CN219845581U - Intelligent wardrobe with multi-region and multi-region temperature control function - Google Patents

Abstract

The utility model discloses an intelligent wardrobe with multiple areas and temperature control areas, which comprises a wardrobe body, wherein a cavity is formed in the wardrobe body, a partition board is arranged in the cavity and divides the cavity into a plurality of cavities, and the intelligent wardrobe further comprises: the nursing equipment comprises a fan, a first heater and a controller, wherein the fan and the first heater are respectively and electrically connected with the controller, the fan is provided with an air inlet and an air outlet, and the first heater is positioned at the air outlet; the air outlet is communicated with the air supply channel, the air supply channel is provided with a plurality of air supply openings, each air supply opening is respectively communicated with one cavity, and an air supply air valve is arranged at each air supply opening and is movably connected with the inner wall surface of the air supply channel; the air inlet is communicated with the air return channel, the air return channel is provided with a plurality of air return inlets, each air return inlet is respectively communicated with one cavity, each air return inlet is provided with an air return valve, and the air return valves are movably connected with the inner wall surface of the air return channel. The utility model can realize intelligent control of different chamber temperatures.

Description

Intelligent wardrobe with multi-region and multi-region temperature control function

Technical Field

The utility model relates to the technical field of intelligent wardrobes, in particular to an intelligent wardrobes with multiple areas for controlling temperature in a partitioning mode.

Background

The wardrobe is furniture for storing clothes, most of the existing wardrobe is provided with a partition plate, and the space for storing the clothes is divided into a plurality of areas so as to realize classified placement. However, the internal temperature of the existing wardrobe changes according to the indoor air temperature, which is not beneficial to nursing various clothes in the wardrobe.

Although some intelligent air-conditioning garderobe exist at present, the space inside the garderobe can be heated or cooled, the garderobe in a plurality of placing areas is provided, the temperature required for nursing of articles placed in each placing area is different, the existing intelligent air-conditioning garderobe can only heat or cool the whole garderobe, and the problem that different temperatures are required in different placing spaces cannot be solved.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the utility model provides the intelligent wardrobe with the multi-region and the temperature control function.

The utility model solves the technical problems as follows:

the utility model provides an intelligent wardrobe of multizone subregion accuse temperature, includes the cabinet body, cabinet body cavity forms the cavity, be equipped with the baffle in the cavity, the baffle will a plurality of cavities are separated into to the cavity, still includes:

the nursing equipment comprises a fan, a first heater and a controller, wherein the fan and the first heater are respectively and electrically connected with the controller, the fan is provided with an air inlet and an air outlet, and the first heater is positioned at the air outlet;

the air outlet is communicated with the air supply channel, the air supply channel is provided with a plurality of air supply openings, each air supply opening is respectively communicated with one cavity, an air supply valve is arranged at each air supply opening, and the air supply valves are movably connected with the inner wall surface of the air supply channel to close or open the air supply openings;

the air inlet is communicated with the air return channel, the air return channel is provided with a plurality of air return inlets, each air return inlet is respectively communicated with one cavity, each air return inlet is provided with an air return valve, and the air return valves are movably connected with the inner wall surface of the air return channel so as to close or open the air return inlets.

The utility model has at least the following beneficial effects: the air supply channel and the air return channel are communicated with each cavity of the cabinet body, air blown by the fan can enter each cavity through the air supply channel after being heated and flow back to the fan through the air return channel, so that gas circulation in the cavity is realized, and the temperature in the cavity is increased; because the air supply channel is provided with the air supply air valve, and the air return channel is provided with the air return air valve, the air supply air valve and the air return air valve of the cavity needing to be heated are opened, and hot air can smoothly enter the cavity needing to be heated, so that the purpose of temperature increase is achieved; for the chambers which do not need to be heated, the air supply air valve and the air return air valve are closed, so that hot air can be prevented from entering, the effect of controlling the temperature of each chamber respectively is achieved, each chamber can be in different temperature states, and the area where each article is placed can meet the nursing requirement; in addition, after the part of the air supply air valve and the return air valve are closed, hot air more intensively enters the cavity needing to be heated from the opened air supply air valve, and the efficiency of nursing equipment can be greatly improved.

