CN113418259A

CN113418259A - Device for adjusting humidity

Info

Publication number: CN113418259A
Application number: CN202110580538.4A
Authority: CN
Inventors: 殷鹏飞; 王海胜; 张中晓; 孙庆; 蔡艳芳; 滕兆龙; 代传民; 孙萍; 孙文志
Original assignee: Qingdao Haier Air Conditioner Gen Corp Ltd; Qingdao Haier Air Conditioning Electric Co Ltd; Haier Smart Home Co Ltd
Current assignee: Qingdao Haier Air Conditioner Gen Corp Ltd; Qingdao Haier Air Conditioning Electric Co Ltd; Haier Smart Home Co Ltd
Priority date: 2021-03-22
Filing date: 2021-05-26
Publication date: 2021-09-21
Also published as: CN215336790U; CN113418246A; CN113432271A; CN115111670A; CN113418260A; CN113375242A; CN113418295A; CN113418245A; CN216132007U; CN215336795U; CN113418277A; CN113375315B; CN216132008U; CN113418260B; CN113324291A; CN113418295B; CN113418278B; CN113418246B; CN113432270B; CN113432270A

Abstract

The application relates to the technical field of humidity control, and discloses a device for humidifying, includes: a housing and a moisture absorption rotary disc. The shell internally defines a first flow passage and a second flow passage; the moisture absorption rotary disc is rotatably arranged in the housing, part of the moisture absorption rotary disc is positioned in the first flow passage, and the rest part of the moisture absorption rotary disc is positioned in the second flow passage; wherein, an axial ascending terminal surface along the moisture absorption carousel has first air inlet end, first air-out end, second air inlet end and second air-out end. In this application, the equal twice moisture absorption carousel that passes of air current that enables to pick up moisture and humidification improves the contact time of air current and moisture absorption carousel, and moisture can be adsorbed by the more efficient in making the air current to and the moisture that absorbs can more efficient regeneration play in the moisture absorption carousel is taken away by the air current, thereby has improved the efficiency of humidification or dehumidification.

Description

Device for adjusting humidity

Technical Field

The application relates to the technical field of humidity adjustment, in particular to a device for adjusting humidity.

Background

At present, some commercial areas such as markets or warehouses often have different requirements on the humidity of the internal air, but the fluctuation of the humidity in the indoor air is large along with the change of seasons, so that the humidity of the internal space needs to be adjusted, for example, a humidifier and a dehumidifier are adopted for humidifying or dehumidifying, and two independent devices such as the humidifier and the dehumidifier are adopted for humidifying and dehumidifying the environment, so that the space occupation is large, and the cost is high.

In the related art, an air flow channel is arranged to replace indoor air and outdoor air, the air flow passes through a moisture absorption rotary disc arranged in the air flow channel in the replacement process, and the moisture in the outdoor air can be absorbed by the moisture absorption rotary disc and released into the indoor air, or the moisture in the indoor air can be absorbed and released out of the room, so as to humidify or dehumidify the indoor air.

Therefore, how to improve the efficiency of moisture adsorption and regeneration in humidity control is a problem to be solved by those skilled in the art.

Disclosure of Invention

The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview nor is intended to identify key/critical elements or to delineate the scope of such embodiments but rather as a prelude to the more detailed description that is presented later.

The embodiment of the disclosure provides a humidity control device to improve the efficiency of moisture adsorption and regeneration, and further improve the efficiency of humidification or dehumidification.

In some embodiments, the apparatus for conditioning moisture comprises: a housing and a moisture absorption rotary disc. The shell internally defines a first flow passage and a second flow passage; the moisture absorption rotary disc is rotatably arranged in the housing, part of the moisture absorption rotary disc is positioned in the first flow passage, and the rest part of the moisture absorption rotary disc is positioned in the second flow passage; wherein, an axial ascending terminal surface along the moisture absorption carousel has first air inlet end, first air-out end, second air inlet end and second air-out end.

The device for adjusting humidity provided by the embodiment of the disclosure can achieve the following technical effects:

hygroscopic air current can pass in the moisture absorption carousel gets into first runner through first air inlet end, then pass the moisture absorption carousel again and blow out through first air-out end, the air current of humidification can pass the moisture absorption carousel through second air inlet end and get into in the second runner, then pass the moisture absorption carousel again and blow out through second air-out end, the equal twice moisture absorption carousel that passes of air current that makes needs moisture absorption and humidification, the contact time of air current and moisture absorption carousel is improved, make moisture can more efficient adsorbed in the air current, and absorbent moisture can more efficient regeneration be taken away by the air current in the moisture absorption carousel, thereby the efficiency of humidification or dehumidification has been improved.

The foregoing general description and the following description are exemplary and explanatory only and are not restrictive of the application.

Drawings

One or more embodiments are illustrated by way of example in the accompanying drawings, which correspond to the accompanying drawings and not in limitation thereof, in which elements having the same reference numeral designations are shown as like elements and not in limitation thereof, and wherein:

FIG. 1 is a cross-sectional view of an apparatus for conditioning moisture provided by an embodiment of the present disclosure;

fig. 2 is a schematic structural view of a lower end face of a moisture absorption rotary disc provided by the embodiment of the disclosure;

fig. 3 is a schematic structural diagram of a heating portion provided in an embodiment of the present disclosure;

FIG. 4 is a schematic structural diagram of a partition mechanism and a housing according to an embodiment of the disclosure;

fig. 5 is a schematic structural diagram of a first partition plate and a second partition plate provided in the embodiment of the present disclosure;

fig. 6 is a schematic position diagram of a first air inlet end, a first air outlet end, a second air inlet end, and a second air outlet end provided in the embodiment of the present disclosure;

fig. 7 is an exploded schematic view of a hygroscopic rotating disc provided by an embodiment of the present disclosure;

fig. 8 is a schematic structural diagram of a first driving portion and a second driving portion provided in the embodiment of the present disclosure;

FIG. 9 is a schematic structural diagram of a mounting base provided by an embodiment of the present disclosure;

FIG. 10 is a schematic view of another apparatus for conditioning humidity provided by the embodiments of the present disclosure;

fig. 11 is a schematic structural view of a partition panel provided in an embodiment of the present disclosure;

FIG. 12 is a schematic view of another humidity conditioning apparatus provided by an embodiment of the present disclosure;

fig. 13 is a schematic structural diagram of a purification mechanism provided in an embodiment of the present disclosure.

