CN217383143U - Low-temperature dehumidification and drying all-in-one machine - Google Patents

Abstract

The application discloses low temperature dehumidification drying machine belongs to air low temperature dehumidification technical field. The all-in-one machine comprises an air supply system and a regenerative air exhaust system, wherein the air supply system forms a diversion chamber, a treatment chamber and an air supply chamber which are communicated with each other; the regeneration air exhaust system forms a regeneration air inlet chamber, a regeneration chamber and a regeneration air exhaust chamber which are communicated, the regeneration air inlet chamber is provided with a regeneration air inlet, the regeneration air inlet chamber is internally provided with a dust removal roller, the regeneration chamber is internally provided with a rotating wheel and is arranged above the treatment chamber, and the regeneration air exhaust chamber is provided with a regeneration air outlet. The air dehumidification system comprises a regeneration air inlet cavity, a regeneration air outlet cavity, a regeneration air inlet cavity and a regeneration air inlet cavity, wherein the regeneration air inlet cavity is arranged in the air inlet cavity, and the regeneration air inlet cavity is arranged in the air inlet cavity.

Description

Low-temperature dehumidification and drying integrated machine

Technical Field

The application relates to a low temperature dehumidification drying machine belongs to air low temperature dehumidification technical field.

Background

The conventional low-temperature air dryer is suitable for spaces with the temperature of more than 7 ℃ and the relative humidity of more than 70 percent and needing dehumidification, and some spaces have lower humidity requirements, for example, when the humidity is required to be 20-50 percent, a unit needs to operate for a long time, so that the load of the unit is increased.

Furthermore, the regeneration air adopted by the existing low-temperature dryer is untreated air, and impurities or bacteria contained in the air can be brought into a room after circulation, so that the indoor air quality is increasingly poor, and human diseases are easily caused.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the application provides a low-temperature dehumidifying dryer which adopts a regenerative exhaust system and an air supply system, can dehumidify air entering a room at a low temperature, can remove dust and sterilize regenerated air by a dust removal roller arranged in a regenerative air inlet cavity, and improves the quality of the air entering the room.

According to an aspect of the present application, there is provided a low temperature dehumidification drying all-in-one machine, including:

the air supply system forms a flow guide cavity, a treatment cavity and an air supply cavity which are communicated, the flow guide cavity is provided with an air supply inlet, a rotating wheel is arranged in the treatment cavity, a condenser is arranged between the treatment cavity and the flow guide cavity, and an air feeder is arranged in the air supply cavity and is provided with an air supply outlet;

the regeneration air exhaust system, regeneration air exhaust system forms regeneration air inlet cavity, regeneration cavity and the regeneration air exhaust cavity that is linked together, regeneration air inlet has been seted up to regeneration air inlet cavity, be provided with the dust removal cylinder in the regeneration air inlet cavity, the last gas outlet of having seted up of dust removal cylinder, dust removal cylinder one end and regeneration air inlet connection, the other end seal sets up, be provided with the runner in the regeneration cavity, the regeneration cavity sets up the top of handling the cavity, the regeneration cavity with be provided with the heater between the regeneration air inlet cavity, be provided with the exhaust fan in the regeneration air exhaust cavity to the regeneration air outlet has been seted up.

Optionally, a first push plate is arranged in the dust removing roller and is in a circular ring shape, the outer periphery of the first push plate is clamped with the inner periphery of the dust removing roller, the first push plate is connected with the top of the dust removing roller through a first telescopic rod, and the first telescopic rod extends out to push the first push plate to move downwards.

Optionally, the dust removal roller is kept away from regeneration wind import one end is sealed through dust removal pipeline, the dust removal pipeline with the dust removal roller is linked together, the dust removal pipeline is close to regeneration cavity one side is provided with second telescopic link and second push pedal, the periphery of second push pedal with the inside wall block of dust removal pipeline, the dust removal pipeline is kept away from regeneration cavity one side is provided with the impurity export, the impurity export is sealed through sealed lid.

Optionally, a limiting block is arranged at the bottom of the dust removing roller, and the limiting block is close to the dust removing pipeline.

Optionally, still include the impurity catch bowl, the dust removal pipeline runs through the lateral wall of regeneration air inlet cavity, the impurity catch bowl sets up the outside of regeneration air inlet cavity, and set up impurity export below.

