box 12 may be pressed when the box door is closed, and the sealing strips 121 may deform under the pressing of the box door, so as to seal the opening of the low temperature box 12 and prevent the cold air in the low temperature box 12 from leaking.

In one possible embodiment, the door of the cryostat is a thermal insulation door, which may be, for example, a double-glazed door or a triple-glazed door or a foam door.

In a possible embodiment, the normal temperature box is provided with a box opening and a box door positioned at the box opening, and the box door of the normal temperature box is provided with a ventilation opening.

In this embodiment, the door of the room temperature box may not have a heat insulating function, and may be a single-layer glass door or the like, for example.

In this embodiment, the ventilation opening is provided in the normal temperature chamber, so that the temperature in the normal temperature chamber is not too high.

In this embodiment, the ventilation fan is arranged at the ventilation opening, and the ventilation fan can regularly replace the air in the normal-temperature box, so that the temperature in the normal-temperature box is not too high, and peculiar smell in the intelligent cabinet can be prevented.

In one possible embodiment, the housing material of the cryostat 12 comprises a thermal insulation material.

In this embodiment, the material of the low temperature boxes 12 includes a thermal insulating material, so that heat transfer between the low temperature boxes 12 can be prevented and the temperature inside the low temperature boxes 12 can be 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. Here, when the low temperature box 12 is a separate box body independent from the cabinet body, the box body material of the low temperature box 12 is a thermal insulation material, and when the low temperature box 12 includes a box body formed by a low temperature shelf and the cabinet body, the material of the low temperature shelf belongs to the thermal insulation material, and it is possible to prevent the cooling of the second heating module above or below the low temperature shelf from being transmitted to the adjacent box body.

In this embodiment, if the low temperature box 12 is a separate box body independent from the cabinet body, since the box body material of the low temperature box is already a thermal insulation material, the cabinet body of the intelligent cabinet does not need to be made of a foaming material as the whole, but the cabinet body 11 is made of a metal material, and the box body of the low temperature box 12 is made of a thermal insulation material, so that the cost of the intelligent cabinet is greatly reduced.

In one possible embodiment, as shown in fig. 2 or 3, at least one support structure 111 is disposed on a side wall inside the cabinet 11, and the support structure 111 is used for supporting the low-temperature box 12.

For example, the supporting structure 111 may include supporting bars on left and right sidewalls of the cabinet 11 as shown in fig. 2 or fig. 3, and a pair of supporting bars on the left and right sidewalls form a supporting structure 111 to support an intelligent cabinet, or the supporting structure may also include supporting bars on left and right sidewalls of the cabinet and a supporting bar on a rear sidewall of the cabinet opposite to the cabinet door, and a pair of supporting bars on the left and right sidewalls and a supporting bar on the rear sidewall form a supporting structure to support an intelligent cabinet. The supporting structure 111 may be a supporting bar shown in fig. 2 or a supporting groove, and at this time, the bottom of the intelligent cabinet needs to be provided with a protrusion to be clamped in the supporting groove, so that the supporting structure supports the intelligent cabinet. The position and shape of the support structure are not limited, and it is only necessary that the support structure 111 be capable of supporting the cabinet or the low temperature shelf of the low temperature box 12 placed thereon.

It should be noted here that if the volume of the constant temperature box formed by the remaining storage space is large, in order to conveniently and regularly place the articles to be stored at normal temperature, the support plate can be placed on the support structure 111 of the constant temperature box, the support plate can divide the storage space in the constant temperature box into a plurality of storage spaces, and the operator can place corresponding articles in the storage space in each support plate.

In a possible implementation, as shown in fig. 4, the intelligent cabinet further includes: the power supply module 14 is arranged on the cabinet 11 and comprises at least one power supply interface 141; the cryogenic box 12 further comprises a connector 122, wherein the connector 122 is connected with the power supply interface 141; the power supply module 14 supplies power to the low temperature box 12 through the power supply interface 141 and the connector 122 which are connected.