Reference numerals:

100. a housing; 110. a first flow passage; 120. a second flow passage; 130. a first air inlet end; 140. a first air outlet end; 150. a second air inlet end; 160. a second air outlet end; 170. a mounting seat; 200. a moisture absorption turntable; 210. a frame portion; 220. a turntable part; 300. a heating section; 310. mica electric heating sheets; 311. an airway; 400. a partition mechanism; 410. a first separator; 420. a second separator; 421. a first plate; 422. a second plate; 430. a connecting frame; 431. a first frame; 432. a second frame; 500. a first driving section; 510. a connecting disc; 511. a first annular rack; 520. a first motor; 600. a second driving section; 610. a transmission disc; 611. a second annular rack; 620. an output shaft; 630. a second motor; 700. a housing; 701. a first air inlet; 702. a first air outlet; 703. a second air inlet; 704. a second air outlet; 710. a first airflow chamber; 720. a second airflow chamber; 730. a third airflow chamber; 740. a fourth airflow chamber; 750. a partition panel; 751. a first vent; 752. a second vent; 800. a purification mechanism; 810. a mounting frame; 820. an activated carbon adsorption plate.

Detailed Description

So that the manner in which the features and elements of the disclosed embodiments can be understood in detail, a more particular description of the disclosed embodiments, briefly summarized above, may be had by reference to the embodiments, some of which are illustrated in the appended drawings. In the following description of the technology, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the disclosed embodiments. However, one or more embodiments may be practiced without these details. In other instances, well-known structures and devices may be shown in simplified form in order to simplify the drawing.

The terms "first," "second," and the like in the description and in the claims, and the above-described drawings of embodiments of the present disclosure, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the present disclosure described herein may be made. Furthermore, the terms "comprising" and "having," as well as any variations thereof, are intended to cover non-exclusive inclusions.

In the embodiments of the present disclosure, the terms "upper", "lower", "inner", "middle", "outer", "front", "rear", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings. These terms are used primarily to better describe the disclosed embodiments and their examples and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation. Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meanings of these terms in the embodiments of the present disclosure can be understood by those of ordinary skill in the art as appropriate.

In addition, the terms "disposed," "connected," and "secured" are to be construed broadly. For example, "connected" may be a fixed connection, a detachable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. Specific meanings of the above terms in the embodiments of the present disclosure can be understood by those of ordinary skill in the art according to specific situations.

The term "plurality" means two or more unless otherwise specified.

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments of the present disclosure may be combined with each other.

In some embodiments, and as shown in conjunction with fig. 1-6, an apparatus for conditioning moisture, comprises: a housing 100 and a moisture absorbing turntable 200. The housing 100 defines a first flow passage 110 and a second flow passage 120 therein; the moisture absorption rotary disc 200 is rotatably arranged in the housing 100, and part of the moisture absorption rotary disc is positioned in the first flow passage 110, and the rest part of the moisture absorption rotary disc is positioned in the second flow passage 120; wherein, one end surface along the axial direction of the moisture absorption rotary disc 200 has a first air inlet end 130, a first air outlet end 140, a second air inlet end 150 and a second air outlet end 160.

By adopting the device for adjusting humidity provided by the embodiment of the disclosure, the moisture-absorbing airflow can pass through the moisture-absorbing turntable 200 through the first air inlet end 130 and enter the first flow channel 110, then pass through the moisture-absorbing turntable 200 again and blow out through the first air outlet end 140, the humidified airflow can pass through the moisture-absorbing turntable 200 through the second air inlet end 150 and enter the second flow channel 120, then pass through the moisture-absorbing turntable 200 again and blow out through the second air outlet end 160, so that the airflow needing moisture absorption and humidification passes through the moisture-absorbing turntable 200 twice, the contact time of the airflow and the moisture-absorbing turntable 200 is prolonged, the moisture in the airflow can be absorbed more efficiently, and the moisture absorbed in the moisture-absorbing turntable 200 can be regenerated more efficiently and taken away by the airflow, thereby improving the humidifying or dehumidifying efficiency.