Optionally, still include clean pipe and clean shower nozzle in the regeneration air inlet cavity, clean pipe sets up on the inside wall of regeneration air inlet cavity to communicate with the feed liquor pump, clean shower nozzle sets up clean on the pipe.

Optionally, the number of the cleaning pipes is at least two, and the cleaning pipes are uniformly arranged on the inner side wall of the regeneration air inlet chamber,

at least two cleaning spray heads are arranged on each cleaning pipe and are uniformly arranged on the cleaning pipes.

Optionally, a first buffer chamber is further disposed between the processing chamber and the air supply chamber.

Optionally, a second buffer chamber is further disposed between the regeneration chamber and the regeneration exhaust chamber.

Optionally, a grid is arranged in the first buffer chamber, and flavoring particles are placed in the grid.

Optionally, the grille is in an "S" shape, and the circumferential direction of the grille abuts against the inner side wall of the first buffer chamber.

Benefits that can be produced by the present application include, but are not limited to:

1. the application provides a low temperature dehumidification drying machine, fresh air carries out two steps of dehumidification through condenser and processing cavity respectively to reduce the humidity that gets into the room air, improve dehumidification efficiency, and the dust removal cylinder can remove dust to the regeneration wind, avoids the regeneration wind to pollute the runner in the regeneration cavity, thereby avoids runner pollution fresh air, improves and gets into indoor air quality.

2. The application provides a low temperature dehumidification drying machine, first push pedal and the cooperation of second push pedal to release the impurity in the dust removal cylinder, clear up the dust removal cylinder, avoid impurity to block up the dust removal cylinder, improve the dust collection efficiency of dust removal cylinder.

3. The application provides a low temperature dehumidification drying machine, clean shower nozzle can spray the cleaning solution to the dust removal cylinder, can clean the dust removal cylinder, improves the inside cleanliness of dust removal cylinder, reduces clean blind area to improve dust removal cylinder's dust collection efficiency, can also give dust removal cylinder bactericidal effect, bacterium and the microorganism content in the reduction regeneration wind.

4. The application provides a low temperature dehumidification drying machine, the first surge chamber of setting can cushion fresh air, improves the stability of air supply outlet air intake, realizes evenly supplying air to be convenient for maintain comparatively stable indoor environment.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

FIG. 1 is a schematic structural diagram of a low-temperature dehumidification and drying all-in-one machine according to an embodiment of the present application;

FIG. 2 is a schematic side cross-sectional view of a regenerative intake chamber according to an embodiment of the present disclosure;

fig. 3 is a side cross-sectional schematic view of a baffle according to embodiments of the present application;

list of parts and reference numerals:

10. a flow-guiding chamber; 11. a guide plate, 111, a first guide hole; 112. a second flow guide hole; 113. a porous separator; 114. a liquid inlet; 115. a liquid outlet; 116. a liquid receiving tank; 117. a liquid inlet system; 12. a compressor; 13. an air supply inlet; 14. a condenser; 20. a processing chamber; 30. an air supply chamber; 31. a first heat exchanger; 32. an air supply outlet; 33. a blower; 40. a regenerative air intake chamber; 41. a regeneration air inlet; 42. a dust removal roller; 421. a first telescopic rod; 422. a first push plate; 423. a limiting block; 43. a dust removal pipeline; 431. a second telescopic rod; 432. a second push plate; 433. an impurity outlet; 434. a sealing cover; 44. an impurity recovery tank; 45. cleaning the tube; 46. cleaning the spray head; 50. a regeneration chamber; 51. a heater; 60. a regenerative exhaust chamber; 61. a regenerated air outlet; 62. an exhaust fan; 63. a second heat exchanger; 70. a first buffer chamber; 71. a grid; 80. a second buffer chamber.

Detailed Description

In order to more clearly explain the overall concept of the present application, the following detailed description is given by way of example in conjunction with the accompanying drawings.

In order that the above objects, features and advantages of the present application can be more clearly understood, the present application will be described in further detail below with reference to the accompanying drawings and detailed description. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, however, the present application may be practiced in other ways than those described herein, and therefore the scope of the present application is not limited by the specific embodiments disclosed below.

