CN219376614U - Moisture transfer system and washing and protecting equipment - Google Patents

Abstract

The utility model discloses a moisture transfer system, which comprises a shell, wherein a containing cavity is formed in the shell, a rotating wheel is rotatably supported in the containing cavity, the containing cavity comprises an adsorption area and a desorption area, a position on the rotating wheel moves back and forth between the adsorption area and the desorption area, and the rotating wheel rotates to the desorption area to be separated after moisture in the containing cavity is adsorbed in the adsorption area; the first connecting channel is arranged on the shell, one end of the first connecting channel is an air inlet, and the other end of the first connecting channel is an air outlet and is used for discharging the desorbed moisture out of the shell; the condenser is arranged outside the shell; and the air inlet at one end of the second connecting channel is communicated with the air outlet of the condenser, and the air outlet at the other end of the second connecting channel is communicated with the shell and is used for guiding the condensed gas into the shell. According to the utility model, the first connecting channel and the second connecting channel are arranged, the dehumidified gas is introduced into the condenser, and then the condensed gas is introduced into the accommodating cavity and dehumidified through the adsorption area again, so that the drying effect of the equipment is further improved, and the dehumidifying and drying time is saved.

Description

Moisture transfer system and washing and protecting equipment

Technical Field

The utility model belongs to the field of dehumidification of washing and protecting equipment, and particularly relates to a moisture transport system and washing and protecting equipment.

Background

The washing and protecting equipment is a machine capable of washing, dry-cleaning and drying articles, and common washing and protecting equipment comprises a dry-cleaning machine for dry-cleaning clothes, a dryer for drying clothes, a washing machine for washing clothes, a dish washing machine for washing and drying bowls and the like.

With the continuous progress of the technology of washing and protecting equipment, the washing and protecting equipment is favored by more families. At present, most of washing and protecting equipment adopts a hot air circulation system to wash and protect so as to realize the effects of drying, deodorizing and the like. When the washing and protecting equipment dehumidifies, the rotating wheel type dehumidifier can be adopted for dehumidification, and the moisture in the washing and protecting equipment is led into the rotating wheel type dehumidifier, so that the adsorption area in the dehumidifier absorbs the moisture and then directly discharges or leads the air into the back washing and protecting equipment.

However, in the dehumidification process, dehumidification is performed only through the adsorption area, so that the dehumidification effect is poor, air with moisture can be directly discharged or guided back into the washing and protecting equipment, the humidity increase or the dehumidification effect is poor at the periphery of the washing and protecting equipment, and the dehumidification drying time is prolonged.

The present utility model has been made in view of this.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art, and aims to provide a moisture transfer system, which is characterized in that a first connecting channel and a second connecting channel are arranged, dehumidified gas is introduced into a condenser, then the condensed gas is introduced into a containing cavity and is guided to an adsorption area for moisture absorption, so that the drying effect of equipment is further improved, and the dehumidifying and drying time is saved.

Another object of the present utility model is to provide a washing and caring apparatus.

In order to solve the technical problems, the utility model adopts the basic conception of the technical scheme that: there is provided a moisture transport system comprising,

the shell is internally provided with a containing cavity, an air inlet is formed in the shell and used for guiding external moisture into the containing cavity, and an air outlet is formed in the shell and used for guiding out dry air;

the rotating wheel is rotatably supported in the accommodating cavity, the accommodating cavity comprises an adsorption area and a desorption area, the rotating wheel is provided with a position which moves back and forth between the adsorption area and the desorption area, and the rotating wheel rotates to the desorption area to be separated after the adsorption area adsorbs moisture in the accommodating cavity;

the first connecting channel is arranged on the shell, one end of the first connecting channel is provided with an air inlet and is used for receiving the moisture in the desorption area, and the other end of the first connecting channel is provided with an air outlet and is used for discharging the desorbed moisture out of the shell;

the condenser is arranged outside the shell, and an air inlet of the condenser is communicated with an air outlet of the first connecting channel and is used for condensing the moisture in the desorption zone received by the first connecting channel;

and the air inlet at one end of the second connecting channel is communicated with the air outlet of the condenser, and the air outlet at the other end of the second connecting channel is communicated with the shell and is used for guiding the condensed gas into the shell.

Further, one end of the first connecting channel is positioned in the accommodating cavity, and an air inlet at one end of the first connecting channel is arranged close to the rotating wheel; the other end of the first connecting channel extends out of the accommodating cavity and is communicated with the condenser.

Further, the method comprises the steps of,

an air inlet is formed in one side wall of the shell, and a first opening is formed in the other opposite side wall;

the air inlet of the first connecting channel extends into the accommodating cavity through the first opening and is arranged close to the wheel surface opposite to the air inlet;

the air outlet at the other end of the first connecting channel extends to the outside of the accommodating cavity through the first opening and is communicated with the air inlet of the condenser.

Further, the first opening is disposed opposite the desorption region.

Further, a second opening is further formed in the other side wall, opposite to the air inlet, of the shell, the second opening is far away from the air inlet, an air inlet at one end of the second connecting channel is communicated with the condenser, and an air outlet at the other end of the second connecting channel extends into the accommodating cavity through the second opening.

Further, the second opening and the first opening are arranged at two opposite ends of the other side wall of the shell;

The gas outlet at the other end of the second connecting channel extends into the accommodating cavity and is arranged close to the adsorption area and used for guiding the condensed gas to the adsorption area.

Further, the method comprises the steps of,

the accommodating cavity comprises a groove which is arranged close to the other side of the shell, and the rotating wheel is arranged in the groove;

the first opening and the second opening are arranged on the bottom wall of the groove at intervals.

Further, the condenser comprises a condenser body, wherein the condenser body comprises,

the air inlet chamber is provided with a condensation inlet which is communicated with the air outlet of the first connecting channel and is used for feeding moisture;

the air outlet chamber is provided with a condensation outlet which is communicated with the air inlet of the second connecting channel and is used for discharging condensed air into the second connecting channel;

a hollow chamber;

the first radiating pipes are communicated with the air inlet cavity and the hollow cavity and are arranged at intervals and used for leading in and then guiding out air in the air inlet cavity into the hollow cavity;

the second radiating pipes are communicated with the hollow cavity and the air outlet cavity and are arranged at intervals and used for leading in and guiding out air in the hollow cavity into the air outlet cavity;

The flux of the second radiating pipes communicated between the air inlet cavity and the hollow cavity is smaller than that of the first radiating pipes.

Further, the condenser further comprises a heat exchanger,

the air inlet chamber and the air outlet chamber are respectively and independently arranged in the first communication part;

the hollow cavity is arranged in the second communication part; the first communication part and the second communication part are oppositely arranged;

the condensation inlet and the condensation outlet are arranged on one side of the first communication part, and one side of the first communication part is opposite to the other side of the shell.

A washing and care apparatus having a moisture transport system as claimed in any one of the preceding claims.