As a further improvement of the technical scheme, the intelligent wardrobe with the multi-region regional temperature control function further comprises an air supply fan and an air return fan, wherein the air supply fan and the air return fan are respectively provided with a plurality of air supply fans which are respectively arranged at the air supply opening, the air return fans are respectively arranged at the air return opening, and the air supply fan and the air return fan are respectively electrically connected with the controller. The air supply fan and the air return fan are arranged, so that the flow of air in the cavity can be accelerated, the air circulation is accelerated, and the efficiency of nursing equipment is further improved.

As a further improvement of the above technical solution, the air supply port in the same chamber is located below the air return port. Because the hot air floats upwards, the arrangement can accelerate the hot air to move from the air supply outlet to the air return outlet, thereby accelerating the gas circulation.

As a further improvement of the above technical solution, the care apparatus further comprises a dehumidifying component, the dehumidifying component being located at the air inlet of the blower. The dehumidifying component is arranged, so that the air flow entering the fan can be dehumidified, each chamber can reach proper humidity, and the condition that articles get moldy due to overhigh humidity in the chamber is avoided.

As a further improvement of the above technical solution, the care apparatus further includes a filter screen, where the filter screen is disposed between the air inlet and the return air channel. The filter screen can filter the gas that gets into the fan, reduces impurity and gets into in the fan, plays the effect of protection to the fan, moreover, can also purify circulating gas effectively, keeps the cleanness in the cavity.

As a further improvement of the technical scheme, the air supply channel and the air return channel are both arranged on the rear side wall surface of the cabinet body. The air supply channel and the air return channel are arranged at the rear side of the cabinet body, so that the intelligent wardrobe with the temperature controlled by the multi-area partition is more attractive as a whole, and the space in the cavity can be used for placing articles to a greater extent.

As a further improvement of the technical scheme, each chamber is internally provided with a temperature and humidity sensor and a second heater, the second heater is arranged at the air supply opening, and the temperature and humidity sensor and the second heater are respectively and electrically connected with the controller. The temperature and humidity sensor detects the temperature and humidity of the chamber, so that whether the temperature in the chamber reaches the required temperature can be accurately known, and the second heater is arranged, so that the gas which is about to enter a certain chamber can be further heated, and the temperature in the chamber is increased.

As a further improvement of the technical scheme, the intelligent wardrobe with the multi-region temperature control function further comprises a movable cabinet and a lifting driving mechanism, wherein the movable cabinet is arranged on the upper portion of the cavity and is in sliding connection with the inner side wall surface of the cavity, the lifting driving mechanism is electrically connected with the controller, and the output end of the lifting driving mechanism is connected with the movable cabinet so as to drive the movable cabinet to move in the cavity along the up-down direction. The movable cabinet and the lifting driving mechanism are arranged, so that a user can more conveniently take and place articles located at the cabinet body, and the user can more fully utilize the space of the cabinet body.

As a further improvement of the technical scheme, the intelligent wardrobe with the multi-region regional temperature control function further comprises a barrier inductor, wherein the barrier inductor is arranged in the cavity and positioned below the movable wardrobe, and the barrier inductor is electrically connected with the controller. The obstacle inductor can sense whether the obstacle exists below the movable cabinet, so that the movable cabinet is prevented from descending and colliding with the obstacle placed below the movable cabinet.

As a further improvement of the above technical solution, the obstacle sensor includes an infrared emitter and an infrared receiver, where the infrared emitter and the infrared receiver are disposed opposite to each other in the inner side of the cavity, and the infrared emitter and the infrared receiver are electrically connected to the controller respectively. The obstacle below the movable cabinet is detected through infrared rays, and when the obstacle below the movable cabinet prevents the movable cabinet from descending, the obstacle can block the infrared receiver to receive the infrared rays emitted by the infrared emitter, so that the effect of detecting the obstacle is achieved.

