CN212777668U - Air conditioner - Google Patents

Abstract

The application relates to the technical field of household appliances, and discloses an air conditioner, including: the device comprises an outdoor unit, a humidifier, a moisture absorption module, a waste heat collecting device and a radiator. A compressor is arranged in the outdoor unit; the humidifier is arranged on the outdoor unit and comprises a moisture absorption channel and a humidification channel; the moisture absorption module is configured to absorb moisture in the moisture absorption channel and release the moisture in the humidification channel; the waste heat collecting device is connected with the compressor and is configured to collect heat generated by the compressor; the radiator is connected with the waste heat collecting device and surrounds the periphery of the moisture absorption channel and/or the humidifying channel. In this application, collect the heat that the compressor during operation produced, utilize the heat to heat moisture absorption passageway and humidification passageway to prevent that the lateral wall of moisture absorption passageway and humidification passageway from producing the phenomenon of condensation because of the subcooling, and then improve the humidification effect.

Description

Air conditioner

Technical Field

The application relates to the technical field of household appliances, for example to an air conditioner.

Background

At present, most areas in China are dry and cold in winter, and the moisture content of air is low. Indoor air with low moisture content can accelerate body water loss, accelerate skin aging and cause respiratory diseases. The window is inconvenient to open for ventilation when the air is cold in winter, indoor air is not circulated, bacteria are easy to breed, and the health is not facilitated. In the related technology, the anhydrous humidification technology is mostly adopted for humidification, and the moisture of the adsorption material of the anhydrous humidification device is regenerated and directly sent to the room.

In the process of implementing the embodiments of the present disclosure, it is found that at least the following problems exist in the related art:

because the outdoor environment is lower in winter, the condensation phenomenon easily appears in humidification device's the pipeline, influences the humidification effect.

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 an air conditioner, which aims to solve the problem that the humidifying effect is influenced by the condensation phenomenon which easily occurs in a pipeline of a humidifying device because the outdoor environment is lower in winter.

In some embodiments, an air conditioner includes: the device comprises an outdoor unit, a humidifier, a moisture absorption module, a waste heat collecting device and a radiator. A compressor is arranged in the outdoor unit; the humidifier is arranged on the outdoor unit and comprises a moisture absorption channel and a humidification channel; the moisture absorption module is configured to absorb moisture in the moisture absorption channel and release the moisture in the humidification channel; the waste heat collecting device is connected with the compressor and is configured to collect heat generated by the compressor; the radiator is connected with the waste heat collecting device and surrounds the periphery of the moisture absorption channel and/or the humidifying channel.

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

collect the heat that the compressor during operation produced to on transmitting the heat to the radiator, encircle the radiator on moisture absorption passageway and heating channel, utilize the heat to heat moisture absorption passageway and humidification passageway, thereby prevent that the lateral wall of moisture absorption passageway and humidification passageway from producing the phenomenon of condensation because of the subcooling, and then improve the humidification effect.

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 view of the interior of a humidifier according to an embodiment of the present disclosure;

fig. 2 is a schematic structural view of the exterior of a humidifier provided by an embodiment of the present disclosure;

fig. 3 is a schematic structural view of the interior of a humidifier provided by an embodiment of the present disclosure;

fig. 4 is a schematic structural view of the moisture absorption module and the slide rail according to the embodiment of the present disclosure;

FIG. 5 is an enlarged view of portion B of FIG. 4;

fig. 6 is a schematic structural diagram of a humidifier provided in an embodiment of the present disclosure connected to a centrifugal fan and an axial flow fan;

fig. 7 is a schematic structural diagram of a humidifier provided by an embodiment of the present disclosure connected to a gas valve;

FIG. 8 is a schematic structural diagram of a gas valve provided by an embodiment of the present disclosure;

fig. 9 is a schematic structural view of a moisture absorption module and a driving device provided in an embodiment of the present disclosure;

fig. 10 is an enlarged view of a portion a in fig. 9;

fig. 11 is a schematic structural view of the interior of another humidifier provided by an embodiment of the present disclosure;

FIG. 12 is a schematic structural diagram of a connection between a rotating shaft and a motor according to an embodiment of the present disclosure;

fig. 13 is a schematic structural view of an example of the interior of a humidifier provided by an embodiment of the present disclosure;

fig. 14 is a schematic structural diagram of an air conditioner according to an embodiment of the present disclosure;

fig. 15 is a schematic structural view of a humidifier sidewall provided in an embodiment of the present disclosure;

fig. 16 is a schematic structural diagram of a waste heat collecting device provided by the embodiment of the disclosure;

FIG. 17 is a cross-sectional view of a waste heat collection device provided by an embodiment of the present disclosure;

fig. 18 is a schematic structural diagram of a combination of a spiral pipe structure and a humidifying pipeline provided by the embodiment of the disclosure;

fig. 19 is a schematic structural diagram of a humidifying pipeline provided by the embodiment of the present disclosure;

FIG. 20 is a schematic structural view of a grid structure in combination with humidification channels provided by embodiments of the present disclosure;

fig. 21 is a schematic structural diagram of a connection between a waste heat collecting device and a grid structure provided in the embodiment of the present disclosure;

fig. 22 is a schematic structural diagram of another air conditioner provided in the embodiment of the present disclosure;

fig. 23 is a schematic structural diagram of a first condenser provided in an embodiment of the present disclosure.