In this embodiment, the power module 14 may be disposed at the top or the bottom of the cabinet 11, the power module 14 may have one end connected to the power line of the intelligent cabinet and the other end provided with at least one power interface 141, and before the cryobox 12 is placed on the supporting structure 111 of the intelligent cabinet, an operator may first insert the connector 122 of the intelligent cabinet into one power interface 141, so that when the power line is powered on, the power module 14 can supply power to the cryobox 12 through the connected power interface 141 and the connector 122.

It should be noted here that the number of the power supply interfaces 141 may be the total number of the cryoboxes 12 that can be placed in the intelligent cabinet, and of course, the number of the power supply interfaces 141 may also be greater than the total number, so that when some power supply interfaces 141 have a problem of not powering on, other spare power supply interfaces 141 may be used.

In a possible embodiment, the at least one power supply interface 141 may be located at a middle region of the rear side wall of the cabinet 11.

In this embodiment, in order to facilitate the connection of each intelligent cabinet to the corresponding power supply interface 141, the at least one power supply interface 141 may be provided at a middle region of the rear side wall of the cabinet body 11.

In a possible embodiment, the cabinet 11 is provided with a recess for placing the at least one power supply interface 141 and the connection 122 of the low-temperature box 12.

In this embodiment, in order to avoid the disorder of connection between the connector 122 and the power supply interface 141 in the cabinet 11, a recess may be provided in the cabinet 11, and the connector 122 and the power supply interface 141 of each of the cryoboxes 12 may be engaged in the recess. For example, a groove may be designed for wiring the connector 122 of each cryogenic box 12, a power supply interface 141 is placed at one end of each groove, and an operator may insert the connector 122 of the cryogenic box 12 into the power supply interface 141 in the corresponding groove, then wire the connector 122 in the corresponding groove, and finally place the cryogenic box 12 completely into the cabinet 11 of the intelligent cabinet.

In one possible embodiment, the height of each cryogenic tank 12 is the same.

In this embodiment, each of the cryoboxes 12 has the same height, so that the corresponding support structures 111 can be disposed at the same interval in the cabinet 11, and the support structures 111 can be used for accommodating independent boxes or low-temperature shelves of the cryoboxes, so that the cryoboxes can be flexibly disposed in the cabinet 11 according to the user's needs.

It should be noted that the size of each cryogenic tank 12 is standardized, which facilitates uniform production.

In a possible embodiment, as shown in fig. 3, a ventilation opening 112 is provided on the inner rear side wall of the cabinet body 11, and the low temperature box is located at the ventilation opening 112.

In this embodiment, a ventilation net or a ventilation fence may be provided at the ventilation opening 112.

In this embodiment, when the cryo-box is located at the ventilation opening 112, the heat generated by the refrigeration module of the cryo-box can be dissipated.

The present disclosure also provides an intelligent cabinet, as shown in fig. 3, the intelligent cabinet includes:

as shown in fig. 3, a cabinet 11, a supporting structure 111 is disposed on a side wall inside the cabinet 11;

at least one cryogenic tank 12, located inside said cabinet 11, placed on a corresponding support structure 111, comprising at least one refrigerator and/or at least one freezer, said cryogenic tank 12 comprising a separate box placed inside said cabinet 11, or a box formed by a cryogenic shelf 120 and said cabinet 11; the low-temperature box 12 further comprises a first refrigeration module, and the first refrigeration module is used for refrigerating to enable the temperature in the low-temperature box 12 to be in a corresponding low-temperature range; each low-temperature box 12 is provided with a box opening and a box door positioned at the box opening, the box opening is provided with a sealing strip 121, after the box door is closed, the box door at the box opening is attached to the sealing strip 121 to seal the box opening of the low-temperature box 12, and the box door of the low-temperature box 12 is a heat preservation box door; the height of each cryobox 12 is the same; a vent 112 is arranged on the rear side wall in the cabinet body 11, the low-temperature box 12 is located at the vent 112, and a ventilation net or a ventilation fence is arranged at the vent 112; the box body material of the low-temperature box 12 comprises a thermal insulation foaming material;

