CN220062634U - Condenser assembly of washing and protecting equipment and washing and protecting equipment - Google Patents

Abstract

The utility model discloses a condenser assembly of washing and protecting equipment and the washing and protecting equipment, which comprise a condenser body, a spray shell, a water inlet end and a water outlet end, wherein a containing cavity is formed in the spray shell, and the containing cavity comprises spray cavities which are sequentially communicated from the water inlet end to the water outlet end in an extending manner; a heat exchange chamber; a drainage chamber; the heat exchange chamber has an inner diameter that decreases in the direction of extension, and is disposed adjacent to the condenser body for directing shower water onto the condenser body. According to the utility model, the spray chamber, the heat exchanger chamber and the drainage chamber which are sequentially and extendedly communicated from the water inlet end to the water outlet end are arranged in the spray shell, so that the inner diameter of the heat exchange chamber is reduced along the extension direction and is close to the condenser body, the flow speed of spray water in the heat exchange chamber is reduced, meanwhile, the heat exchange chamber can also guide the spray water to the condenser body, the heat exchange efficiency of the spray water and the condenser body is improved, the structure is simple, the application range is wide, and the cooling effect on the condenser body is improved.

Description

Condenser assembly of washing and protecting equipment and washing and protecting equipment

Technical Field

The utility model belongs to the field of condensation dehumidification, and particularly relates to a condenser assembly of washing and protecting equipment and the washing and protecting equipment.

Background

In the prior art, the washing and protecting equipment is used for condensing and dehumidifying high-humidity or high-temperature and high-humidity air through a condenser in the process of drying and washing units after washing or in the process of drying the washing and protecting equipment, the water vapor in the existing condenser is lower and lower in the dehumidifying process, and the flow of dehumidifying all the air with large flow is still needed, so that the problems of weak dehumidifying capacity, long time for dehumidifying and high energy consumption are solved.

In order to solve the technical problem, the temperature of the condenser is reduced by adopting spraying or air cooling, the condenser is directly provided with a spray head to spray the condenser for cooling, the structure is complex, the cooling effect is uneven, the spraying fringe of the spraying assembly is larger, and the heat exchange effect is poor.

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 provides a condenser assembly, which is characterized in that a containing cavity is formed in a shell, the containing cavity is divided into a spraying cavity, a heat exchanger cavity and a drainage cavity which are sequentially communicated from a water inlet end to a water outlet end, the inner diameter of the heat exchange cavity is reduced along the extending direction and is arranged close to a condenser body, the flowing speed of spray water in the heat exchange cavity is reduced, meanwhile, the heat exchange cavity can also guide the spray water to the condenser body, the heat exchange efficiency of the spray water and the condenser body is improved, the structure is simple, the application range is wide, and the cooling effect on the condenser body is improved.

It is a further object of the present utility model 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 condenser assembly for a washing apparatus, comprising,

the condenser body is used for discharging dry air after air intake condensation and dehumidification;

the spray shell is internally provided with a containing cavity, and the containing cavity comprises a spray cavity, a heat exchange cavity and a drainage cavity which are sequentially communicated from a water inlet end to a water outlet end in an extending mode;

the spraying chamber is used for guiding the water to spray to the heat exchange chamber;

the condenser body is arranged in the heat exchange cavity, and the heat exchange cavity is used for reducing the temperature of the condenser body through spray water;

the drainage chamber is used for collecting spray water and draining the spray water;

the inner diameter of the heat exchange chamber is reduced along the extending direction, and the heat exchange chamber is arranged close to the condenser body and used for guiding spray water onto the condenser body.

Further, two ends of the condenser body are respectively arranged close to the spraying chamber and the drainage chamber;

when the heat exchange chamber extends from one end of the communicating spraying chamber to the water outlet end, the inner diameter of the heat exchange chamber is reduced and gradually approaches to the condenser body, and then the heat exchange chamber extends to the water outlet end to be communicated with the drainage chamber.

Further, one side of the condenser body is arranged close to the inner wall of one side of the heat exchange chamber, and the other side of the condenser body is at least partially provided with a gap with the inner wall of the other side of the heat exchange chamber;

the distance between the two side walls of the condenser body gradually decreases from one end close to the spraying chamber to the other end close to the draining chamber.

Further, the other side wall of the heat exchange chamber comprises a plurality of heat exchange chambers which are sequentially connected,

one end of the first connecting plate is connected with the spraying cavity, and a gap is reserved between the inner wall of the first connecting plate and the condenser body;

the second connecting plate is obliquely arranged from the other end of the first connecting plate to the direction of the condenser body;

and the inner wall of the third connecting plate is close to the condenser body.

