CN111000372B - Intelligent wardrobe - Google Patents

Abstract

The invention discloses an intelligent wardrobe, which comprises: the wardrobe body is provided with a placing cavity for placing clothes; the disinfection and sterilization device is arranged in the placing cavity and comprises a shell and an ultraviolet disinfection and sterilization light source, the shell is provided with an accommodating cavity and a lamp hole, the lamp hole is communicated with the placing cavity and the accommodating cavity, and the ultraviolet disinfection and sterilization light source is arranged in the accommodating cavity and corresponds to the lamp hole; the dehumidifying device is arranged on the wardrobe main body and comprises a shell and a refrigerating structure, the shell is provided with an installation cavity and a first air inlet and a first air outlet which are communicated with the installation cavity, the refrigerating structure is arranged in the installation cavity, and the first air inlet and the first air outlet are communicated with the placing cavity. The invention aims to provide an intelligent wardrobe which can realize circulation dehumidification, ensure drying of clothes, and realize disinfection, sterilization and peculiar smell removal of the clothes.

Description

Intelligent wardrobe

Technical Field

The invention relates to the technical field of intelligent home furnishing, in particular to an intelligent wardrobe.

Background

The wardrobe is the essential household equipment, and the current wardrobe is usually provided with the spatial structure of placing articles such as clothing or shoes. If the space in which clothes, shoes and other objects are placed in the wardrobe is wet, bacteria are easy to breed, so that the clothes and the wardrobe become moldy and the human health is harmed. Meanwhile, articles such as clothes or shoes are easy to generate bacteria or have peculiar smell and the like, so that the clothes in the wardrobe are easy to breed the bacteria, and the human health is harmed.

Disclosure of Invention

The invention mainly aims to provide an intelligent wardrobe, and aims to provide an intelligent wardrobe which can realize cyclic dehumidification, ensure drying of clothes, and realize disinfection, sterilization and peculiar smell removal of the clothes.

In order to achieve the purpose, the intelligent wardrobe provided by the invention comprises:

the wardrobe body is provided with a placing cavity for placing clothes;

the disinfection and sterilization device is arranged in the placing cavity and comprises a shell and an ultraviolet disinfection and sterilization light source, the shell is provided with an accommodating cavity and a lamp hole, the lamp hole is communicated with the placing cavity and the accommodating cavity, and the ultraviolet disinfection and sterilization light source is arranged in the accommodating cavity and corresponds to the lamp hole; and

the dehumidifying device is arranged on the wardrobe main body and comprises a shell and a refrigerating structure, the shell is provided with an installation cavity and a first air inlet and a first air outlet which are communicated with the installation cavity, the refrigerating structure is arranged in the installation cavity, and the first air inlet and the first air outlet are communicated with the placing cavity.

In an embodiment, the disinfection and sterilization device further comprises an ozone generator disposed in the accommodating cavity, and the ozone generator and the ultraviolet sterilization light source are arranged at intervals.

In an embodiment, the disinfection and sterilization device further comprises a circuit board arranged in the accommodating cavity, the circuit board is arranged at an interval with the ozone generator and the ultraviolet sterilization light source, and the circuit board is electrically connected with the ozone generator and the ultraviolet sterilization light source.

In one embodiment, the disinfection and sterilization device further comprises an ozone detection sensor arranged on the circuit board, and the ozone detection sensor is used for detecting the concentration of ozone.

In an embodiment, the housing is provided with a plurality of through holes arranged at intervals, and the plurality of through holes are arranged around the lamp hole and communicated with the placing cavity and the accommodating cavity.

In an embodiment, the outer casing is further provided with a second air inlet and a second air outlet which are communicated with the installation cavity, the dehumidifying device further comprises a first valve body and a second valve body, the first valve body is used for opening or closing the first air inlet and opening or closing the second air inlet, the second valve body is used for opening or closing the first air outlet and opening or closing the second air outlet, and the second air inlet and the second air outlet are communicated to the outside of the wardrobe body.

In one embodiment, the refrigeration structure comprises:

the sealing shell is arranged in the mounting cavity and provided with a sealing cavity, a first air port and a second air port, and the first air port and the second air port are communicated with the sealing cavity; and

the refrigerator is arranged in the sealing cavity;

the first valve body opens a first air inlet and closes the second air inlet to enable the first air port to be communicated with the first air inlet, the second valve body opens the first air outlet and closes the second air outlet to enable the second air port to be communicated with the first air outlet, and therefore the placing cavity, the first air inlet, the first air port, the sealing cavity, the second air port and the first air outlet form an internal circulation flow channel; or the first valve body closes the first air inlet and opens the second air inlet to enable the first air port to be communicated with the second air inlet, the second valve body closes the first air outlet and opens the second air outlet to enable the second air port to be communicated with the second air outlet, and therefore the second air inlet, the first air port, the sealing cavity, the second air port and the second air outlet form an external circulation flow channel.

In an embodiment, the dehumidification device further comprises a heat sink arranged in the installation cavity, and the heat sink is connected with the outer wall of the sealed shell and arranged corresponding to the refrigerator;

and/or, the dehumidification device also comprises a cooling fan arranged in the mounting cavity, and the cooling fan is arranged corresponding to the refrigerator.

In an embodiment, the dehumidifying device further comprises a temperature and humidity sensor arranged in the installation cavity, and the temperature and humidity sensor is arranged at the first air inlet.

In an embodiment, the dehumidifying device further includes a first exhaust fan disposed in the mounting cavity, and the first exhaust fan is disposed corresponding to the first air outlet;

and/or, the dehumidifying device further comprises a second exhaust fan arranged in the mounting cavity, and the second exhaust fan is arranged corresponding to the second air outlet.