Reference numerals:

001. a humidifier; 100. a moisture absorption module; 100-1, part A; 100-2, part B; 200. a humidifier housing; 201. a moisture absorption channel; 201-1, A moisture absorption channel; 201-2, B moisture absorption channel; 202. a humidification channel; 203. a humidifying pipeline; 204. a slide rail; 205. a slider; 206. a chute; 207. a rotating shaft; 208. an interlayer; 209. a movable opening; 210. a gas valve; 211. a motor; 212. a rotating plate; 300. a drive device; 301. a rack; 302. a gear; 303. a motor; 400. an outdoor unit; 401. a compressor; 500. a waste heat collecting device; 501. a heat dissipation port; 502. a heat conductive layer; 503. a heat-insulating layer; 504. a heat conducting pipeline; 505. a first connecting pipe; 506. a T-shaped joint; 507. a stop valve; 508. an airflow inlet; 600. a heat sink; 601. a spiral pipe structure; 602. a grid structure; 603. a heat dissipation pipeline; 604. an airflow outlet; 605. an air pump; 700. a first condenser; 701. a second connecting pipe; 702. a thermal insulation layer; 703. a heat absorption pipeline; 704. a control valve; 705. a second 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 connection with fig. 1-12, embodiments of the present disclosure provide a humidifier. The method comprises the following steps: a humidifier housing 200 including a humidification passage 202 and moisture absorption passages 201 adjoining to both sides of the humidification passage 202; the moisture absorption module 100 is arranged in such a way that a part of the moisture absorption module is positioned in the humidification channel 202 to release moisture and the other part of the moisture absorption module is positioned in the moisture absorption channel 201 to absorb moisture; a driving device 300 connected to the moisture absorption module 100 and configured to drive the moisture absorption module 100 to move back and forth between the humidification passage 202 and the moisture absorption passage 201; when a part of the moisture absorption module 100 is located in the humidification passage 202 to release moisture, the remaining part is located in the moisture absorption passage 201 to absorb moisture.

Like this, moisture absorption module 100 absorbs moisture in moisture absorption passageway 201, release moisture in humidification passageway 202, can let in the moisture of release indoor, to indoor humidification, drive arrangement 300 drives moisture absorption module 100 reciprocal translation in the movable passage between moisture absorption passageway 201 and humidification passageway 202, accomplish the process of absorbing moisture and release moisture simultaneously, can be for a long time to indoor humidification, cancel the basin that traditional air conditioner humidification was used, the problem of there being the easy scale deposit of basin to breed the bacterium is solved, and sustainable humidification, the humidification scope is wider.

Alternatively, the moisture absorption channels 201 are provided in an even number and symmetrically arranged at both sides of the humidification channel 202. Thus, when a part of the moisture absorption module 100 moves from one side of the moisture absorption channel 201 to the humidification channel 202, the part of the original humidification channel 202 moves from the humidification channel 202 to the other side of the moisture absorption channel 201, so that the other part of the moisture absorption module 100 releases moisture while absorbing moisture, and humidification can be continued.

Optionally, two or more moisture absorption channels 201 on the same side of the humidification channel 202 are adjacent to each other. Thus, the distance between the moisture absorption channels 201 is short, which facilitates the movement of the moisture absorption module 100 in different moisture absorption channels 201.

Alternatively, the moisture absorption channel 201 and the humidification channel 202 are adjacently arranged, and the moisture absorption channel 201 and the humidification channel 202 are adjacent and connected through only one partition layer 208.

Alternatively, the humidifying passage 202 has the same width as that of one moisture absorbing passage 201. Therefore, the part of the moisture absorption module 100 absorbing moisture in the moisture absorption channel 201 can just enter the humidifying channel 202 to release moisture, the utilization rate of the moisture absorption module 100 is improved, and the humidifying efficiency is increased.

Alternatively, the width of the moisture absorption module 100 is the same as the depth of the humidification channel 201, and the length of the moisture absorption module 100 is equal to the sum of the width of one humidification channel 202 and the width of one moisture absorption channel 201. Therefore, while the moisture absorption channel 201 can keep the moisture absorption of the moisture absorption module 100, the humidification channel 202 can release the moisture from other parts, the utilization rate of the moisture absorption module 100 is improved, and the humidification efficiency is increased.

Alternatively, the width of the moisture absorption module 100 is the same as the depth of the moisture absorption channel 201 and the depth of the humidification channel 202, and the length of the moisture absorption module 100 is equal to the sum of the width of the humidification channel 202 and the width of all the moisture absorption channels 201 on one side of the humidification channel 202. Thus, when the moisture is released from the part at one end of the moisture absorption module 100 in the humidification channel 202, the other part of the moisture absorption module 100 can absorb the moisture in the whole moisture absorption channel 201 at one side of the humidification channel 202, so that the utilization rate of the moisture absorption channel 201 is improved, the moisture absorption efficiency is improved, and the overall humidification efficiency is further improved.

Optionally, the width of the absorbent module 100 is the distance between the front side and the back side of the absorbent module 100; the depth of the moisture absorption channel 201 is the distance between the front inner wall and the rear inner wall of the moisture absorption channel 201; the depth of the humidification passage 202 is the distance between the front-side inner wall and the rear-side inner wall of the humidification passage 202.

