CN215336794U

CN215336794U - Humidity regulator

Info

Publication number: CN215336794U
Application number: CN202121171170.8U
Authority: CN
Inventors: 栗岩; 殷鹏飞; 王海胜; 孙明明; 蔡艳芳; 窦宁宁; 张中晓; 滕兆龙; 代传民; 孙萍
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: 2021-05-27
Publication date: 2021-12-28
Anticipated expiration: 2031-05-27
Also published as: CN215637669U; CN215637668U; CN113294852A; CN215336793U; CN113294853A; CN215336792U; CN113294851A

Abstract

The application relates to the technical field of humidity control, discloses a damping machine, includes: the air path switching mechanism comprises a shell, an air path switching mechanism, a first humidity regulating block and a second humidity regulating block. The inside of the shell is provided with a partition board which divides the inside of the shell into an air inlet channel and an air exhaust channel, and the partition board is provided with a mounting groove; the air path switching mechanism comprises a shell and a sealing partition plate arranged in the shell, a first channel is defined between the shell and one side surface of the sealing partition plate, and a second channel is defined between the shell and the other side surface of the sealing partition plate; the first humidity adjusting block is rotatably arranged in the first channel; the second humidity adjusting block is rotatably arranged in the second channel. According to the humidification and dehumidification system, outdoor airflow can be selectively utilized, dependence on outdoor environment is reduced, indoor airflow internal circulation and outdoor airflow internal circulation are carried out simultaneously in the internal circulation humidification or dehumidification process, humidification or dehumidification can be carried out continuously, and humidification or dehumidification efficiency is improved.

Description

Humidity regulator

Technical Field

The application relates to the technical field of humidity adjustment, for example to a humidity conditioner.

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 technology, indoor air and outdoor air are replaced, moisture in the outdoor air is absorbed and released to the indoor or moisture in the indoor air is absorbed and released to the outdoor in the replacement process to humidify or dehumidify the indoor, the mode has high dependence on the outdoor environment, and when the outdoor air is poor, the outdoor air enters the indoor to cause the quality of the indoor air to be reduced.

Therefore, how to achieve continuous humidification or dehumidification and improve the efficiency of humidification and dehumidification becomes a problem to be solved by those skilled in the art on the premise of reducing the dependence on outdoor environment.

SUMMERY OF THE UTILITY MODEL

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 conditioner, which selectively utilizes outdoor airflow, reduces the dependence on outdoor environment, improves the stability of humidity regulation, and maintains the quality of indoor air.

In some embodiments, a humidifier includes: the air path switching mechanism comprises a shell, an air path switching mechanism, a first humidity regulating block and a second humidity regulating block. The inside of the shell is provided with a partition board which divides the inside of the shell into an air inlet channel and an air exhaust channel, and the partition board is provided with a mounting groove; the air path switching mechanism comprises a shell and a sealing partition plate arranged in the shell, a first channel is defined between the shell and one side surface of the sealing partition plate, a second channel is defined between the shell and the other side surface of the sealing partition plate, the shell is arranged in the mounting groove and penetrates through the air inlet channel and the air exhaust channel, and the part of the shell arranged in the air inlet channel and the part of the shell arranged in the air exhaust channel are respectively provided with a vent opening which can be controlled to be opened or closed; the first humidity adjusting block is rotatably arranged in the first channel; the second humidity adjusting block is rotatably arranged in the second channel.

The humidity conditioner provided by the embodiment of the disclosure can realize the following technical effects:

the air path switching mechanism is partially arranged in the air inlet channel, the rest parts are arranged in the air exhaust channel, and the air path switching mechanism is respectively communicated with the air inlet channel and the air exhaust channel through different vents which can be controlled to be opened or closed, so that the air flow can realize internal circulation and external circulation The indoor air flow internal circulation and the outdoor air flow internal circulation are simultaneously carried out in the internal circulation humidifying or dehumidifying process, the humidifying or dehumidifying can be continuously carried out, and the humidifying or dehumidifying efficiency is 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 schematic structural diagram of a humidity conditioner provided in an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of an air path switching mechanism according to an embodiment of the disclosure;

fig. 3 is a perspective view of an air path switching mechanism according to an embodiment of the disclosure;

fig. 4 is a schematic structural diagram of another air path switching mechanism according to an embodiment of the disclosure;

FIG. 5 is a schematic diagram of a switch assembly provided by embodiments of the present disclosure;

fig. 6 is a perspective view of another air path switching mechanism provided in the embodiment of the present disclosure;

FIG. 7 is a schematic structural view of a drive mechanism coupled to a first humidity control block and a second humidity control block in accordance with an embodiment of the present disclosure;

fig. 8 is a schematic structural diagram of another humidity conditioner provided in the embodiment of the present disclosure;

FIG. 9 is a schematic structural diagram of a housing provided by embodiments of the present disclosure;

fig. 10 is a schematic view of an internal structure of a humidity conditioner according to an embodiment of the present disclosure;

fig. 11 is a schematic view of the internal structure of another humidity conditioner provided in the embodiment of the present disclosure;

fig. 12 is an external structural schematic diagram of a humidity conditioner provided in the embodiment of the present disclosure.