As a further improvement of the technical scheme, the cabinet body comprises a main body framework and a panel, wherein the main body framework is of a metal pipe structure, the panel is made of wood materials, and the panel is wrapped on the outer side of the main body framework so as to form the cavity. The wire of nursing equipment in the intelligent wardrobe of multizone subregion accuse temperature can lay in main part skeleton to can hide the wire, let the intelligent wardrobe of multizone subregion accuse temperature whole more pleasing to the eye, moreover, this structure can let the cabinet body be firm more, firm.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present utility model, the drawings that are required to be used in the description of the embodiments will be briefly described below. It is evident that the drawings described are only some embodiments of the utility model, but not all embodiments, and that other designs and drawings can be obtained from these drawings by a person skilled in the art without inventive effort.

FIG. 1 is a schematic diagram of the overall structure of a multi-zone temperature-controlled intelligent wardrobe according to an embodiment of the utility model;

FIG. 2 is a schematic diagram of the overall structure of the multi-region, zoned, temperature-controlled intelligent wardrobe according to an embodiment of the utility model under another angle;

FIG. 3 is a front view of the multi-zone temperature control intelligent wardrobe according to the embodiment of the utility model, with the cabinet door omitted;

FIG. 4 is a schematic diagram of the multi-region, temperature-controlled intelligent wardrobe according to an embodiment of the utility model after a cabinet door is omitted;

FIG. 5 is a cross-sectional view taken along the direction A-A in FIG. 3;

FIG. 6 is an enlarged schematic view of a portion C of FIG. 5;

FIG. 7 is a cross-sectional view taken in the direction B-B of FIG. 4;

FIG. 8 is a partially enlarged schematic illustration of portion D of FIG. 7;

fig. 9 is a schematic structural view of a nursing apparatus according to an embodiment of the present utility model;

fig. 10 is a top view of a care apparatus of an embodiment of the present utility model;

fig. 11 is a schematic view of the movable cabinet in a lowered state according to the embodiment of the present utility model.

Reference numerals: 100. a cabinet body; 110. a cabinet door; 120. a chamber; 121. an infrared emitter; 122. an infrared receiver; 130. a partition plate; 140. a clothes hanging rod; 200. an air supply channel; 210. an air supply port; 211. an air supply air valve; 212. an air supply fan; 213. a second heater; 300. a return air channel; 310. an air return port; 311. a return air valve; 312. a return air fan; 400. a movable cabinet; 410. a lifting driving mechanism; 500. a blower; 510. a first heater; 520. a compressor; 530. a condenser; 540. an evaporator; 550. and (5) a filter screen.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are exemplary only for explaining the present utility model and are not to be construed as limiting the present utility model.

In the description of the present utility model, references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, only for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or element in question must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, a number means one or more, a number means two or more, and greater than, less than, exceeding, etc. are understood to not include the present number, and above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed 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.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

It is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and that other embodiments obtained by those skilled in the art without inventive effort are within the scope of the present utility model based on the embodiments of the present utility model. The technical features of the utility model can be interactively combined on the premise of no contradiction and conflict.

Referring to fig. 1 to 11, an embodiment of the present utility model provides a multi-region and multi-region temperature-controlling intelligent wardrobe, which includes a wardrobe body 100, wherein a cavity for placing articles is formed in the wardrobe body 100, a plurality of partitions 130 are disposed in the cavity, and the partitions 130 divide the cavity into a plurality of chambers 120, which is beneficial for users to place articles in a classified manner. The intelligent wardrobe of multizone subregion accuse temperature in this embodiment can be respectively to nursing each cavity 120, lets the region that each article was placed all can satisfy the nursing demand.