Optionally, the length of the absorbent module 100 is the distance between the left side and the right side of the absorbent module 100; the width of the moisture absorption channel 201 is the distance between the left inner wall and the right inner wall of the moisture absorption channel 201; the width of the humidification passage 202 is the distance between the left and right inner walls of the humidification passage 202.

Optionally, the moisture absorption module 100 is slidably connected to the humidification duct 202 and the inner wall of the moisture absorption duct 201 through a slide rail 204, and is configured to make the moisture absorption module 100 reciprocate along the slide rail 204 under the driving of the driving device 300. Thus, the moisture absorption module 100 can move back and forth along the slide rail 204, and the moving stability of the moisture absorption module 100 is improved.

Alternatively, the sliding rails 204 are strip-shaped protrusions disposed on the inner walls of the humidification duct 202 and the moisture absorption duct 201, and the edges of the moisture absorption module 100 are disposed on the strip-shaped protrusions and can slide along the strip-shaped protrusions. Thus, the structure is simple, and the moisture absorption module 100 can be conveniently disassembled and assembled.

Optionally, the sliding track 204 comprises: a slide block 205 and a slide groove 206, wherein the slide block 205 can slide in the slide groove 206, and one of the slide block and the slide groove is arranged on the moisture absorption module 100, and the other is arranged on the inner walls of the humidification channel 202 and the moisture absorption channel 201. Thus, the moisture absorption module 100 can move back and forth along the slide rail 204, and the moving stability of the moisture absorption module 100 is improved.

Alternatively, the length of the sliding block 205 is smaller than that of the sliding groove 206, the sliding groove 206 is arranged on the inner wall of the humidifying channel 202 and the moisture absorption channel 201, and the sliding block 205 is arranged on the moisture absorption module 100. Thus, the moisture absorption module 100 can move back and forth along the slide rail 204, and the moving stability of the moisture absorption module 100 is improved.

Optionally, the sliding rail 204 extends through the humidification passage 202 and the moisture absorption passage 201. Thus, the moisture absorption module 100 can slide back and forth between the humidification channel 202 and the moisture absorption channel 201 along the slide rail 204, and the moisture absorption module 100 can move between the humidification channel 202 and the moisture absorption channel 201 conveniently.

Optionally, a heating device is provided in the humidification passage 202. Therefore, the air flow can be directly introduced into the humidifying channel 202, the passing air flow is heated through the heating device, the temperature is increased, the humidifying module in the humidifying channel 202 releases moisture in the heated air flow, and the moisture release efficiency is improved.

Optionally, the air outlets of the humidifying channel 202 and the moisture absorbing channel 201 are provided with a centrifugal fan or an axial flow fan. Like this, adopt centrifugal fan or axial fan at the exit position, usable negative pressure forms the air current in humidification passageway 202 and moisture absorption passageway 201, and then makes the air current more even stable when moisture absorption module 100, improves the stability of moisture absorption process and humidification process to select centrifugal fan or axial fan according to the demand, axial fan simple structure stable performance, centrifugal fan produces the negative pressure great and can change the wind direction.

Optionally, the air outlets of the humidifying channel 202 and the moisture absorbing channel 201 are communicated with the air inlet of a centrifugal fan or an axial flow fan. Like this, usable centrifugal fan or axial fan form the negative pressure in humidification passageway 202 and moisture absorption passageway 201, and the guide air current passes through humidification passageway 202 and moisture absorption passageway 201, and then more even stable when making the air current pass through moisture absorption module 100, improves the stability of moisture absorption process and humidification process.

Optionally, the air outlet of the humidification channel 202 is provided with a centrifugal fan, and the air outlet of the moisture absorption channel 201 is provided with an axial flow fan. Thus, the air outlet of the humidifying channel 202 turns and discharges the humidified air flow through the centrifugal fan, so that the humidifying channel is conveniently connected with a humidifying pipeline to introduce the humidified air flow into a space needing to be humidified; the air outlet of the moisture absorption channel 201 adopts an axial flow fan to directly discharge the air flow which is absorbed moisture in the moisture absorption channel 201, and the structure is simple and the performance is stable.

Optionally, an air outlet of the humidification channel 202 is communicated with an air inlet of a centrifugal fan, and the air outlet of the centrifugal fan is perpendicular to the humidification channel 202. In this way, it is convenient to separately lead out the humidified gas flowing out of the humidification passage 202 in one direction.

Optionally, an air inlet grille and a filter layer are arranged between the air inlets of the humidifying channel 202 and the moisture absorption channel 201 and the moisture absorption module 100. In this way, dust in the air can be filtered. Preventing dust from being deposited on the moisture absorption module 100, resulting in a decrease in the ventilation of the moisture absorption module 100.

Alternatively, both the centrifugal fan and the axial fan may be rotated in opposite directions. In this way, the moisture absorption module 100 and the air intake grill and filter layer are cleaned of dust by reverse blowing.

Optionally, the air inlet of the humidification channel 202 and the moisture absorption channel 201 is provided with an air valve 210, the air valve can move 360 degrees, when the air valve 210 is perpendicular to the air inlet, the humidification channel 202 or the moisture absorption channel 201 is opened, and when the air valve 210 is horizontal to the air inlet, the humidification channel 202 or the moisture absorption channel 201 is closed. Thus, the humidifying passage 202 and the moisture absorption passage 201 can be opened or closed to prevent dust from entering when not in use.