Further, the condenser body comprises a plurality of air-conditioning units,

the first communication part is independently provided with an air inlet cavity and an air outlet cavity, the air inlet cavity is used for feeding moisture, and the air outlet cavity is used for discharging condensed air;

the second communication part is internally provided with a hollow cavity, and the first communication part and the second communication part are oppositely arranged;

The first radiating pipe is arranged between the air inlet cavity and the opposite side of the hollow cavity in a straight extending mode;

the second radiating pipe is arranged between the opposite sides of the hollow cavity and the air outlet cavity in a straight extending mode;

the first communicating part and the second communicating part are arranged in the heat exchange cavity and are respectively close to the two ends of the spraying cavity and the draining cavity, and the inner diameter of the heat exchange cavity is gradually reduced to be close to the first radiating pipe and the second radiating pipe.

Further, one side of the first communication part and one side of the second communication part are close to one side wall of the heat exchange chamber;

the first connecting plate is provided with a gap with the other side of the first communication part, and at least part of the first radiating pipe and the second radiating pipe connected with the first communication part are provided with the gaps;

the second connecting plate is gradually close to the first radiating pipe and the second radiating pipe;

the third connecting plate is closely arranged with the other side of the second communication part and the parts of the first radiating pipe and the second radiating pipe connected with the second communication part.

Further, the third connecting plate is provided with an air inlet and an air outlet which are respectively used for air inlet and air outlet in the spray shell;

The second communication part is provided with an air inlet and an air outlet which are respectively communicated with the air inlet cavity and the air outlet cavity;

the air inlet and the air outlet are correspondingly communicated with the air inlet and the air outlet respectively;

preferably, a first condensation water outlet pipe and a second condensation water outlet pipe are arranged on the first communication part and correspondingly communicated with the air inlet cavity and the air outlet cavity, and the water outlet ends of the first condensation water outlet pipe and the second condensation water outlet pipe are communicated with the water drainage cavity and used for discharging condensed water outwards;

the air inlet and the air outlet are arranged on the same side with the water outlet of the drainage cavity.

Further, the inner diameter of the spray cavity gradually increases from the direction close to the water inlet end to the direction close to the water outlet end;

preferably, the spraying chamber is in a horn-shaped structure from the water inlet end to the water outlet end.

Further, a separation plate is arranged at the joint of the spraying chamber and the heat exchange chamber, a plurality of spraying holes are formed in the separation plate, the spraying holes are communicated with the spraying chamber and the heat exchange chamber and used for separating inflow water to form a water curtain, and the water curtain is sprayed into the heat exchange chamber.

A washing and care apparatus having a condenser assembly 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 spray shell is arranged outside the condenser body, the spray shell is sequentially communicated from the water inlet end to the water outlet end to form the spray cavity, the heat exchange cavity and the drainage cavity, the condenser body is arranged in the heat exchange cavity, the spray cavity is used for spraying water into the heat exchange cavity to reduce the temperature of the condenser body, meanwhile, the inner diameter of the heat exchange cavity is reduced along the extending direction and is arranged close to the condenser body, the flow speed of the spray water in the heat exchange cavity is reduced, meanwhile, the heat exchange cavity can also guide the spray water onto the condenser body, the heat exchange efficiency of the spray water and the condenser body is improved, the structure is simple, the application range is wide, and the cooling effect on the condenser body is improved.

(2) According to the utility model, a plurality of first radiating pipes are arranged between the air inlet cavity and the hollow cavity, a plurality of second radiating pipes are arranged between the hollow cavity and the air outlet cavity, and moisture is introduced into the first radiating pipes through the air inlet cavity to perform air-cooled radiating and dehumidifying, so that preliminary condensation and dehumidifying are performed; then, continuously introducing moisture into the second radiating pipe through the hollow cavity to radiate, cool and dehumidify, and performing secondary condensation and dehumidification; and because the internal diameter of second cooling tube is less than the internal diameter of first cooling tube, the moisture is when the second cooling tube, and the moisture receives bigger windage, is favorable to complete condensation, produces more comdenstions water, and dehumidification effect is higher, can improve the dehumidification effect of condenser, reduces condensation dehumidification energy consumption, simple structure, with low costs.