the power supply module 14 is arranged on the cabinet 11 and comprises at least one power supply interface 141; the cryogenic box 12 further comprises a connector 122, wherein the connector 122 is connected with the power supply interface 141; the power supply module 14 supplies power to the low-temperature box 12 through the power supply interface 141 and the joint 122 which are connected; the number of the power supply interfaces 141 is greater than or equal to the total number of the cryoboxes 12 placed in the intelligent cabinet;

the storage space in the cabinet body 11 except the at least one low-temperature box 12 forms a normal-temperature area, the normal-temperature area is provided with at least one normal-temperature box, the normal-temperature box comprises an independent box body placed in the cabinet body 11, or a box body formed by the outer wall of the at least one low-temperature box 12 and the cabinet body 11, and the temperature in the normal-temperature box is normal-temperature; the normal temperature box is provided with a box opening and a box door located at the box opening, the box door of the normal temperature box is provided with a ventilation opening, and the ventilation opening is provided with a ventilation fan.

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, wherein a supporting structure 111 is arranged on the side wall in the cabinet body 11;

at least one cryogenic tank 12, located inside said cabinet 11, resting on a corresponding support structure 111, comprising at least one refrigerator and/or at least one freezer, said cryogenic tank 12 comprising a separate box placed inside said cabinet 11; the low-temperature box 12 further comprises a first refrigeration module, and the first refrigeration module is used for refrigerating to enable the temperature in the low-temperature box 12 to be in a corresponding low-temperature range; each low-temperature box 12 is provided with a box opening and a box door positioned at the box opening, the box opening is provided with a sealing strip 121, after the box door is closed, the box door at the box opening is attached to the sealing strip 121 to seal the box opening of the low-temperature box 12, and the box door of the low-temperature box 12 is a heat preservation box door; the height of each cryobox 12 is the same; a vent 112 is arranged on the rear side wall in the cabinet body 11, the low-temperature box 12 is located at the vent 112, and a ventilation net or a ventilation fence is arranged at the vent 112; the box body material of the low-temperature box 12 comprises a thermal insulation foaming material;

the power supply module 14 is arranged on the cabinet 11 and comprises at least one power supply interface 141; the cryogenic box 12 further comprises a connector 122, wherein the connector 122 is connected with the power supply interface 141; the power supply module 14 supplies power to the low-temperature box 12 through the power supply interface 141 and the joint 122 which are connected; the number of the power supply interfaces 141 is greater than or equal to the total number of the cryoboxes 12 placed in the intelligent cabinet;

the storage space in the cabinet body 11 except the at least one low-temperature box 12 forms a normal-temperature area, the normal-temperature area is provided with at least one normal-temperature box, the normal-temperature box is a box body formed by the outer wall of the at least one low-temperature box 12 and the cabinet body 11, and the temperature in the normal-temperature box is normal-temperature; the normal temperature box is provided with a box opening and a box door located at the box opening, the box door of the normal temperature box is provided with a ventilation opening, and the ventilation opening is provided with a ventilation fan.

Example 2:

a cabinet 11, at least one cryogenic tank 12, located inside said cabinet 11, resting on a corresponding support structure 111, comprising at least one refrigerator and/or at least one freezer, said cryogenic tank 12 comprising a separate box placed inside said cabinet 11; the low-temperature box 12 further comprises a first refrigeration module, and the first refrigeration module is used for refrigerating to enable the temperature in the low-temperature box 12 to be in a corresponding low-temperature range; the low-temperature box 12 is provided with a box opening, sealing strips 121 are arranged on the periphery of the box opening, and when a cabinet door on the cabinet body 11 is closed, the sealing strips 121 on the low-temperature box 12 are extruded to seal the box opening of the low-temperature box 12; the height of each cryobox 12 is the same; a vent 112 is arranged on the rear side wall in the cabinet body 11, the low-temperature box 12 is located at the vent 112, and a ventilation net or a ventilation fence is arranged at the vent 112; the box body material of the low-temperature box 12 comprises a thermal insulation foaming material;