By adopting the technical scheme, compared with the prior art, the utility model has the following beneficial effects.

(1) According to the utility model, the rotating wheel is rotatably arranged in the accommodating cavity, moisture is adsorbed by the adsorption area in the accommodating cavity, the rotating wheel is separated from the desorption area after rotating to the desorption area, the moisture in the desorption area is discharged out of the shell through the first connecting channel, then the condenser is arranged outside the shell, the moisture in the first connecting channel enters the condenser to perform condensation dehumidification, and finally the condensed air is guided to the adsorption area in the accommodating cavity again to perform re-dehumidification through the second connecting channel which is respectively communicated with the condenser and the shell, so that the drying effect of equipment is further improved, the dehumidification drying time is saved, and the technical problems of poor dehumidification effect and long drying time of the rotating wheel in the prior art are solved.

(2) According to the utility model, the air inlet is formed in the shell, moisture is conveniently fed into the accommodating cavity in the shell, the air inlet is large, the moisture can be quickly dehumidified, the rotating wheel is rotatably supported in the accommodating cavity, the moisture in the accommodating cavity is adsorbed by the adsorption area in the accommodating cavity to obtain dry air, the dry air is discharged through the air outlet in the shell, the moisture adsorbed by the adsorption area is received by the desorption area, the moisture is discharged to the condenser outside the shell through the first connecting channel to finish dehumidification again, the high-air-volume low-concentration water vapor can be converted into the low-air-volume high-temperature water vapor, the water vapor is condensed and dried, the dehumidification effect is good, the first connecting channel is arranged at the first opening of the shell, the moisture transfer module is compact in structure, small in size and small in occupied space, and is suitable for users who want to wash and protect the volume of the equipment in home, and the user use experience is good.

(3) This application is through set up the air intake on one lateral wall of casing, set up first opening, second opening on the another relative lateral wall, will first connecting channel is through first opening wears to establish to hold the intracavity portion, be close to with the runner wheel face setting that the air intake is relative, make the one end of first connecting channel can stablely insert hold the intracavity, the other end extend to hold the intracavity portion with the air inlet intercommunication of condenser, get into the condenser with the moisture of desorption district, dehumidify the moisture, the air inlet of second connecting channel one end with the condensation export intercommunication of the outside condenser of casing, the gas after the condensation enters into again through the second connecting channel holds in the chamber, dehumidifies once more, dries through the adsorption area that holds the intracavity to export dry air through the air outlet, further improve moisture transfer system's dehumidification, drying effect.

The following describes the embodiments of the present utility model in further detail with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model. It is evident that the drawings in the following description are only examples, from which other drawings can be obtained by a person skilled in the art without the inventive effort. In the drawings:

FIG. 1 is a schematic illustration of a moisture transport system of the present utility model;

FIG. 2 is a schematic view of a rotor of the present utility model;

FIG. 3 is a schematic view of the utility model at another angle to FIG. 2;

FIG. 4 is a schematic cross-sectional view taken along the direction A-A in FIG. 3 in accordance with the present utility model;

FIG. 5 is a schematic view of a wheel coupling drive apparatus according to the present utility model;

FIG. 6 is a schematic view of a condenser of the present utility model;

FIG. 7 is a schematic view of the utility model at another angle to FIG. 6;

FIG. 8 is a schematic view of the utility model at still another angle from FIG. 6;

FIG. 9 is a schematic view of the utility model at another angle to FIG. 8;

FIG. 10 is a schematic cross-sectional view taken along the direction B-B in FIG. 9 in accordance with the present utility model;

fig. 11 is a schematic view of a washing apparatus of the present utility model.

In the figure: 1. a housing; 11. a receiving chamber; 111. an air inlet; 112. an air outlet; 113. a groove; 114. a first opening; 115. a second opening; 116. an adsorption zone; 117. a desorption zone; 12. a rotor wheel mounting shell; 13. an air duct case; 14. a rotating shaft; 15. a bearing seat; 16. a circulating fan; 2. a rotating wheel; 21. a rotating disc; 211. an annular wheel; 2111. chamfering; 212. a support base; 2121. a shaft hole; 2122. a connection hole; 2123. an annular groove; 22. a ring member; 221. a gear tooth structure; 222. ventilation holes; 3. a first connection channel; 31. a heating unit; 32. a dehumidifying fan; 4. a second connection channel; 5. a condenser; 51. a first communication section; 511. an air inlet chamber; 512. a condensing inlet; 513. a first condensing water outlet pipe; 514. an air outlet chamber; 515. a condensation outlet; 516. a second condensing water outlet pipe; 517. a separation groove; 52. a second communication portion; 521. a hollow chamber; 53. a first radiating pipe; 54. a second radiating pipe; 55. a plug hole; 6. a driving device; 61. a driving unit; 62. a speed reducing commutator; 63. a transmission gear; 64. a housing; 7. a dehumidifying case; 71. an accommodation space; 8. washing and protecting equipment; 81. a housing; 82. a processing unit; 83. a first channel; 84. a water collecting box.

It should be noted that these drawings and the written description are not intended to limit the scope of the inventive concept in any way, but to illustrate the inventive concept to those skilled in the art by referring to the specific embodiments.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions in the embodiments will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present utility model, and the following embodiments are used to illustrate the present utility model, but are not intended to limit the scope of the present utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

As shown in fig. 1 to 10, the present utility model provides a moisture transporting system including a housing 1, a rotating wheel 2, a first connection channel 3, a condenser 5, and a second connection channel 4.

The housing 1 is provided with a containing cavity 11, the housing 1 is provided with an air inlet 111 for guiding external moisture into the containing cavity 11, and the housing 1 is provided with an air outlet 112 for guiding out dry air.

The rotating wheel 2 is rotatably supported in the accommodating cavity 11, the accommodating cavity 11 comprises an adsorption area 116 and a desorption area 117, a position on the rotating wheel 2 moves back and forth between the adsorption area 116 and the desorption area 117, and the rotating wheel 2 rotates to the desorption area 117 to be separated after the adsorption area 116 adsorbs moisture in the accommodating cavity 11.

The first connecting channel 3 is disposed on the housing 1, and has an air inlet at one end for receiving the moisture desorbed from the desorption area 117, and an air outlet at the other end for discharging the desorbed moisture out of the housing 1.

The condenser 5 is arranged outside the shell 1, and an air inlet of the condenser 5 is communicated with an air outlet of the first connecting channel 3 and is used for condensing the moisture desorbed from the desorption zone 117 received by the first connecting channel 3.

The air inlet at one end of the second connecting channel 4 is communicated with the air outlet of the condenser 5, and the air outlet at the other end of the second connecting channel is communicated with the shell 1 and is used for guiding the condensed gas into the shell 1.