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 view of a condensing shell according to the present utility model;

FIG. 2 is a schematic view of the utility model at another angle to FIG. 1;

FIG. 3 is a cross-sectional view taken along the direction B-B in FIG. 2 in accordance with the present utility model;

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

FIG. 5 is a schematic view of a condenser body of the present utility model;

FIG. 6 is a schematic view of the utility model at another angle to FIG. 5;

FIG. 7 is a schematic illustration of the utility model at yet another angle to FIG. 5;

FIG. 8 is a schematic view of the utility model at another angle to FIG. 7;

FIG. 9 is a schematic cross-sectional view taken along the direction A-A in FIG. 7 in accordance with the present utility model;

FIG. 10 is a schematic view of a washing apparatus of the present utility model;

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

In the figure: 1. a condenser body; 11. a first communication section; 111. an air inlet chamber; 112. an air inlet; 113. a first condensing water outlet pipe; 114. an air outlet chamber; 115. an air outlet; 116. a second condensing water outlet pipe; 117. a separation groove; 12. a second communication portion; 121. a hollow chamber; 13. a first radiating pipe; 14. a second radiating pipe; 15. a plug hole; 2. a rotary dehumidifier; 21. a housing; 211. an adsorption zone; 212. a desorption zone; 22. a first channel; 221. a first fan; 23. a second channel; 231. a heater; 232. a second fan; 3. washing and protecting equipment; 31. a housing; 32. a processing unit; 33. a water collecting box; 34. a dehumidifying chamber; 4. spraying the shell; 41. a housing chamber; 42. a spray chamber; 421. a water inlet end; 43. a heat exchange chamber; 431. a first connection plate; 432. a second connecting plate; 433. a third connecting plate; 4331. an air inlet; 4332. an air outlet; 44. a drainage chamber; 441. a water outlet; 45. a partition plate; 451. spraying holes; 46. a temperature sensor; 47. a liquid level sensor.

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 4, the utility model provides a condenser assembly of washing and protecting equipment, which comprises a condenser body 1 and a spray shell 4.

The condenser body 1 is used for discharging dry air after air intake condensation dehumidification.

The spray shell 4 is internally provided with a containing chamber 41, and the containing chamber 41 comprises a spray chamber 42, a heat exchange chamber 43 and a drainage chamber 44 which are sequentially communicated from a water inlet end 421 to a water outlet end.

The spray chamber 42 is used to direct the incoming water spray to the heat exchange chamber 43.

The condenser body 1 is arranged in the heat exchange chamber 43, and the heat exchange chamber 43 is used for reducing the temperature of the condenser body 1 through spray water.

The drain chamber 44 is used to collect and drain shower water.

The heat exchange chamber 43 has an inner diameter decreasing in the extending direction, and is disposed close to the condenser body 1 for guiding shower water onto the condenser body 1.

According to the utility model, the spray shell 4 is arranged outside the condenser body 1, the spray shell 4 is sequentially communicated from the water inlet end 421 to the water outlet end to form the spray chamber 42, the heat exchange chamber 43 and the drainage chamber 44, the condenser body 1 is arranged in the heat exchange chamber 43, the spray chamber 42 is used for spraying water into the heat exchange chamber 43 to reduce the temperature of the condenser body 1, meanwhile, the inner diameter of the heat exchange chamber 43 is reduced along the extending direction and is arranged close to the condenser body 1, the flow speed of the spray water in the heat exchange chamber 43 is reduced, meanwhile, the heat exchange chamber 43 can also guide the spray water to the condenser body 1, the heat exchange efficiency of the spray water and the condenser body 1 is improved, the structure is simple, the application range is wide, and the cooling effect on the condenser body 1 is improved.

Specifically, in the use, only need be in the outside of condenser body 1 sets up sprays shell 4 to with condenser body 1 alone sets up in spray shell 4's heat exchange cavity 43, make spray cavity 42 to when the heat exchange cavity sprays water, realize cooling down condenser body 1, then reduce at heat exchange cavity 43's internal diameter, be close to condenser body 1 and set up, make the rivers that spray can reduce the velocity of flow in heat exchange cavity 43, spray water can be through heat exchange cavity 43's internal runoff to condenser body 1 on, increase the heat transfer effect, simultaneously, drainage cavity 44 is with spray water and comdenstion water export to the outside of equipment.

Further, both ends of the condenser body 1 are respectively disposed near the spray chamber 42 and the drain chamber 44.

When the heat exchange chamber 43 extends from one end of the communicating shower chamber 42 toward the water outlet end, the inner diameter is then reduced to be gradually close to the condenser body 1, and then extends toward the water outlet end to be communicated with the drain chamber 44.