the power supply module 14 is arranged on the cabinet 11 and comprises at least one power supply interface 141; the cryogenic box 12 further comprises a connector 122, wherein the connector 122 is connected with the power supply interface 141; the power supply module 14 supplies power to the low-temperature box 12 through the power supply interface 141 and the joint 122 which are connected; the number of the power supply interfaces 141 is greater than or equal to the total number of the cryoboxes 12 placed in the intelligent cabinet;

the storage space in the cabinet body 11 except the at least one low-temperature box 12 forms a normal-temperature area, the normal-temperature area is provided with at least one normal-temperature box, the normal-temperature box is a box body formed by the outer wall of the at least one low-temperature box 12 and the cabinet body 11, and the temperature in the normal-temperature box is normal-temperature; the normal temperature box is provided with a box opening and a box door located at the box opening, the box door of the normal temperature box is provided with a ventilation opening, and the ventilation opening is provided with a ventilation fan.

Example 3

A cabinet body 11; a supporting structure 111 is arranged on the side wall in the cabinet body 11; the low-temperature box 12 is positioned in the cabinet body 11, is placed on the corresponding supporting structure 111, and comprises a refrigerating box and a freezing box, and the low-temperature box 12 comprises a box body formed by the low-temperature shelf 120 and the cabinet body 11; the freezer compartment and the refrigerator compartment share a common low temperature shelf 120; the refrigerating box comprises a first refrigerating module and a second refrigerating module, wherein the first refrigerating module is used for refrigerating to enable the temperature in the refrigerating box to be within a corresponding refrigerating temperature range; the shared low-temperature shelf 120 is provided with an electric air door, the electric air door is communicated with the freezer and the refrigerator, and the valve size of the electric air door is adjusted to enable the temperature in the freezer to be within a corresponding freezing temperature range and the temperature in the refrigerator to be within a corresponding refrigerating temperature range; the low-temperature box 12 is provided with a box opening, sealing strips 121 are arranged around the box opening, and when a cabinet door on the cabinet body 11 is closed, the sealing strips 121 on the low-temperature box 12 are pressed to seal the box opening of the low-temperature box 12; the height of each cryobox 12 is the same; a vent 112 is arranged on the rear side wall in the cabinet body 11, the low-temperature box 12 is located at the vent 112, and a ventilation net or a ventilation fence is arranged at the vent 112; the box body material of the low-temperature box 12 comprises a thermal insulation foaming material;

the power supply module 14 is arranged on the cabinet 11 and comprises at least one power supply interface 141; the cryogenic box 12 further comprises a connector 122, wherein the connector 122 is connected with the power supply interface 141; the power supply module 14 supplies power to the low temperature box 12 through the power supply interface 141 and the connector 122 which are connected; the number of the power supply interfaces 141 is greater than or equal to the total number of the cryoboxes 12 placed in the intelligent cabinet;

the storage space in the cabinet body 11 except the at least one low-temperature box 12 forms a normal-temperature area, the normal-temperature area is provided with at least one normal-temperature box, the normal-temperature box is a box body formed by the outer wall of the at least one low-temperature box 12 and the cabinet body 11, and the temperature in the normal-temperature box is normal-temperature; the normal temperature box is provided with a box opening and a box door located at the box opening, the box door of the normal temperature box is provided with a ventilation opening, and the ventilation opening is provided with a ventilation fan.

In the above embodiments, the refrigeration module may include a semiconductor refrigeration sheet, and refrigeration is performed by using a semiconductor refrigeration technology, or the refrigeration module or the heating module may be a compressor for refrigeration or heating, as shown in fig. 5, the refrigeration module or the heating module includes a compressor 51, a condenser 52, a throttling element 53, and an evaporator 54, where the compressor 51, the condenser 52, the throttling element 53, and the evaporator 54 are connected by a pipe filled with a refrigerant to form a closed pipeline, so as to form a refrigeration module capable of circulating the refrigerant.