In addition, in the description of the present application, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", and the like, indicate orientations and positional relationships based on those shown in the drawings, are only for convenience of description and simplicity of description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral parts; the connection can be mechanical connection, electrical connection or communication; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through intervening media. In the description herein, reference to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the application. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Referring to fig. 1 to 3, an embodiment of the present application discloses a low-temperature dehumidification and drying all-in-one machine, which includes: the air supply system forms a diversion chamber 10, a treatment chamber 20 and an air supply chamber 30 which are communicated, the diversion chamber 10 is provided with an air supply inlet 13, a rotating wheel is arranged in the treatment chamber 20, a condenser 14 is arranged between the treatment chamber 20 and the diversion chamber 10, an air supply device 33 is arranged in the air supply chamber 30, and an air supply outlet 32 is formed; the regeneration air exhaust system comprises a regeneration air inlet cavity 40, a regeneration cavity 50 and a regeneration air exhaust cavity 60 which are communicated with each other, wherein the regeneration air inlet cavity 40 is provided with a regeneration air inlet 41, a dust removal roller 42 is arranged in the regeneration air inlet cavity 40, the dust removal roller 42 is provided with an air outlet, one end of the dust removal roller 42 is connected with the regeneration air inlet 41, the other end of the dust removal roller is arranged in a sealing way, a rotating wheel is arranged in the regeneration cavity 50, the regeneration cavity 50 is arranged above the treatment cavity 20, a heater 51 is arranged between the regeneration cavity 50 and the regeneration air inlet cavity 40, an exhaust fan 62 is arranged in the regeneration air exhaust cavity 60, and a regeneration air outlet 61 is arranged.

Fresh air carries out two steps of dehumidification through condenser 14 and processing chamber 20 respectively, can dry the air at low temperature, in order to reduce the humidity that gets into indoor air, improve dehumidification efficiency, reduce the work load of this all-in-one, and dust removal cylinder 42 can remove dust to the regeneration wind, improve the cleanliness of regeneration wind, avoid the regeneration wind to pollute the runner in the regeneration chamber 50, thereby avoid the runner to pollute fresh air, improve and get into indoor air quality, provide more comfortable and pure indoor environment for the user.

Specifically, the working process of the low-temperature dehumidification and drying integrated machine is as follows: fresh air enters the diversion chamber 10 for diversion through the air supply inlet 13, is cooled through the condenser 14, enters the treatment chamber 20 after primary dehumidification, is further dried and dehumidified by contacting with a rotating wheel in the treatment chamber 20, and is sent to the indoor through the air blower 33 after being treated and dried; the regeneration air enters the regeneration air inlet chamber 40 from the regeneration air inlet, is dedusted by the dedusting roller 42 to obtain high-cleanliness regeneration air, is heated to the temperature required by the regeneration desorption of the rotating wheel by the heater 51, and the high-temperature air regenerates the rotating wheel in the regeneration chamber 50 by the regeneration chamber 50 to take out the moisture in the rotating wheel, then passes through the regeneration air exhaust chamber 60 and is exhausted outdoors by the exhaust fan 62 to achieve the regeneration effect. After the integrated machine operates for a certain time, the rotating wheels of the treatment chamber 20 and the regeneration chamber 50 are exchanged, and the rotating wheels are recycled.

Specifically, the way of exchanging the rotating wheels of the processing chamber 20 and the regeneration chamber 50 is not particularly limited, as long as the rotating wheels can be exchanged, for example, a rotating partition plate may be disposed between the regeneration chamber 50 and the processing chamber 20, and the rotating wheels can be rotated mutually by the rotation of the partition plate, or rotating wheel boxes for placing the rotating wheels may be disposed in the processing chamber 20 or the regeneration chamber 50, respectively, and the rotating wheel boxes can reciprocate between the processing chamber 20 or the regeneration chamber 50, or a closed loop may be opened between the regeneration chamber 50 and the processing chamber 20, and the rotating wheels are disposed in the closed loop, and the transmission mechanism drives the closed loop to rotate, so as to drive the rotating wheels to be exchanged between the processing chamber 20 and the regeneration chamber 50.

Specifically, the regeneration wind can be indoor air, can be outdoor air, can filter the regeneration wind through this all-in-one, reduces the impurity content in the regeneration wind, avoids the regeneration wind to pollute the runner to the heater 51 that sets up heats the regeneration wind, can play bactericidal effect to the regeneration wind, improves the cleanliness of regeneration wind.