The rotor 2 is capable of rapidly absorbing moisture in a large volume of low concentration water vapor gas, such as a zeolite rotor. The rotating wheel 2 can concentrate the gas with large air quantity and low concentration water vapor into the gas with small air quantity and high concentration water vapor, thereby improving the dehumidification effect and reducing the dehumidification cost.

According to the utility model, the rotating wheel 2 is rotatably supported in the accommodating cavity 11, when moisture enters the accommodating cavity 11 from the air inlet 111 and flows to the air outlet 112, the adsorption area 116 adsorbs the moisture in the accommodating cavity 11, the rotating wheel 2 is separated from the desorption area 117 after rotating to the desorption area 117, the moisture desorbed from the desorption area 117 is discharged out of the shell 1 through the first connecting channel 3, then the condenser 5 is arranged outside the shell 1, the moisture in the first connecting channel 3 enters the condenser 5 to be condensed and dehumidified, finally, the condensed air is led into the accommodating cavity 11 again through the second connecting channel 4 and is dehumidified again through the adsorption area 116, and the technical problems of poor dehumidification effect and long drying time of a moisture transfer system in the prior art are solved.

Specifically, the air inlet 111 is arranged on the shell 1, moisture is conveniently fed into the accommodating cavity 11 in the shell 1, the rotating wheel 2 is rotatably supported in the accommodating cavity 11, the rotating wheel 2 absorbs the moisture in the accommodating cavity 11 in the absorption area 116 to obtain dry air to be discharged through the air outlet 112 on the shell 1, meanwhile, the moisture absorbed by the absorption area 116 is rotated to the desorption area 117, after the desorption area 117 is desorbed, the moisture is discharged to the outside of the shell 1 through the first connecting channel 3 to finish dehumidification, the high-air-quantity low-concentration water vapor can be converted into the low-air-quantity high-concentration water vapor, the dehumidification effect is good, the first connecting channel 3 is arranged at the air inlet 111 of the shell 1, the moisture transfer module is compact in structure, small in size and small in occupied space, and can be suitable for being used on household appliance washing and protecting equipment 7 which occupies small space in a user's home and is required to be compact in structure.

The concentration of the moisture desorbed from the desorption region 117 may be N times the concentration of the intake moisture of the adsorption region 116. Wherein N is more than 1 and less than 200.

The rotating wheel 2 is made of a low-temperature moisture absorption and high-temperature dehumidification material.

The rotating wheel 2 has larger specific surface area, various pore structures, pore size distribution and rich surface properties, and has stronger adsorption capacity on water vapor.

In a specific embodiment, the accommodating cavity is sequentially provided with an adsorption area 116 and a desorption area 117 along the circumferential direction to form a plurality of sector areas, and the angle of the sector area where the adsorption area 116 is located is greater than the angle of the sector area where the desorption area 117 is located.

The positions of the adsorption area 116 and the desorption area 117 are fixed, and the rotating wheel 2 rotates at a certain rotating speed. The rotating speed of the rotating wheel 2 is 0.01-60r/min. Preferably, the rotating speed of the rotating wheel 2 is 0.02-10r/min.

Preferably, the adsorption zone 116 is angled at a reflex angle and the desorption zone 117 is angled at an acute angle.

The rotating wheel 2 is at least partially made of low-temperature moisture-absorbing and high-temperature moisture-removing materials and is of a porous structure. The porous structure of the rotating wheel 2 is arranged opposite to the adsorption area 116 and the desorption area 117.

Further, the rotating wheel 2 is a zeolite rotating wheel, a silica gel rotating wheel, a graphene rotating wheel or an activated alumina rotating wheel.

Zeolite wheel (zeolite AmBpO2 p.nh 2O), which is an aluminosilicate mineral containing alkali or alkaline earth elements, the crystal structure of which is usually connected into a rack-like nanocrystalline structure by silicon oxygen tetrahedron and aluminum oxygen tetrahedron, forming cavities of different shapes and sizes, and being capable of selectively adsorbing and filtering nonpolar/polar molecules having smaller molecular sizes than the pore channels. When the humidity is too high, the zeolite can absorb moisture through numerous fine pores on the surface; when the environment is dry, moisture can be released again to keep moist. In addition, in the process of changing the environmental humidity, the temperature is naturally changed and adjusted along with the humidity.

Silica gel wheel (silica gel (mSiO2.nH2O), aliased silicic acid gel.

Activated alumina wheel (activated alumina, english name is Activatedalumina) with chemical formula of Al2O3.

The rotating wheels 2 have the characteristics of low temperature moisture absorption and high Wen Tuoshi.

Further, one end of the first connecting channel 3 is located inside the accommodating cavity 11, and an air inlet at one end of the first connecting channel 3 is disposed near the tread of the rotating wheel 2.

The other end of the first connecting passage 3 protrudes outside the accommodating chamber 11 to communicate with the condenser 5.

This application is through locating the one end of first connecting channel 3 hold the inside of chamber 11, and will the air inlet of first connecting channel 3 is close to runner 2 tread sets up, is moisture passing desorption area 117 gets into after the first connecting channel 3, with the moisture is imported in the outside condenser 5 of casing 1, improve the transportation efficiency of moisture.

Further, a moisture extraction fan 32 is disposed in the first connection channel 3, and the moisture extraction fan 32 is used for extracting and discharging moisture in the first connection channel 3.

According to the utility model, the moisture suction fan 32 is arranged in the first connecting channel 3, so that moisture adsorbed on the adsorption area 116 is separated from the desorption area 117 after the rotating wheel 2 rotates to the desorption area 117, and the moisture in the desorption area 117 is discharged from the air outlet of the first connecting channel 3 and enters the condenser 5, so that a large amount of moisture is prevented from accumulating in the moisture transfer system, and the desorption effect of the desorption area 117 is improved.

The inlet of the first connection 3 communicates with the desorption zone 117; a heating unit 31 is arranged at the air inlet, and the heating unit 31 is used for heating the desorption zone 117.

According to the utility model, the heating unit 31 is arranged at the air inlet, and the desorption area 117 is continuously heated by the heating unit 31, so that the desorption area 117 is kept in a high-temperature state, the desorption area 117 is further ensured to continuously receive the moisture adsorbed in the adsorption area 116, and the working efficiency of the desorption area 117 is improved.

Further, an air inlet 111 is provided on one side wall of the housing 1, and a first opening 114 is provided on the opposite side wall.

The air inlet of the first connecting channel 3 extends into the accommodating cavity 11 through the first opening 114, and is disposed near the wheel surface of the wheel 2 opposite to the air inlet 111.

The air outlet of the other end of the first connecting passage 3 extends to the outside of the accommodating chamber 11 through the first opening 114 to communicate with the air inlet of the condenser 5.

This application is through set up air intake 111 on the lateral wall of casing 1, set up first opening 114 on the another relative lateral wall, will first connecting channel 3 warp first opening 114 wears to establish to hold the intracavity portion, be close to with the runner 2 round surface setting that air intake 111 is relative makes first connecting channel 3's one end can stablely insert hold in the intracavity portion 11, the other end extend to hold the intracavity portion 11 with the air inlet intercommunication of condenser 5 will follow moisture after desorption district 117 gets into condenser 5, dehumidifies the moisture after the desorption.