According to the intelligent wardrobe, the dehumidifying device is arranged on the wardrobe main body, the first air inlet and the first air outlet are arranged on the shell of the dehumidifying device, the mounting cavity and the placing cavity are communicated through the first air inlet and the first air outlet, a circulating state is formed in the wardrobe main body, so that moist air in the placing cavity enters the mounting cavity from the first air inlet under the circulating state by utilizing the refrigerating structure in the mounting cavity, moisture in the moist air is condensed out by the refrigerating structure, and dry air is blown to the placing cavity from the first air outlet, so that the dehumidifying of the intelligent wardrobe is realized, the drying of clothes in the wardrobe main body is ensured, and the breeding of bacteria on the clothes is effectively prevented. Furthermore, the disinfection and sterilization device is arranged in the placing cavity of the wardrobe main body, and the ultraviolet sterilization light source of the disinfection and sterilization device is utilized to realize radiation sterilization and sterilization on clothes or shoes in the placing cavity, so that the disinfection and sterilization effect of the intelligent wardrobe is further realized, and the sterile environment in the placing cavity of the wardrobe main body is ensured; simultaneously, through setting up the ultraviolet sterilization light source in the casing to when guaranteeing to place the clothing or shoes of intracavity and can not damage the ultraviolet sterilization light source, be favorable to disinfection and sterilization device to utilize the casing to realize easy to assemble, improve assembly efficiency. The intelligent wardrobe provided by the invention can realize cyclic dehumidification, ensures the drying of clothes, and can realize disinfection, sterilization and peculiar smell removal on the clothes.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of an intelligent wardrobe according to the present invention;

FIG. 2 is an enlarged schematic view at A in FIG. 1;

FIG. 3 is an enlarged schematic view at B of FIG. 1;

FIG. 4 is a schematic cross-sectional view of an embodiment of an intelligent wardrobe according to the present invention;

FIG. 5 is an enlarged schematic view at C of FIG. 4;

FIG. 6 is an enlarged schematic view at D of FIG. 4;

FIG. 7 is a schematic structural diagram of an embodiment of the disinfection apparatus according to the present invention;

FIG. 8 is an exploded view of an embodiment of the disinfection apparatus according to the present invention;

FIG. 9 is a schematic structural diagram of a dehumidifying apparatus according to an embodiment of the present invention;

FIG. 10 is an exploded view of an embodiment of the dehumidifier;

FIG. 11 is a schematic diagram of the inner cycle of the dehumidifier in accordance with an embodiment of the present invention;

fig. 12 is a schematic diagram of the structure of the circulation of the dehumidifying apparatus according to an embodiment of the present invention.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				100	Intelligent wardrobe	3113	Second air outlet
1	Wardrobe main body	312	Upper cover
				11	Placing cavity	3121	First air outlet
2	Disinfection and sterilization device	313	Baffle plate
				21	Shell body	314	First air duct
21a	Containing cavity		315					Second air duct
				211	Lower casing	32	Refrigeration structure
212	Upper casing	321	Sealing shell
				2121	Lamp hole	321a	Sealed cavity
2122	Limiting groove	3211	Sealed upper shell
				2124	Through hole	3212	Sealed lower casing
22	Ozone generator	3213	First tuyere
				23	Ultraviolet sterilization light source	3214	Second tuyere
231	Lamp panel	322	Refrigerating device
				232	Ultraviolet lamp bead	33	First valve body
24	Circuit board	34	Second valve body
				25	Ozone detection sensor	35	Heat sink
3	Dehumidifying device	36	Heat radiation fan
				31	Outer casing	37	Temperature and humidity sensor
31a	Mounting cavity		38					First exhaust fan
				311	Lower cover	39	Second exhaust fan
3111	First air inlet
				3112	Second air inlet

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

Also, the meaning of "and/or" and/or "appearing throughout is meant to encompass three scenarios, exemplified by" A and/or B "including scenario A, or scenario B, or scenarios where both A and B are satisfied.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The invention provides an intelligent wardrobe 100.

Referring to fig. 1 to 12, in an embodiment of the present invention, the intelligent wardrobe 100 includes a wardrobe body 1, a disinfection and sterilization device 2, and a dehumidifying device 3, wherein the wardrobe body 1 is provided with a placing cavity 11 for placing clothes; the disinfection and sterilization device 2 is arranged in the placing cavity 11, the disinfection and sterilization device 2 comprises a shell 21 and an ultraviolet sterilization light source 23, the shell 21 is provided with an accommodating cavity 21a and a lamp hole 2121, the lamp hole 2121 is communicated with the placing cavity 11 and the accommodating cavity 21a, and the ultraviolet sterilization light source 23 is arranged in the accommodating cavity 21a and corresponds to the lamp hole 2121; the dehumidifier 3 is arranged on the wardrobe body 1, the dehumidifier 3 comprises a shell 31 and a refrigeration structure 32, the shell 31 is provided with an installation cavity 31a and a first air inlet 3111 and a first air outlet 3121 which are communicated with the installation cavity 31a, the refrigeration structure 32 is arranged in the installation cavity 31a, and the first air inlet 3111 and the first air outlet 3121 are communicated with the placing cavity 11.

In the present embodiment, the wardrobe body 1 is used to store and place articles such as clothes, shoes, etc. In order to place clothes, shoes and other articles in a classified manner conveniently, the wardrobe body 1 is provided with a plurality of placing cavities 11 for storing the clothes, the placing cavities 11 are arranged at intervals, and the wardrobe is specifically arranged according to actual requirements without limitation.

It can be understood that, in order to realize the dehumidification, disinfection, sterilization and odor removal of the clothes or shoes and the like in each placing cavity 11, a disinfection and sterilization device 2 and a dehumidification device 3 are arranged in each placing cavity 11. Certainly, in order to simplify the structure, save the cost, wardrobe main part 1a plurality of chamber 11 of placing are intercommunication setting each other, so can be provided with disinfection and sterilization device 2 and dehydrating unit 3 in one places chamber 11, so usable disinfection and sterilization device 2 and dehydrating unit 3 carry out dehumidification, disinfection and sterilization and remove the peculiar smell to a plurality of clothing or shoes etc. of placing in the chamber 11.

According to the intelligent wardrobe 100, the dehumidifying device 3 is arranged on the wardrobe main body 1, the first air inlet 3111 and the first air outlet 3121 are arranged on the shell 31 of the dehumidifying device 3, the installation cavity 31a and the placing cavity 11 are communicated through the first air inlet 3111 and the first air outlet 3121, and a circulation state is formed in the wardrobe main body 1, so that when moist air in the placing cavity 11 enters the installation cavity 31a from the first air inlet 3111 under the circulation state through the refrigerating structure 32 in the installation cavity 31a, moisture in the moist air is condensed out by the refrigerating structure 32, and the dry air is blown to the placing cavity 11 from the first air outlet 3121, so that the dehumidifying of the intelligent wardrobe 100 is realized, the drying of clothes in the wardrobe main body 1 is ensured, and bacteria breeding of the clothes is effectively prevented. Further, the disinfection and sterilization device 2 is arranged in the placing cavity 11 of the wardrobe main body 1, and the ultraviolet sterilization light source 23 of the disinfection and sterilization device 2 is utilized to realize radiation sterilization and sterilization on clothes or shoes in the placing cavity 11, so that the disinfection and sterilization effect of the intelligent wardrobe 100 is further realized, and the sterile environment is ensured to be realized in the placing cavity 11 of the wardrobe main body 1; meanwhile, the ultraviolet sterilization light source 23 is arranged in the shell 21, so that the ultraviolet sterilization light source is prevented from being damaged by clothes or shoes placed in the cavity 11, the disinfection and sterilization device 2 is convenient to install by utilizing the shell 21, and the assembly efficiency is improved. The intelligent wardrobe 100 provided by the invention can realize circulation dehumidification, ensure drying of clothes, and realize disinfection, sterilization and peculiar smell removal of the clothes.