Specifically, the intelligent wardrobe of multizone subregion accuse temperature in this embodiment still includes nursing equipment, and nursing equipment is including fan 500, first heater 510 and controller, and fan 500 is provided with air intake and air outlet, and first heater 510 sets up the air outlet department at fan 500, and the wind that fan 500 blown out can heat through first heater 510.

It can be appreciated that the fan 500 and the first heater 510 are electrically connected to a controller, which may be a single-chip microcomputer, a PLC controller, etc., so that the first heater 510 can be simply turned on or off.

In some embodiments, the first heater 510 is controlled to be turned on by a controller, the controller presets the on time of the first heater 510, and after the first heater 510 is turned on for a preset time, the controller controls the first heater 510 to be turned off.

In this embodiment, the intelligent wardrobe with multi-zone and zone temperature control further includes an air supply channel 200 and an air return channel 300. The air supply channel 200 is communicated with the air outlet of the blower 500, the air return channel 300 is communicated with the air inlet of the blower 500, the air supply channel 200 is provided with a plurality of air supply openings 210, the air supply openings 210 are communicated into the chambers 120, the air return channel 300 is provided with a plurality of air return openings 310, and the air return openings 310 are also communicated into the chambers 120. Namely, the chamber 120, the return air channel 300, the fan 500 and the air supply channel 200 form a circulating air flow channel, air in the chamber 120 enters the fan 500 through the return air channel 300 and is blown out through an air outlet of the fan 500, and enters the air supply channel 200 after being heated by the first heater 510 and then flows into the chamber 120, so that good air flow circulation is achieved, the temperature of the air in the chamber 120 is maintained, and the effect of removing mites is also achieved.

In this embodiment, each air supply port 210 is provided with an air supply valve 211, and the air supply valve 211 is movably connected to the inner wall surface of the air supply passage 200, so that the air supply port 210 can be closed or opened. It is understood that the air supply valve 211 may be manually opened or closed, or may be electrically controlled. In this embodiment, the air supply air valve 211 is provided with a first air valve motor and a first air valve plate, the output end of the first air valve motor is connected with the first air valve plate, the first air valve motor is electrically connected with the controller, and the first air valve plate can rotate under the driving action of the first air valve motor.

It will be appreciated that when the first air valve plate rotates to a position perpendicular to the flow direction, the first air valve plate blocks the air supply channel 200, the air supply port 210 is closed, and as shown in fig. 6, the air in the air supply channel 200 cannot be blown out from the air supply port 210 into the chamber 120; when the first air valve plate rotates to a position parallel to the pipe wall of the air supply channel 200, the air supply port 210 is opened, and the air in the air supply channel 200 can be smoothly blown into the chamber 120 from the air supply port 210, so that the circulation and heating of the air flow in the chamber 120 are realized.

In addition, each air inlet is provided with an air return valve 311, and the air return valve 311 is movably connected with the inner wall surface of the air return channel 300, and can be controlled manually or electrically. In this embodiment, the return air valve 311 is electrically controlled, and has a specific structure similar to the supply air valve 211, and includes a second air valve plate and a second air valve motor. The second air valve plate is connected with the output end of the second air valve motor, the second air valve motor is electrically connected with the controller, and the second air valve plate can rotate under the driving action of the second air valve motor.

When the second air valve plate rotates to a position perpendicular to the air flowing direction, the second air valve plate blocks the return air channel 300, the return air inlet 310 is closed, and air in the chamber 120 cannot be blown into the return air channel 300 from the return air inlet 310; when the second air valve plate rotates to a position parallel to the pipe wall of the air return channel 300, the air return port 310 is opened, and as shown in fig. 8, the dotted arrow indicates the air flow direction, so that the air in the chamber 120 can smoothly enter the air return channel 300, and the circulation and heating of the air flow in the chamber 120 are realized.