Specifically, the air inlet 111 is arranged on one side wall of the shell 1, moisture enters the moisture transfer system from the air inlet 111, the first opening 114 is arranged on the other side wall opposite to the air inlet 111, the moisture can pass through the wheel surface of the rotating wheel 2, the air inlet of the first connecting channel 3 extends into the accommodating cavity 11 through the first opening 114, the air inlet is arranged close to the wheel surface of the rotating wheel 2 opposite to the air inlet 111, so that the moisture better enters the first connecting channel 3, then the air outlet at the other end of the first connecting channel 3 extends to the outside of the accommodating cavity 11 through the first opening 114 and is communicated with the air inlet of the condenser 5, and the moisture entering the first connecting channel 3 passes through the air outlet and enters the condenser 5, so that dehumidification is realized.

Further, the first opening 114 is disposed opposite the desorption region 117.

This application is through will first opening 114 with desorption zone 117 sets up relatively, realizes desorption zone 117 with first opening 114 furthest's corresponds the setting, makes the air inlet of first connecting channel 3 one end stretches into hold in the chamber 11 furthest with hold the desorption zone 117 in the chamber 11 and correspond the setting, avoid desorption zone 117 is great or less, reduces the efficiency that the moisture got into first connecting channel 3, heats through the heating unit 31 in the first connecting channel 3, improves the desorption effect of moisture, simultaneously, enters into condenser 5 with the air of high temperature high humidity, dehumidifies the air.

Further, a second opening 115 is further provided on the other side wall of the housing 1 opposite to the air inlet 111, the second opening 115 is far away from the air inlet 111, an air inlet at one end of the second connection channel 4 is communicated with the condenser 5, and an air outlet at the other end extends into the accommodating cavity 11 through the second opening 115.

This application is through setting up the second opening 115 on another lateral wall on the casing 1 to keep away from the second opening 115 the air intake 111 sets up, the air inlet of second connecting channel 4 one end with condenser 5 intercommunication, the gas outlet of the other end is passed through the second opening 115 extends to hold in the chamber 11, make second connecting channel 4 accessible second opening 115 with hold chamber 11 intercommunication, make the air after the condenser 5 condensation get into again and hold in the chamber 11, dehumidify once more, dry, improve moisture transfer system's drying effect.

Further, the second opening 115 and the first opening 114 are disposed at opposite ends of the other sidewall of the housing 1.

The air outlet at the other end of the second connection channel 4 extends into the accommodating cavity 11, and is disposed near the adsorption area 116, so as to guide the condensed gas to the adsorption area 116.

Specifically, in this application, the gas outlet of second connecting channel 4 other end is passed through second opening 115 stretches into hold in the chamber 11, be close to adsorption zone 116 sets up, the air inlet of second connecting channel 4 one end with the outside condenser 5's of casing 1 condensation export 515 intercommunication, the gaseous after the condensation enters into holds in the chamber 11 once more through second connecting channel 4, dehumidifies, dries once more through adsorption zone 116 to export dry air through air outlet 112, further improve moisture transfer system's dehumidification, drying effect.

Further, the receiving chamber 11 includes a groove 113 provided near the other side of the housing 1, and the wheel 2 is provided in the groove 113.

The first opening 114 and the second opening 115 are spaced apart from each other on the bottom wall of the recess 113.

By arranging the receiving chamber 11 near the other side of the housing 1 with the groove 113 and arranging the rotating wheel 2 in the groove 113, the moisture can intensively penetrate into the adsorption area 116, and the adsorption effect of the moisture is improved.

The accommodating chamber 11 includes a groove 113, and the groove 113 is concavely provided on an inner wall of the housing 1 on the other side opposite to the one side having the air inlet 111. The rotating wheel 2 is arranged in the groove 113, and the rotating wheel 2 is rotatably supported on the bottom of the groove 113.

The runner 2 is provided with a honeycomb hole structure, moisture passes through tiny holes on the surface of the runner 2, so that the contact area with moist air is greatly increased, the moisture absorption capacity is improved, wind directly penetrates into honeycomb gaps of the runner 2, and the moisture absorption capacity of the runner 2 is improved to the greatest extent.

Preferably, the wheel surface of the wheel 2 is in rotary sealing arrangement with the opening of the groove 113.

Preferably, the housing 1 includes a wheel mounting housing 12 and a duct housing 13.

One side of the wheel mounting housing 12 has an inwardly recessed groove 113, and the wheel 2 is rotatably supported in the groove 113. The air duct shell 13 is connected with a part of peripheral edge of one side of the rotating wheel installation shell 12, the part of structure buckled on one side of the rotating wheel installation shell 12 forms the accommodating cavity 11, the rest of structure on one side of the rotating wheel installation shell 12 forms the air inlet 111, and the air outlet 112 is arranged on the peripheral side of the air duct shell 13.

Specifically, a supporting table formed by outwards turning and extending is arranged at the periphery of the opening of the groove 113 of the runner mounting shell 12. A notch is formed on one side wall of the air duct shell 13 and is connected with the matched periphery of the supporting table. The other side wall of the air duct housing 13 covers part of the openings of the supporting table and the groove 113, and forms an air outlet channel with the opposite rotating wheel mounting housing 12.

And a circulating fan 16 is arranged at an air outlet 112 in the air duct shell 13 and is used for discharging dehumidified dry air. The circulating fan 16 is disposed on the other side inner wall of the duct housing 13 opposite to the support table.

After the moisture of the large-volume low-concentration water vapor enters the accommodating cavity 11 from the air inlet 111 or is quickly absorbed by the absorbing area 116, the circulating fan 16 guides the moisture to move towards the air outlet 112 because the air outlet 112 and the air inlet of the first connecting channel 3 are positioned at two opposite ends, and in the moving process, the moisture flows through the surface of the absorbing area 116 arranged in the groove 113, so that efficient moisture absorption is realized, and the obtained dry air is discharged from the air outlet 112.

One end of the air duct shell 13 in the circumferential direction is an opening, and the opening is communicated with the notch to form a notch. The other end of the air duct housing 13 in the circumferential direction has a peripheral wall, and the air outlet 112 is provided on the peripheral wall of the other end of the air duct housing 13. Preferably, a protruding air outlet channel is provided on the peripheral wall of the other end of the air duct housing 13 for discharging the dry air. The circulating fan 16 is arranged in the air duct shell 13 and is arranged close to the air outlet channel.

The air duct housing 13 is covered on the opening of the partial groove 113.

As shown in fig. 2 to 5, the wheel 2 includes a wheel disc 21 and an annular member 22.