According to the utility model, the two ends of the condensation body are respectively close to the spraying chamber 42 and the drainage chamber 44, so that the condenser body 1 can be just filled in the heat exchange chamber 43 and is matched with the heat exchange chamber 43.

When the heat exchange chamber 43 extends from one end of the communicating spraying chamber 42 to the water outlet end, then the inner diameter is gradually reduced and is gradually close to the condenser body 1, then the heat exchange chamber 43 is communicated with the water discharge chamber 44 and is divided into different inner diameter spaces, one end of the heat exchange chamber 43 close to the spraying chamber 42 is extended and arranged, so that spraying water is better used for cooling one end of the condenser body 1, then the inner diameter is gradually reduced and is gradually close to the condenser body 1, and the space of the heat exchange chamber 43 is gradually reduced. The spray water is led to flow slowly in the heat exchange chamber 43 and can flow to the condenser body 1 to increase the heat exchange effect, and then is led to the water outlet end direction to be communicated with the water discharge chamber 44, so that the spray water is discharged from the water discharge chamber 44.

Further, one side of the condenser body 1 is disposed close to the inner wall of one side of the heat exchange chamber 43, and the other side is at least partially spaced from the inner wall of the other side of the heat exchange chamber 43.

The distance between the two side walls of the condenser body 1 gradually decreases from one end near the shower chamber 42 to the other end near the drain chamber 44.

Specifically, according to the utility model, by arranging one side of the condenser body 1 close to the inner wall of one side of the heat exchange chamber 43, the other side of the condenser body 1 has a gap with at least part of the inner wall of the other side of the heat exchange chamber 43, and the distance between the two side walls of the condenser body 1 and the heat exchange chamber 43 is reduced from one end close to the spray chamber 42 to the other end close to the drain chamber 44, only the other side wall of the heat exchange chamber 43 is provided with a gap with the condenser body 1, thereby reducing the complexity of the structure of the spray shell 4, saving the production cost and better realizing the cooling effect on the condenser body 1.

Further, the other side wall of the heat exchange chamber 43 includes a first connection plate 431, a second connection plate 432 and a third connection plate 433 connected in sequence.

One end of the first connecting plate 431 is connected to the spray chamber 42, and an inner wall of the first connecting plate 431 has a gap with the condenser body 1.

The second connection plate 432 is disposed obliquely from the other end of the first connection plate 431 toward the condenser body 1.

The third connection plate 433 extends from the other end of the second connection plate 432 to the drainage chamber 44, and an inner wall of the third connection plate 433 is disposed near the condenser body 1.

Specifically, the other side wall of the heat exchange chamber 43 is divided into a first connection plate 431, one end of the first connection plate 431 is connected with the spray chamber 42, a certain gap is formed between the first connection plate 431 and the condenser body 1, a better spray effect on one end of the condenser body 1 close to the spray chamber 42 is achieved, then a second connection plate 432 is arranged, spray water is obliquely arranged from the other end of the first connection plate 431 to the direction of the condenser body 1, the spray water is guided to the condenser body 1 through the second connection plate 432, meanwhile, the water flow speed of the spray water in the heat exchange chamber 43 is slowed down, the heat exchange efficiency is increased, the spray water is pressed close to the condenser body 1 through the inner wall of a third connection plate 433 and extends to a drainage chamber 44, the spray water can flow to the other end of the condenser body 1 and is discharged from the drainage chamber 44, insufficient contact between the water flow and the condenser body 1 is avoided, and the condensation effect on the condenser body 1 is improved.

Further, the condenser body 1 includes a first communication portion 11, a second communication portion 12, a first radiating pipe 13, and a second radiating pipe 14.

The first communicating part 11 is independently provided with an air inlet chamber 111 and an air outlet chamber 114, the air inlet chamber 111 is used for entering moisture, and the air outlet chamber 114 is used for discharging condensed air; a hollow chamber 121 is provided in the second communication portion 12, and the first communication portion 11 is disposed opposite to the second communication portion 12.

The first radiating pipe 13 is arranged between the air inlet chamber 111 and the opposite side of the hollow chamber 121 in a straight extending manner; the second radiating pipe 14 is disposed to extend straight between the hollow chamber 121 and the opposite side of the air outlet chamber 114.