Reference numerals:

100. a housing; 101. an air path switching mechanism; 102. a housing; 103. sealing the partition plate; 104. a first channel; 105. a second channel; 106. a first region; 107. a second region; 108. a third region; 109. a fourth region; 110. sealing the protrusion; 200. a first humidity conditioning block; 300. a second humidity conditioning block; 400. a vent; 401. a vent A; 402. a vent B; 403. a vent C; 404. a vent D; 405. a vent E; 406. a vent F; 407. a vent G; 408. a vent H; 500. a switch assembly; 501. a closing baffle; 502. a drive motor; 610. a first drive mechanism; 611. a motor; 612. a drive shaft; 620. a second drive mechanism; 700. a separator plate; 701. mounting grooves; 710. an air inlet channel; 711. a first air inlet end; 712. a first air outlet end; 713. a first heating mechanism; 714. a first fan; 720. an air exhaust channel; 721. a second air inlet end; 722. a second air outlet end; 723. a second heating mechanism; 724. a second fan; 800. an evaporator; 900. a condenser.

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.

In the embodiment of the present disclosure, the character "/" indicates that the preceding and following objects are in an or relationship. For example, A/B represents: a or B.

The term "and/or" is an associative relationship that describes objects, meaning that three relationships may exist. For example, a and/or B, represents: a or B, or A and B.

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.

As shown in fig. 1 to 6, an embodiment of the present disclosure provides a humidity conditioner including: the air path switching mechanism includes a casing 100, an air path switching mechanism 101, a first humidity control block 200, and a second humidity control block 300. The inside of the casing 100 is provided with a partition plate 700, the inside of the casing 100 is divided into an air inlet channel 710 and an air outlet channel 720, and the partition plate 700 is provided with a mounting groove 701; the air path switching mechanism 101 comprises a casing 102 and a sealing partition 103 arranged in the casing 102, a first channel 104 is defined between one side surface of the casing 102 and the sealing partition 103, a second channel 105 is defined between the casing 102 and the other side surface of the sealing partition 103, the casing 102 is arranged in a mounting groove 701 and penetrates through an air inlet channel 710 and an air exhaust channel 720, and a ventilation opening 400 which can be controlled to be opened or closed is arranged at the part of the casing 102 arranged in the air inlet channel 710 and the part of the casing 102 arranged in the air exhaust channel 720; the first humidifying block 200 is rotatably disposed in the first passage 104; the second humidifying block 300 is rotatably disposed in the second passage 105.

By adopting the humidity regulator provided by the embodiment of the disclosure, the air path switching mechanism 101 is partially arranged in the air inlet channel 710, and the rest is arranged in the air outlet channel 720, wherein the air path switching mechanism 101 is respectively communicated with the air inlet channel 710 and the air outlet channel 720 through different air vents 400 which can be controlled to be opened or closed, so that the air flow can realize the internal circulation and the external circulation, meanwhile, the sealing partition plate 103 is arranged in the path sealing switching mechanism, the interior of the air path switching mechanism 101 is divided into the first channel 104 and the second channel 105 through the sealing partition plate 103, and the humidity regulating blocks are arranged in the first channel 104 and the second channel 105, so that when the first channel 104 performs the internal circulation of the indoor air flow, the second channel 105 performs the internal circulation of the outdoor air flow, after the working set time, the second channel 105 can perform the internal circulation of the indoor air flow, and the first channel 104 performs the external circulation of the outdoor air flow, through the circulation work of two kinds of states, can carry out continuous humidification or dehumidification, consequently can make do not take place to exchange between indoor air current and the outdoor air current under the relatively poor condition that does not have the trade wind demand of outdoor air quality, avoid outdoor dirty air to enter into indoor, the outdoor air current of selective utilization reduces the reliance to outdoor environment, and carry out indoor air current inner loop simultaneously in inner loop humidification or dehumidification process, and outdoor air current inner loop, sustainable continuous humidification or dehumidification, the efficiency of humidification or dehumidification is improved.

Optionally, both the first and second humidifying blocks 200, 300 may be rotated 90 degrees with respect to the housing 102. Thus, under the condition that the indoor air exchange requirement is not needed, the different ventilation openings 400 are controlled to be opened, the air flow entering from the outdoor space is exhausted from the outdoor space through the ventilation openings 400 on the same side after passing through the first channel 104, the air flow passing through the indoor space is exhausted into the indoor space through the ventilation openings 400 on the same side after passing through the second channel 105, the positions of the first humidity regulating block 200 and the second humidity regulating block 300 are changed after the first humidity regulating block 200 and the second humidity regulating block 300 are controlled to rotate for 90 degrees, the first humidity regulating block 200 and the second humidity regulating block 300 can always cross over the flow path of the air flow, the air flow fully passes through the first humidity regulating block 200 and the second humidity regulating block 300, the efficiency of moisture absorption and moisture regeneration is improved, and the efficiency of humidifying or dehumidifying the air is further improved.

Optionally, the housing 102 is rectangular, and half of the ventilation openings 400 are disposed on a first side of the housing 102, and the remaining half of the ventilation openings 400 are disposed on the housing 102 opposite to each other and on a second side opposite to the first side. Thus, half of the plurality of ventilation openings 400 can be positioned on one side surface of the shell 102, the other half of the plurality of ventilation openings 400 can be positioned on the other opposite side surface, so that the half of the ventilation openings 400 can be conveniently communicated with the indoor space when being installed, the other half of the ventilation openings 400 can be communicated with the outdoor space, the installation structure can be simplified, and the installation and the use in the later period can be more conveniently realized.