The rotary disk 21 is rotatably supported on the inner wall of the housing 1 by a rotary shaft 14 for adsorbing or desorbing moisture.

The ring 22 is fixed to a side wall of the wheel disc 21, and is provided at an outer peripheral edge of one side of the wheel disc 21. The ring 22 is in transmission connection with the drive device 6 for rotation under the drive of the drive device 6.

Preferably, the ring 22 is arranged on the side of the rotary disk 21 opposite the first connecting channel 3.

The outer circumferential wall of the ring element 22 has a toothing 221, which is in geared connection with the drive device 6.

The outer peripheral edge of the side of the rotary disk 21 opposite to the ring member 22 is provided with a chamfer 2111 for avoiding the transmission gear 63 so that the transmission gear 63 is engaged with the gear tooth structure 221.

The side wall of the ring-shaped member 22, which is close to the inner ring, is provided with a plurality of ventilation holes 222, which penetrate through two sides of the ring-shaped member 22 and are used for air inlet or air outlet of the rotary disk 21 opposite to the ring-shaped member 22. The plurality of ventilation holes 222 are disposed at intervals in the circumferential direction.

More preferably, the wheel disc 21 is rotatably supported on the bottom wall of the recess 113. The ring 22 is provided on the side of the roulette plate 21 opposite the bottom of the recess 113.

The side wall of the ring 22 is provided with communication holes penetrating through both sides, and the ring 22 is fixed on one side of the rotary table 21 by a connecting member such as a screw. Alternatively, the ring 22 is inserted in a hole reserved at the rim of the wheel 2.

Preferably, the communication hole is disposed between two adjacent ventilation holes 222, and is disposed at intervals along the circumferential direction with the ventilation holes 222. The number of communication holes is less than the number of ventilation holes 222. The ring member 22 is a plastic member, and the gear tooth structure 221 is a metal member or a plastic member.

Further, the outer diameter of the ring 22 is slightly larger than the outer diameter of the roulette wheel 21. When the rotating shaft 14 is released, the outer diameter of the annular piece 22 is abutted with the inner peripheral wall of the groove 113, so that the rotating wheel 2 can still keep rotating to play a role in dehumidification.

Further, the turntable 21 includes an annular wheel 211 and a support base 212.

The annular wheel 211 is used for adsorbing or desorbing moisture. The ring wheel 211 has a low temperature moisture absorption and high temperature moisture removal characteristic. The outer peripheral wall of the support base 212 is connected with the inner ring side of the annular rotary disk 21, one end of the rotary shaft 14 is fixed on the support base 212, and the other end of the rotary shaft 14 can rotate on a bearing seat 15 arranged in the shell 1. The annular wheel 211 is formed in a honeycomb hole structure.

The axial direction of the support base 212 is provided with a through shaft hole 2121, one side of the support base 212 opposite to the air inlet 111 is provided with an annular groove 2123, and a connecting hole 2122 is arranged in the annular groove 2123. An annular flanging is arranged at one end of the rotating shaft 14, and an assembly hole matched with the connecting hole 2122 is arranged on the annular flanging. The shaft hole 2121 is penetrated by the rotating shaft 14, the annular flanging is arranged in the annular groove 2123, and the annular flanging is fixed on the annular groove 2123 through a screw or a stud.

Preferably, the ring wheel 211 is a zeolite wheel, and when the humidity is too high, the ring wheel 211 can absorb moisture through numerous fine holes on the surface. The bearing housing 15 is arranged on the bottom wall in the recess 113.

As shown in fig. 5, the moisture transport module further comprises a drive means 6. The drive means 6 comprise a transmission gear 63 and a drive unit 61. The drive gear 63 is in geared connection with the ring 22. The driving unit 61 is in transmission connection with the transmission gear 63 through a transmission shaft, and is used for driving the rotating wheel 2 to rotate through the transmission gear 63. Preferably, the driving unit 61 is a motor.

The driving device 6 further comprises a housing 64, the housing 64 is disposed outside the casing 1 to form a sealed cavity, and the driving unit 61 is disposed inside the housing 64 to avoid the driving unit 61 from being wetted, so that the driving unit 61 can operate normally and with high reliability under the condition of high temperature and high humidity. The transmission gear 63 is disposed in the groove 113, and the transmission shaft is disposed in the groove 113 and penetrates through the housing 1, and is located at the periphery of the gear tooth structure 221 of the ring 22.

According to the utility model, the driving unit 61 is covered outside the shell 1, so that the driving unit 61 can be prevented from being in a humid environment in the accommodating cavity 11 for a long time, the driving unit 61 is prevented from being damaged, and wires for externally connecting the driving unit 61 are facilitated.

The cover 64 is fastened to the outer peripheral edge of the recess 113. The cover 64 extends from the outer peripheral edge of the groove 113 to the outer peripheral edge of the support table along the radial direction of the rotor 2, and extends outward in the circumferential direction of the groove 113.

The cover 64 is provided on one end of the first connecting passage 3 provided on the housing 1. The cover 64 extends to a pipe section extending axially toward the other side of the housing 1 near the first connecting passage 3.

The drive device 6 further comprises a support for fixing the drive unit 61 and the transmission gear 63. One end of the supporting frame is arranged in the housing 64, and the other end of the supporting frame penetrates through the shell 1 to the groove 113.

A through hole is formed in the side wall of the other side of the housing 1, and the opening is formed in the peripheral edge of the groove 113. The support frame is arranged through the through hole.

The output shaft of the drive unit 61 is arranged extending in the radial direction of the rotor 2. The drive means 6 comprise a reduction gear 62, wherein the reduction gear is in driving connection with the output shaft of the drive unit 61, the output shaft of the reduction gear is in driving connection with the gear, and the transmission shaft is connected between the output of the gear and the transmission gear 63. The decelerator and the commutator are disposed within the housing 64.

The support frame includes first board, second board, the third board that connects gradually. The first plate extends from outside to inside along the radial direction and is arranged in the housing 64, the second plate extends from the first plate along the axial direction to be close to the direction of the shell 1 and is arranged in the housing 64, and the third plate extends from the second plate obliquely to the middle of the groove 113 and penetrates through the through hole into the shell 1.

The transmission gear 63 is fixed on a third plate located in the housing 1, the transmission shaft penetrates through the third plate, and the commutator is arranged on a side wall, away from the first plate, of the second plate. The speed reducer is arranged on one side of the second plate, which is close to the first plate. The driving unit 61 is fixed to the first plate and is disposed on the same side as the decelerator.

As shown in fig. 6 to 10, further, the condenser 5 includes an air inlet chamber 511, an air outlet chamber 514, a central control chamber, a first radiating pipe 53 and a second radiating pipe 54.

The air inlet chamber 511 is provided with a condensation inlet 512 which is communicated with the air outlet of the first connecting channel 3 and is used for feeding moisture.

The air outlet chamber 514 is provided with a condensation outlet 515, which is communicated with the air inlet of the second connection channel 4, and is used for discharging the condensed air into the second connection channel 4.