Specifically, in order to ensure the cleanliness of the fresh air entering the room, the air entering the diversion chamber 10 from the air supply inlet 13 may be filtered before the air supply inlet 13, or a dust removal component may be disposed in the diversion chamber 10 to remove dust from the air. Specifically, a compressor 12 may be further disposed in the guide chamber 10 to supply air to the guide chamber 10.

Specifically, the material of the rotating wheel is not particularly limited, and may be silica gel, molecular sieve or other hygroscopic polymer materials.

Referring to fig. 2, as an embodiment, a first push plate 422 is disposed in the dust removing drum 42, the first push plate 422 is annular, an outer periphery of the first push plate 422 is engaged with an inner periphery of the dust removing drum 42, the first push plate 422 is connected to the top of the dust removing drum 42 through a first telescopic rod 421, and the first telescopic rod 421 extends out to push the first push plate 422 to move downward. Regenerated air enters the dust removing roller 42 to be filtered and purified, impurities contained in the regenerated air are intercepted on the inner periphery of the dust removing roller 42, the all-in-one machine is operated to a certain time and stretches out through the first telescopic rod 421 to drive the first push plate 422 to move downwards, so that the impurities in the dust removing roller 42 are pushed out, the dust removing roller 42 is automatically cleaned, the dust removing roller 42 is prevented from being blocked by the impurities, and the dust removing efficiency of the dust removing roller 42 is improved.

Specifically, the impurities in the dust removing drum 42 are pushed to the lower part of the dust removing drum 42, and the impurities accumulated below the dust removing drum 42 can be cleaned manually or mechanically by arranging an opening below the dust removing drum 42.

In one embodiment, one end of the dust removing roller 42, which is far away from the regeneration air inlet 41, is sealed by a dust removing pipeline 43, the dust removing pipeline 43 is communicated with the dust removing roller 42, a second telescopic rod 431 and a second push plate 432 are arranged on one side of the dust removing pipeline 43, which is close to the regeneration chamber 50, the outer periphery of the second push plate 432 is clamped with the inner side wall of the dust removing pipeline 43, an impurity outlet 433 is arranged on one side of the dust removing pipeline 43, which is far away from the regeneration chamber 50, and the impurity outlet 433 is sealed by a sealing cover 434. Under this setting, first telescopic link 421 drives first push pedal 422 downstream, pushes away the impurity in the dust removal cylinder 42 to the dust removal pipeline 43 in, and second telescopic link 431 in the dust removal pipeline 43 stretches out, promotes the motion of second push pedal 432 to impurity export 433, opens the sealed lid 434 of impurity export 433, can release the impurity in the dust removal pipeline 43, replaces manual operation, improves the convenience of this dust removal cylinder 42's clearance, realizes clearing up fast.

The first telescopic link 421 and the second telescopic link 431 that above-mentioned set up provide power for the removal of first push pedal 422 and second push pedal 432 respectively, can play firm and supporting role to first push pedal 422 and second push pedal 432 respectively simultaneously, avoid first push pedal 422 and second push pedal 432 to appear shifting at the removal in-process, improve the clean efficiency of impurity. Specifically, the extension and retraction of the first telescopic rod 421 and the second telescopic rod 431 can be driven by a cylinder or a screw rod, the driving mechanisms of the first telescopic rod 421 and the second telescopic rod 431 are motors, the power supply mechanism of the motors can be a plug-in mechanism or a charging mechanism, and the existing driving mode is adopted, which is not described herein.

Specifically, the shape of the second pushing plate 432 is not specifically limited, and the second pushing plate is adapted to the shape of the dust removing pipe 43, so that the impurities in the dust removing pipe 43 can be pushed to the impurity outlet 433. Preferably, the second push plate 432 has an area equal to the area of the radial cross-section of the dust removal duct 43.

As an embodiment, the bottom of the dust removing roller 42 is provided with a limit block 423, and the limit block 423 is close to the dust removing pipeline 43. If the first telescopic rod 421 extends too long, the first push plate 422 will be pushed into the dust removing pipeline 43, and at this time, since the first push plate 422 is no longer engaged with the inner circumference of the dust removing drum 42, the first push plate 422 will shift, so that the first push plate 422 cannot be correctly reset. Therefore, the limiting block 423 is arranged to limit the first pushing plate 422, the first pushing plate 422 is prevented from being pushed to the dust removing pipeline 43, the resetting accuracy of the first pushing plate 422 is improved, and the cleaning efficiency of the dust removing roller 42 is improved.