The compressor 51 is a driven fluid machine for lifting a low-pressure refrigerant into a high-pressure refrigerant, the compressor 51 can suck a low-temperature low-pressure gaseous refrigerant, and the compressor 51 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 51 can include a reciprocating compressor, a screw compressor, a rotary compressor, a scroll compressor, a centrifugal compressor and the like, and the specific type of the compressor is not limited in the embodiment of the present application.

The condenser 52 is a heat exchanger for exchanging heat between the refrigerant in the condenser 52 and the air outside the condenser 52 to dissipate heat. Specifically, the condenser 52 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 52, a heat radiation fin having excellent heat conductivity may be provided on the pipe to increase the heat radiation area, thereby accelerating the heat exchange speed and improving the heat exchange efficiency. The fan or fan matched with the condenser 52 can be arranged to increase the flow speed of the air around the condenser 52, so that the heat exchange speed is increased, and the heat exchange efficiency is improved.

The throttling element 53 is used for throttling the liquid refrigerant at normal temperature and high pressure by the throttling element 53 to become a gas refrigerant at low temperature and low pressure, wherein the throttling element 53 may also be referred to as the throttling element 53 or a regulating valve, and the throttling element 53 may include an expansion valve, a capillary tube, and the like. In addition, the throttling element 53 can also control the flow rate of the refrigerant flowing through the throttling element 53, so as to avoid the flow rate of the refrigerant flowing through the throttling element 53 from being too large or too small. If the flow rate of the refrigerant flowing through the throttling element 53 is too large, the refrigerant flowing out of the throttling element 53 still includes a liquid refrigerant, and the liquid refrigerant entering the compressor 51 may generate liquid impact to damage the compressor 51; if the flow rate of the refrigerant flowing through the throttle member 53 is too small, the refrigerant entering the compressor 51 is too small, and the operation efficiency of the compressor 51 is lowered.

The evaporator 54 is a heat exchanger for exchanging heat between the refrigerant in the evaporator 54 and the air outside the condenser 52 to absorb heat. Specifically, the evaporator 54 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 order to improve the heat exchange efficiency of the condenser 52, a heat sink having excellent heat conductivity may be provided on the pipe to increase a heat dissipation 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 54 may be further provided, and the flow speed of the air around the evaporator 54 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.

Refrigerant, which may also be referred to as refrigerant, refrigerant or snow, refers to a medium substance that performs energy conversion in a refrigeration 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 monochloromethane, dichlorodifluoromethane, trifluoromethane, tetrafluoroethane, trifluorodichloroethane, etc.

In the low temperature box, the low temperature and low pressure vapor refrigerant flows into the compressor 51 from the evaporator 54, the low temperature and low pressure vapor refrigerant is compressed by the compressor 51, and the high temperature and high pressure vapor refrigerant flows into the condenser 52; the high-temperature and high-pressure gaseous refrigerant exchanges heat with air outside the condenser 52 through the condenser 52, so that the high-temperature and high-pressure gaseous refrigerant is cooled in the condenser 52 to be a normal-temperature and high-pressure liquid refrigerant, then the normal-temperature and high-pressure liquid refrigerant flows into the throttling element 53, and the throttling element 53 throttles the normal-temperature and high-pressure liquid refrigerant, so that the refrigerant flowing out of the throttling element 53 is converted into a low-temperature and low-pressure liquid refrigerant; the low-temperature low-pressure liquid refrigerant flows into the evaporator 54, the low-temperature low-pressure liquid refrigerant exchanges heat with the air outside the evaporator 54 through the evaporator 54, 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 54 can be guided into the box body of the low-temperature box, and the air outside the condenser 52 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.

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 the technical features disclosed in the present disclosure (but not limited to) having similar functions are replaced with each other to form the technical solution.