In this embodiment, the disinfection and sterilization apparatus 2 may be fixedly disposed on the inner wall of the placing cavity 11, for example, by welding, interference fit, etc., so that the installation stability of the disinfection and sterilization apparatus 2 can be ensured. Of course, in order to improve the assembly efficiency of the disinfection and sterilization device 2 and facilitate the replacement, the maintenance, etc., the disinfection and sterilization device 2 may be detachably disposed on the inner wall of the placing cavity 11, for example, the detachable connection manner such as the snap connection, the insertion fit, the threaded connection, the screw or the pin may be any structure as long as the structure that the housing 21 of the disinfection and sterilization device 2 can be detachably connected with the inner wall of the placing cavity 11 is not limited herein.

It can be understood that the housing 21 of the disinfection and sterilization device 2 plays a role in supporting, installing and fixing, and the housing 21 may be a seat, a plate, a mounting rack, etc. It is understood that the shape of the housing 21 may be a circular, square, triangular, polygonal or irregular structure, and the change is adjusted according to the actual use scenario, which is not limited herein.

In this embodiment, the lamp hole 2121 is disposed on the housing 21, so that the ultraviolet germicidal light source 23 in the accommodating cavity 21a can irradiate ultraviolet light onto articles such as clothes or shoes in the accommodating cavity 11 through the lamp hole 2121, thereby achieving sterilization and disinfection and achieving the purpose of environmental protection.

As shown in fig. 5, fig. 7 and fig. 8, in an embodiment, the housing 21 of the disinfection and sterilization apparatus 2 includes an upper housing 212 and a lower housing 211, wherein the lower housing 211 is connected to the wall of the placing chamber 11, the upper housing 212 and the lower housing 211 enclose to form a containing chamber 21a, the ozone generator 22 is located in the containing chamber 21a and is connected to the upper housing 212 and/or the lower housing 211, the upper housing 212 is provided with a lamp hole 2121, and the ultraviolet sterilization light source 23 is located in the upper housing 212 and is disposed corresponding to the lamp hole 2121.

It will be appreciated that the upper and lower shells 212, 211 may be fixedly connected, such as by welding or interference fit, to improve the structural strength and stability of the housing 21. In order to facilitate installation of the ozone generator 22 and the ultraviolet germicidal light source 23 and improve assembly efficiency, and facilitate replacement and maintenance of the ozone generator 22 and the ultraviolet germicidal light source 23, thereby reducing cost, in this embodiment, the upper shell 212 and the lower shell 211 are detachably connected, for example, detachably connected by a snap connection, an insertion fit, a threaded connection, a screw, or a pin, and the like, and the structure is not limited herein as long as the detachable connection of the upper shell 212 and the lower shell 211 can be realized. Optionally, the upper shell 212 and the lower shell 211 are fixedly connected by screws.

In this embodiment, the lower case 211 is provided with a receiving groove, so that the ozone generator 22 can be conveniently mounted in a limited manner by the receiving groove, thereby improving the mounting stability. In order to improve the connection stability of the upper shell 212 and the lower shell 211, a convex edge is arranged at the position, close to the groove opening of the accommodating groove, of the lower shell 211, the convex edge surrounds the groove opening of the accommodating groove and extends towards the direction far away from the center of the accommodating groove, so that the convex edge can be used for being connected with the upper shell 212, the contact area between the convex edge and the upper shell 212 is increased, and the arrangement of fasteners (such as screws and bolts) is facilitated.

In an embodiment, as shown in fig. 5, a limiting groove 2122 is concavely provided on one side of the upper shell 212 facing the lower shell 211, the lamp hole 2121 is provided in a bottom wall of the limiting groove 2122, the ultraviolet germicidal light source 23 includes a lamp plate 231 and an ultraviolet lamp bead 232 provided on the lamp plate 231, the lamp plate 231 is accommodated and limited in the limiting groove 2122, and the ultraviolet lamp bead 232 and the lamp hole 2121 are opposite to each other.

It can be understood that, by providing the limiting groove 2122 on the upper housing 212, the ultraviolet germicidal light source 23 can be limited and mounted by using the limiting groove 2122, thereby improving the mounting stability. As can be appreciated, the light panel 231 is a circuit board or substrate. Optionally, the lamp panel 231 is made of a conductive metal, for example, the lamp panel 231 is an aluminum substrate, and the like, which is not limited herein.

In this embodiment, ultraviolet lamp bead 232 sets up at lamp plate 231, and in order to improve the sterile efficiency of disinfecting, be provided with a plurality of ultraviolet lamp beads 232 on lamp plate 231, epitheca 212 corresponds a plurality of ultraviolet lamp beads 232 and is provided with a plurality of lamp holes 2121 this moment, and each lamp hole 2121 corresponds the setting with an ultraviolet lamp bead 232. It can be understood that the ultraviolet lamp beads 232 can emit purple light, thereby realizing sterilization. The wavelength of ultraviolet light emitted by the ultraviolet lamp bead 232 is 400 nm-435 nm. The disinfection and sterilization device 2 is a sterilization module formed by the ultraviolet lamp beads 232 on the ultraviolet sterilization light source 23, so that the original mercury lamp function is replaced, and the requirement of environmental protection is met. Optionally, be provided with the ultraviolet lamp pearl 232 that a plurality of intervals set up on lamp plate 231, a plurality of ultraviolet lamp pearls 232 are the array and arrange.