Optionally, the first air inlet end 130 and the first air outlet end 140 are both communicated with the outdoor, the second air inlet end 150 and the second air outlet end 160 are both communicated with the indoor, the first flow channel 110 is communicated with the first air outlet end 140 through the first air inlet end 130 outdoors, and the second flow channel 120 is communicated with the second air outlet end 160 through the second air inlet end 150 indoors. Therefore, outdoor air enters the first flow channel 110 through the first air inlet end 130 and then is blown out to the outside again through the first air outlet end 140, indoor air enters the second flow channel 120 through the second air inlet end 150 and then is blown out to the indoor again through the second air outlet end 160, the outdoor air circulates in the first flow channel 110, the indoor air circulates in the second flow channel 120, the indoor air is in an internal circulation state and passes through the moisture absorption turntable 200 for two times in the air circulation process, the contact time of the air flow and the moisture absorption turntable 200 is prolonged, moisture in the air flow can be adsorbed more efficiently, moisture absorbed in the moisture absorption turntable 200 can be regenerated more efficiently and taken away by the air flow, and the indoor air flow or the outdoor air flow can be humidified or dehumidified continuously by controlling the temperature of the indoor air flow or the outdoor air flow, so that the humidifying or dehumidifying efficiency is improved. In some examples of humidifying the indoor, the outdoor normal temperature air flow enters the first flow channel 110 through the moisture absorption turntable 200 located in the first flow channel 110 through the first air inlet end 130, because the first air outlet end 140 and the first air inlet end 130 are located on the same end surface of the moisture absorption turntable 200, the air flow passing through the moisture absorption turntable 200 and flowing in the first flow channel 110 will again pass through the moisture absorption turntable 200 and flow out to the outdoor through the first air outlet end 140, the moisture in the air flow is absorbed by the moisture absorption turntable 200 during the process of passing through the moisture absorption turntable 200 twice, the indoor heated air flow passes through the moisture absorption turntable 200 located in the second flow channel 120 through the second air inlet end 150 and flows into the second flow channel 120, because the second air inlet end 150 and the second air outlet end 160 are located on the same end surface of the moisture absorption turntable 200, the air flow passing through the moisture absorption turntable 200 and flowing in the second flow channel 120 will again pass through the moisture absorption turntable 200 and flow out to the indoor through the second air outlet end 160, the heated moisture absorbed in the moisture absorption turntable 200 can be regenerated, and the regenerated moisture is blown into the room along with the airflow, thereby playing a role of humidifying the room. In some examples of dehumidifying the indoor, the indoor normal temperature air flow enters the second flow channel 120 and then flows out, and the outdoor heated air flow enters the first flow channel 110 and then flows out, so as to dehumidify the indoor.

Optionally, the first flow channel 110 communicates with the outdoor and the indoor through the first air inlet end 130 and the second air outlet end 160, and the second flow channel 120 communicates with the indoor and the outdoor through the second air inlet end 150 and the first air outlet end 140. Therefore, outdoor air flow passes through the moisture absorption rotary table 200 through the first air inlet end 130 to enter the first flow channel 110 and is discharged to the indoor through the second air outlet end 160, indoor air flow passes through the moisture absorption rotary table 200 through the second air inlet end 150 to enter the second flow channel 120 and is discharged to the outdoor through the first air outlet end 140, indoor air flow is in an outer circulation state, outdoor fresh air is introduced to the indoor, the outdoor air flow and the indoor air flow pass through the moisture absorption rotary table 200 for two times in the flowing process of the first flow channel 110 and the second flow channel 120, contact time of the air flow and the moisture absorption rotary table 200 is prolonged, moisture in the air flow can be adsorbed more efficiently, moisture absorbed in the moisture absorption rotary table 200 can be regenerated and taken away by the air flow more efficiently, and indoor humidification or dehumidification effect is improved. In some examples of humidifying the indoor, the indoor normal temperature air flow passes through the moisture absorption rotary disc 200 through the second air inlet end 150 and enters the second flow channel 120, and then is discharged to the outdoor through the first air outlet end 140, the moisture in the indoor air flow is absorbed by the moisture absorption rotary disc 200, the outdoor heating air flow passes through the moisture absorption rotary disc 200 through the first air inlet end 130 and enters the first flow channel 110, and then is discharged to the indoor through the second air outlet end 160, and the moisture absorbed by the moisture absorption rotary disc 200 can be regenerated by the heated air flow, and the heated air flow enters the indoor together with the air flow, so as to achieve the effect of continuously humidifying the indoor. In some examples of dehumidifying the indoor, the outdoor normal temperature air flow enters the first flow channel 110 and then flows out to the indoor, and the indoor heating air flow enters the second flow channel 120 and then flows out to the outdoor, so as to dehumidify the indoor.

Optionally, a heating part 300 is disposed in the first flow channel 110 and/or the second flow channel 120. Therefore, the airflow flowing through the first flow channel 110 and/or the second flow channel 120 can be heated, and the heated airflow can better regenerate the moisture absorbed in the moisture absorption turntable 200 when passing through the moisture absorption turntable 200, better take away the moisture regenerated in the moisture absorption turntable 200, and play a role in humidification or dehumidification, thereby better performing continuous humidification or dehumidification indoors.

Optionally, a heating part 300 is disposed in the first flow passage 110 or the second flow passage 120. In this way, the air flow passing through the heating unit 300 can be heated, and the heated air flow can carry away the moisture absorbed in the moisture absorption turntable 200, thereby better humidifying or dehumidifying the indoor environment.