According to the utility model, the two oppositely arranged first communication parts 11 and second communication parts 12 are arranged, the plurality of first radiating pipes 13 are arranged between the air inlet cavity 111 of the first communication part 11 and the hollow cavity 121 of the second communication part 12, and the plurality of second radiating pipes 14 are arranged between the air outlet cavity 114 of the first communication part 11 and the hollow cavity 121, so that the first radiating pipes 13 and the second radiating pipes 14 of the condenser are simply connected, the U-shaped air reflux is formed between the first communication part 11 and the second communication part 12, the increase of the air resistance of the flow of moisture in the second radiating pipes 14 is facilitated, and the radiating effect is improved, thereby improving the dehumidification effect.

The first communication part 11 and the second communication part 12 are disposed in the heat exchange chamber 43, and are respectively adjacent to both ends of the shower chamber 42 and the drain chamber 44, and the inner diameter of the heat exchange chamber 43 is gradually reduced and is gradually disposed adjacent to the first radiating pipe 13 and the second radiating pipe 14.

According to the utility model, the inner diameter of the heat exchange chamber 43 is gradually reduced to be close to the first radiating pipe 13 and the second radiating pipe 14, so that spray water can be guided to the first radiating pipe 13 and the second radiating pipe 14, the first radiating pipe 13 and the second radiating pipe 14 are cooled, and the condensation effect of the condenser body 1 is improved.

Further, one side of the first communication portion 11 and the second communication portion 12 is disposed close to one side wall of the heat exchange chamber 43.

The first connection plate 431 has a gap with the other side of the first communication part 11 and at least part of the first radiating pipe 13 and the second radiating pipe 14 connected to the first communication part 11.

The utility model realizes better spray cooling of the upper part of the condenser body 1 by arranging one side of the first communication part 11 and one side of the second communication part 12 close to one side wall of the heat exchange chamber 43, and arranging the first connection plate 431 with the other side of the first communication part 11 and at least part of the first radiating pipe 13 and the second radiating pipe 14 connected with the first communication part 11 with gaps and gaps between the upper part of the condenser body 1 and the other side wall of the heat exchange chamber 43.

The second connection plate 432 is gradually disposed closer to the first radiating pipe 13 and the second radiating pipe 14.

The second radiating pipes 13 and 14 are gradually close to each other, so that the shower water can be guided to the first radiating pipes 13 and 14 while the shower water slowly flows on the inner wall of the heat exchange chamber 43, and the heat exchange effect is improved.

The third connection plate 433 is disposed adjacent to the other side of the second communication part 12 and the portions of the first and second radiating pipes 13 and 14 connected to the second communication part 12.

Through will third connecting plate 433 with the opposite side of second intercommunication portion 12 and with the second intercommunication portion 12 is connected the part of first cooling tube 13, second cooling tube 14 press close to the setting, realize spraying rivers can follow first cooling tube 13, second cooling tube 14 on flow to second intercommunication portion 12 surface, realize cooling to whole condenser body 1, improve the cooling effect of condenser body 1, increase the condensation effect.

Further, an air inlet 4331 and an air outlet 4332 are arranged on the third connecting plate 433, and are respectively used for air inlet and air outlet in the spray shell 4.

The second communicating portion 12 is provided with an air inlet 112 and an air outlet 115 which are respectively communicated with the air inlet chamber 111 and the air outlet chamber 114.

The air inlet 112 and the air outlet 115 are respectively and correspondingly communicated with the air inlet 4331 and the air outlet 4332.

According to the application, the air inlet 4331 and the air outlet 4332 are arranged on the third connecting plate 433 and correspondingly communicated with the air inlet 112 and the air outlet 115 arranged on the second communicating part 12, so that the air inlet efficiency into the condenser body 1 is improved, and the complexity of the structure is reduced.

Preferably, the first communicating portion 11 is provided with a first condensation water outlet pipe 113 and a second condensation water outlet pipe 116, which are correspondingly communicated with the air inlet chamber 111 and the air outlet chamber 114, and water outlet ends of the first condensation water outlet pipe 113 and the second condensation water outlet pipe 116 are communicated with the water outlet chamber 44, so as to discharge condensed water outwards.

Through be equipped with first condensation outlet pipe 113, second condensation outlet pipe 116 on the first intercommunication portion 11, correspond with air inlet cavity 111, air-out cavity 114 intercommunication, the play water end of first condensation outlet pipe 113, second condensation outlet pipe 116 with drainage cavity 44 intercommunication, the comdenstion water that produces at condenser body 1 condensation can be discharged to through first condensation outlet pipe 113, second condensation outlet pipe 116 in drainage cavity 44, discharge to the equipment outside through drainage cavity 44, need not set up the condensation outlet pipe way alone, simplified structure.