It can be understood that the ultraviolet light wave band that ultraviolet lamp pearl 232 sent disinfects and disinfects to compare with current mercury lamp, can avoid the pollution problem that the inside virulent pollutant of mercury lamp causes water. When light with the wavelength of 400 nm-470 nm is used for irradiating bacteria for a long time, because a large amount of endogenous porphyrin is generated in the metabolism of the bacteria, the endogenous porphyrin can be activated into unstable porphyrin after being irradiated by shorter wavelength (such as 405nm) and combined with triplet oxygen to form unstable singlet oxygen, and the singlet oxygen is combined with compounds on cell membranes to damage the cell membranes, thereby causing the death of the bacteria. In the present embodiment, the ultraviolet germicidal light source 23 emits ultraviolet light having a wavelength of 400nm to 435 nm. Realize disinfecting and degerming function through ultraviolet germicidal light source 23, replace the tradition and utilize the mercury lamp to carry out degerming, deodorization to articles such as the clothing or shoes of placing in the chamber 11, realized the demand of intelligent wardrobe 100 green. The disinfection and sterilization device 2 also has the characteristic of repeated use, so that the use cost is effectively reduced.

Optionally, the upper shell 212 is arcuately disposed. It can be understood that, by providing the upper housing 212 with an arc-shaped structure, the aesthetic appearance of the disinfection and sterilization device 2 can be improved, and the ozone can be diffused uniformly. As shown in fig. 8, the lower shell 211 is further provided with a wire passing hole, and the wire passing hole is communicated with the accommodating cavity 21 a. Through the arrangement of the wire through hole, the external power supply can be conveniently connected and conducted with the ozone generator 22 and the ultraviolet sterilization light source 23 in the cavity 21a of the housing body 21 through the wire through hole.

In the present embodiment, the casing 31 of the dehumidifying apparatus 3 plays a role of supporting, installing and fixing, and the casing 31 may be a box, or the like. It is understood that the shape of the housing 31 may be a circular, square, triangular, polygonal or special-shaped structure, and the shape is not limited herein, and the transformation is adjusted according to the actual use scenario. The refrigeration structure 32 is used to condense out moisture in the air, thereby achieving the purpose of dehumidification.

In the embodiment, the dehumidifying device 3 can be fixedly arranged on the wardrobe body 1, for example, by welding, interference fit, etc., so that the installation stability of the dehumidifying device 3 can be ensured. Of course, in order to improve the assembly efficiency of the dehumidifying apparatus 3 and facilitate the replacement, maintenance, etc., the dehumidifying apparatus 3 may be detachably disposed on the wardrobe body 1, for example, a detachable connection manner such as a snap connection, a plug-in fit, a threaded connection, a screw or a pin may be adopted, as long as the structure that the housing 31 of the dehumidifying apparatus 3 is detachably connected with the wardrobe body 1 is adopted, which is not limited herein.

In order to facilitate installation of the dehumidifying device 3, in this embodiment, the wardrobe body 1 is provided with a mounting hole communicated with the placing cavity 11, and the dehumidifying device 3 is installed in the mounting hole, so that the first air inlet 3111 and the first air outlet 3121 on the casing 31 of the dehumidifying device 3 are communicated with the placing cavity 11, and thus internal circulation can be achieved by using the first air inlet 3111 and the first air outlet 3121 of the dehumidifying device 3 and the placing cavity 11 of the wardrobe body 1.

It can be understood that, after the dehumidifying apparatus 3 is installed in the wardrobe body 1, the first inlet 3111 and the first outlet 3121 of the dehumidifying apparatus 3 are located inside the wardrobe body 1, that is, the first inlet 3111 and the first outlet 3121 are located inside the placing cavity 11 and are communicated with the placing cavity 11. At this time, a communicated sealed space is formed between the installation cavity 31a in the dehumidifying device 3 and the inside of the placing cavity 11 of the wardrobe body 1, the air in the placing cavity 11 of the wardrobe body 1 passes through the first air inlet 3111, the moisture in the humid air is condensed out through the refrigerating structure 32 in the dehumidifying device 3, and then the dry air enters the wardrobe body 1 through the first air outlet 3121, so that the circulating dehumidification of the air inside the wardrobe body 1 is formed.

In one embodiment, as shown in fig. 5 and 8, the disinfection and sterilization apparatus 2 further includes an ozone generator 22 disposed in the accommodating cavity 21a, and the ozone generator 22 and the ultraviolet sterilization light source 23 are disposed at intervals. It can be understood that, by providing the ozone generator 22, ozone is generated by the ozone generator 22 and is diffused into the placing cavity 11 of the wardrobe body 1 through the lamp holes 2121, so as to sterilize and disinfect clothes and the like and remove odor.

In order to facilitate the rapid diffusion of the ozone generated by the ozone generator 22 into the placing chamber 11, in one embodiment, as shown in fig. 2, 5, 7 and 8, the housing 21 is provided with a plurality of through holes 2124 spaced apart from each other, and the plurality of through holes 2124 are disposed around the lamp hole 2121 and communicate the placing chamber 11 and the accommodating chamber 21 a. Therefore, the ozone generated by the ozone generator 22 can be diffused into the placing cavity 11 through the through holes 2124, and the efficiency of sterilization and deodorization can be improved.

In the present embodiment, the plurality of through holes 2124 are uniformly distributed on the housing 21. Of course, the through holes 2124 may be distributed on the housing 21 in an array. Alternatively, a plurality of through holes 2124 are radially arranged around the lamp hole 2121, so as to improve the appearance of the housing 21 of the disinfection device 2.

In an embodiment, as shown in fig. 5 and 8, the disinfection and sterilization apparatus 2 further includes a circuit board 24 disposed in the accommodating cavity 21a, the circuit board 24 is disposed at an interval with the ozone generator 22 and the ultraviolet sterilization light source 23, and the circuit board 24 is electrically connected with the ozone generator 22 and the ultraviolet sterilization light source 23.

It can be understood that by providing the circuit board 24, the circuit board 24 can be used to control the ozone generator 22 and the ultraviolet germicidal light source 23, so as to conveniently control the operating states of the ozone generator 22 and the ultraviolet germicidal light source 23 according to actual requirements.

In this embodiment, in order to improve the installation stability of the circuit board 24, a plurality of mounting posts are arranged on the bottom wall of the accommodating groove of the lower shell 211, each mounting post is provided with a mounting hole, a plurality of through holes are formed in the circuit board 24, so that each through hole corresponds to one mounting post, and the circuit board 24 is fixedly connected to the mounting posts by passing through the through holes and the mounting holes through fasteners.

It is understood that, in order to avoid the electronic components on the circuit board 24, a gap is formed between the circuit board 24 and the bottom wall of the receiving groove of the lower case 211. In order to further improve the installation stability of the circuit board 24, a plurality of protrusions are arranged on the bottom wall of the containing groove of the lower shell 211, the plurality of protrusions are arranged at intervals, and the circuit board 24 is arranged on the installation column and abutted against the protrusions in a limiting manner.