Optionally, the vent 400 comprises: a vent a401, a vent B402 located on one side of the first duct 104, and a vent C403 located on the other side of the first duct 104 and opposite to the vent a401, and a vent D404 located opposite to the vent B402; a vent E405, a vent F406 on one side of the second channel 105, a vent G407 opposite the vent E405 on the other side of the second channel 105, and a vent H408 opposite the vent F406; wherein, the vent A401 and the vent E405 are corresponding in position and are positioned on the same vertical line. Like this, through setting up a plurality of vents 400 and arranging at the both ends of first passageway 104 and second passageway 105 according to above-mentioned mode, the mode that the open or close of steerable different vents 400 changed the circulation through first passageway 104 and second passageway 105, and then make the air current possess multiple different circulation route, can switch the circulation route of air current according to demand control, better humidification or dehumidification carry out, and whether control carries out indoor and outdoor trades the wind, reduce the demand to outdoor air quality, improve the stability of humidification or dehumidification.

Alternatively, the first humidifying block 200 divides the first duct 104 into the first region 106 and the second region 107, and the first region 106 communicates with the vent a401 and the vent C403 in the case of the first position, the second region 107 communicates with the vent B and the vent D404 in the case of the second position, and the first region 106 communicates with the vent a401 and the vent B402 in the case of the second position, and the second region 107 communicates with the vent C403 and the vent D404. Thus, with the first humidity conditioning block 200 in the first position, airflow may enter through vent a401 and exit through the first humidity conditioning block 200 through vent B402, or enter through vent D404 through the first humidity conditioning block 200 and exit through vent C403; and the air current can enter through the vent A401 and pass through the first humidity adjusting block 200 to be discharged from the vent C403 under the condition that the first humidity adjusting block 200 is at the second position, or enter through the first humidity adjusting block 200 by the vent D404 to be discharged from the vent B402, so that the air current can better pass through the first humidity adjusting block 200, the moisture absorption or release efficiency is improved, and the humidification or dehumidification efficiency is further improved.

Alternatively, the second damping block 300 divides the second passage 105 into the third zone 108 and the fourth zone 109, and the third zone 108 communicates with the vent E405 and the vent G407, the fourth zone 109 communicates with the vent F and the vent H408 in the case of the first position, the third zone 108 communicates with the vent E405 and the vent F406, and the fourth zone 109 communicates with the vent G407 and the vent H408 in the case of the second position. Thus, with the second humidity conditioning block 300 in the first position, airflow can enter through the vent E405, pass through the first humidity conditioning block 200, and exit through the vent F406, or enter through the vent H408, pass through the first humidity conditioning block 200, and exit through the vent G407; and the air current can enter through the vent E405 and pass through the first humidity adjusting block 200 to be discharged from the vent G407 or enter through the first humidity adjusting block 200 from the vent H408 to be discharged from the vent F406 under the condition that the first humidity adjusting block 200 is at the second position, so that the air current can better pass through the second humidity adjusting block 300, the moisture absorption or release efficiency is improved, and the humidification or dehumidification efficiency is further improved.

Optionally, the inner wall of the housing 102 is provided with a sealing protrusion 110 at the first position and the second position corresponding to the first humidity control block 200 and the second humidity control block 300, respectively, and the sealing protrusion 110 can contact with the first humidity control block 200 and the second humidity control block 300. In this way, the sealing protrusion 110 is in contact with the first humidity control block 200 and the second humidity control block 300, so that air flow can be prevented from leaking from a gap between the first humidity control block 200 and the inner wall of the housing 102 and a gap between the second humidity control block 300 and the inner wall of the housing 102, the air flow can better pass through the first humidity control block 200 and the second humidity control block 300, and the humidifying and dehumidifying efficiency is improved.

Alternatively, when the dehumidifier is in the first operating state, the vent a401, the vent C403, the vent F406, and the vent H408 are opened, and the other vents 400 are closed; when the dehumidifier is in the second operating state, the vent B402, the vent D404, the vent E405, and the vent G407 are opened, and the other vents 400 are closed; when the dehumidifier is in the third operating state, the vent a401, the vent B402, the vent G407, and the vent H408 are opened, and the other vents 400 are closed; when the dehumidifier is in the fourth operating state, the vent C403, the vent D404, the vent E405, and the vent F406 are opened, and the other vents 400 are closed. Like this, open through the combination of vent 400 of multiple difference, remaining vent 400 closes, can make the ventilation form certain airflow channel, and then make the damping machine possess multiple operating condition, can change operating condition according to the demand, and the suitability is stronger, improves the stability of humidification and dehumidification.

Alternatively, the first humidity control block 200 and the second humidity control block 300 are identical in structure and each include: a skeleton and a moisture-absorbing material. The framework is of a rectangular structure; the moisture absorption material is filled in the framework. In this way, by providing the frame, the structural stability of the humidifying block (the first and second humidifying blocks 200 and 300 may be collectively referred to as a humidifying block) can be improved, preventing damage of the humidifying block.

Optionally, the skeleton is composed of glass fibers or ceramic fibers. Thus, the structure is stable and light, and the rotation of the first and second humidifying blocks 200 and 300 is facilitated.

Optionally, the moisture absorbent material comprises: silica gel, molecular sieves. Therefore, the moisture in the airflow can be efficiently absorbed, and the moisture can be efficiently released under the heating condition, so that the humidifying or dehumidifying efficiency is improved.