Optionally, the gas valve 210 comprises: a motor 211 having a rotating shaft; and a rotation plate 212 having a side connected to a rotation shaft of the motor 211. In this way, the motor 211 rotates the rotating plate to open or close the humidification duct 202 or the moisture absorption duct 201.

Optionally, sensing devices are arranged in the humidifying channel 202 and the moisture absorption channel 201, and are used for sensing whether the humidifying channel 202 or the moisture absorption channel 201 provided with the sensors has the moisture absorption module 100; the sensor can be an infrared sensing switch; when the moisture absorption module 100 is sensed not to be arranged in the humidification channel 202 or the moisture absorption channel 201, the axial flow fan or the centrifugal fan communicated with the humidification channel 202 or the moisture absorption channel 201 is closed, and the gas valve 210 at the gas inlet of the humidification channel 202 or the moisture absorption channel 201 is closed.

Optionally, a movable opening 209 is arranged on the partition 208 between the moisture absorption channel 201 and the humidification channel 202, and the moisture absorption module 100 reciprocates in the movable opening 209.

Alternatively, the size of the access opening 209 may be the same as the size of the cross-section of the absorbent module 100 through the access opening 209. In this way, the size of the moisture absorption module 100 completely closes the movable opening 209, and prevents the air flows in the humidification passage 202 and the moisture absorption passage 201 from communicating with each other, which affects the overall humidification effect.

Optionally, a sealing strip is arranged around the movable opening 209. In this way, the sealing property between the movable opening 209 and the moisture absorption module 100 is improved by the sealing tape.

Alternatively, the driving device 300 includes: a rack 301 disposed on the moisture absorption module 100; a gear 302 engaged with the rack 301; a motor 303 including a power output portion fixedly connected to the gear 302; the gear 302 is driven by the motor 303 to rotate, so as to drive the rack 301 and the moisture absorption module 100 to reciprocate. Therefore, the gear 302 is driven by the motor 303 to rotate through the structure of the gear 302 engaged with the rack 301, so that the moisture absorption module 100 can move back and forth, the position of the moisture absorption module 100 can be switched conveniently, and the moisture absorption process and the humidification process can be completed conveniently.

Alternatively, the rack 301 is provided on the frame of the absorbent module 100. Thus, the firmness of the rack 301 is improved, the damage rate of the rack 301 is reduced, and the service life is prolonged.

Optionally, the rack 301 is integrated with the bezel. Thus, the rigidity of the rack 301 is improved.

Alternatively, the moisture absorption module 100 is rotatably connected with the middle position of the partition 208 between the humidification channel 202 and the moisture absorption channel 201 through the rotating shaft 207, and the driving device 300 drives the moisture absorption module 100 to rotate along the rotating shaft 207. Thus, rotation along the rotation axis 207 facilitates switching of the positions of both ends of the absorbent module 100.

Optionally, the hinge 207 is connected to the frame of the moisture absorption module 100. Thus, the robustness of the connection of the shaft 207 to the moisture absorption module 100 is improved.

Alternatively, the driving device 300 includes: and a motor 303 having a motor shaft and a power output part connected to the motor shaft, wherein the motor shaft is connected to the rotating shaft 207, and the motor shaft is driven by the motor 303 to rotate so as to drive the motor shaft and the moisture absorption module 100 to rotate. Like this, through the drive of motor 303, make moisture absorption module 100 can rotate the both ends switching position of being convenient for moisture absorption module 100 along pivot 207, the other end gets into moisture absorption passageway 201 when moisture absorption module 100's one end gets into humidification passageway 202, can accomplish simultaneously and absorb moisture and release moisture, is convenient for continuously carry out the humidification.

Fig. 13 is a schematic structural diagram illustrating an example of the interior of a humidifier 001 provided by an embodiment of the present disclosure;

as an example, the humidifier 001 includes a humidifying channel 202 and two moisture absorption channels 201, the two moisture absorption channels 201 are an a moisture absorption channel 201-1 and a B moisture absorption channel 201-2, respectively, wherein the width of the humidifying channel 202, the width of the a moisture absorption channel 201-1 and the width of the B moisture absorption channel 201-2 are the same; a moisture absorption module 100 having a length equal to the sum of the width of the humidification passage 202 and the width of a moisture absorption passage 201 and divided into an A part 100-1 and a B part 100-2 from the middle; when the part A100-1 is positioned in the airflow in the moisture absorption channel A201-1 to absorb moisture, the part B100-2 is positioned in the heated airflow in the humidification channel 202 to release moisture, the driving device 300 drives the moisture absorption module 100 to translate after a preset time, so that the part A100-1 enters the heated airflow in the humidification channel 202 to release moisture, and the part B100-2 enters the airflow in the moisture absorption channel B201-2 to absorb moisture, and with the reciprocating movement of the moisture absorption module 100, one of the part A100-1 and the part B100-2 is always kept to release moisture in the humidification channel 202, and then humidification is continuously performed.

As shown in fig. 14 to 21, an embodiment of the present disclosure provides an air conditioner including: the humidifier of any one of the above embodiments.