The first heat dissipating pipes 53 are configured to communicate the air inlet chamber 511 with the hollow chamber 521, and have a plurality of first heat dissipating pipes 53 disposed at intervals, and are configured to introduce and then guide air in the air inlet chamber 511 into the hollow chamber 521.

The second heat dissipating pipes 54 communicate the hollow chamber 521 with the air outlet chamber 514, and have a plurality of second heat dissipating pipes 54 disposed at intervals, for introducing the air in the hollow chamber 521 and guiding the air out of the air outlet chamber 514.

The flux of the plurality of second radiating pipes 54 communicated between the air inlet chamber 511 and the hollow chamber 521 is smaller than that of the plurality of first radiating pipes 53.

The first heat dissipation tube 53 and the second heat dissipation tube 54 are used for air cooling, heat dissipation and dehumidification of moisture.

According to the utility model, the plurality of first radiating pipes 53 are arranged between the air inlet chamber 511 and the hollow chamber 521, the plurality of second radiating pipes 54 are arranged between the hollow chamber 521 and the air outlet chamber 514, and moisture is introduced into the plurality of first radiating pipes 53 through the air inlet chamber 511 for air cooling, heat dissipation and dehumidification, so that the moisture is split, the contact area with air is increased, and preliminary condensation dehumidification is performed by utilizing air cooling; then, moisture is continuously led into the plurality of second radiating pipes 54 through the hollow chamber 521, so that the contact area with air is large, and the secondary condensation dehumidification is facilitated for radiating heat; and because the total flux of a plurality of second cooling tubes 54 is less than the total flux of a plurality of first cooling tubes 53, when moisture passes through a plurality of second cooling tubes 54, the moisture receives bigger windage, increases the stay time of moisture in the second cooling tubes 54, is favorable to moisture to condense completely, produces more comdenstion water, and dehumidification effect is higher, can improve the dehumidification effect of condenser 5, reduces condensation dehumidification energy consumption, simple structure, with low costs.

Preferably, the inner diameter d2 of the second radiating pipe 54 is smaller than the inner diameter d1 of the first radiating pipe 53.

The condenser 5 of the present utility model may include a hollow chamber 521, and may further include a plurality of independent hollow chambers 521, wherein a heat dissipating pipe is connected between two adjacent hollow chambers 521, and the plurality of independent hollow chambers 521 are sequentially connected between the air inlet chamber 511 and the air outlet chamber 514 through the heat dissipating pipe. The inner diameters of the various radiating pipes are sequentially reduced from one side close to the air inlet chamber 511 to one side close to the air outlet chamber 514, so that the wind resistance is increased gradually, and the condensation dehumidification effect is improved.

Further, the condenser 5 further includes a first communicating portion 51 and a second communicating portion 52.

The air inlet chamber 511 and the air outlet chamber 514 are respectively and independently disposed inside the first communication portion 51.

The hollow chamber 521 is provided inside the second communication section 52; the first communication portion 51 is disposed opposite to the second communication portion 52.

The condensation inlet 512 and the condensation outlet 515 are disposed on one side of the first communication portion 51, and one side of the first communication portion 51 is disposed opposite to the other side of the housing 1.

The first radiating pipe 53 and the second radiating pipe 54 are connected between the first communicating portion 51 and the second communicating portion 52.

The air inlet chamber 511 and the air outlet chamber 514 are respectively and independently disposed inside the first communication portion 51. The hollow chamber 521 is disposed inside the second communication portion 52 and is disposed opposite to the air inlet chamber 511 and the air outlet chamber 514.

According to the utility model, by arranging the two oppositely arranged first communicating parts 51 and second communicating parts 52, a plurality of first radiating pipes 53 are arranged between the air inlet chamber 511 of the first communicating part 51 and the hollow chamber 521 of the second communicating part 52, and a plurality of second radiating pipes 54 are arranged between the air outlet chamber 514 of the first communicating part 51 and the hollow chamber 521, so that the first radiating pipes 53 and the second radiating pipes 54 of the condenser 5 are simply connected, and an air U-shaped backflow is formed between the first communicating part 51 and the second communicating part 52, thereby being beneficial to increasing the air resistance of the flow of moisture in the second radiating pipes 54 and improving the radiating effect, thereby improving the dehumidifying effect, and also being small in volume, simple in structure and low in cost of the condenser 5.

The first communicating portion 51 has a certain extension length, and the air inlet chamber 511 and the air outlet chamber 514 are sequentially extended and disposed on the first communicating portion 51 along the length direction of the first communicating portion 51. The second communication portion 52 has a certain extension length, and the second communication portion 52 is disposed in both the air inlet chamber 511 and the air outlet chamber 514 on one side of the first communication portion 51.

The first radiating pipe 53 is disposed to extend straight between opposite sides of the air inlet chamber 511 and the hollow chamber 521, and the second radiating pipe 54 is disposed to extend straight between opposite sides of the hollow chamber 521 and the air outlet chamber 514.

The first radiating pipe 53 and the second radiating pipe 54 are straight pipes. The first radiating pipes 53 and the second radiating pipes 54 are respectively and uniformly arranged at intervals.

A plurality of plugging holes 55 are respectively provided on opposite sides of the first communication portion 51 and the second communication portion 52. The plurality of plug holes 55 include a plurality of first plug holes, a plurality of second plug holes, a plurality of third plug holes, and a plurality of fourth plug holes. The first and second plugging holes are disposed on the first communicating portion 51 and correspondingly communicate with the air inlet chamber 511 and the air outlet chamber 514. The third and fourth plugging holes are disposed on the second communicating portion 52 and are all communicated with the hollow chamber 521.

The two ends of the first radiating pipe 53 are inserted into the first insertion hole and the third insertion hole. The two ends of the second radiating pipe 54 are inserted into the second insertion hole and the fourth insertion hole. The aperture of the second plug hole is smaller than that of the first plug hole.

Preferably, the third plugging hole is opposite to the air inlet chamber 511, and the aperture of the third plugging hole is the same as that of the first plugging hole. The fourth plugging hole is opposite to the air outlet chamber 514, and the aperture of the fourth plugging hole is the same as the aperture of the second plugging hole.

The first radiating pipe 53, the second radiating pipe 54 and the plugging hole 55 are sealed by a sealing member or sealant. The seal may be a silicone or rubber seal.

In order to reduce the cost of the first and second radiating pipes 53, 54 and the ease of insertion, the flexible polymer material such as PE, PP, etc. can be used

In one embodiment, the number n2 of the second radiating pipes 54 is smaller than the number n1 of the first radiating pipes 53, and the inner diameter d2 of the second radiating pipes 54 is equal to the inner diameter d1 of the first radiating pipes 53. The wind resistance in the plurality of second radiating pipes 54 can be increased to improve the dehumidifying effect. Compared with the number of the second radiating pipes 54, the inner diameter of the second radiating pipes 54 is reduced, and the contact area between the plurality of second radiating pipes 54 and the air is smaller.