Optionally, the first humidity control block 200 and the second humidity control block 300 both have a set angle with the sealing partition 103, and the set angle is greater than or equal to 30 degrees and less than or equal to 90 degrees. In this way, the first humidity control block 200 and the second humidity control block 300 are inclined at a set angle with respect to the sealing partition 103, so that the area of contact with the air flow can be increased by the first humidity control block 200 and the second humidity control block 300 by the inclined arrangement, and the efficiency of the first humidity control block 200 and the second humidity control block 300 with respect to moisture absorption and regeneration can be increased, and the smaller the angle with respect to the sealing partition 103, the larger the area of contact with the air flow is, but the larger the space occupied by the first humidity control block 200 and the second humidity control block 103, the smaller the space occupied by the first humidity control block 200 and the second humidity control block 300, so that the set angle is set between 30 degrees and 90 degrees, and the inclination angle of the first humidity control block 200 and the second humidity control block 300 can be selected according to the demand for the space occupied or the area of contact with the air flow, so as to meet different demands under different conditions.

Optionally, the first humidity conditioning block 200 and the second humidity conditioning block 300 both have a 90 degree angle with the sealing partition 103. Thus, the space occupied by the first humidity control block 200 and the second humidity control block 300 is reduced, the whole volume can be effectively reduced, and the structure is more compact.

Optionally, the first humidity conditioning block 200 and the second humidity conditioning block 300 both have an angle of 45 degrees with the sealing partition 103. Therefore, the space occupied by the first humidity control block 200 and the second humidity control block 300 is not too large, and the contact area with the air flow can be increased, so that the humidifying or dehumidifying effect is enhanced.

Optionally, a switch assembly 500 is disposed within each vent 400 to close or open the vent 400. Thus, the switch assembly 500 arranged on the vent 400 can be used for opening or closing the vent 400, different gas flow paths can be realized by opening different vents 400, and further internal circulation humidification and dehumidification and external circulation humidification and dehumidification are carried out, outdoor airflow is selectively utilized according to different requirements, dependence on outdoor environment is reduced, the stability of humidity regulation is improved, and the quality of indoor air is maintained.

Optionally, the switch assembly 500 comprises: a closing flap 501 and a drive motor 502. One side of the closed baffle 501 is rotatably connected with one side of the vent 400 through a rotating shaft; the driving motor 502 is fixedly disposed on the housing 102, and an output shaft thereof is connected to the rotating shaft, and can drive the closing flap 501 to rotate, so that the closing flap closes the ventilation opening 400 in the case of the first position, and opens the ventilation opening 400 in the case of the second position. In this way, the vent 400 is opened or closed through the structure of the closed baffle 501, the structure is simple and easy to realize, and the closed baffle 501 opens or closes the vent 400 through rotation, so that the space occupation of the closed baffle 501 during installation can be reduced, and the structure is more compact.

Optionally, the periphery of the vent 400 and/or the periphery of the closure flap 501 are provided with sealing rings. Thus, the sealing effect when the vent 400 is closed can be improved, and the leakage of the air flow can be prevented, resulting in a decrease in the efficiency of humidification or dehumidification.

Optionally, the sealing partition 103 is horizontally disposed in the housing 102, such that the separated first channel 104 and the second channel 105 are disposed in parallel, and the sealing baffle 501 can be opened by rotating towards the side edge of the ventilation opening 400 close to the edge of the housing 102, and has a predetermined included angle with the ventilation opening 400 when located at the second position. Thus, the opened vent 400 is arranged at one side in the middle of the first channel 104 or the second channel 105, so that the air flow at the other side in the first channel 104 or the second channel 105 is less, and when the vent 400 is opened by the closed baffle 501, a preset included angle is formed between the closed baffle 501 and the vent 400, so that the closed baffle 501 has a certain flow guiding effect, the air flow more uniformly passes through the first channel 104 and the second channel 105, the uniformity of the air flow is improved, the air flow more uniformly passes through the first humidity regulating block 200 and the second humidity regulating block 300, and the humidifying or dehumidifying efficiency is improved.

Alternatively, the housing 102 completely separates the intake air passage 710 and the exhaust air passage 720 from an intermediate position. Thus, the air flow can sufficiently pass through the housing 102, and the first humidity control block 200 and the second humidity control block 300 in the housing 102 are used for absorbing or releasing moisture, so that the indoor humidity or dehumidification can be better performed, and the efficiency of the humidity and dehumidification is improved.

Alternatively, the vent a401, the vent C403, the vent E405, and the vent G407 are located in the air intake duct 710, and the vent B402, the vent D404, the vent F406, and the vent H408 are located in the air exhaust duct 720. Therefore, the air flow passing through the shell 102 can selectively flow through the air inlet channel 710 and the air exhaust channel 720, so that the whole body has multiple working states, the working states can be switched according to requirements, and the humidifying or dehumidifying stability is improved.

Optionally, the air inlet channel 710 may be communicated through a first micro fresh air port disposed on one side when the air inlet channel is blocked by the housing 102, and a switch structure is disposed in the first micro fresh air port, so that the first micro fresh air port can be opened or closed; under the condition that air exhaust channel 720 is cut off by casing 102, the accessible sets up the little fresh air port intercommunication of second in one side, and is equipped with the switch structure in the little fresh air port of second, can open or close the little fresh air port of second. Like this, do not carry out gas exchange indoor with outdoor, carry out under the circumstances that inner loop humidification or inner loop dehumidified, can carry out a small amount of air current exchanges through little new trend opening, satisfy different demands, improve the variety of work revolving stage.