It will be appreciated that when the return air valve 311 and the supply air valve 211 of one or more of the chambers 120 are closed, the one or more chambers 120 will not circulate and heat the air, and the chambers 120 opened by the return air valve 311 and the supply air valve 211 can circulate and heat the air, so that the zoned temperature control nursing of different areas can be realized, and the nursing of different articles with different nursing temperature requirements can be well carried out in different chambers 120. By the arrangement, the air quantity waste and loss can be reduced, hot air is intensively introduced into the cavity 120 which needs to be heated and air-dried, and the efficiency of nursing equipment is greatly improved.

In some embodiments, the intelligent wardrobe with multi-zone and zone temperature control further includes an air supply fan 212 and a return air fan 312, wherein the air supply fan 212 and the return air fan 312 are respectively provided with a plurality of air supply fans 212 and the return air fan 312 respectively electrically connected with the controller. Wherein the supply fan 212 is disposed at the supply port 210, and the return fan 312 is disposed at the return port 310.

It can be appreciated that the air supply fan 212 and the air return fan 312 can accelerate the air flow in the chamber 120, so that the hot air in the air supply channel 200 flows into the chamber 120 to be heated and dried, and the air flow leaves the chamber 120 from the air return channel 300 rapidly, thereby accelerating the air circulation and greatly improving the efficiency of the nursing equipment.

It will be appreciated that the return air fan 312 and the air supply fan 212 of each chamber 120 are independent, so that a user can select a chamber 120 to be heated and air-dried, and turn on the air supply fan 212 and the return air fan 312 of the chamber 120, while other chambers 120 not to be heated and air-dried turn off the air supply fan 212 and the return air fan 312, thereby greatly saving electricity consumption and reducing waste.

In some embodiments, a temperature and humidity sensor and a second heater 213 are respectively disposed in each chamber 120, the second heater 213 is disposed at the air supply port 210, and the temperature and humidity sensor is disposed on the inner wall of the chamber 120. It can be appreciated that the temperature and humidity sensor and the second heater 213 are electrically connected to the controller, respectively, where the temperature and humidity sensor is used to detect the temperature and humidity in the chamber, and transmit the detected temperature and humidity data to the controller, and the controller controls whether to turn on the second heater 213 according to a preset temperature and humidity value, so as to further regulate and control the temperature and humidity in the chamber 120, and more accurately ensure that the temperature and humidity in the chamber 120 reaches the temperature and humidity required for nursing the articles.

It will be appreciated that the second heater 213 can further heat the gas to be introduced into a certain chamber 120, so as to compensate for the heat dissipation of the hot air during the flowing process of the air supply passage 200, and accelerate the temperature rise in the chamber 120.

It can be understood that the second heaters 213 in each chamber 120 are independent, and the second heaters 213 in each chamber 120 are turned on or off independently, so that a user can preset the temperature and humidity value of each chamber 120 according to actual requirements, and the temperature and humidity values of each chamber 120 can be the same or different.

In the present embodiment, in one chamber 120, the air supply port 210 is disposed below the air return port 310. Because the chamber 120 is usually cleaned by circulating hot air, the air return opening 310 is disposed above the air supply opening 210, which is beneficial for the hot air to float upwards, so as to accelerate circulation.

It should be understood that the air supply port 210 and the air return port 310 may be disposed on the rear wall surface of the chamber 120, or may be disposed on the upper wall surface, the lower wall surface, the left wall surface, or the right wall surface of the chamber 120, which is not particularly limited herein.

In this embodiment, the air supply channel 200 and the air return channel 300 are disposed on the rear side wall surface of the cabinet body 100, and the whole intelligent wardrobe with the temperature controlled by the multi-area partition can be more beautiful through shielding the rear side wall surface of the cabinet body 100.

In this embodiment, the care apparatus further includes a dehumidifying component, which is used for reducing the humidity of the hot air, and is installed between the air inlet of the blower 500 and the return air channel 300, so as to perform a dehumidifying function, keep the interior of the chamber 120 dry, and avoid the mildewing of the chamber 120.