In some embodiments, an air conditioner includes: the outdoor unit 400, the humidifier 001, the moisture absorption module 100, the waste heat collecting device 500, and the radiator 600. A compressor 401 is provided in the outdoor unit 400; the humidifier is arranged on the outdoor unit 400 and comprises a moisture absorption channel 201 and a humidification channel 202; the moisture absorption module 100 is configured to absorb moisture in the moisture absorption channel 201 and release moisture in the humidification channel 202; the waste heat collecting device 500 is connected with the compressor 401 and configured to collect heat generated by the compressor 401; the radiator 600 is connected with the residual heat collecting device 500 and surrounds the circumference of the moisture absorption channel 201 and/or the humidification channel 202.

The air conditioner provided by the embodiment of the disclosure can collect heat generated by the compressor 401 during operation, and transfer the heat to the radiator 600, surround the radiator 600 on the moisture absorption channel 201 and the heating channel, and heat the moisture absorption channel 201 and the humidification channel 202 by using the heat, so that the phenomenon that condensation is generated on the side walls of the moisture absorption channel 201 and the humidification channel 202 due to supercooling is prevented, and the humidification effect is further improved.

Optionally, the outlet end of the humidification channel 202 is connected to the room through a humidification pipe 203. Therefore, the humidified air flow is conveniently conveyed to the indoor, and the humidity of the indoor environment is improved.

Optionally, the radiator 600 is further disposed to surround the humidification line 203. In this way, the humidifying pipeline 203 is heated by the radiator 600, and condensation caused by supercooling of the side wall of the humidifying pipeline 203 is prevented.

Optionally, a thermal insulation sleeve is disposed outside the humidification pipe 203, and the heat sink 600 is surrounded between the humidification pipe 203 and the thermal insulation sleeve. Therefore, the heat of the radiator 600 can be prevented from being dissipated outwards, the humidifying pipeline 203 can be better heated by the radiator 600, and the anti-condensation effect is improved.

Optionally, the heat sink 600 includes: the spiral tube structure 601 surrounds the side wall of the moisture absorption channel 201 and/or the humidification channel 202. Thus, the heat radiator 600 can heat the moisture absorption channel 201 and the humidification channel 202 more uniformly, and the heat exchange efficiency between the heat radiator 600 and the side walls of the moisture absorption channel 201 and the humidification channel 202 is improved.

Optionally, the heat sink 600 surrounds the side walls of the humidification channel 202. Thus, the humidity in the humidification channel 202 is high, and condensation is easily generated, and the side wall of the humidification channel 202 is heated by the radiator 600, so that the condensation on the side wall of the humidification channel 202 can be effectively prevented.

Optionally, a heat sink 600 surrounds the humidification channel 202 and the humidification line 203. In this way, the humidification channel 202 and the humidification pipeline 203 are both in positions where condensation is easily generated, and the humidification channel 202 and the humidification pipeline 203 are heated by the radiator 600, so that the condensation phenomenon generated on the humidification channel 202 and the humidification pipeline 203 can be effectively prevented.

Alternatively, the radiator 600 passes through the humidification channel 202 and then the humidification pipe 203. Thus, the humid air forms humid and hot air after being heated by the humidifying channel 202, and the humid and hot air is more prone to generating condensation when being cooled, so that the radiator 600 heats the humidifying channel 202 through the timely channel, the temperature of the side wall of the humidifying channel 202 can be increased, and the humid and hot air is prevented from being pre-cooled and condensed.

Optionally, a radiator 600 is disposed on each of the humidification channel 202 and the humidification pipe 203. Like this, heat humidification passageway 202 and humidification pipeline 203 through different radiators 600 respectively, make humidification passageway 202 and humidification pipeline 203 all with obtain the heat, make the heating more even, prevent that local heating temperature from causing the temperature to be lower inadequately, produce the condensation phenomenon.

Alternatively, the spiral tube structure 601 of the radiator 600 passes through the humidifying passage 202 and then passes through the moisture absorbing passage 201. In this way, the heat radiator 600 heats the humidification passage 202 preferentially and then heats the moisture absorption passage 201, so that the heat quantity for heating the moisture absorption passage 201 is prevented from being too high, and the moisture absorption module 100 in the moisture absorption passage 201 is prevented from absorbing moisture.

Alternatively, the spiral tube structure 601 of the radiator 600 is embedded in the side wall of the humidification passage 202 and/or the moisture absorption passage 201. In this way, the heat sink 600 does not occupy the space in the humidification channel 202 and/or the moisture absorption channel 201, thereby avoiding forming wind resistance, affecting the airflow passing through the humidification channel 202 and/or the moisture absorption channel 201, and embedding the heat sink 600 in the side wall of the humidification channel 202 and/or the moisture absorption channel 201, so that the side wall of the humidification channel 202 and/or the moisture absorption channel 201 can be better heated, and the heat is prevented from being dissipated into the humidification channel 202 and/or the moisture absorption channel 201.

Alternatively, the length of the coil structure 601 of the radiator 600 surrounding the humidification passage 202 is longer than the length of the coil structure surrounding the moisture absorption passage 201. Thus, the heat exchange amount between the radiator 600 and the humidification channel 202 is increased, the heat exchange amount between the radiator 600 and the moisture absorption channel 201 is reduced, and the phenomenon that the heat for heating the moisture absorption channel 201 is too high to influence the moisture absorption module 100 in the moisture absorption channel 201 to absorb moisture is prevented.

Alternatively, the toroidal tube structure 601 is a hollow tube with a phase change inhibiting material disposed therein. Like this, set up the phase transition suppression material through the hollow tube inside, can transmit the heat through the phase transition suppression material, reduce the thermal loss among the remote transmission process, improve thermal transmission efficiency.