In some examples, in the case that the indoor airflow is in an internal circulation state, that is, the first flow channel 110 is communicated with the outside of the room through the first air inlet end 130 and the first air outlet end 140, and the second flow channel 120 is communicated with the inside of the room through the second air inlet end 150 and the second air outlet end 160, if the heating portion 300 is arranged in the first flow channel 110, the moisture in the indoor airflow flowing through the second flow channel 120 is absorbed by the moisture absorption turntable 200 arranged in the second flow channel 120, the outdoor airflow flowing through the first flow channel 110 is heated by the heating portion 300, the heated airflow can regenerate and release the moisture in the indoor airflow absorbed in the moisture absorption turntable 200, and discharge the moisture to the outside of the room to perform the indoor dehumidification function, if the heating portion 300 is arranged in the second flow channel 120, the moisture in the outdoor airflow flowing through the first flow channel 110 is absorbed by the moisture absorption turntable 200, and the airflow flowing through the second flow channel 120 is heated by the heating portion 300, the heated air flow can regenerate and release the moisture in the outdoor air flow absorbed in the moisture absorption turntable 200, and the moisture is discharged to the indoor, so that the indoor humidification effect is achieved; when the indoor airflow is in an external circulation, that is, the first flow channel 110 is communicated with the second air outlet end 160 through the first air inlet end 130 and the second flow channel 120 is communicated with the indoor and the outdoor through the second air inlet end 150 and the first air outlet end 140, if the heating part 300 is arranged in the first flow channel 110, the indoor normal temperature airflow flows out to the outdoor through the second flow channel 120, the moisture in the airflow is absorbed by the moisture absorption turntable 200, the outdoor airflow flows into the indoor through the first flow channel 110, the outdoor airflow is heated by the heating part 300 in the first flow channel 110, the heated airflow can regenerate and release the moisture in the indoor airflow absorbed in the moisture absorption turntable 200 into the indoor to humidify the indoor, if the heating part 300 is arranged in the second flow channel 120, the outdoor normal temperature airflow flows into the indoor through the first flow channel 110, the moisture in the airflow is absorbed by the moisture absorption turntable 200, and the indoor airflow flows out to the outdoor through the second flow channel 120, the air flow is heated by the heating unit 300 in the second flow path 120, and the heated air flow can regenerate and release the moisture in the outdoor air flow absorbed in the moisture absorption turntable 200 to the outside, thereby performing an indoor dehumidification function.

Alternatively, the heating part 300 is provided in each of the first flow passage 110 and the second flow passage 120. In this way, when the indoor air is circulated internally or externally, the indoor air can be humidified or humidified more effectively by controlling the opening and closing of the heating unit 300 in the first and

second flow channels

110 and 120 to dehumidify or humidify the indoor environment. In some examples, when the indoor airflow is in an internal circulation state, that is, the first flow channel 110 is communicated with the outside of the room through the first air inlet end 130 and the first air outlet end 140, and the second flow channel 120 is communicated with the inside of the room through the second air inlet end 150 and the second air outlet end 160, the indoor dehumidification function can be performed by controlling the opening of the heating part 300 in the first flow channel 110 and the closing of the heating part 300 in the second flow channel 120, and the indoor humidification function can be performed by controlling the closing of the heating part 300 in the first flow channel 110 and the opening of the heating part 300 in the second flow channel 120; under the condition that indoor air current is in extrinsic cycle, first runner 110 communicates outdoor and indoor through first air inlet end 130 and second air-out end 160, second runner 120 communicates indoor and outdoor through second air inlet end 150 and first air-out end 140, through controlling opening of heating portion 300 in first runner 110, heating portion 300 in second runner 120 closes, can play the effect to indoor humidification, through controlling closing of heating portion 300 in first runner 110, heating portion 300 in second runner 120 opens, can play the effect to indoor dehumidification.

Optionally, the heating part 300 blocks the flow surface of the first flow channel 110 and/or the second flow channel 120. Thus, the airflow flowing through the first flow channel 110 and the second flow channel 120 can better contact with the heating part 300, the heat exchange efficiency between the airflow and the heating part 300 is improved, the flowing airflow is better heated, and the heated airflow can more efficiently regenerate and release the moisture absorbed in the moisture absorption turntable 200, so that the humidification or dehumidification efficiency is improved.

It can be understood that, when the heating portion 300 is provided in the first flow channel 110, the heating portion 300 blocks the flow surface of the first flow channel 110, when the heating portion 300 is provided in the second flow channel 120, the heating portion 300 blocks the flow surface of the second flow channel 120, and when the heating portions 300 are provided in both the first flow channel 110 and the second flow channel 120, the heating portion 300 in the first flow channel 110 blocks the flow surface of the first flow channel 110, and the heating portion 300 in the second flow channel 120 blocks the flow surface of the second flow channel 120.

Alternatively, the heating part 300 is a rectangular frame structure, and a plurality of mica electric heating plates 310 are uniformly arranged along the width direction of the heating part, and an air passage 311 is defined between adjacent mica electric heating plates 310. Therefore, the airflow flowing through the heating part 300 can pass through the mica electric heating sheet 310 through the airflow, the contact area with the mica electric heating sheet 310 is increased, the heat exchange efficiency is improved, and the mica electric heating sheet 310 has a better heating effect, so that the flowing airflow can be heated more efficiently.

Optionally, a partition mechanism 400 is disposed in the housing 100, and the first flow passage 110 and the second flow passage 120 are defined between the partition mechanism 400 and the inner wall of the housing 100. In this way, the first flow channel 110 and the second flow channel 120 are defined by the partition mechanism 400 and the inner wall of the housing 100, so that the air flows flowing in the first flow channel 110 and the second flow channel 120 are not interfered with each other, the stability of the device in the working process is improved, and the moisture absorption rotary disc 200 is convenient to mount.

Optionally, the partition mechanism 400 comprises: a first separator 410 and a second separator 420. The first partition 410 is disposed above the interior of the casing 100; the second partition plate 420 is connected to the first partition plate 410 and disposed below the housing 100; the hygroscopic rotating disk 200 is disposed between the first partition 410 and the second partition 420, and blocks the first flow channel 110 and the second flow channel 120 along the radial direction. Thus, the first partition 410 and the second partition 420 define the installation space of the moisture absorption rotary table 200, so that the moisture absorption rotary table 200 can be more stably installed in the housing 100, and vertical first and

second flow passages

110 and 120 are defined in the housing 100 by the first and

second partition plates

410 and 420, so that the installed portion is located in the first flow passage 110, the remaining part of the hygroscopic rotary disk 200 located in the second flow path 120 can be better rotated continuously, the moisture absorption rotary disc 200 blocks the first flow channel 110 and the second flow channel 120 along the radial direction, so that the air flow in the first flow channel 110 and the second flow channel 120 can better pass through the moisture absorption rotary disc 200, the contact area between the air flow and the moisture absorption rotary disc 200 is increased, the moisture in the air flow can be more efficiently absorbed, and the moisture absorbed in the moisture absorption rotary disc 200 can be more efficiently regenerated and taken away by the airflow, so that the humidifying or dehumidifying efficiency is improved.