As shown in fig. 7, optionally, the humidity conditioner further includes: a first drive mechanism 610 and a second drive mechanism 620. The first driving mechanism 610 is connected with the first humidity control block 200 and can drive the first humidity control block 200 to rotate; the second driving mechanism 620 is connected to the second damping block 300 and can drive the second damping block 300 to rotate. In this way, the position of the first humidity control block 200 is adjusted by the first driving mechanism 610, and the position of the second humidity control block 300 is adjusted by the second driving mechanism 620, so that the positions of the first humidity control block 200 and the second humidity control block 300 can be better controlled, and the first humidity control block 200 and the second humidity control block 300 are respectively driven, so that the first humidity control block 200 and the second humidity control block 300 do not need to move synchronously, and the use flexibility is improved. For example, when the first humidity control block 200 is at the first position, the outdoor airflow enters through the vent D404 and passes through the first humidity control block 200, the moisture of the outdoor airflow is absorbed by the first humidity control block 200 and discharged to the outdoor through the vent C403, and the moisture outside the room is collected, at this time, the second humidity control block 300 may be at the second position, so that the outdoor airflow enters through the vent H408 and passes through the second humidity control module, the moisture on the second humidity control block 300 is released and discharged to the indoor through the vent F406, and the indoor is humidified, and more moisture in the outdoor airflow can be used to humidify the indoor, thereby improving the humidifying efficiency.

Optionally, the first driving mechanism 610 and the second driving mechanism 620 have the same structure, and taking the first driving mechanism 610 as an example, the first driving mechanism 610 includes: a motor 611 and a drive shaft 612. The driving shaft 612 is connected to an output end of the motor 611 and is fixedly connected to the first humidifying block 200. Therefore, the first humidity adjusting block 200 can be driven to rotate by the motor 611, the driving structure is simplified, the operation is stable, and the cost is lower.

As shown in fig. 8-12, in some embodiments, the air intake channel 710 includes: a first air inlet end 711 and a first air outlet end 712. One end of the first air inlet end 711 is communicated with the outside, the other end of the first air inlet end 711 can be communicated with the first channel 104 or the second channel 105, and a first heating mechanism 713 is arranged inside the first air inlet end 711; the first outlet end 712 has one end communicating with the indoor space and the other end communicating with the first channel 104 or the second channel 105, and is provided with a first fan 714 therein. Thus, the first heating mechanism 713 is arranged in the first air inlet end 711 to heat the air flow so that the heated air flow passes through the first humidity regulating block 200 or the second humidity regulating block 300, the heated air flow is used to heat the first humidity regulating block 200 or the second humidity regulating block 300 in the humidity regulator, and then the moisture in the air flow is regenerated, so that the indoor moisture can be collected and released to be discharged into the room when the indoor air and the outdoor air are exchanged, the indoor humidity is kept, or the moisture in the first humidity regulating block 200 and the second humidity regulating block 300 is regenerated by heating the outdoor air when the indoor air is internally circulated and dehumidified, so that the indoor air flow can be continuously and subsequently dehumidified, the first air outlet end 712 of the air inlet channel 710 is provided with the first fan 714 to drive the air flow to circulate, because the first heating mechanism 713 is required to be arranged at the first air inlet end 711, the air flow is heated firstly and then passes through the first humidity control block 200 or the second humidity control block 300, so that the first fan 714 is arranged at the first air outlet end 712, the first fan 714 and the first heating mechanism 713 are prevented from being arranged at adjacent positions, the influence generated between the first fan 714 and the first heating mechanism 713 is avoided, the service life of each fan is shortened, and the mounting structure is more reasonable.

Alternatively, vent a401 and vent E405 communicate with the first intake end 711, and vent C403 and vent G407 communicate with the first exhaust end. Thus, the outdoor air entering the first air inlet 711 can enter the housing 102 through the vent a401 or the vent E405, and is discharged into the first air outlet through the vent C403 or the vent G407, and then enters the room.

Optionally, the exhaust duct 720 includes: a second air inlet end 721 and a second air outlet end 722. One end of the second air inlet end 721 is communicated with the indoor, the other end can be communicated with the first channel 104 or the second channel 105, and a second heating mechanism 723 is arranged in the second air inlet end 721; one end of the second air outlet end 722 is communicated with the outside, the other end can be communicated with the first channel 104 or the second channel 105, and a second fan 724 is arranged inside. Thus, the second heating mechanism 723 is arranged in the second air inlet end 721 to heat the air flow so that the heated air flow passes through the first humidity conditioning block 200 or the second humidity conditioning block 300, the heated air flow is used to heat the first humidity conditioning block 200 or the second humidity conditioning block 300 in the humidity conditioner, and then the moisture in the air flow is regenerated, so that the moisture in the outdoor air is absorbed and regenerated by the heated indoor air flow when the indoor air and the outdoor air are exchanged, the indoor dryness is maintained, or the indoor air is internally circulated and humidified, the moisture in the outdoor air is absorbed by the first humidity conditioning block 200 or the second humidity conditioning block 300, then the moisture in the first humidity conditioning block 200 and the second humidity conditioning block 300 is regenerated by the heated air in the indoor air, the indoor air is discharged to the indoor air to be humidified, and the second fan 724 is arranged at the second air outlet end 722 of the air inlet channel 710 to drive the air flow to circulate, because the second heating mechanism 723 needs to be arranged at the second air inlet end 721, the air flow is heated first and then passes through the first humidity regulating block 200 or the second humidity regulating block 300, so that the second fan 724 is arranged at the second air outlet end 722, the second fan 724 and the second heating mechanism 723 are prevented from being arranged at adjacent positions, influence is generated between the second fan 724 and the second heating mechanism 723, the service life of each fan is shortened, and the installation structure is more reasonable.