Optionally, the heat sink 600 further comprises: a mesh structure 602 disposed within the humidification passage 202. In this way, the heat of the heat sink 600 is transferred into the humidification duct 202 through the mesh structure 602, and the airflow in the humidification duct 202 is heated, thereby promoting the regeneration of the moisture on the moisture absorption plate, more efficiently utilizing the heat of the heat sink 600, and reducing the energy consumption.

Optionally, the grid structure 602 is disposed at the windward end of the moisture absorption module 100, so that the heat of the grid structure 602 can be sufficiently dissipated into the humidification channel 202, and the utilization rate of the humidification channel 202 to the heat is improved.

Optionally, the mesh structure 602 covers the entire cross-section of the humidification channel 202. Thus, the contact area between the mesh structure 602 and the humidification channel 202 is increased, and the humidification channel 202 can sufficiently utilize the heat emitted by the mesh structure 602 to heat the moisture absorption module 100 in the humidification channel 202, thereby promoting the release of the moisture in the moisture absorption module 100.

Optionally, the lattice structure 602 is arranged obliquely within the humidification channel 202. Therefore, the contact area between the grid structure 602 and the humidifying channel 202 can be increased, the heat emitted by the grid structure 602 can be fully utilized by the humidifying channel 202, the moisture absorption modules 100 in the humidifying channel 202 are heated, the moisture in the moisture absorption modules 100 is promoted to be released, and the overall humidifying efficiency is further improved.

Optionally, the inclination angle of the lattice structure 602 is greater than or equal to 30 degrees and less than or equal to 60 degrees. Like this, the inclination setting of grid structure 602 is between 30 degrees to 60 degrees, can make grid structure 602 occupy the space of humidification passageway 202 little, can increase the area of contact of grid structure 602 and humidification passageway 202 again, guarantees that the heat that grid structure 602 gived off can be abundant by humidification passageway 202 utilization, improves humidification efficiency.

Optionally, the grid structure 602 is inclined at an angle of 45 degrees. Like this, both rationally utilized humidification passageway 202's space, conveniently installed grid structure 602, can guarantee again that grid structure 602 and humidification passageway 202 between area of contact is big, guarantee that the heat that grid structure 602 gived off can be abundant by humidification passageway 202 utilization, improve humidification efficiency.

Optionally, the air conditioner further includes: an auxiliary heating device is disposed in the humidification channel 202 and configured to supplement heat to promote the release of moisture on the moisture absorption module 100. In this way, the auxiliary heating device heats the passing airflow to increase the temperature, so that the humidification module in the humidification channel 202 releases moisture in the heated airflow, and the moisture release efficiency is improved.

Optionally, the auxiliary heating device is perpendicular to the inner wall of the humidification channel 202. Therefore, the auxiliary heating device is vertical to the direction of the air flow, so that the air flow can pass through the auxiliary heating device more easily, the passing air flow is heated completely, and the heating efficiency is improved.

Optionally, the auxiliary heating device is an electric heating wire. Like this, electrical heating possesses the high and fast characteristic of heating efficiency, heats through electric heating wire, can ensure to have sufficient heat in the heating channel to make moisture on the moisture absorption module 100 all released, promotes humidification efficiency.

Optionally, the auxiliary heating device is disposed between the lattice structure 602 and the moisture absorption module 100, so that the heat provided by the lattice structure 602 for the heating channel is smaller than the heat provided by the auxiliary heating device, and when the heat provided by the lattice structure 602 is insufficient, the auxiliary heating device can continuously release the heat, so that the heating channel has enough heat to release all the moisture on the moisture absorption module 100, thereby improving the humidification efficiency.

Optionally, the spiral tube structure 601 is in communication with a mesh structure 602, and the mesh structure 602 is connected to the waste heat collecting device 500. Like this, make waste heat collection device 500's heat pass through grid structure 602 earlier and pass through again spiral tube structure 601, reduce spiral tube structure 601's heat, prevent to the heating temperature of moisture absorption passageway 201 too high, influence moisture absorption efficiency of moisture absorption plate.

Optionally, the waste heat collecting device 500 is a sleeve structure and configured to cover the outside of the compressor 401. Like this, utilize the whole compressor 401 of the waste heat collection device 500 parcel of sleeve structure, with the better heat transfer of compressor 401, improve the efficiency that waste heat collection device 500 heat was collected.

Optionally, the sleeve structure is an arc-shaped plate, the cover is disposed on the side of the compressor 401, and the arc-shaped plate is provided with a heat dissipation opening 501. Thus, while collecting heat, the compressor 401 itself can still dissipate heat through the heat dissipating port 501, thereby preventing the stability of the operation of the compressor 401 from being affected by an excessively high temperature.

Optionally, the height of the sleeve structure is greater than or equal to the height of the compressor 401. Like this, make waste heat collection device 500 can be better collect the heat that compressor 401 gived off, it is higher to heat collection efficiency, prevented thermal loss.

Optionally, the waste heat collecting device 500 is detachably connected to the compressor 401. Like this, can dismantle the maintenance alone to waste heat collection device 500 to can directly install waste heat collection device 500 on current ordinary compressor 401, be convenient for reform transform current ordinary compressor 401.