Optionally, the second separator 420 includes: a first plate 421 and a second plate 422. The first plate 421 is parallel to the first partition 410, and has the center on the same vertical line; the second plate 422 is arranged to intersect the first plate 421; the first plate 421 and the second plate 422 define a first air inlet end 130, a first air outlet end 140, a second air inlet end 150, and a second air outlet end 160 on one end surface of the moisture absorption rotary disc 200. Therefore, the first plate 421 and the first partition plate 410 in the second partition plate 420 are located on the same vertical plane, the first flow channel 110 and the second flow channel 120 can be better defined between the first plate 421 and the second plate 422, and the first air inlet end 130, the first air outlet end 140, the second air inlet end 150 and the second air outlet end 160 are defined on one end surface of the moisture absorption rotary disc 200 through the first plate 421 and the second plate 422 which are arranged in a cross manner, so that the air inlet flow and the air outlet flow on one end surface of the moisture absorption rotary disc 200 are not interfered with each other, the stability of air inlet and air outlet on one end surface of the moisture absorption rotary disc 200 is improved, the humidification or dehumidification stability is further improved, and the device can perform better humidification or dehumidification indoors.

Optionally, the first partition plate 410 and the second partition plate 420 are connected by a connecting frame 430, the connecting frame 430 includes a first frame 431 and a second frame 432, the first frame 431 and the second frame 432 are both vertically arranged plate-shaped structures, the upper end and the lower end of the first frame 431 are respectively connected to one end of the first plate 421 and one end of the first partition plate 410, and the upper end and the lower end of the second frame 432 are respectively connected to the other end of the first plate 421 and the other end of the first partition plate 410. In this way, since the first plate 421 of the second partition plate 420 and the first partition plate 410 are located on the same vertical plane, and both ends are connected by the vertically arranged connecting frame 430, the stability of the partition mechanism 400 is improved, so that the first flow channel 110 and the second flow channel 120 are better defined in the housing 100.

Alternatively, the center of the first plate 421 is cross-connected with the center of the second plate 422, and the first plate 421 is perpendicular to the second plate 422. In this way, the first air inlet end 130, the first air outlet end 140, the second air inlet end 150 and the second air outlet end 160 defined on one end surface of the moisture absorption rotary disc 200 by the first plate 421 and the second plate 422 are uniform in size, and the air inlet amount is relatively uniform, so that the indoor and outdoor air flow can better enter the first flow channel 110 and the second flow channel 120 and then flow out.

Optionally, the partition mechanism 400 is rotatably disposed within the housing 100. Thus, the first flow channel 110 and the second flow channel 120 are defined between the partition mechanism 400 and the inner wall of the housing 100, and the first air inlet end 130, the first air outlet end 140, the second air inlet end 150 and the second air outlet end 160 are further disposed on one end surface of the moisture absorption turntable 200, so that the communication relationship between the first flow channel 110, the second flow channel 120, the first air inlet end 130, the first air outlet end 140, the second air inlet end 150 and the second air outlet end 160 can be changed by the rotation of the partition mechanism 400 to switch the circulation state of the indoor air, so that the indoor air is in the states of internal circulation dehumidification or humidification and external circulation dehumidification or humidification, and the indoor and outdoor communication states can be changed while better dehumidifying or humidifying the indoor, thereby better meeting the requirements of users.

In some examples, when the partition mechanism 400 is located at the first position, the first flow channel 110 is communicated with the first air outlet end 140 through the first air inlet end 130 to the outside, and the second flow channel 120 is communicated with the second air outlet end 160 through the second air inlet end 150 to the inside, that is, the indoor air is in an internal circulation state; when the partition mechanism 400 is located at the second position, the first flow channel 110 communicates with the outdoor and the indoor through the first air inlet end 130 and the second air outlet end 160, and the second flow channel 120 communicates with the indoor and the outdoor through the second air inlet end 150 and the first air outlet end 140, that is, the indoor air is in an external circulation state.

Alternatively, one of the two heating parts 300 is positioned at one side of the first partition plate 410 and the other is positioned at the other side of the first partition plate 410, and opposite ends of the two heating parts 300 are both connected to the first partition plate 410. In this way, when the blocking mechanism 400 is rotated to switch the position, the heating unit 300 can be rotated with the first partition plate 410 so that one of the two heating units 300 is always positioned in the first flow path 110 and the other is always positioned in the second flow path 120, and thus the air flow passing through the first flow path 110 and the second flow path 120 can be preferably heated.

It will be appreciated that when the partition mechanism 400 is switched from the first position to the second position, the partition mechanism 400 rotates 90 degrees in a counterclockwise direction, such that when the second position is switched to the first position, the partition mechanism 400 rotates 90 degrees in a clockwise direction.

As shown in connection with fig. 7-9, in some alternative embodiments, the absorbent turntable 200 comprises: frame portion 210 and carousel portion 220. The frame part 210 is disc-shaped, a circular mounting frame is defined at the inner side, and the periphery of the frame part 210 is connected with the inner wall of the housing 100; the turntable part 220 is rotatably disposed in the circular mounting frame. In this way, the outer circumference of the frame part 210 is connected to the inner wall of the cover casing 100 to seal the cover casing 100, so that the airflow can be prevented from passing through the edge of the moisture absorption turntable 200, the airflow can be guided to better pass through the turntable 220, the airflow passing through the turntable 220 can be better humidified or dehumidified, and the humidifying or dehumidifying efficiency can be improved.