In one embodiment, as shown in fig. 5 and 8, the disinfection and sterilization apparatus 2 further includes an ozone detection sensor 25 disposed on the circuit board 24, and the ozone detection sensor 25 is used for detecting the concentration of ozone.

As can be appreciated, ozone detecting sensor 25 is electrically connected to circuit board 24. Ozone detection sensor 25's setting, usable ozone detection sensor 25 realizes detecting the ozone in the chamber 11 of placing of wardrobe main part 1 to make circuit board 24 realize opening the disinfection function automatically according to the concentration of placing the interior ozone of chamber 11. Alternatively, ozone detecting sensor 25 is soldered to circuit board 24, so that the strength of connection between ozone detecting sensor 25 and circuit board 24 can be increased.

In an embodiment, as shown in fig. 6, 9, 10, 11 and 12, the housing 31 is further provided with a second inlet 3112 and a second outlet 3113 communicating with the installation cavity 31a, the dehumidifying apparatus 3 further includes a first valve body 33 and a second valve body 34, the first valve body 33 is used for opening or closing the first inlet 3111 and for opening or closing the second inlet 3112; the second valve body 34 is used to open or close the first outlet 3121 and to open or close the second outlet 3113, and the second inlet 3112 and the second outlet 3113 are located at an outer wall of the wardrobe body 1, that is, the second inlet 3112 and the second outlet 3113 are communicated to the outside of the wardrobe body 1.

In this embodiment, by providing the second air inlet 3112 and the second air outlet 3113 on the housing 31 of the dehumidifying apparatus 3, and a first valve body 33 and a second valve body 34 are provided, and by the cooperation of the first valve body 33 and the second valve body 34, the first valve body 33 opens the first inlet 3111 and closes the second inlet 3112, and the second valve body 34 opens the first outlet 3121 and closes the second outlet 3113, so that the dehumidifying apparatus 3 assumes an internal circulation state, so that moisture in the humid air entering from the first air inlet 3111 is condensed out by the refrigerating structure 32 in the mounting cavity 31a of the housing 31 in the internal circulation state, and the dry air is blown out from the first air outlet 3121, when the dehumidification equipment is applied to smart homes, the first air inlet 3111 and the first air outlet 3121 are respectively communicated with the placing cavity 11 of the wardrobe body 1, and air in the placing cavity 11 of the wardrobe body 1 can be dehumidified through internal circulation; then, by matching the first valve body 33 and the second valve body 34, the first valve body 33 opens the second air inlet 3112 and closes the first air inlet 3111, and the second valve body 34 opens the second air outlet 3113 and closes the first air outlet 3121, when the dehumidifying apparatus is applied to a smart home, the second air inlet 3112 and the second air outlet 3113 are located outside the smart home, that is, are communicated with air outside the wardrobe body 1, and at this time, the dehumidifying apparatus 3 is in an external circulation state. Certainly, refrigeration structure 32 can stop the refrigeration during extrinsic cycle to utilize the outside air to get into by second air intake 3112, take out the moisture in shell 31 installation cavity 31a by second air outlet 3113, clear away the ponding that persists when refrigeration structure 32 refrigerates, when dehydrating unit 3 was applied to the intelligence house, the effect of the air dehumidification in the intelligence house is realized through dehydrating unit 3's inner loop and extrinsic cycle effect. The dehumidifying device 3 provided by the invention can realize internal and external circulation, and when the dehumidifying device 3 is applied to the intelligent wardrobe 100, the internal and external circulation can be utilized to ensure that the intelligent wardrobe 100 is dry, so that bacteria breeding or mildew growth can be effectively prevented.

In the present embodiment, as shown in fig. 6, 9 and 10, the casing 31 of the dehumidifying apparatus 3 includes an upper cover 312 and a lower cover 311, and the upper cover 312 and the lower cover 311 enclose to form a mounting cavity 31 a. The refrigeration structure 32 may be disposed on the upper cover 312 and/or the lower cover 311. It will be appreciated that the upper cover 312 and the lower cover 311 may be fixedly connected, such as by welding or interference fit, to improve the structural strength and stability of the housing 31. In order to facilitate installation of the refrigeration structure 32 and improve assembly efficiency, and meanwhile, the refrigeration structure 32 is convenient to replace and maintain, so as to reduce cost, in this embodiment, the upper cover 312 and the lower cover 311 are detachably connected, for example, detachably connected by using a snap connection, a plug-in fit, a threaded connection, a screw, or a pin, and the like, and any structure that can realize detachable connection between the upper cover 312 and the lower cover 311 is not limited herein. Optionally, the upper cover 312 and the lower cover 311 are fixedly connected by screws.

In this embodiment, in order to achieve the simultaneous opening of the first inlet 3111 and the simultaneous closing of the second inlet 3112, and the simultaneous opening of the first outlet 3121 and the simultaneous closing of the second outlet 3113, the first valve body 33 and the second valve body 34 may adopt a three-way valve structure or two-way valve structure, etc. The first valve body 33 and the second valve body 34 may be solenoid valves, respectively, that is, by electromagnetically controlling the open or closed states of the first valve body 33 and the second valve body 34. Of course, the first valve body 33 and the second valve body 34 may also be mechanical valves, so that the first valve body 33 and the second valve body 34 are opened or closed by the rotation of a mechanical structure, which is not limited herein.

Of course, the first valve body 33 and the second valve body 34 respectively include two check valve structures. The two check valves of the first valve body 33 are respectively disposed at the first air inlet 3111 and the second air inlet 3112, and when the first air inlet 3111 is opened by controlling the check valve at the first air inlet 3111, the check valve at the second air inlet 3112 is controlled to close the second air inlet 3112. Alternatively, when one check valve of the first valve body 33 closes the first inlet 3111, the other check valve of the first valve body 33 opens the second inlet 3112.

Similarly, the two check valves of the second valve body 34 are respectively disposed at the first outlet 3121 and the second outlet 3113, so that when one check valve of the second valve body 34 opens the first outlet 3121, the other check valve of the second valve body 34 closes the second outlet 3113; alternatively, when one of the one-way valves of the second valve body 34 closes the first outlet 3121, the other one-way valve of the second valve body 34 opens the second outlet 3113.