Alternatively, the first heating mechanism 713 is identical in structure to the second heating mechanism 723. Taking the first heating mechanism 713 as an example, the first heating mechanism 713 is a rectangular frame structure, and a plurality of mica electric heating sheets uniformly arranged along the width direction thereof are disposed inside the first heating mechanism 713, and air passages are disposed between adjacent mica electric heating sheets. In this way, the airflow passing through the first heating mechanism 713 can be heated more uniformly, and the wind resistance is reduced, so that the airflow can better pass through, and the humidification or dehumidification can be better performed.

Alternatively, the vent B402 and the vent F406 are in communication with the second air exhaust end, and the vent D404 and the vent H408 are in communication with the second air intake end 721. Thus, the outdoor air entering from the second air intake end 721 can enter the housing 102 through the vent D404 or the vent H408, and is discharged to the second air exhaust end through the vent B402 or the vent F406 to be discharged to the outside, and the humidification or dehumidification is continuously performed by switching operation of the two alternate flow paths, so that the continuity of the humidification or dehumidification is maintained.

Optionally, an evaporator 800 is disposed in the first wind outlet end 712 and/or the second wind outlet end 722. In this way, since the evaporator 800 has a refrigerating effect, the water vapor can be condensed when meeting cold, and further a dehumidifying effect is achieved, so that the evaporator 800 is arranged at the first air outlet end 712 or the second air outlet end 722, and the air flow dehumidified by the first humidifying block 200 or the second humidifying block 300 can be dehumidified for the second time, thereby improving the dehumidifying efficiency.

Optionally, the evaporator 800 is disposed in the first outlet end 712. In this way, when there is a dehumidification demand indoors, the evaporator 800 provided in the first air outlet end 712 can perform secondary dehumidification to keep the air discharged indoors dry when the dehumidification is not complete by the first and second dehumidification blocks 200 and 300, thereby improving the dehumidification effect.

Optionally, a condenser 900 is provided in the first inlet end 711 and/or the second inlet end 721. Thus, when the air conditioner is adopted indoors for refrigeration, the condenser 900 communicated with the air conditioner is arranged at the first air inlet end 711 or the second air inlet end 721, the flowing air flow can be heated by utilizing the heat of the condenser 900, the water in the first humidity regulating block 200 or the second humidity regulating block 300 can be regenerated by utilizing the waste heat generated in the refrigeration process, the power of a heating mechanism is reduced, the utilization rate of energy is improved, and the air conditioner is more environment-friendly.

Optionally, a condenser 900 is disposed in each of the first air inlet end 711 and the second air inlet end 721. Therefore, under the condition of indoor refrigeration, the heat generated by the condenser 900 is mostly discarded, and the heat generated by the condenser 900 can be used for promoting the moisture in the first humidity control block 200 or the second humidity control block 300 to be released, so that the requirement on a heating mechanism is reduced, and the energy-saving and environment-friendly effects are achieved.

Alternatively, the evaporator 800 and the condenser 900 are connected to a compressor of an indoor air conditioner. Therefore, the compressor of the air conditioner is used for generating heat and cold, energy is saved, the environment is protected, and the cost is reduced.

Alternatively, the evaporator 800 and the condenser 900 are each provided with an on-off valve capable of controlling turning on or off the evaporator 800 and the refrigerator. Thus, the condenser 900 and some or all of the evaporators 800 can be turned on or off according to the operating conditions, thereby preventing the normal operation of humidification or dehumidification from being affected. For example, in the process of humidifying the indoor space, the condenser 900 needs to be turned off to prevent the moisture from being liquefied, thereby reducing the humidifying efficiency.

Optionally, the humidity conditioner further comprises: the evaporator 800 may be a cold end of the semiconductor refrigeration device, and the condenser 900 may be a hot end of the semiconductor refrigeration device. Therefore, the semiconductor refrigeration device can simultaneously utilize the cold quantity generated by the cold end of the semiconductor and the heat quantity generated by the hot end of the semiconductor during refrigeration, thereby improving the utilization rate of energy, being more energy-saving and environment-friendly, and being smaller in semiconductor refrigeration volume and convenient to install.

In some examples, when the humidity conditioner is in the condition of external circulation humidification, the first heating mechanism 713 is turned on, the second heating mechanism 723 is turned off, the vent 400 is turned on in a first combination mode, that is, the vent a401, the vent C403, the vent F406 and the vent H408 are turned on, the other vents 400 are turned off, after the set time of operation, the vent 400 is turned on in a second combination mode, that is, the vent B402, the vent D404, the vent E405 and the vent G407 are turned on, the other vents 400 are turned off, and the first combination mode and the second combination mode of the vent 400 are cyclically and alternately turned on, so that the external circulation humidification can be continuously performed. During operation, indoor air flow enters the second channel 105 from the second air inlet end 721, enters the second air outlet end 722 through the ventilation opening H408 and passes through the second humidity regulating block 300 in the second channel 105, moisture is absorbed by the second humidity regulating block 300 and then enters the second air outlet end 722 through the ventilation opening F406 to be discharged to the outside, outdoor air flow enters the first channel 104 through the first heating mechanism 713 after being heated by the first air inlet end 711 and passes through the ventilation opening A401 and the first humidity regulating block 200 in the first channel 104 to regenerate moisture in the first humidity regulating block 200, and enters the first air inlet end 711 through the ventilation opening C403 and then is discharged to the inside of the room, and enters the inside of the room together with moisture in outdoor air, so that the indoor humidity is improved; after the set time, the ventilation opening 400 is switched, the indoor air flow enters from the second air inlet end 721 and then enters the first channel 104 through the ventilation opening D404, passes through the first humidity regulating block 200 in the first channel 104, the moisture is absorbed by the first humidity regulating block 200, enters the second air outlet end 722 through the ventilation opening B402, is discharged to the outside, the outdoor air flow enters from the first air inlet end 711, is heated by the first heating mechanism 713, enters the second channel 105 through the ventilation opening E405, passes through the second humidity regulating block 300 in the second channel 105, regenerates the moisture in the second humidity regulating block 300, enters the first air inlet end 711 through the ventilation opening G407, is discharged to the inside, enters the inside together with the moisture in the outdoor air, increases the humidity in the inside of the room, and can humidify the inside of the room continuously, and the outdoor air is continuously supplemented to the inside of the room.