Optionally, the waste heat collecting device 500 is fixedly connected with the compressor 401 through screws. Like this, can realize dismantling the connection, and the structure of screw fixation is relatively stable, can not cause and drop, improves the stability of connecting.

Optionally, the waste heat collecting device 500 includes: a heat conducting layer 502 disposed in close contact with the compressor 401; the heat insulation layer 503 is arranged outside the heat conduction layer 502; and a heat conducting pipe 504 arranged between the heat conducting layer 502 and the heat insulating layer 503. Thus, the heat conducting layer 502 is arranged close to the compressor 401, heat exchange with the compressor 401 can be better achieved, heat generated by the compressor 401 can be collected, the heat can be better transmitted through the heat conducting pipeline 504, the heat insulating layer 503 arranged on the outermost layer can prevent heat from dissipating, and heat can be better collected.

Optionally, the heat conducting layer 502 is made of graphene. Like this, the graphite alkene material possesses good heat conductivity, through adopting graphite alkene as heat-conducting layer 502, can high-efficient heat that the conduction compressor 401 gived off, has promoted heat transfer efficiency.

Optionally, the insulating layer 503 is made of glass wool. Therefore, the glass wool has good heat preservation performance, and can preserve heat of the waste heat collecting device 500 by adopting the glass wool as the heat preservation layer 503 to prevent heat dissipation.

Optionally, the heat conducting pipe 504 is provided in plurality. Thus, the heat of the heat conduction layer 502 can be efficiently conducted, and the heat transfer efficiency is improved.

Optionally, the waste heat collecting device 500 is connected to the radiator 600 through a first connection pipe 505. In this way, the waste heat collecting device 500 is transported to the radiator 600 through the first connecting pipe 505, and the humidifying channel 202 and the moisture absorbing channel 201 are better heated by the heat collected by the waste heat collecting device 500.

The first connection pipe 505 is connected with the waste heat collecting device 500 through a T-shaped joint 506, so that heat collected in the waste heat collecting device 500 is gathered and transferred to the first connection pipe 505 through the T-shaped joint 506, and heat transfer efficiency is improved.

Optionally, the T-joint 506 comprises: riser and cross tube. In this way, the vertical pipe is connected with the heat conduction pipeline 504, the heat in the heat conduction pipeline 504 is led out, the horizontal pipe is connected with the first connecting pipe 505, the horizontal pipe gathers the heat led out by the vertical pipe and transmits the heat to the first connecting pipe 505 connected with the horizontal pipe, and the heat transfer efficiency is improved.

Optionally, a plurality of connectors are disposed on the vertical pipe, and each connector is communicated with a heat conducting pipeline 504. Therefore, heat in the heat conduction pipeline 504 can be fully led out, the heat in the heat conduction pipeline 504 is completely transferred to the radiator 600, and the heat utilization rate is improved.

Optionally, a phase change inhibiting material is disposed within the first connecting tube 505. Therefore, heat is transmitted through the phase change inhibiting material, heat loss in the long-distance transmission process can be reduced, and heat transmission efficiency is improved.

Optionally, the air conditioner further comprises: and a shut-off valve 507 provided on the first connection pipe 505. In this way, the stop valve 507 can control to stop the transmission of heat, and thus stop the heating of the humidification passage 202 and the humidification passage 201.

Optionally, the valve core of the stop valve 507 is made of heat insulating material. Therefore, the heat transmission through the valve core caused by the heat conduction of the valve core can be prevented, and the heat transmission can not be cut off.

Optionally, the heat conducting pipe 504 is connected to the first connecting pipe 505 at one end, and is provided with an air inlet 508 at the other end. Thus, one end of the heat conduction pipeline 504 can be communicated with the air near the compressor 401, so that the air can be sucked, and the air flow is convenient to form.

Optionally, the grid structure 602 of the heat sink 600 is provided with heat dissipation pipes 603 distributed in a grid pattern. Therefore, the heat can be more uniformly transmitted to each part of the radiator 600 through the heat dissipation pipelines 603 distributed in a grid shape, so that the heat dissipation uniformity of the radiator 600 is improved, and the heat dissipation efficiency is further improved.

Optionally, the heat sink 600 is provided with an airflow outlet 604 communicating with the heat dissipation pipeline 603. In this way, the hotter air flow in the heat dissipation pipeline 603 can be directly discharged into the humidification channel 202, and the hotter air flow is directly used for heating the humidification module 100, so that the heat transfer efficiency is higher, and the heat generated by the compressor 401 can be more efficiently used.

Optionally, the first connection pipe 505 is a hollow structure configured to communicate the heat conduction pipe 504 and the heat dissipation pipe 603. Thus, the heat conducting pipe 504 is communicated with the heat dissipating pipe 603 through the first connecting pipe 505 to form a complete air flow passage, which facilitates the air flow heated by the compressor 401 to be delivered to the vicinity of the heat sink 600.

Optionally, an air pump 605 is disposed on the first connection pipe 505, and configured to deliver the air flow at one end of the heat conducting pipe 504 to one end of the heat dissipating pipe 603. Thus, the air flow heated in the heat conduction pipeline 504 can be efficiently conveyed to one end of the heat dissipation pipeline 603 and discharged into the humidification channel 202, thereby promoting the moisture absorption module 100 to release moisture and improving the humidification effect.