Optionally, the turntable portion 220 seals off the circular mounting frame in the radial direction. Thus, the air flow passing through the circular mounting frame can pass through the turntable part 220, and the moisture absorption turntable 200 can better absorb or release moisture, thereby improving the humidifying or dehumidifying efficiency.

Optionally, the turntable unit 220 includes: a skeleton and a moisture-absorbing material. The framework is disc-shaped; the moisture absorption material is filled in the framework. In this way, by providing the frame, the structural stability of the turntable unit 220 can be improved, the damage of the turntable unit 220 can be prevented, the moisture absorbing material is filled in the frame, and when the airflow passes through the frame, the moisture in the airflow is absorbed by the moisture absorbing material filled in the frame, or the moisture absorbed in the moisture absorbing material is released to bring the airflow, thereby better humidifying or dehumidifying the indoor space.

Optionally, the skeleton is composed of glass fibers or ceramic fibers. Thus, the framework is stable and light in structure, the turntable part 220 can rotate conveniently, and the stability of the turntable part 220 is improved.

Optionally, the moisture absorbent material comprises: silica gel, MOF, molecular sieves. In this way, one or more of the above materials can efficiently absorb moisture in the air stream at normal temperature and can efficiently release moisture upon heating.

Optionally, a first driving portion 500 is disposed at a lower end of the second partition 420, and is capable of driving the second partition 420 to rotate, and the first driving portion 500 includes: a coupling disc 510 and a first motor 520. The connecting disc 510 is arranged at the lower end of the second partition 420, is connected with the lower end surface of the second partition 420, and is provided with a first annular rack 511 at the periphery; the output end of the first motor 520 is engaged with the first annular rack 511. Like this, under the condition that cuts off mechanism 400 needs the switch position, can rotate through first motor 520 drive connection pad 510, and then drive second baffle 420 and rotate, because second baffle 420 passes through link 430 and is connected with first baffle 410, thereby can drive first baffle 410 through second baffle 420 and rotate in step, stability when making cut off mechanism 400 rotate is higher, thereby better switching first runner 110, second runner 120 and first air inlet end 130, first air-out end 140, second air inlet end 150 and second air-out end 160 intercommunicating relation, switch the circulation state of indoor air, satisfy user's demand.

Optionally, the lower side of the connecting disc 510 is provided with a second driving part 600 capable of driving the moisture absorption rotary disc 200 to rotate, and the second driving part 600 includes: a drive disk 610, an output shaft 620, and a second motor 630. The transmission disc 610 is rotatably arranged on the lower side of the driving disc and is concentric with the driving disc, and a second annular rack 611 is arranged on the periphery of the transmission disc 610; the output shaft 620 passes through the centers of the driving disc and the second partition plate 420, and one end of the output shaft is fixedly connected with the round part of the driving disc 610, and the other end of the output shaft is fixedly connected with the circle center of the moisture absorption turntable 200; the output end of the second motor 630 is engaged with the second annular rack 611. Therefore, the transmission disc 610 can be driven to rotate by the second motor 630, the transmission disc 610 further drives the output shaft 620 to rotate, the moisture absorption rotary disc 200 arranged in the housing 100 is driven to continuously rotate by the output shaft 620, the part of the moisture absorption rotary disc 200 positioned in the first flow passage 110 and the rest part of the moisture absorption rotary disc 200 positioned in the second flow passage 120 are continuously switched, continuous moisture absorption and moisture release are performed in the rotating process, and therefore indoor humidification or dehumidification is better performed.

Alternatively, the connection of the output shaft 620 to the central position of the second separator 420 is connected by a sealed bearing. Therefore, the output shaft 620 can freely rotate relative to the second partition plate 420, and the friction force between the center of the second partition plate 420 and the output shaft 620 is reduced, so that the moisture absorption rotary disc 200 is better driven to rotate through the output shaft 620, and the stability of the moisture absorption rotary disc 200 during rotation is further improved.

Alternatively, the connection frame 430 is connected to the housing 100, the housing 100 is provided at an upper end thereof with a mounting seat 170, and the housing 100 is rotatably mounted on the mounting seat 170. In this way, the housing 100 can be connected to the blocking mechanism 400 via the connecting frame 430, and when the communication relationship between the first flow channel 110 and the second flow channel 120 and the indoor and outdoor needs to be switched as the blocking mechanism 400 rotates, the housing 100 and the blocking mechanism 400 are driven to rotate simultaneously, thereby further enhancing the stability of the blocking mechanism 400 during rotation.

In some optional embodiments, as shown in fig. 10 to 11, the apparatus for conditioning further comprises: a housing 700. The housing 700 defines a mounting cavity therein, and the cover 100 is mounted within the mounting cavity to divide the mounting cavity into a first airflow cavity 710, a second airflow cavity 720, a third airflow cavity 730, and a fourth airflow cavity 740. Thus, the rotation switching position of the partition mechanism 400 can be driven according to the outdoor environment quality or the user requirement in the process of humidifying or dehumidifying the indoor, and the communication relation of the first airflow cavity 710, the second airflow cavity 720, the third airflow cavity 730 and the fourth airflow cavity 740 can be switched, so that the change of the circulation state of the indoor air can be realized in the humidifying or dehumidifying process, the indoor air is in an internal circulation state or an external circulation state, the indoor airflow is exchanged with the outdoor airflow or not, the indoor airflow is exchanged with the outdoor airflow under the condition that the indoor ventilation requirement exists, the indoor airflow is not exchanged with the outdoor airflow under the condition that the outdoor air quality is poor and the ventilation requirement does not exist, the outdoor dirty air is prevented from entering the indoor, the outdoor airflow is selectively utilized, the dependence on the outdoor environment is reduced, and the stability of humidity regulation is improved, the quality of the indoor air is maintained.