It is understood that, when the first and second valve bodies 33 and 34 are respectively of a three-way valve structure, two ports of the first valve body 33 are respectively communicated with the first and second intake ports 3111 and 3112, and two ports of the second valve body 34 are respectively communicated with the first and second outlet ports 3121 and 3113. In this way, the first valve body 33 opens the first inlet 3111 and closes the second inlet 3112 at the same time, and the second valve body 34 opens the first outlet 3121 and closes the second outlet 3113 at the same time; alternatively, the first valve body 33 closes the first inlet 3111 and opens the second inlet 3112, and the second valve body 34 closes the first outlet 3121 and opens the second outlet 3113.

In this embodiment, an air duct is formed in the mounting cavity 31a of the housing 31, the refrigeration structure 32 is located in the air duct, the first air inlet 3111 and the second air inlet 3112 are communicated with the air duct through a pipeline, and the first air outlet 3121 and the second air outlet 3113 are communicated with the air duct through a pipeline, so that the first valve 33 and the second valve 34 can be conveniently disposed on the pipeline, and the first air inlet 3111, the second air inlet 3112, the first air outlet 3121 and the second air outlet 3113 are controlled to be opened or closed through the first valve 33 and the second valve 34.

In this embodiment, as shown in fig. 6, 9 and 10, the lower cover 311 is provided with a first inlet 3111, a second inlet 3112 and a second outlet 3113 which are spaced apart from each other, and the upper cover 312 is provided with a first outlet 3121. Optionally, the lower cover 311 is provided with a receiving groove for realizing the limiting installation of the refrigeration structure 32. The upper cover 312 is in an arc shape, and it can be understood that the upper cover 312 is in an arc structure, so that the appearance attractiveness of the dehumidifying device 3 can be improved, and the air can be uniformly diffused at the first air outlet 3121.

In order to avoid snake, worm, mouse and the like and dust from entering the shell 31 of the dehumidifying device 3 and affecting the normal operation of the refrigerating structure 32 and other components, in this embodiment, the first air inlet 3111, the second air inlet 3112, the first air outlet 3121 and the second air outlet 3113 are provided with a mesh enclosure, and the mesh enclosure is provided with a plurality of air vents arranged at intervals. It can be understood that the plurality of vent holes are arranged in an array or in a radial shape on the mesh enclosure, and the like, and the mesh enclosure is not limited herein.

In an embodiment, as shown in fig. 6, 10, 11 and 12, the refrigeration structure 32 includes a sealed shell 321 and a refrigerator 322, wherein the sealed shell 321 is disposed in the installation cavity 31a, and the sealed shell 321 is provided with a sealed cavity 321a and a first air opening 3213 and a second air opening 3214 which are communicated with the sealed cavity 321 a; the refrigerator 322 is disposed in the hermetic chamber 321 a. Optionally, the refrigerator 322 is a semiconductor refrigerator.

In one embodiment, as shown in fig. 11, the first valve body 33 is used to open the first inlet 3111 and close the second inlet 3112, such that the first outlet 3213 is communicated with the first inlet 3111, the second valve body 34 is used to open the first outlet 3121 and close the second outlet 3113, and the second outlet 3214 is communicated with the first outlet 3121, such that the first inlet 3111, the first outlet 3213, the sealed cavity 321a, the second outlet 3214 and the first outlet 3121 form an internal circulation flow passage.

In another embodiment, as shown in fig. 12, the first valve body 33 is used to close the first inlet 3111 and open the second inlet 3112, so that the first outlet 3213 is communicated with the second inlet 3112, the second valve body 34 is used to close the first outlet 3121 and open the second outlet 3113, and the second outlet 3214 is communicated with the second outlet 3113, so that the second inlet 3112, the first outlet 3213, the sealed cavity 321a, the second outlet 3214 and the second outlet 3113 form an external circulation channel.

So make dehydrating unit 3 utilize the cooperation of first valve body 33 and second valve body 34, realize that the installation cavity 31a of shell 31 and the sealed cavity 321a cooperation of refrigeration structure 32 realize inner loop and extrinsic cycle, so be applied to intelligent house with dehydrating unit 3, for example intelligent wardrobe 100, the moisture in the usable internal loop of dehydrating unit 3 dehumidifies the back with the humid air in the intelligent wardrobe 100, discharge the moisture in the sealed cavity 321a outside intelligent wardrobe 100 through the extrinsic cycle, thereby ensure the drying of intelligent wardrobe 100, effectively avoided growing bacteria or going mouldy in the intelligent wardrobe 100.

In this embodiment, after the dehumidifying apparatus 3 is installed in the wardrobe body 1, the second air inlet 3112 and the second air outlet 3113 are located outside the wardrobe body 1, the first air inlet 3111 and the first air outlet 3121 are closed while the second air inlet 3112 and the second air outlet 3113 are opened by the cooperation of the first valve body 33 and the second valve body 34, the sealed cavity 321a inside the dehumidifying apparatus 3 is communicated with the outside of the wardrobe body 1, and the outside air of the wardrobe body 1 passes through the second air inlet 3112, passes through the sealed cavity 321a inside the dehumidifying apparatus 3, and is discharged to the outside of the wardrobe body 1 through the second air outlet 3113, thereby forming the circulation of the outside air of the wardrobe body 1.

It can be understood that the sealed casing 321 plays a role in supporting, installing and fixing, and the sealed casing 321 may be a box, or the like. It can be understood that the shape of the sealing shell 321 may be a circular, square, triangular, polygonal or special-shaped structure, and the transformation is adjusted according to the actual use scenario, which is not limited herein. The refrigerator 322 is used to condense out moisture in the air, thereby achieving the purpose of dehumidification. It can be understood that, by providing the sealed casing 321, the moisture condensed out by the refrigerator 322 can be isolated in the sealed cavity 321a by the sealed casing 321, so as to effectively avoid the moisture from affecting other components in the installation cavity 31a of the housing 31.

As shown in fig. 6 and 10, the sealing shell 321 includes a sealing upper shell 3211 and a sealing lower shell 3212, and the sealing upper shell 3211 and the sealing lower shell 3212 enclose a sealing cavity 321 a. The refrigerator 322 may be provided on the sealing upper case 3211 and/or the sealing lower case 3212. It is understood that, in order to improve the structural strength and stability of the sealing shell 321, the sealing upper shell 3211 and the sealing lower shell 3212 may be fixedly connected, for example, by welding or interference fit. In order to conveniently install the refrigerator 322, improve the assembly efficiency, and conveniently replace and maintain the refrigerator 322 at the same time, thereby reducing the cost, in this embodiment, the sealing upper shell 3211 and the sealing lower shell 3212 adopt a detachable connection mode, for example, a detachable connection mode such as a snap connection, a plug-in fit, a threaded connection, a screw or a pin, and any structure that can realize the detachable connection of the sealing upper shell 3211 and the sealing lower shell 3212 is not limited herein. Optionally, the upper sealing shell 3211 and the lower sealing shell 3212 are fixedly connected by screws.