As an embodiment, the device further comprises a impurity recycling groove 44, the dust removing pipeline 43 penetrates through the side wall of the regeneration air inlet chamber 40, and the impurity recycling groove 44 is arranged outside the regeneration air inlet chamber 40 and below the impurity outlet 433. Impurity outlet 433 is located the lateral wall of regeneration air inlet cavity 40, and this setting can directly push away impurity to fall to impurity recovery tank 44 in through second telescopic link 431 and second push pedal 432, further improves the dust collection efficiency of dust removal cylinder 42.

As an implementation mode, the regeneration air inlet chamber 40 further comprises a cleaning pipe 45 and a cleaning nozzle 46, the cleaning pipe 45 is arranged on the inner side wall of the regeneration air inlet chamber 40 and is communicated with the liquid inlet pump, and the cleaning nozzle 46 is arranged on the cleaning pipe 45. Cleaning shower nozzle 46 can spray the cleaning solution to dust removal cylinder 42, can clean dust removal cylinder 42, improve the inside cleanliness of dust removal cylinder 42, reduce clean blind area, thereby improve dust removal cylinder 42's dust collection efficiency, and the cleaning solution that sprays can be the cleaning solution that has bactericidal effect, can give dust removal cylinder 42 bactericidal effect, reduce bacterium and the microorganism content in the regeneration wind.

In one embodiment, at least two cleaning pipes 45 are uniformly disposed on the inner sidewall of the regeneration air intake chamber 40, and at least two cleaning nozzles 46 are disposed on each cleaning pipe 45 and are uniformly disposed on the cleaning pipe 45. The cleaning pipe 45 and the cleaning nozzle 46 can be uniformly arranged along the periphery of the dust-removing drum 42 under the arrangement, and the cleaning uniformity of the cleaning liquid to the dust-removing drum 42 is improved.

In one embodiment, a first buffer chamber 70 is further provided between the process chamber 20 and the air supply chamber 30, and a second buffer chamber 80 is further provided between the regeneration chamber 50 and the regeneration exhaust chamber 60. The first buffer chamber 70 is arranged to buffer fresh air, so that the stability of the air intake at the air supply outlet 32 is improved, and uniform air supply is realized, thereby facilitating the maintenance of a relatively stable indoor environment; the second buffer chamber 80 that sets up can cushion the regeneration wind, avoids regeneration wind export 61 air output too big, causes the increase of exhaust fan 62 energy consumption.

In one embodiment, a grill 71 is disposed in the first buffer chamber 70, and flavor particles are disposed in the grill 71. The aroma-enhancing particles placed in the grille 71 can enhance aroma of fresh air, improve the freshness of air entering a room, and create a more comfortable environment.

Specifically, the shape of the flavoring particles is not specifically limited, and the flavoring particles can be circular, square or polygonal, and can be placed with different flavors according to the actual needs of users. The aroma-enhancing particles can also contain a bactericide, so that the air can be further sterilized, and bacteria or microorganisms in the air can be reduced.

In one embodiment, the grill 71 has an "S" shape, and the peripheral direction of the grill 71 abuts against the inner side wall of the first buffer chamber 70. With this arrangement, the contact area between the grill 71 and the air in the first buffer chamber 70 can be increased, and the grill 71 can enhance the air buffering effect and further improve the uniformity of the air blowing amount.

In a preferred embodiment, a first heat exchanger 31 may be further disposed in the blowing chamber 30, and the first heat exchanger 31 may further adjust the temperature of the air entering the room, so that the temperature of the air flowing out of the blowing outlet 32 is appropriate, thereby improving comfort.

In one embodiment, a second heat exchanger 63 is further disposed in the regenerative exhaust chamber 60. The second heat exchanger 63 can adjust the temperature of the regeneration air introduced into the regeneration discharge chamber 60, and can further utilize the energy of the collected regeneration air, which can be used to supply the condenser 14, the heater 51, or the first heat exchanger 31, thereby improving the recovery rate of the regeneration air.