Claims (10)

1. A multi-temperature combined intelligent cabinet, comprising:

a cabinet body;

the low-temperature box is positioned in the cabinet body and comprises at least one freezing box and/or at least one refrigerating box, the low-temperature box comprises an independent box body placed in the cabinet body, or a box body formed by the low-temperature shelf and the cabinet body, and the temperature in the low-temperature box is lower than the normal temperature;

wherein, the internal except that the object space of putting of at least one cryogenic tank forms normal warm district, normal warm district is provided with at least one normal temperature case, normal temperature case is including placing the internal independent box of cabinet, perhaps, by the outer wall of at least one cryogenic tank with the box that the cabinet body formed, the temperature in the normal temperature case is normal atmospheric temperature.

2. The intelligent cabinet according to claim 1, wherein for each cryogenic tank, the cryogenic tank further comprises a first refrigeration module for refrigerating the temperature within the cryogenic tank to be within a respective cryogenic range.

3. The intelligent cabinet according to claim 1, wherein a freezer compartment and a refrigerator compartment are arranged in the cabinet body, the freezer compartment is a box body formed by a low-temperature shelf and the cabinet body, and the freezer compartment and the refrigerator compartment share a shared low-temperature shelf;

the refrigerating box comprises a first refrigerating module and a second refrigerating module, wherein the first refrigerating module is used for refrigerating to enable the temperature in the refrigerating box to be within a corresponding refrigerating temperature range; the shared low-temperature shelf is provided with an electric air door, the electric air door is communicated with the freezing box and the refrigerating box, and the valve size of the electric air door is adjusted to enable the temperature in the freezing box to be within a corresponding freezing temperature range and the temperature in the refrigerating box to be within a corresponding refrigerating temperature range.

4. The intelligent cabinet according to claim 1, wherein the low-temperature box is provided with a box opening, sealing strips are arranged around the box opening, and when the cabinet door on the cabinet body is closed, the sealing strips on the low-temperature box are pressed to seal the box opening of the low-temperature box.

5. The intelligent cabinet according to claim 1, wherein each cryogenic box is provided with a box opening and a box door located at the box opening, the box opening is provided with a sealing strip, and after the box door is closed, the box door at the box opening is attached to the sealing strip to seal the box opening of the cryogenic box.

6. The intelligent cabinet according to claim 5, wherein the door of the cold box is a heat-preservation door.

7. The intelligent cabinet according to claim 5, wherein the constant temperature box is provided with a box opening and a box door at the box opening, and the box door of the constant temperature box is provided with a ventilation opening.

8. The intelligent cabinet according to claim 7, wherein a ventilation fan is arranged at the ventilation port.

9. Intelligent cabinet according to claim 1,

the box body material of the low-temperature box comprises a heat insulation material.

10. A multi-temperature combined intelligent cabinet, comprising:

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

the low-temperature box is positioned in the cabinet body, is placed on a corresponding supporting structure and comprises at least one refrigerating box and/or at least one freezing box, and comprises an independent box body placed in the cabinet body or a box body formed by a low-temperature layer rack and the cabinet body; the low-temperature box also comprises a first refrigeration module, and the first refrigeration module is used for refrigerating to enable the temperature in the low-temperature box to be in a corresponding low-temperature range; each low-temperature box is provided with a box opening and a box door positioned at the box opening, the box opening is provided with a sealing strip, after the box door is closed, the box door at the box opening is attached to the sealing strip to seal the box opening of the low-temperature box, and the box door of the low-temperature box is a heat preservation box door; the height of each low-temperature box is 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 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 more than or equal to the total number of the low-temperature boxes placed in the intelligent cabinet;

the cabinet body is internally provided with at least one low-temperature box, wherein the storage space except the at least one low-temperature box in the cabinet body forms a normal-temperature area, the normal-temperature area is provided with at least one normal-temperature box, the normal-temperature box comprises an independent box body placed in the cabinet body, or a box body formed by the outer wall of the at least one low-temperature box and the cabinet body, and the temperature in the normal-temperature box is normal-temperature; the normal temperature case is provided with a case mouth and a case door located at the case mouth, the case door of the normal temperature case is provided with a ventilation hole, and the ventilation hole is provided with a ventilation fan.

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