In this embodiment, in order to improve the installation stability of the refrigerator 322 and realize the limit installation of the refrigerator 322, the sealing lower shell 3212 is provided with a limit groove, and the refrigerator 322 is limit-installed in the limit groove.

In an embodiment, an air duct is defined by an outer wall of the sealing housing 321 and an inner wall of the mounting cavity 31a, a baffle 313 is disposed on the outer wall of the sealing housing 321, the air duct is divided into a first air duct 314 and a second air duct 315 by the baffle 313, the first air inlet 3111, the second air inlet 3112 and the first air inlet 3213 are communicated with the first air duct 314, and the first air outlet 3121, the second air outlet 3113 and the second air inlet 3214 are communicated with the second air duct 315.

In this embodiment, the upper sealing shell 3211 of the sealing shell 321 abuts against the upper cover 312 of the housing 31, an air duct is formed between the lower sealing shell 3212 of the sealing shell 321 and the lower cover 311 of the housing 31, the lower sealing shell 3212 of the sealing shell 321 is provided with the baffle 313, the air duct can be divided into the first air duct 314 and the second air duct 315 by the baffle 313, so that the first air inlet 3111 and the second air inlet 3112 on the lower cover 311 are communicated with the first air duct 314, the first air outlet 3213 of the sealing shell 321 is communicated with the first air duct 314, the second air outlet 3113 on the lower cover 311 and the first air outlet 3121 on the upper cover 312 are communicated with the second air duct 315, and the second air outlet 3214 of the sealing shell 321 is communicated with the second air duct 315, so that air entering the first air duct 314 from the first air inlet 3111 or the second air inlet 3112 can only enter the sealing cavity 321a through the first air inlet 3, enter the second air duct 321315, and then exit the mounting cavity 32131 a through the first air outlet 3113121 or the second air outlet 3113, thus, the air flow interference can be effectively prevented.

In order to further improve the air intake efficiency or the air exhaust efficiency, when the first valve body 33 opens the first air inlet 3111 and closes the second air inlet 3112, the first air inlet 3213 is communicated with the first air inlet 3111 through the first air duct 314, and at this time, the second air inlet 3112 is isolated from or not communicated with the first air duct 314. When the second valve body 34 opens the first outlet 3121 and closes the second outlet 3113, the second outlet 3214 is communicated with the first outlet 3121 through the second duct 315, and at this time, the second outlet 3113 is isolated from or not communicated with the second duct 315, so that the first inlet 3111, the first outlet 3213, the sealed cavity 321a, the second outlet 3214 and the first outlet 3121 form an internal circulation channel.

It can be understood that when the first valve body 33 closes the first air inlet 3111 and opens the second air inlet 3112, the first air inlet 3213 is communicated with the second air inlet 3112 through the first air duct 314, and at this time, the first air inlet 3111 is isolated from or not communicated with the first air duct 314. The second valve body 34 closes the first air outlet 3121 and opens the second air outlet 3113, the second air outlet 3214 is communicated with the second air outlet 3113 through the second air duct 315, at this time, the first air outlet 3121 is isolated from or not communicated with the second air duct 315, so that the second air inlet 3112, the first air outlet 3213, the sealed cavity 321a, the second air outlet 3214 and the second air outlet 3113 form an external circulation channel.

In an embodiment, as shown in fig. 6 and 10, the dehumidifying apparatus 3 further includes a heat sink 35 disposed in the mounting chamber 31a, and the heat sink 35 is connected to an outer wall of the sealed housing 321 and disposed corresponding to the refrigerator 322.

It will be appreciated that by providing the heat sink 35, the heat sink 35 can be utilized to dissipate heat from the refrigerator 322. In the present embodiment, as shown in fig. 6 and 10, in order to rapidly dissipate the heat of the refrigerator 322, a plurality of heat dissipating holes are provided on the housing 31, and the plurality of heat dissipating holes are provided corresponding to the heat dissipating fins 35.

In an embodiment, as shown in fig. 6 and 10, the dehumidifying apparatus 3 further includes a heat dissipating fan 36 disposed in the mounting cavity 31a, and the heat dissipating fan 36 is disposed corresponding to the refrigerator 322.

It can be understood that by providing the heat dissipation fan 36, the heat transferred from the refrigerator 322 to the heat dissipation fin 35 can be quickly exhausted from the heat dissipation hole by the heat dissipation fan 36. In the present embodiment, the heat dissipation fan 36 is disposed corresponding to the heat dissipation hole and disposed on a side of the heat dissipation plate 35 facing away from the sealing case 321.

In an embodiment, as shown in fig. 6 and 10, the dehumidifying apparatus 3 further includes a temperature and humidity sensor 37 disposed in the mounting cavity 31a, and the temperature and humidity sensor 37 is disposed at the first air inlet 3111.

It can be understood that, by providing the temperature and humidity sensor 37, the temperature of the air entering from the first air inlet 3111 can be measured by the temperature and humidity sensor 37, so as to conveniently control the operating state of the refrigerator 322. In the present embodiment, the temperature and humidity sensor 37 can detect temperature and humidity at the same time.

In an embodiment, as shown in fig. 6, 10, 11 and 12, the dehumidifying apparatus 3 further includes a first exhaust fan 38 disposed in the installation cavity 31a, and the first exhaust fan 38 is disposed corresponding to the first air outlet 3121.

As can be appreciated, by providing the first exhaust fan 38 at the first air outlet 3121, the air flow can be accelerated by the first exhaust fan 38, so that the air flow of the inner circulation flow passage can be accelerated, thereby improving the dehumidification efficiency.

In this embodiment, dehydrating unit 3's the during operation of first exhaust fan 38, the inside air flow of wardrobe main part 1 accelerates, disinfection and sterilization apparatus 2 disinfects the inside air of intelligence wardrobe simultaneously, both cooperations can be carried the air that disinfects and sterilizes through disinfection and sterilization apparatus 2 to the holding chamber 11 of wardrobe main part 1 fast in, and the bacterium that breeds the thing in holding chamber 11, or the bacterium rapid cycle in the air goes out to disinfection and sterilization apparatus 2, utilize disinfection and sterilization apparatus 2 to disinfect, so can ensure that the clothing in the holding chamber 11 is dry and aseptic, make the holding chamber 11 of wardrobe main part 1 become dry and aseptic environment.