Referring to fig. 1 and 3, as an embodiment, a flow guide plate 11 is disposed in the flow guide chamber 10, flow guide holes are formed in the flow guide plate 11, and the flow guide plate 11 is perpendicular to the air supply direction of the air supply inlet 13. The guide plate 11 is perpendicular with the flow direction of new trend, can reduce the flow resistance of new trend to following the situation and carrying out water conservancy diversion and buffering to the new trend, reduce the electric energy loss of this all-in-one, thereby reduce the running cost.

In one embodiment, the first guide holes 111 are disposed on the side of the guide plate 11 close to the air supply inlet 13, the second guide holes 112 are disposed on the side of the guide plate 11 away from the air supply inlet 13, and the first guide holes 111 and the second guide holes 112 are arranged alternately. A porous partition 113 is further disposed in the flow guide plate 11, and the porous partition 113 is used for filtering the gas flowing through the flow guide plate 11. The arranged porous partition plate 113 can filter the gas in the guide plate 11, so that the cleanliness of the air is improved, and the indoor air quality is improved; further, porous baffle 113 also can block the air, improves the dwell time of new trend in guide plate 11 to promote buffering and dust removal effect. Preferably, the number of the porous partition 113 is plural, and the porous partition 113 is disposed perpendicular to the flow guide plate 11.

In one embodiment, referring to fig. 3, the porous partition 113 has a "V" shape, and at least one porous partition 113 is disposed between each adjacent first diversion hole 111 or second diversion hole 112. The contact area of porous baffle 113 and new trend can be increased to the porous baffle 113 that "V" shape set up, improve the filter effect to first water conservancy diversion hole 111 and second water conservancy diversion hole 112 are under the crisscross condition that sets up, set up porous baffle 113 between adjacent first water conservancy diversion hole 111 or second water conservancy diversion hole 112, can make in the guide plate 11 air can only flow from second water conservancy diversion hole 112 after must passing through porous baffle 113, further optimize indoor air quality.

In one embodiment, the top of the baffle 11 is provided with a liquid inlet 114, the liquid inlet 114 is communicated with a liquid inlet system 117, and the liquid flowing out from the liquid inlet 114 can flow to the porous partition 113. The liquid inlet system 117 is communicated with the liquid inlet 114 and can spray liquid into the porous partition 113, the liquid can be a flavoring agent, and at the moment, air can be flavored after passing through the porous partition 113 so as to transmit fresh air to the room and improve the sensory feeling of a user; this liquid also can be the cleaning solution, and the cleaning solution can clean porous partition 113 to impurity on the clean porous partition 113 avoids impurity contaminated air, in order to improve porous partition 113's filter effect.

In one embodiment, the bottom of the flow guiding plate 11 is provided with a liquid outlet 115, and a liquid receiving tank 116 is connected below the liquid outlet 115. When the cleaning liquid flows out from the liquid inlet 114, the liquid outlet 115 and the liquid receiving groove 116 are used for collecting the liquid flowing out from the liquid inlet 114, so as to transfer the liquid in the guide plate 11 in time, and avoid the secondary pollution of the cleaning liquid to the air.

As an embodiment, a movable slide rail is disposed at the bottom of the diversion chamber 10, and the liquid receiving tank 116 is movably mounted below the liquid outlet 115 through the movable slide rail. The movable sliding rail is convenient for taking and placing the liquid receiving groove 116, and the convenience of the all-in-one machine is improved.

Specifically, the liquid inlet 114 and the liquid outlet 115 may be respectively provided with a switch valve, and the switch valve may open and close the liquid inlet 114 and the liquid outlet 115 to prevent air from flowing through the liquid inlet 114 or the liquid outlet 115.

Specifically, the shape of the movable slide rail is not specifically limited, as long as the movable slide rail can be matched with the liquid receiving groove 116, so as to facilitate the taking and placing of the liquid receiving groove 116, for example, the movable slide rail may be a strip-shaped rail, a groove is arranged at the top of the liquid receiving groove 116, and the groove is matched with the strip-shaped rail to achieve the taking and placing of the liquid receiving groove 116; the movable slide rail may also be a square frame capable of sleeving the liquid receiving tank 116, the liquid receiving tank 116 is drawer-shaped, and the liquid receiving tank 116 is pulled to pick up and place the liquid receiving tank 116.