Optionally, the air conditioner further comprises: and a controller configured to control the opening or closing of the stop valve 507 according to the outdoor environment temperature and humidity and the temperature and humidity at the outlet of the humidification passage 202. Like this, judge through the difference of humidification passageway 202 export humiture and outdoor environment humiture whether humidification passageway 202 and moisture absorption passageway 201 department can the condensation, heat or stop heating humidification passageway 202 and moisture absorption passageway 201 then to prevent to produce the phenomenon of condensation because of the subcooling, and then improve the humidification effect.

Optionally, the controller is further configured to control the air pump 605 to be turned on or off according to the outdoor environment temperature and humidity and the temperature and humidity at the outlet of the humidification channel 202. Like this, judge through the difference of humidification passageway 202 export humiture and outdoor environment humiture whether humidification passageway 202 and moisture absorption passageway 201 department can the condensation, heat or stop heating humidification passageway 202 and moisture absorption passageway 201 then to prevent to produce the phenomenon of condensation because of the subcooling, and then improve the humidification effect.

As shown in fig. 22 and 23, an embodiment of the present disclosure provides another air conditioner, which further includes: a first condenser 700. The first condenser 700 communicates with a refrigerant in the compressor 401. In this way, the condenser of the compressor 401 can be used to generate heat, the heat is transferred to the radiator 600, the radiator 600 is surrounded on the moisture absorption channel 201 and the heating channel, the moisture absorption channel 201 and the humidification channel 202 are heated by the heat generated by the condenser, the phenomenon that condensation is generated on the side walls of the moisture absorption channel 201 and the humidification channel 202 due to supercooling is prevented, and the humidification effect is further improved

Alternatively, the first condenser 700 communicates with the radiator 600 through a second connection pipe 701. In this way, the heat generated by the first condenser 700 is efficiently transferred to the radiator 600.

Optionally, the first condenser 700 is externally covered with a heat insulating layer 702, and a plurality of heat absorbing pipes 703 are provided between the heat insulating layer 702 and the first condenser 700. Therefore, the heat generated by the first condenser 700 can be concentrated to prevent the heat from being dissipated, and the heat dissipated by the first condenser 700 can be better collected.

Alternatively, the plurality of heat absorption pipelines 703 are each in communication with the second connection pipe 701. In this way, the heat generated at each position of the first condenser 700 can be intensively transferred into the second connection pipe 701, thereby improving the heat collection efficiency.

Optionally, the air conditioner further comprises: and a control valve 704 provided in a passage between the first condenser 700 and the compressor 401. In this way, the refrigerant flowing to the first condenser 700 may be cut off, and the operation of the first condenser 700 may be stopped, thereby facilitating the control of the anti-condensation process.

Optionally, the controller is further configured to control the opening or closing of the control valve 704 according to the outdoor environment temperature and humidity and the temperature and humidity at the outlet of the humidification channel 202. Like this, judge through the difference of humidification passageway 202 export humiture and outdoor environment humiture whether humidification passageway 202 and moisture absorption passageway 201 department can the condensation, heat or stop heating humidification passageway 202 and moisture absorption passageway 201 then to prevent to produce the phenomenon of condensation because of the subcooling, and then improve the humidification effect.

Optionally, the air conditioner further comprises: a second condenser 705. The second condenser 705 and the first condenser 700 are connected in parallel to a refrigerant circuit of the compressor 401. In this way, after the control valve 704 closes the first condenser 700, the second condenser 705 can be used to dissipate heat, thereby maintaining the normal operation of the compressor 401.

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 (10)

1. An air conditioner, comprising:

an outdoor unit having a compressor therein;

the humidifier is arranged on the outdoor unit and comprises a moisture absorption channel and a humidification channel;

a moisture absorption module configured to absorb moisture in the moisture absorption channel and release moisture in the humidification channel;

the waste heat collecting device is connected with the compressor and is configured to collect heat generated by the compressor;

and the radiator is connected with the waste heat collecting device and surrounds the periphery of the moisture absorption channel and/or the humidifying channel.

2. The air conditioner according to claim 1, wherein the radiator comprises:

and the spiral pipe structure is wound on the side wall of the moisture absorption channel and/or the humidifying channel.

3. The air conditioner according to claim 2, wherein the spiral pipe structure of the radiator passes through the humidifying passage first and then passes through the moisture absorbing passage.

4. The air conditioner according to claim 2, wherein the length of the coil structure of the radiator that surrounds the humidification passage is greater than the length of the coil structure that surrounds the moisture absorption passage.

5. The air conditioner of claim 1, wherein the waste heat collecting device is a sleeve structure configured to cover the outside of the compressor.

6. The air conditioner according to claim 5, wherein the residual heat collecting means includes:

the heat conduction layer is arranged close to the compressor;

the heat-insulating layer is arranged on the outer side of the heat-conducting layer;

and the heat conduction pipeline is arranged between the heat conduction layer and the heat insulation layer.

7. The air conditioner according to any one of claims 1 to 6, wherein the waste heat collecting device is connected to the radiator through a first connection pipe.

8. The air conditioner according to claim 7, wherein a phase change suppressing material is provided in the first connection pipe.

9. The air conditioner according to claim 7, further comprising:

and the stop valve is arranged on the first connecting pipe.

10. The air conditioner according to claim 9, further comprising:

and the controller is configured to control the opening or closing of the stop valve according to the outdoor environment temperature and humidity and the temperature and humidity at the outlet of the humidification channel.

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