In another embodiment, the number n2 of the second radiating pipes 54 is greater than or equal to the number n1 of the first radiating pipes 53, the inner diameter d2 of the second radiating pipes 54 is smaller than the inner diameter d1 of the first radiating pipes 53, the greater the number of the second radiating pipes 54 is than the number of the first radiating pipes 53 is, and the smaller the inner diameter d2 of the second radiating pipes 54 is relative to the inner diameter d1 of the first radiating pipes 53.

According to the utility model, the number of the second radiating pipes 54 is larger than that of the first radiating pipes 53, so that the contact area between the second radiating pipes 54 and air can be increased, the radiating effect during secondary condensation is improved, the inner diameter d2 of the second radiating pipes 54 is smaller than the inner diameter d1 of the first radiating pipes 53, when moisture enters the second radiating pipes 54, the inner diameter is reduced, the encountered wind resistance is increased, the residence time of the moisture in the second radiating pipes 54 can be improved, the radiating effect in the second radiating pipes 54 is better, the dehumidifying effect of secondary condensation can be further improved, the dehumidifying speed is high, and the dehumidifying effect of the whole condenser 5 is improved.

Let the lengths of the first radiating pipe 53 and the second radiating pipe 54 be equal, and they are all l.

The total flux of the plurality of second radiating pipes 54 is smaller than that of the plurality of first radiating pipes 53 as follows: pi (d 2/2) 2.l.n2 < pi (d 1/2) 2.l.n1

D2 < (. V.n1/. V.n2). D1 can be obtained

Accordingly, the larger the number of the second radiating pipes 54 than the first radiating pipes 53, the smaller the inner diameter d2 of the second radiating pipe 54 with respect to the inner diameter d1 of the first radiating pipe 53.

The volume V1 of the air inlet chamber 511 is smaller than the volume V2 of the air outlet chamber 514, and the extension length of the air inlet chamber 511 is smaller than the extension length of the air outlet chamber 514.

Preferably, the volume V2 of the air outlet chamber 514 is greater than the volume V1 of the air inlet chamber 511, and the volume V2 of the air outlet chamber 514 is less than 2 times the volume V1 of the air inlet chamber 511. The second radiating pipe 54 is provided at a density greater than that of the first radiating pipe 53.

The number of the second radiating pipes 54 is at least twice the number of the first radiating pipes 53.

The preferable specific scheme is that V2 is more than or equal to 1.2.V 1 and less than or equal to 1.6.V 1. 0.2d1.ltoreq.d2 <.v2d1, more preferably 0.4d1.ltoreq.d2.ltoreq.0.7d1.

Through setting up first cooling tube 53 into many intervals setting, to the moisture reposition of redundant personnel, the area of contact of the perisporium of increase many first cooling tubes 53 and air improves forced air cooling dehumidification effect, and the setting quantity of second cooling tube 54 is at least first cooling tube 53 sets up twice of quantity, further shunts the moisture, through the perisporium and the air heat transfer of a plurality of second cooling tubes 54, moisture cooling dehumidification in the second cooling tube 54 to the internal diameter of cooperation second cooling tube 54 reduces, increases the windage, increases the dwell time of moisture in the second cooling tube 54, makes complete dehumidification as far as possible, further improves the dehumidification effect.

Further, the first communicating portion 51 is provided with a first condensation water outlet pipe 513 and a second condensation water outlet 516, which are correspondingly communicated with the air inlet chamber 511 and the air outlet chamber 514, and are used for discharging condensed water outwards.

The inner diameter of the first condensation water outlet pipe 513 is smaller than that of the second condensation water outlet pipe 516, and the inner diameters of the first condensation water outlet pipe 513 and the second condensation water outlet pipe 516 are less than or equal to 6mm.

According to the utility model, the inner diameters of the first condensation water outlet pipe 513 and the second condensation water outlet pipe 516 are less than or equal to 6mm, so that a large amount of moisture can be prevented from overflowing, gas overflow is reduced, and maximum condensation is realized; through setting up the internal diameter of the first condensation outlet pipe 513 of air inlet cavity 511 and being less than the internal diameter of the second condensation outlet pipe 516 of air-out cavity 514, can avoid just getting into the excessive moisture of air inlet cavity 511, lead to moisture dehumidification efficiency to reduce, and the air that gets into in the air-out cavity 514 is through dehumidification, and very big part steam has been handled, therefore the aforesaid reasonable setting can enough guarantee comdenstion water play water, can not reduce the dehumidification efficiency of condenser 5 again.

Further, the first and second condensation water outlet pipes 513 and 516 are disposed on a side of the first communication part 51 opposite to the second communication part 52.

Preferably, the first condensation water outlet pipe 513 and the second condensation water outlet pipe 516 are correspondingly disposed at the most protruding parts of the air inlet chamber 511 and the air outlet chamber 514 in a direction opposite to the second communicating part 52.

One side of the first communication portion 51 is disposed opposite to the second communication portion 52, and the other side of the first communication portion 51 is disposed opposite to the second communication portion 52. In actual use, the other side of the first communication portion 51 is disposed downward, so as to conveniently set an external condensate water pipeline.

The other side of the first communicating portion 51 is protruded from opposite ends of the air inlet chamber 511 and the air outlet chamber 514 toward the adjacent ends. The first condensation water outlet pipe 513 and the second condensation water outlet 516 are correspondingly arranged at the end parts of the air inlet chamber 511 and the air outlet chamber 514, which are close to each other.

The other side of the first communication portion 51 is provided with an inwardly recessed separation groove 517, which separates the interior of the first communication portion 51 into an independent air inlet chamber 511 and an independent air outlet chamber 514. The partition groove 517 penetrates both side walls adjacent to the other side of the first communicating portion 51.

The other sides of the air inlet chamber 511 and the air outlet chamber 514 are protruded obliquely outward from both ends of the length extending direction of the first communicating portion 51 to the middle portion to form an inclined structure, and then extend to the partition groove 517 along the length extending direction to form a planar structure. The first condensation water outlet pipe 513 and the second condensation water outlet 516 are both arranged on the plane structures on the other sides of the air inlet chamber 511 and the air outlet chamber 514.

In actual use, the other side of the first communication portion 51 is disposed downward, and the inclined structure is used for guiding the condensed water collected in the air inlet chamber 511 and the air outlet chamber 514 to flow to the first condensation water outlet pipe 513 and the second condensation water outlet 516 at the lowest positions.

Preferably, the second communicating portion 52 is a rectangular parallelepiped, the first communicating portion 51 is a boat shape, the dividing groove 517 is concavely provided on the bottom side of the boat,

further, the air intake chamber 511 is provided with a condensation inlet 512, and the condensation inlet 512 is disposed on a side wall of the first communication part 51 adjacent to the side having the first heat dissipating pipe 53. The air outlet chamber 514 is provided with a condensation outlet 515, and the condensation outlet 515 is provided on a side wall of the first communication part 51 adjacent to the side having the second radiating pipe 54.