The air inlet 4331 and the air outlet 4332 are arranged on the same side as the water outlet 441 of the drainage chamber 44. By arranging the air inlet 4331 and the air outlet 4332 on the spray shell 4 on the same side as the water outlet 441 of the drainage chamber 44, the space for installing the condenser assembly is saved, and the installation scheme is optimized.

The water outlet pipe at the water outlet 441 of the drainage chamber 44 has a circular pipe structure converging after the horn, so that water residue in the drainage chamber 44 can be avoided.

The drain chamber 44 is provided in integral communication with the heat exchange chamber 43.

Further, the inner diameter of the spray chamber 42 increases gradually from the vicinity of the water inlet end 421 to the direction of the water outlet end.

The inner diameter of the spray chamber 42 is gradually increased from the direction close to the water inlet end 421 to the direction close to the water outlet end, so that the spray range of the outlet water of the spray water is increased, and the spray effect into the heat exchange chamber 43 is improved.

Preferably, the spray chamber 42 has a horn-like structure from the adjacent water inlet end 421 to the water outlet end.

Further, a partition plate 45 is disposed at the connection between the spray chamber 42 and the heat exchange chamber 43, and a plurality of spray holes 451 are disposed on the partition plate 45, and the spray holes 451 are communicated with the spray chamber 42 and the heat exchange chamber 43, and are used for separating the inflow water to form a water curtain, and spraying into the heat exchange chamber 43.

In the present utility model, the partition board 45 is disposed at the connection between the spray chamber 42 and the heat exchange chamber 43, and a plurality of spray holes 451 are disposed on the partition board 45, the spray holes 451 are connected to the spray chamber 42 and the heat exchange chamber 43, and after the spray chamber 42 is fed with water through the water inlet end 421, the spray water is separated to form a water curtain by the spray holes 451 on the partition board 45, and sprayed into the heat exchange chamber 43, so as to improve the spray range and the spray effect.

Further, a temperature sensor 46 is arranged in the spraying shell 4 and used for detecting the temperature in the spraying shell 4, a circulating pump is arranged, after the fact that the temperature in the spraying shell 4 reaches the set temperature is detected, the circulating pump is controlled to spray water, the condenser body 1 is cooled, and the condensation effect is improved. Meanwhile, a liquid level sensor 47 is further arranged in the spray shell 4, and when the water level in the spray shell 4 reaches a set water level in the water inlet spraying process, the water inlet valve stops water inlet or opens the circulating pump/valve to enable water to flow out.

Preferably, the set liquid level does not exceed the ends of the first and second condensation water outlet pipes 113, 116.

As shown in fig. 5 to 9, in particular, the condenser body 1 is an air-cooled condenser body 1, which can be used for moisture dehumidification of the washing and care apparatus 3. The condenser body 1 of the washing and protecting equipment 3 comprises an air inlet chamber 111, an air outlet chamber 114, a hollow chamber 121, a plurality of first radiating pipes 13 and a plurality of second radiating pipes 14.

The air intake chamber 111 is used for taking in moisture to the inside. The air outlet chamber 114 is used for discharging the condensed air. The hollow chambers 121 are communicated with the air inlet chamber 111 and the air outlet chamber 114.

The first heat dissipating tube 13 communicates the air inlet chamber 111 with the hollow chamber 121, and is configured to introduce and dissipate heat from air in the air inlet chamber 111 to the hollow chamber 121. The plurality of first radiating pipes 13 are disposed in spaced communication. The second heat dissipating pipe 14 communicates the hollow chamber 121 with the air outlet chamber 114, and is configured to introduce and dissipate heat from air in the hollow chamber 121 to the air outlet chamber 114. The plurality of second radiating pipes 14 are disposed in spaced communication.

The total air flux of the second heat dissipating pipes 14 communicated between the air inlet chamber 111 and the hollow chamber 121 is smaller than the total air flux of the first heat dissipating pipes 13 communicated between the air outlet chamber 114 and the hollow chamber 121.

The first radiating pipe 13 and the second radiating pipe 14 are used for air cooling, radiating and dehumidifying of moisture.