Optionally, the cover 100 is disposed in an intermediate position of the mounting cavity. In this way, the first airflow chamber 710, the second airflow chamber 720, the third airflow chamber 730 and the fourth airflow chamber 740 partitioned by the cover 100 have uniform sizes and relatively uniform flow areas, so that the airflow can flow more smoothly.

Alternatively, with the partition mechanism 400 in the first position, the first airflow chamber 710 and the second airflow chamber 720 communicate through the first flow passage 110, and the third airflow chamber 730 and the fourth airflow chamber 740 communicate through the second flow passage 120; with the partition mechanism 400 in the second position, the first air flow chamber 710 is in communication with the third air flow chamber 730 via the first flow passage 110, and the second air flow chamber 720 is in communication with the fourth air flow chamber 740 via the second flow passage 120. In this way, by switching the position of the partition mechanism 400, the communication relationship of the flow passages in the housing 700 can be switched, so that outdoor and outdoor communication, indoor and indoor communication, or indoor and outdoor communication is achieved, and the switching of the airflow passages can be performed according to the quality of the outdoor environment or the requirements of users while the indoor environment is continuously humidified or dehumidified, thereby improving the environmental adaptability.

Optionally, the housing 700 includes a first inlet 701 and a first outlet 702 communicating with the exterior, a second inlet 703 and a second outlet 704 communicating with the interior, the first inlet 701 communicating with the first airflow chamber 710, the first outlet 702 communicating with the second airflow chamber 720, the second inlet 703 communicating with the fourth airflow chamber 740, and the second outlet 704 communicating with the third airflow chamber 730. In this way, the communication relationship of the flow channel in the housing 700 can be switched by switching the position of the partition mechanism 400, and further the indoor and outdoor communication relationship can be switched, so that the air flow channel can be switched according to the quality of the outdoor environment or the user requirement while the indoor environment is continuously humidified or dehumidified, and the environmental adaptability is improved.

In some examples, when the partition mechanism 400 is located at the first position, the outdoor airflow enters the first airflow chamber 710 through the first air inlet 701, then passes through the moisture absorbing turntable 200 through the first air inlet end 130 on the lower end surface of the moisture absorbing turntable 200 to enter the first flow channel 110, then is blown out through the first air outlet end 140 to flow into the second airflow chamber 720, and finally is blown out to the outdoor through the first air outlet 702, thereby completing a circulation of the outdoor airflow, the indoor airflow enters the fourth airflow chamber 740 through the second air inlet 703, then enters the second flow channel 120 through the second air inlet end 150 on the lower end surface of the moisture absorbing turntable 200, then is blown out through the second air outlet end 160 to flow into the third airflow chamber 730, and finally is blown out to the indoor through the second air outlet 704, thereby completing a circulation of the indoor airflow, wherein the outdoor is communicated with the outdoor, and the indoor is communicated with the indoor; when the partition mechanism 400 is located at the second position, the outdoor airflow enters the first airflow cavity 710 through the first air inlet 701, then passes through the moisture absorption turntable 200 through the first air inlet end 130 on the lower end surface of the moisture absorption turntable 200 to enter the first flow channel 110, then is blown out into the third airflow cavity 730 through the second air outlet end 160, and finally is blown out into the room through the second air outlet 704, so that a cycle from the outdoor to the indoor is completed, the indoor airflow enters the fourth airflow cavity 740 through the second air inlet 703, then enters the second flow channel 120 through the second air inlet end 150 on the lower end surface of the moisture absorption turntable 200, then flows out into the second airflow cavity 720 through the first air outlet end 140, and finally is discharged to the outdoor through the first air outlet 702, so that a cycle from the indoor to the outdoor is completed, and at this time, the indoor is communicated with the outdoor.

Optionally, fans are disposed in both the second airflow chamber 720 and the third airflow chamber 730. In this way, the fans can better exhaust the airflow in the second airflow chamber 720 and the third airflow chamber 730, and negative pressure is generated in the second airflow chamber 720 and the third airflow chamber 730 to provide sufficient power for airflow.

Alternatively, the housing 100 has a circular structure, and the partition plate 750 is disposed at the outer periphery of the housing, and the partition plate 750 extends to the inner wall of the casing 700 corresponding to the partition plate. Thus, the installation cavity is better divided into the first air flow cavity 710, the second air flow cavity 720, the third air flow cavity 730 and the fourth air flow cavity 740 by the cooperation of the cover case 100 and the partition plate 750, and the structural stability of the device is improved.

Alternatively, the mounting seat 170 at the upper end of the cover 100 is fixedly disposed on the upper inner wall of the housing 700. In this way, the upper inner wall of the housing 700 supports the mount 170, thereby improving stability of the cover 100 during rotation.

Alternatively, four partition plates 750 are provided, which are respectively located at 12 o 'clock, 3 o' clock, 6 o 'clock and 9 o' clock positions of the outer circumference of the cover case 100, and respectively extend onto the inner wall of the housing 700 corresponding thereto. Thus, the four partition plates 750 are matched with the housing 100, so that the installation cavity can be better and uniformly divided into the first airflow cavity 710, the second airflow cavity 720, the third airflow cavity 730 and the fourth airflow cavity 740, and the structural stability of the device is further improved.