Specifically, as shown in fig. 9 and 10, the dotted arrow indicates the direction of the air flow, the dehumidifying component includes a compressor 520, an evaporator 540, a condenser 530, a throttle valve, and the like, the compressor 520 has an air outlet and an air inlet, the air outlet of the compressor 520 is connected with the inlet of the condenser 530, the outlet of the condenser 530 is connected with the inlet of the throttle valve, the outlet of the throttle valve is connected with the inlet of the evaporator 540, the outlet of the evaporator 540 is connected with the air inlet of the compressor 520, the refrigerant circulates in the dehumidifying component in a closed manner, the air passes through the evaporator 540 first and then passes through the condenser 530 to realize dehumidification, and the dry air is sucked through the air inlet of the fan 500 and then flows to the air supply channel 200 through the air outlet of the fan 500, so that the humidity of the chamber 120 can be reduced to a proper humidity value.

In addition, the compressor 520 has good dehumidification effect, the water outlet of the compressor can be communicated with a drain pipe in a home, and generated condensed water can directly flow into the drain pipe without frequent water pouring of a user, so that the use experience of the user is improved.

In some embodiments, the care apparatus further includes a filter screen 550, where the filter screen 550 is disposed between the air inlet of the blower 500 and the return air channel 300, and can filter the air entering the blower 500, reduce impurities entering the blower 500, protect the blower 500, and effectively purify the circulating air, keep the chamber 120 clean, and play a role in removing mites.

In this embodiment, the care devices such as the dehumidifying component, the fan 500, the first heater 510 and the like are installed in a device box, the device box has an inlet and an outlet, the air inlet of the fan 500 faces the inlet of the device box, the air outlet of the fan 500 faces the outlet of the device box, the inlet of the device box is communicated with the return air channel 300, the outlet of the device box is communicated with the air supply channel 200, the first heater 510 in this embodiment is installed at the outlet of the device box, the filter screen 550 is installed at the inlet of the device box, the filter screen 550 covers the inlet of the device box, the dehumidifying component is installed at the space between the air inlet of the fan 500 and the inlet of the device box, and the air before dehumidification is filtered by the filter screen 550 and can also protect the dehumidifying component.

In this embodiment, in order to more facilitate the user to take and place the articles at the high position of the cabinet body 100, the intelligent wardrobe with multi-region temperature control further comprises a movable cabinet 400 and a lifting driving mechanism 410, wherein the movable cabinet 400 is disposed at the upper portion of the cavity and is slidably connected with the inner side wall surface of the cavity, the lifting driving component is mounted at the rear side of the cabinet body 100, the output end of the lifting driving mechanism 410 is connected with the movable cabinet 400, and the movable cabinet 400 can move in the up-down direction in the cavity under the driving action of the lifting driving mechanism 410.

It can be appreciated that the lifting driving component is installed at the rear side of the cabinet body 100, so that the whole intelligent cabinet with multi-region and multi-region temperature control is more attractive. The rear wall surface of the cavity is provided with a connecting rail, the connecting rail extends along the up-down direction, the movable cabinet 400 and the lifting driving component are connected through the connecting rail, and the overall attractiveness of the cabinet body 100 is not affected, and the up-down movement of the movable cabinet 400 is not affected.

It is understood that the lifting driving component is electrically connected to the controller, and the lifting driving component may be a lifting motor, a cylinder, etc., which is not limited herein.

In this embodiment, four movable cabinets 400 are provided, the four movable cabinets 400 are arranged in the left-right direction, and the four movable cabinets 400 are driven by one lifting driving component respectively, that is, four lifting driving components are provided at the rear side of the cabinet body 100, and the four lifting driving components are electrically connected with the controller respectively, and the four lifting driving components are mutually independent. A user may control one or more of the lifting driving parts as needed to realize lifting of one or more of the movable cabinets 400. When the movable cabinet 400 descends, as shown in the leftmost movable cabinet 400 in fig. 11, a user can conveniently take and put articles in the movable cabinet 400.