In an embodiment, as shown in fig. 6, 10, 11 and 12, the dehumidifying apparatus 3 further includes a second exhaust fan 39 disposed in the mounting cavity 31a, and the second exhaust fan 39 is disposed corresponding to the second outlet 3113.

It can be understood that, by providing the second exhaust fan 39 at the second outlet 3113, the air flow can be accelerated by the second exhaust fan 39, so that the air flow in the external circulation flow channel can be accelerated, and the moisture in the sealed cavity 321a can be rapidly exhausted. Meanwhile, the moisture generated in the sealed cavity 321a by internal circulation can be prevented from breeding bacteria, so that the clothes in the accommodating cavity 11 of the wardrobe body 1 can be prevented from generating bacteria again to affect the health of human body.

In this embodiment, a temperature/humidity sensor is provided in the dehumidifier 3, and the internal circulation system stops operating when the humidity of the air in the wardrobe body 1 reaches a set value. The inner circulation system stops working, the outer circulation system is opened, that is, the first air inlet 3111 and the first air outlet 3121 are closed, the second air inlet 3112 and the second air outlet 3113 are opened at the same time, the second exhaust fan 39 at the second air outlet 3113 is used for exhausting air, the air outside the wardrobe body 1 enters from the second air inlet 3112, passes through the sealed cavity 321a in the dehumidifying device 3, the moisture condensed out of the refrigerator 322 is exhausted to the outside of the wardrobe body 1 from the second air outlet 3113, and the moisture remained in the sealed cavity 321a of the dehumidifying device 3 is removed.

In this embodiment, the principle of implementing the drying and dehumidifying of the intelligent wardrobe 100 is as follows: the inner circulation system is opened, the outer circulation system is closed, that is, the first air inlet 3111 and the first air outlet 3121 are opened, the second air inlet 3112 and the second air outlet 3113 are closed at the same time, the first exhaust fan 38 at the first air outlet 3121 is used for exhausting air, so that the air inside the wardrobe body 1 flows circularly, the air inside the wardrobe body 1 enters from the first air inlet 3111, passes through the sealed cavity 321a in the dehumidifying device 3, the moisture in the air passing through the sealed cavity 321a in the dehumidifying device 3 is condensed out by the refrigerator 322, and the dry air enters into the wardrobe body 1 from the first air outlet 3121, so that the air inside the wardrobe body 1 is dried.

The above description is only an alternative embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. An intelligent wardrobe, comprising:

the wardrobe body is provided with a placing cavity for placing clothes;

the disinfection and sterilization device is arranged in the placing cavity and comprises a shell, an ultraviolet disinfection and sterilization light source and an ozone generator, the shell is provided with an accommodating cavity and a lamp hole, the lamp hole is communicated with the placing cavity and the accommodating cavity, the ultraviolet disinfection and sterilization light source is arranged in the accommodating cavity and corresponds to the lamp hole, and the ozone generator is arranged in the accommodating cavity and is spaced from the ultraviolet disinfection and sterilization light source; and

the dehumidifying device is arranged in the wardrobe main body and comprises a shell and a refrigerating structure, the shell is provided with an installation cavity, a first air inlet and a first air outlet, the first air inlet and the first air outlet are communicated with the installation cavity, the refrigerating structure is arranged in the installation cavity, and the first air inlet and the first air outlet are communicated with the placing cavity;

the disinfection and sterilization device also comprises a circuit board arranged in the containing cavity, the circuit board is arranged at intervals with the ozone generator and the ultraviolet sterilization light source, and the circuit board is electrically connected with the ozone generator and the ultraviolet sterilization light source.

2. The intelligent wardrobe according to claim 1, wherein the disinfection and sterilization apparatus further comprises an ozone detection sensor disposed on the circuit board, wherein the ozone detection sensor is configured to detect a concentration of ozone.

3. The intelligent wardrobe according to claim 1, wherein the housing is provided with a plurality of through holes arranged at intervals, and the plurality of through holes are arranged around the lamp hole and communicated with the placing cavity and the accommodating cavity.

4. The intelligent wardrobe according to any one of claims 1 to 3, wherein the outer casing is further provided with a second air inlet and a second air outlet communicating with the installation cavity, the dehumidifying device further comprises a first valve body for opening or closing the first air inlet and for opening or closing the second air inlet, and a second valve body for opening or closing the first air outlet and for opening or closing the second air outlet, the second air inlet and the second air outlet communicating to the outside of the wardrobe body.

5. The intelligent wardrobe of claim 4, wherein the cooling structure comprises:

the sealing shell is arranged in the mounting cavity and provided with a sealing cavity, a first air port and a second air port, and the first air port and the second air port are communicated with the sealing cavity; and

the refrigerator is arranged in the sealing cavity;

the first valve body opens a first air inlet and closes the second air inlet to enable the first air port to be communicated with the first air inlet, the second valve body opens the first air outlet and closes the second air outlet to enable the second air port to be communicated with the first air outlet, and therefore the placing cavity, the first air inlet, the first air port, the sealing cavity, the second air port and the first air outlet form an internal circulation flow channel; or the first valve body closes the first air inlet and opens the second air inlet to enable the first air port to be communicated with the second air inlet, the second valve body closes the first air outlet and opens the second air outlet to enable the second air port to be communicated with the second air outlet, and therefore the second air inlet, the first air port, the sealing cavity, the second air port and the second air outlet form an external circulation flow channel.

6. The intelligent wardrobe according to claim 5, wherein the dehumidifying device further comprises a heat sink disposed in the installation cavity, the heat sink being connected to an outer wall of the enclosure and disposed corresponding to the refrigerator;

and/or, the dehumidification device also comprises a cooling fan arranged in the mounting cavity, and the cooling fan is arranged corresponding to the refrigerator.

7. The intelligent wardrobe of claim 5, wherein the dehumidifying device further comprises a temperature and humidity sensor disposed in the mounting cavity, wherein the temperature and humidity sensor is disposed at the first air inlet.

8. The intelligent wardrobe of claim 5, wherein the dehumidifying apparatus further comprises a first exhaust fan disposed in the mounting cavity, the first exhaust fan being disposed in correspondence to the first air outlet;

and/or, the dehumidifying device further comprises a second exhaust fan arranged in the mounting cavity, and the second exhaust fan is arranged corresponding to the second air outlet.

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