The embodiments in the present specification are described in a progressive manner, and the same and similar parts among the embodiments are referred to each other, and each embodiment focuses on the differences from the other embodiments. In particular, for the system embodiment, since it is substantially similar to the method embodiment, the description is simple, and for the relevant points, reference may be made to the partial description of the method embodiment.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement or the like made within the spirit and principle of the present application shall be included in the scope of the claims of the present application.

Claims (10)

1. The utility model provides a low temperature dehumidification drying machine which characterized in that includes:

the air supply system forms a flow guide cavity, a treatment cavity and an air supply cavity which are communicated, the flow guide cavity is provided with an air supply inlet, a rotating wheel is arranged in the treatment cavity, a condenser is arranged between the treatment cavity and the flow guide cavity, and an air feeder is arranged in the air supply cavity and is provided with an air supply outlet;

the regeneration air exhaust system, regeneration air exhaust system forms regeneration air inlet cavity, regeneration cavity and the regeneration air exhaust cavity that is linked together, regeneration air inlet has been seted up to regeneration air inlet cavity, be provided with the dust removal cylinder in the regeneration air inlet cavity, the last gas outlet of having seted up of dust removal cylinder, dust removal cylinder one end and regeneration air inlet connection, the other end seal sets up, be provided with the runner in the regeneration cavity, the regeneration cavity sets up the top of handling the cavity, the regeneration cavity with be provided with the heater between the regeneration air inlet cavity, be provided with the exhaust fan in the regeneration air exhaust cavity to the regeneration air outlet has been seted up.

2. The low-temperature dehumidifying and drying all-in-one machine according to claim 1, wherein a first push plate is arranged in the dust removing roller, the first push plate is annular, the outer periphery of the first push plate is clamped with the inner periphery of the dust removing roller, the first push plate is connected with the top of the dust removing roller through a first telescopic rod, and the first telescopic rod extends out to push the first push plate to move downwards.

3. The low-temperature dehumidifying and drying all-in-one machine according to claim 2, wherein one end of the dust removing roller, which is far away from the regeneration air inlet, is sealed through a dust removing pipeline, the dust removing pipeline is communicated with the dust removing roller, a second telescopic rod and a second push plate are arranged on one side, which is close to the regeneration chamber, of the dust removing pipeline, the periphery of the second push plate is clamped with the inner side wall of the dust removing pipeline, an impurity outlet is arranged on one side, which is far away from the regeneration chamber, of the dust removing pipeline, and the impurity outlet is sealed through a sealing cover.

4. The all-in-one machine with low temperature dehumidification and drying as claimed in claim 3, wherein a limiting block is arranged at the bottom of the dust removal roller, and the limiting block is close to the dust removal pipeline.

5. The low-temperature dehumidifying and drying all-in-one machine according to claim 4, further comprising an impurity recycling groove, wherein the dust removing pipeline penetrates through the side wall of the regeneration air inlet chamber, and the impurity recycling groove is arranged on the outer side of the regeneration air inlet chamber and below the impurity outlet.

6. The low-temperature dehumidifying and drying all-in-one machine according to any one of claims 1 to 5, further comprising a cleaning pipe and a cleaning nozzle in the regeneration air inlet chamber, wherein the cleaning pipe is arranged on the inner side wall of the regeneration air inlet chamber and is communicated with the liquid inlet pump, and the cleaning nozzle is arranged on the cleaning pipe.

7. The integrated machine of claim 6, wherein the number of the cleaning pipes is at least two, and the cleaning pipes are uniformly arranged on the inner side wall of the regeneration air inlet chamber,

at least two cleaning spray heads are arranged on each cleaning pipe and are uniformly arranged on the cleaning pipes.

8. The all-in-one machine with low temperature dehumidification and drying functions as claimed in any one of claims 1 to 5, wherein a first buffer chamber is further arranged between the processing chamber and the air supply chamber; and/or

And a second buffer chamber is also arranged between the regeneration chamber and the regeneration exhaust chamber.

9. The all-in-one machine with low temperature dehumidification and drying as claimed in claim 8, wherein a grid is arranged in the first buffer chamber, and aroma-enhancing particles are placed in the grid.

10. The all-in-one machine for dehumidifying and drying at low temperature as claimed in claim 9, wherein the grille is S-shaped, and the circumference of the grille abuts against the inner side wall of the first buffer chamber.

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