It will be appreciated that the number of movable cabinets 400 may be one, two, or other numbers, without limitation. One elevation driving part may drive a plurality of movable cabinets 400 at the same time, or may control the elevation of one movable cabinet 400, which is not particularly limited.

In this embodiment, an obstacle sensor is disposed in the cavity and is used to sense whether an obstacle exists below the movable cabinet 400, so as to avoid the movable cabinet 400 from colliding with an article placed below the movable cabinet 400 when descending.

It can be understood that the obstacle sensor is electrically connected to the controller, when the obstacle sensor senses that an article is placed under the movable cabinet 400, a signal is transmitted to the controller, if the user wants to descend the movable cabinet 400, the controller sends a prompt signal to the user, so as to prompt the user to take out the article under the movable cabinet 400 first, and then control the movable cabinet 400 to descend.

In this embodiment, the obstacle sensor is disposed 5 to 10 mm below the lower limit of the movable cabinet 400, and the controller prompts the user to take out the object below the movable cabinet 400 when the object below the movable cabinet 400 is higher than the obstacle sensor.

It is understood that the obstacle sensor may be a grating sensor, an infrared sensor, or the like. In this embodiment, the obstacle sensor includes an infrared transmitter 121 and an infrared receiver 122, and the infrared receiver 122 and the infrared transmitter 121 are electrically connected to the controller respectively. In this embodiment, the infrared emitter 121 and the infrared receiver 122 are both installed on the side wall of the cavity, and are located on the left and right sides of the lower part of the movable cabinet 400, respectively, and are disposed opposite to each other, and the infrared emitter 121 can emit infrared rays, and the infrared receiver 122 can receive the infrared rays emitted from the infrared emitter 121. When the reception of the infrared rays is blocked, it means that there is an article below the movable cabinet 400 that can block the movable cabinet 400 from being lowered.

It can be appreciated that the obstacle sensor is configured with a prompter, such as an indicator light, a warning bell, etc., for prompting the user, and the prompter is electrically connected to the controller, and when the obstacle sensor senses that an obstacle is located below the movable cabinet 400, the controller controls the prompter to prompt the user in a visual, audible, etc. manner.

In this embodiment, the cabinet body 100 of the intelligent wardrobe with multi-region and multi-region temperature control is composed of a main body framework, a panel and a cabinet door 110, wherein the main body framework is of a steel pipe structure, the panel and the partition 130 are made of wood sheets, and the whole cabinet body 100 is stronger and firmer and has a reliable structure.

It can be appreciated that the use of the steel tube structure as the main body skeleton allows the circuitry for electrically connecting the controller to other mechanisms to be hidden within the hollow steel tube, resulting in a more aesthetically pleasing cabinet 100. Of course, the main body framework can be made of other metal materials.

The cavity in this embodiment is divided into seven chambers 120 by a partition 130, and the chambers 120 may be provided with a clothes hanging rod 140, etc., so as to facilitate the placement or hanging of clothes by a user. Seven chambers 120 have a main cabinet for holding large items of clothing, two drawer cabinets for holding small items of clothing, and four functional cabinets for holding other items of clothing. The equipment box in this embodiment is disposed below the main cabinet and at the space between the two drawer cabinets. The cabinet 100 thus arranged is beautiful and can also realize various clothes placing functions.

In this embodiment, the main cabinet and the drawer share one fan 500, and the four functional cabinets share another fan 500, so that the arrangement of the air supply channel 200 and the air return channel 300 is facilitated, and the air circulation function of each chamber 120 can be ensured. In other embodiments, the main cabinet, drawers, and functional cabinets may also share a single blower 500.

It can be understood that the intelligent wardrobe with multi-region and multi-region temperature control in the embodiment of the utility model can be controlled in a wireless or wired mode. In some embodiments, the controller is further connected with a wireless receiver, which may be an infrared receiver or a bluetooth receiver, etc., where the wireless receiver is in communication connection with a peripheral wireless transmitter, and the wireless transmitter may be an infrared remote controller or a terminal device with bluetooth, etc., which is not illustrated herein, and can control the mode change of the intelligent wardrobe with multi-area partition temperature control through wireless communication.