When the dehumidifier is in the outer circulation dehumidification condition, the second heating mechanism 723 is turned on, the first heating mechanism 713 is turned off, the vent 400 is turned on in a first combination mode, that is, the vent a401, the vent C403, the vent F406 and the vent H408 are turned on, the other vents 400 are turned off, after the operation setting time, the vent 400 is turned on in a second combination mode, that is, the vent B402, the vent D404, the vent E405 and the vent G407 are turned on, the other vents 400 are turned off, and the first combination mode and the second combination mode of the vent 400 are turned on alternately in a circulation mode, so that the outer circulation humidification can be continuously performed. During operation, outdoor airflow enters from the first air inlet end 711, enters the first channel 104 through the vent A401, passes through the first humidity regulating block 200 in the first channel 104, moisture contained in the outdoor airflow is absorbed by the first humidity regulating block 200, then enters the first air inlet end 711 through the vent C403, and is discharged into a room, indoor airflow enters from the second air inlet end 721, is heated by the second heating mechanism 723, then enters the second channel 105 through the vent H408, passes through the second humidity regulating block 300 in the second channel 105, moisture on the second humidity regulating block 300 is regenerated, enters the second air outlet end 722 through the vent F406, and is discharged to the outside to further reduce indoor humidity; after the set time, the ventilation opening 400 is switched, outdoor airflow enters the second channel 105 through the ventilation opening E405 from the first air inlet end 711, passes through the second humidity regulating block 300 in the second channel 105, moisture is absorbed by the second humidity regulating block 300, enters the first air inlet end 711 through the ventilation opening G407, then dry air is discharged into the room, indoor airflow enters the first channel 104 through the ventilation opening D404 after being heated by the second heating mechanism 723 from the second air inlet end 721, passes through the first humidity regulating block 200 in the first channel 104, moisture in the first humidity regulating block 200 is released, enters the second air outlet end 722 through the ventilation opening B402, is discharged to the outside together with indoor moisture, and humid air is discharged by continuously supplementing dry air, so that indoor dehumidification is rapidly performed.

When the dehumidifier is in the internal circulation dehumidification condition, the first heating mechanism 713 is turned on, the second heating mechanism 723 is turned off, the vent 400 is turned on in a third combined mode, that is, the vent a401, the vent B402, the vent G407 and the vent H408 are turned on, the other vents 400 are turned off, after the operation setting time, the vent 400 is turned on in a fourth combined mode, that is, the vent C403, the vent D404, the vent E405 and the vent F406 are turned on, the other vents 400 are turned off, and the third combined mode and the fourth combined mode of the vent 400 are alternately turned on in a circulating mode, so that the internal circulation dehumidification can be continuously performed. During operation, indoor air flow enters the second channel 105 from the second air inlet end 721, enters the second channel 105 through the vent H408, passes through the second humidity regulating block 300 in the second channel 105, is absorbed by the second humidity regulating block 300, enters the first air inlet end 711 through the vent G407, is discharged into the room again, enters the first channel 104 through the vent A401 after being heated by the first heating mechanism 713 from the first air inlet end 711, passes through the first humidity regulating block 200 in the first channel 104, regenerates moisture in the first humidity regulating block 200, enters the second air outlet end 722 through the vent B402, and is discharged to the outside to reduce indoor humidity; after the set time, the ventilation opening 400 is switched, the indoor air flow enters from the second air inlet end 721 and then enters the first channel 104 through the ventilation opening D404, and passes through the first humidity regulating block 200 in the first channel 104, the moisture is absorbed by the first humidity regulating block 200, enters the first air inlet end 711 through the ventilation opening C403, and is discharged to the indoor again, the outdoor air flow enters from the first air inlet end 711, is heated by the first heating mechanism 713, enters the second channel 105 through the ventilation opening E405, passes through the second humidity regulating block 300 in the second channel 105, the moisture in the second humidity regulating block 300 is regenerated, and enters the second air outlet end 722 through the ventilation opening F406, and is discharged to the outdoor, the indoor can be dehumidified continuously, and the outdoor air and the indoor air do not generate air exchange, and the quality of the indoor air is maintained.