According to the utility model, the plurality of first radiating pipes 13 are arranged between the air inlet chamber 111 and the hollow chamber 121, the plurality of second radiating pipes 14 are arranged between the hollow chamber 121 and the air outlet chamber 114, and moisture is introduced into the plurality of first radiating pipes 13 through the air inlet chamber 111 to cool, dissipate and dehumidify, split the moisture, increase the contact area with air, and perform primary condensation dehumidification by utilizing air cooling; then, the moisture is continuously led into the plurality of second radiating pipes 14 through the hollow cavity 121, so that the contact area with the air is large, and the secondary condensation dehumidification is facilitated for radiating; and because the total flux of a plurality of second cooling tubes 14 is less than the total flux of a plurality of first cooling tubes 13, when moisture passes through a plurality of second cooling tubes 14, the moisture receives bigger windage, increases the stay time of moisture in the second cooling tubes 14, is favorable to moisture to condense completely, produces more comdenstion water, and dehumidification effect is higher, can improve the dehumidification effect of condenser body 1, reduces condensation dehumidification energy consumption, simple structure, with low costs.

Preferably, the inner diameter d2 of the second radiating pipe 14 is smaller than the inner diameter d1 of the first radiating pipe 13.

The condenser body 1 of the present utility model may include a hollow chamber 121, and may further include a plurality of independent hollow chambers 121, wherein a heat dissipation pipe is connected between two adjacent hollow chambers 121, and the plurality of independent hollow chambers 121 are sequentially connected between the air inlet chamber 111 and the air outlet chamber 114 through the heat dissipation pipe. The inner diameters of the various radiating pipes are sequentially reduced from one side close to the air inlet chamber 111 to one side close to the air outlet chamber 114, so that the wind resistance is increased gradually, and the condensation dehumidifying effect is improved.

Further, the condenser body 1 includes a first communication portion 11 and a second communication portion 12. The first communication portion 11 is disposed opposite to the second communication portion 12. The first radiating pipe 13 and the second radiating pipe 14 are connected between the first communicating portion 11 and the second communicating portion 12.

The air inlet chamber 111 and the air outlet chamber 114 are respectively and independently provided in the first communication portion 11. The hollow chamber 121 is disposed inside the second communication portion 12, and is disposed opposite to the air inlet chamber 111 and the air outlet chamber 114.

According to the utility model, the two oppositely arranged first communication parts 11 and second communication parts 12 are arranged, the plurality of first radiating pipes 13 are arranged between the air inlet cavity 111 of the first communication part 11 and the hollow cavity 121 of the second communication part 12, and the plurality of second radiating pipes 14 are arranged between the air outlet cavity 114 of the first communication part 11 and the hollow cavity 121, so that the first radiating pipes 13 and the second radiating pipes 14 of the condenser body 1 are simply connected, and an air U-shaped backflow is formed between the first communication part 11 and the second communication part 12, thereby being beneficial to increasing the air resistance of the flow of moisture in the second radiating pipes 14, improving the radiating effect, further improving the dehumidifying effect, and also being smaller in volume, simple in structure and low in cost of the condenser body 1.

The first communicating portion 11 has a certain extension length, and the air inlet chamber 111 and the air outlet chamber 114 are sequentially disposed on the first communicating portion 11 in an extending manner along the length direction of the first communicating portion 11. The second communication portion 12 has a certain extension length, and the second communication portion 12 is disposed in both the air inlet chamber 111 and the air outlet chamber 114 on one side of the first communication portion 11.

The first radiating pipe 13 is disposed between the air inlet chamber 111 and the opposite side of the hollow chamber 121 in a straight extending manner, and the second radiating pipe 14 is disposed between the hollow chamber 121 and the opposite side of the air outlet chamber 114 in a straight extending manner.

The first radiating pipe 13 and the second radiating pipe 14 are straight-through pipes. The first radiating pipes 13 and the second radiating pipes 14 are respectively and uniformly arranged at intervals.

A plurality of plugging holes 15 are respectively arranged on two opposite sides of the first communication part 11 and the second communication part 12. The plurality of plug holes 15 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 communication portion 11 and correspondingly communicate with the air inlet chamber 111 and the air outlet chamber 114. The third and fourth plugging holes are disposed on the second communicating portion 12 and are all communicated with the hollow cavity 121.

The two ends of the first radiating pipe 13 are inserted into the first inserting hole and the third inserting hole. The two ends of the second radiating pipe 14 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 111, and the aperture of the third plugging hole is the same as the aperture of the first plugging hole. The fourth plugging hole is opposite to the air outlet chamber 114, and the aperture of the fourth plugging hole is the same as the aperture of the second plugging hole.

The first radiating pipe 13, the second radiating pipe 14 and the plug hole 15 are sealed by a sealing piece or sealant. The seal may be a silicone or rubber seal.