Optionally, a first vent 751 is disposed between the first airflow chamber 710 and the third airflow chamber 730; a second ventilation opening 752 is disposed between the second airflow chamber 720 and the fourth airflow chamber 740. Thus, when the partition mechanism 400 is in the first position and the indoor air is in the internal circulation, the first airflow chamber 710 is communicated with the second airflow chamber 720, the third airflow chamber 730 is communicated with the fourth airflow chamber 740, and a small amount of outdoor air can enter the third airflow chamber 730 through the first airflow chamber 710 and then enter the indoor through the first ventilation opening 751, and a small amount of indoor air enters the second airflow chamber 720 through the fourth airflow chamber 740 and then is discharged to the outdoor through the second ventilation opening 752 to circulate outside the mini-fresh air, thereby improving the indoor air quality.

Optionally, the first ventilation opening 751 is disposed on the partition plate 750 between the first airflow chamber 710 and the third airflow chamber 730, the second ventilation opening 752 is disposed on the partition plate 750 between the second airflow chamber 720 and the fourth airflow chamber 740, and the first ventilation opening 751 and the second ventilation opening 752 are both provided with a switch structure. Thus, the first ventilation opening 751 and the second ventilation opening 752 can exchange fresh air indoors and outdoors to improve the quality of indoor air, and the opening and closing of the first ventilation opening 751 and the second ventilation opening 752 can be controlled by the opening and closing structure.

12-13, in some alternative embodiments, a purge mechanism 800 is disposed within third airflow chamber 730. Thus, the third airflow chamber 730 is communicated with the second air inlet 703 for supplying air to the room, and therefore the purification mechanism 800 is arranged in the third airflow chamber 730, so that pollutants flowing into the indoor airflow can be purified, and the indoor air quality is further improved in the process of humidifying or dehumidifying the room.

Optionally, purge mechanism 800 comprises: a mounting frame 810 and an activated carbon adsorption plate 820. The mounting frame 810 is disposed in the third airflow chamber 730, and an inner side thereof is provided with a flow passing port; the activated carbon adsorption plate 820 is disposed in the flow passage. In this way, the airflow flowing through the third airflow chamber 730 can pass through the flow passage on the inner side of the mounting bracket 810, and the pollutants in the airflow are adsorbed by the activated carbon adsorption plate 820, thereby improving the quality of the airflow flowing into the room.

Optionally, the mounting bracket 810 seals off the flow surface of the third airflow chamber 730. Therefore, the air flow circulating in the third air flow cavity 730 can pass through the flow passing opening on the inner side of the mounting frame 810, the air flow is in better contact with the activated carbon adsorption plate 820 in the flow passing opening, pollutants in the air flow are better adsorbed by the activated carbon adsorption plate 820, and the quality of the air flow flowing into the room is further improved.

The above description and drawings sufficiently illustrate embodiments of the disclosure to enable those skilled in the art to practice them. Other embodiments may include structural and other changes. The examples merely typify possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others. The embodiments of the present disclosure are not limited to the structures that have been described above and shown in the drawings, and various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims

1. An apparatus for conditioning moisture, comprising:

a housing (100) defining a first flow passage (110) and a second flow passage (120) therein;

the moisture absorption rotary disc (200) is rotatably arranged in the housing (100), and part of the moisture absorption rotary disc is positioned in the first flow passage (110) while the rest part of the moisture absorption rotary disc is positioned in the second flow passage (120);

the moisture absorption turntable (200) is provided with a first air inlet end (130), a first air outlet end (140), a second air inlet end (150) and a second air outlet end (160) along one axial end face.

2. The device for conditioning moisture according to claim 1, characterized in that a heating section (300) is provided in the first flow channel (110) and/or the second flow channel (120).

3. The device for conditioning moisture according to claim 1, wherein a partition means (400) is provided in the casing (100), and the first flow passage (110) and the second flow passage (120) are defined between the partition means (400) and an inner wall of the casing (100).

4. Device for conditioning according to claim 3, characterized in that said interruption means (400) comprise:

a first partition plate (410) provided above the inside of the casing (100);

a second partition plate (420) connected to the first partition plate (410) and disposed below the housing (100);

wherein the moisture absorption rotary disc (200) is arranged between the first partition plate (410) and the second partition plate (420), and blocks the first flow passage (110) and the second flow passage (120) along the radial direction.

5. Device for conditioning according to claim 4, characterized in that said second diaphragm (420) comprises:

a first plate (421) parallel to the first barrier (410) and centered on the same vertical line;

a second plate (422) provided to cross the first plate (421);

the first air inlet end (130), the first air outlet end (140), the second air inlet end (150) and the second air outlet end (160) are defined by the first plate (421) and the second plate (422) on one end surface of the moisture absorption rotary disc (200).

6. Device for conditioning according to claim 3, characterized in that said interruption means (400) are rotatably arranged inside said casing (100).

7. The apparatus for conditioning moisture as set forth in any one of claims 1 to 6, further comprising:

a housing (700) defining a mounting cavity therein, the enclosure (100) being mounted within the mounting cavity to divide the mounting cavity into a first airflow cavity (710), a second airflow cavity (720), a third airflow cavity (730), and a fourth airflow cavity (740).

8. The apparatus for conditioning a body according to claim 7, wherein the housing (700) comprises a first air inlet (701) and a first air outlet (702) communicating with the outside of the chamber, a second air inlet (703) and a second air outlet (704) communicating with the inside of the chamber, the first air inlet (701) communicating with the first air flow chamber (710), the first air outlet (702) communicating with the second air flow chamber (720), the second air inlet (703) communicating with the fourth air flow chamber (740), and the second air outlet (704) communicating with the third air flow chamber (730).

9. The device for conditioning according to claim 7, characterized in that a first ventilation opening (751) is provided between the first air flow chamber (710) and the third air flow chamber (730); a second ventilation opening (752) is arranged between the second airflow cavity (720) and the fourth airflow cavity (740).

10. The device for conditioning moisture according to claim 7, characterized in that a purging mechanism (800) is provided in the third air flow chamber (730).