The condensation inlet 512 and the condensation outlet 515 are provided on the same side wall of the first communicating portion 51.

As shown in fig. 11, the present utility model also provides a washing and caring apparatus 8 having any of the moisture transport systems described above. The washing and care appliance 8 may be a dishwasher, a washing machine, a dryer and a laundry care cabinet.

The washing and caring apparatus 8 further comprises a cabinet 81, a processing unit 82, a first channel 83 and a condenser 5. The processing unit 82 is used for washing and/or drying articles. Both ends of the first channel 83 are communicated with the processing unit 82, the dehumidifying casing 7 is communicated with the first channel 83, and is used for guiding out the moisture in the processing unit 82 into the dehumidifying casing 7, dehumidifying the moisture by the adsorption area 116 to obtain dry air, and then guiding the dry air back into the processing unit 82 to dry the objects in the processing unit 82.

The second connection channel 4 is communicated with the air outlet of the first connection channel 3, and is used for discharging moisture outside the washing and caring equipment 8, or the second connection channel 4 is communicated with the air outlet of the first connection channel 3, a condenser 5 is arranged between the first connection channel 3 and the second connection channel 4, and is used for condensing the received moisture, and the obtained dry air is led into the first channel 83 or directly back into the processing unit 82.

Preferably, the washing and caring apparatus 8 further comprises a water collecting box 84 for receiving condensed water generated by condensation of the condenser 5.

Further, the moisture transport system further comprises a dehumidification housing 7. The dehumidifying casing 7 is internally provided with an accommodating space 71, the dehumidifying casing 7 is arranged in a casing 81 of the washing and protecting equipment 8, the casing 1 is arranged in the accommodating space 71, and an air inlet 111 of the casing 1 is communicated with the first channel 83 and is used for receiving the introduced moisture.

In the present utility model, as in fig. 11, the laundry care cabinet is taken as an example, but the solution is not limited to the laundry care cabinet, but can be applied to a washing machine, a clothes dryer, and a dish washer

The foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited to the above-mentioned embodiment, but is not limited to the above-mentioned embodiment, and any simple modification, equivalent change and modification made by the technical matter of the present utility model can be further combined or replaced by the equivalent embodiment without departing from the scope of the technical solution of the present utility model.

Claims (10)

1. A moisture transport system, characterized by: comprising the steps of (a) a step of,

the shell is internally provided with a containing cavity, an air inlet is formed in the shell and used for guiding external moisture into the containing cavity, and an air outlet is formed in the shell and used for guiding out dry air;

the rotating wheel is rotatably supported in the accommodating cavity, the accommodating cavity comprises an adsorption area and a desorption area, the rotating wheel is provided with a position which moves back and forth between the adsorption area and the desorption area, and the rotating wheel rotates to the desorption area to be separated after the adsorption area adsorbs moisture in the accommodating cavity;

the first connecting channel is arranged on the shell, one end of the first connecting channel is provided with an air inlet and is used for receiving the moisture in the desorption area, and the other end of the first connecting channel is provided with an air outlet and is used for discharging the desorbed moisture out of the shell;

the condenser is arranged outside the shell, and an air inlet of the condenser is communicated with an air outlet of the first connecting channel and is used for condensing the moisture in the desorption zone received by the first connecting channel;

and the air inlet at one end of the second connecting channel is communicated with the air outlet of the condenser, and the air outlet at the other end of the second connecting channel is communicated with the shell and is used for guiding the condensed gas into the shell.

2. A moisture transport system according to claim 1, wherein: one end of the first connecting channel is positioned in the accommodating cavity, and an air inlet at one end of the first connecting channel is arranged close to the rotating wheel; the other end of the first connecting channel extends out of the accommodating cavity and is communicated with the condenser.

3. A moisture transport system according to claim 2, characterized in that:

an air inlet is formed in one side wall of the shell, and a first opening is formed in the other opposite side wall;

the air inlet of the first connecting channel extends into the accommodating cavity through the first opening and is arranged close to the wheel surface opposite to the air inlet;

the air outlet at the other end of the first connecting channel extends to the outside of the accommodating cavity through the first opening and is communicated with the air inlet of the condenser.

4. A moisture transport system according to claim 3, characterized in that: the first opening is arranged opposite to the desorption area.

5. A moisture transport system according to claim 3, characterized in that: the shell is provided with a first opening, the first opening is arranged on the side wall of the shell, the second opening is arranged on the side wall of the shell, the side wall of the shell is opposite to the air inlet, the first opening is far away from the air inlet, the air inlet at one end of the first connecting channel is communicated with the condenser, and the air outlet at the other end of the first connecting channel extends into the accommodating cavity through the first opening.

6. A moisture transport system as set forth in claim 5 wherein: the second opening and the first opening are arranged at two opposite ends of the other side wall of the shell;

the gas outlet at the other end of the second connecting channel extends into the accommodating cavity and is arranged close to the adsorption area and used for guiding the condensed gas to the adsorption area.

7. A moisture transport system according to any of claims 3-6, characterized in that:

the accommodating cavity comprises a groove which is arranged close to the other side of the shell, and the rotating wheel is arranged in the groove;

the first opening and the second opening are arranged on the bottom wall of the groove at intervals.

8. A moisture transport system according to any of claims 3-6, characterized in that: the condenser may be comprised of a combination of a condenser and a condenser,

the air inlet chamber is provided with a condensation inlet which is communicated with the air outlet of the first connecting channel and is used for feeding moisture;

the air outlet chamber is provided with a condensation outlet which is communicated with the air inlet of the second connecting channel and is used for discharging condensed air into the second connecting channel;

a hollow chamber;

the first radiating pipes are communicated with the air inlet cavity and the hollow cavity and are arranged at intervals and used for leading in and then guiding out air in the air inlet cavity into the hollow cavity;

The second radiating pipes are communicated with the hollow cavity and the air outlet cavity and are arranged at intervals and used for leading in and guiding out air in the hollow cavity into the air outlet cavity;

the flux of the second radiating pipes communicated between the air inlet cavity and the hollow cavity is smaller than that of the first radiating pipes.

9. A moisture transport system as set forth in claim 8, wherein: the condenser may further comprise a heat exchanger configured to heat the heat exchanger,

the air inlet chamber and the air outlet chamber are respectively and independently arranged in the first communication part;

the hollow cavity is arranged in the second communication part; the first communication part and the second communication part are oppositely arranged;

the condensation inlet and the condensation outlet are arranged on one side of the first communication part, and one side of the first communication part is opposite to the other side of the shell.

10. A washing and caring device, characterized in that: a moisture transport system as claimed in any one of claims 1 to 9.