While the preferred embodiment of the present utility model has been described in detail, the utility model is not limited to the embodiments, and various equivalent modifications and substitutions can be made by those skilled in the art without departing from the spirit of the utility model, and these modifications and substitutions are intended to be included in the scope of the present utility model as defined in the appended claims.

Claims (11)

1. The utility model provides an intelligent wardrobe of multizone subregion accuse temperature, includes the cabinet body, cabinet body cavity forms the cavity, be equipped with the baffle in the cavity, the baffle will a plurality of cavities are separated into to the cavity, its characterized in that still includes:

the nursing equipment comprises a fan, a first heater and a controller, wherein the fan and the first heater are respectively and electrically connected with the controller, the fan is provided with an air inlet and an air outlet, and the first heater is positioned at the air outlet;

the air outlet is communicated with the air supply channel, the air supply channel is provided with a plurality of air supply openings, each air supply opening is respectively communicated with one cavity, an air supply valve is arranged at each air supply opening, and the air supply valves are movably connected with the inner wall surface of the air supply channel to close or open the air supply openings;

the air inlet is communicated with the air return channel, the air return channel is provided with a plurality of air return inlets, each air return inlet is respectively communicated with one cavity, each air return inlet is provided with an air return valve, and the air return valves are movably connected with the inner wall surface of the air return channel so as to close or open the air return inlets.

2. The intelligent wardrobe according to claim 1, further comprising a plurality of air supply fans and a plurality of air return fans, wherein the plurality of air supply fans are respectively arranged at the air supply opening, the plurality of air return fans are respectively arranged at the air return opening, and the air supply fans and the air return fans are respectively electrically connected with the controller.

3. The multi-zone temperature controlled intelligent closet of claim 1 wherein said supply air outlets in the same chamber are located below said return air inlets.

4. The multi-zone temperature-controlled intelligent wardrobe of claim 1, wherein the care facility further comprises a dehumidification component located at an air inlet of the blower.

5. The multi-zone temperature-controlled intelligent wardrobe of claim 1, wherein the care facility further comprises a filter screen disposed between the air inlet and the return air channel.

6. The multi-zone temperature-controlled intelligent wardrobe of claim 1, wherein the supply air channel and the return air channel are both disposed on a rear sidewall surface of the wardrobe body.

7. The intelligent wardrobe with multi-region and zone temperature control according to claim 1, wherein each chamber is provided with a temperature and humidity sensor and a second heater, the second heater is arranged at the air supply opening, and the temperature and humidity sensor and the second heater are respectively and electrically connected with the controller.

8. The intelligent wardrobe of claim 1, further comprising a movable cabinet and a lifting driving mechanism, wherein the movable cabinet is arranged on the upper portion of the cavity and is in sliding connection with the inner side wall surface of the cavity, the lifting driving mechanism is electrically connected with the controller, and an output end of the lifting driving mechanism is connected with the movable cabinet to drive the movable cabinet to move in the vertical direction in the cavity.

9. The multi-zone temperature-controlled intelligent wardrobe of claim 8, further comprising a barrier sensor disposed within the cavity and below the movable cabinet, the barrier sensor being electrically connected to the controller.

10. The intelligent wardrobe according to claim 9, wherein the obstacle sensor comprises an infrared transmitter and an infrared receiver, the infrared transmitter and the infrared receiver are disposed on the inner side of the cavity opposite to each other, and the infrared transmitter and the infrared receiver are electrically connected to the controller respectively.

11. The multi-zone temperature-controlled intelligent wardrobe of claim 1, wherein the wardrobe body comprises a main body framework and a panel, the main body framework is of a metal pipe structure, the panel is made of wood materials, and the panel is wrapped on the outer side of the main body framework to form the cavity.