When the humidity conditioner is in the working condition of internal circulation humidification, the second heating mechanism 723 is turned on, the first heating mechanism 713 is turned off, the vent 400 is turned on in a third combined mode, that is, the vent a401, the vent B402, the vent G407 and the vent H408 are turned on, the other vents 400 are turned off, after the working set time, the vent 400 is turned on in a fourth combined mode, that is, the vent C403, the vent D404, the vent E405 and the vent F406 are turned on, the other vents 400 are turned off, and the third combined mode and the fourth combined mode of the vent 400 are alternately turned on in a circulating mode, so that the internal circulation humidification can be continuously performed. During operation, outdoor airflow enters from the first air inlet end 711, enters the first channel 104 through the vent A401, passes through the first humidity regulating block 200 in the first channel 104, moisture contained in the outdoor airflow is absorbed by the first humidity regulating block 200, then enters the second air outlet end 722 through the vent B402, then dry air is discharged to the outdoor, indoor airflow enters from the second air inlet end 721, is heated by the second heating mechanism 723, then enters the second channel 105 through the vent H408, passes through the second humidity regulating block 300 in the second channel 105, moisture on the second humidity regulating block 300 is regenerated, enters the first air inlet end 711 through the vent G407, and humid air is discharged to the indoor; after the set time, the ventilation opening 400 is switched, outdoor air flow enters from the first air inlet end 711, enters the second channel 105 through the ventilation opening E405, passes through the second humidity regulating block 300 in the second channel 105, moisture is absorbed by the second humidity regulating block 300, enters the second air outlet end 722 through the ventilation opening F406, then dry air is discharged to the outdoor, indoor air flow enters from the second air inlet end 721, is heated by the second heating mechanism 723, enters the first channel 104 through the ventilation opening D404, passes through the first humidity regulating block 200 in the first channel 104, moisture in the first humidity regulating block 200 is released, enters the second air outlet end 722 through the ventilation opening C403, is discharged to the outdoor, can humidify the indoor continuously, and no air exchange between the outdoor air and the indoor air occurs, so that the quality of the indoor air is maintained.

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. A humidity conditioner, comprising:

the air conditioner comprises a shell (100), wherein a partition plate (700) is arranged in the shell (100), the shell (100) is divided into an air inlet channel (710) and an air outlet channel (720), and a mounting groove (701) is formed in the partition plate (700);

the air path switching mechanism (101) comprises a shell (102) and a sealing partition plate (103) arranged in the shell (102), a first channel (104) is defined between the shell (102) and one side surface of the sealing partition plate (103), a second channel (105) is defined between the shell (102) and the other side surface of the sealing partition plate (103), the shell (102) is arranged in the mounting groove (701) and penetrates through the air inlet channel (710) and the air exhaust channel (720), and a ventilation opening (400) which can be controlled to be opened or closed is arranged at the part of the shell (102) arranged in the air inlet channel (710) and the part of the shell (102) arranged in the air exhaust channel (720);

a first humidifying block (200) rotatably disposed within the first channel (104);

a second humidifying block (300) rotatably disposed within the second channel (105).

2. A damping machine according to claim 1, characterized in that the first damping block (200) divides the first duct (104) into a first zone (106) and a second zone (107), and in that the first zone (106) communicates with a vent a (401) and a vent C (403) in the case of a first position, the second zone (107) communicates with a vent B (402) and a vent D (404), and in that the first zone (106) communicates with the vent a (401) and the vent B (402) in the case of a second position, the second zone (107) communicates with the vent C (403) and the vent D (404).

3. The damping machine according to claim 1, characterized in that the second damping block (300) divides the second duct (105) into a third zone (108) and a fourth zone (109), and in the case of the first position the third zone (108) communicates with a vent E (405) and a vent G (407), the fourth zone (109) communicates with a vent F (406) and a vent H (408), in the case of the second position the third zone (108) communicates with the vent E (405) and the vent F (406), and the fourth zone (109) communicates with the vent G (407) and the vent H (408).

4. The damping machine according to claim 1, characterized in that the housing (102) is rectangular and that half of the ventilation openings (400) are arranged on a first side of the housing (102) and the remaining half of the ventilation openings (400) are arranged opposite on the housing (102) on a second side opposite to the first side.

5. The humidifier according to claim 1, further comprising:

the first driving mechanism (600) is connected with the first humidity regulating block (200) and can drive the first humidity regulating block (200) to rotate;

and a second driving mechanism (620) connected to the second damping block (300) and capable of driving the second damping block (300) to rotate.

6. The damping machine according to claim 1, characterized in that a switch assembly (500) is provided in each of the ventilation openings (400) to close or open the ventilation openings (400).

7. The damping machine according to any one of claims 1 to 6, characterised in that the air intake channel (710) comprises:

a first air inlet end (711), one end of which is communicated with the outside, the other end of which can be communicated with the first channel (104) or the second channel (105), and a first heating mechanism (713) is arranged inside;

and a first air outlet end (712), one end of which is communicated with the indoor space, the other end of which can be communicated with the first channel (104) or the second channel (105), and a first fan (714) is arranged in the first air outlet end.

8. The damping machine according to claim 7, characterized in that the exhaust duct (720) comprises:

a second air inlet end (721), one end of which is communicated with the indoor, the other end of which can be communicated with the first channel (104) or the second channel (105), and a second heating mechanism (723) is arranged in the second air inlet end;

and one end of the second air outlet end (722) is communicated with the outside, the other end of the second air outlet end can be communicated with the first channel (104) or the second channel (105), and a second fan (724) is arranged in the second air outlet end.

9. The damping machine according to claim 8, characterized in that an evaporator (800) is arranged in the first wind outlet end (712) and/or the second wind outlet end (722).

10. A damping machine according to claim 8, characterized in that a condenser (900) is arranged in the first air inlet end (711) and/or the second air inlet end (721).