In order to reduce the cost of the first radiating pipe 13 and the second radiating pipe 14 and the ease of plugging, the flexible polymer material such as PE, PP, etc. can be used

In one embodiment, the number n2 of the second radiating pipes 14 is smaller than the number n1 of the first radiating pipes 13, and the inner diameter d2 of the second radiating pipes 14 is equal to the inner diameter d1 of the first radiating pipes 13. The wind resistance in the plurality of second radiating pipes 14 can be increased, and the dehumidifying effect can be improved. Compared with the number of the second radiating pipes 14, the inner diameter of the second radiating pipes 14 is reduced, and the contact area between the plurality of second radiating pipes 14 and the air is smaller.

In another embodiment, the number n2 of the second radiating pipes 14 is greater than or equal to the number n1 of the first radiating pipes 13, the inner diameter d2 of the second radiating pipes 14 is smaller than the inner diameter d1 of the first radiating pipes 13, the greater the number of the second radiating pipes 14 is than the number of the first radiating pipes 13 is, and the smaller the inner diameter d2 of the second radiating pipes 14 is relative to the inner diameter d1 of the first radiating pipes 13.

According to the utility model, the number of the second radiating pipes 14 is larger than that of the first radiating pipes 13, so that the contact area between the second radiating pipes 14 and air can be increased, the radiating effect during secondary condensation is improved, the inner diameter d2 of the second radiating pipes 14 is smaller than the inner diameter d1 of the first radiating pipes 13, when moisture enters the second radiating pipes 14, the inner diameter is reduced, the encountered wind resistance is increased, the residence time of the moisture in the second radiating pipes 14 can be improved, the radiating effect in the second radiating pipes 14 is better, the dehumidifying effect of secondary condensation can be further improved, and the dehumidifying speed is high, so that the dehumidifying effect of the whole condenser body 1 is improved.

Let the lengths of the first radiating pipe 13 and the second radiating pipe 14 be equal, and they are all l.

The total flux of the plurality of second radiating pipes 14 is smaller than that of the plurality of first radiating pipes 13 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

Therefore, the larger the number of the second radiating pipes 14 than the first radiating pipes 13 is, the smaller the inner diameter d2 of the second radiating pipe 14 is with respect to the inner diameter d1 of the first radiating pipe 13.

The volume V1 of the air inlet chamber 111 is smaller than the volume V2 of the air outlet chamber 114, and the extension length of the air inlet chamber 111 is smaller than the extension length of the air outlet chamber 114.

Preferably, the volume V2 of the air outlet chamber 114 is greater than the volume V1 of the air inlet chamber 111, and the volume V2 of the air outlet chamber 114 is less than 2 times the volume V1 of the air inlet chamber 111. The second radiating pipe 14 is arranged at a density greater than that of the first radiating pipe 13.

The number of the second radiating pipes 14 is at least twice the number of the first radiating pipes 13.

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 13 into many intervals setting, to the moisture reposition of redundant personnel, the area of contact of the perisporium of the first cooling tube 13 of increase and air improves forced air cooling dehumidification effect, and the setting quantity of second cooling tube 14 is at least first cooling tube 13 sets up twice of quantity, further shunts the moisture, through the perisporium and the air heat transfer of the second cooling tube 14 of a great deal of quantity, moisture cooling dehumidification in the second cooling tube 14 to the internal diameter of cooperation second cooling tube 14 reduces, increases the windage, increases the dwell time of moisture in the second cooling tube 14, makes complete dehumidification as far as possible, further improves dehumidification effect.

Further, the first communicating portion 11 is provided with a first condensation water outlet pipe 113 and a second condensation water outlet pipe 116, which are correspondingly communicated with the air inlet chamber 111 and the air outlet chamber 114, and are used for discharging condensed water outwards.

The inner diameter of the first condensation water outlet pipe 113 is smaller than the inner diameter of the second condensation water outlet pipe 116, and the inner diameters of the first condensation water outlet pipe 113 and the second condensation water outlet pipe 116 are less than or equal to 6mm.

According to the utility model, the inner diameters of the first condensation water outlet pipe 113 and the second condensation water outlet pipe 116 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 113 of air inlet cavity 111 and being less than the internal diameter of the second condensation outlet pipe 116 of air-out cavity 114, can avoid just getting into the excessive moisture of air inlet cavity 111, lead to moisture dehumidification efficiency to reduce, and get into the air in the air-out cavity 114 and be through dehumidification, 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 body 1 again.

Further, the first and second condensation water outlet pipes 113 and 116 are disposed on a side of the first communication part 11 opposite to the second communication part 12.

Preferably, the first condensation water outlet pipe 113 and the second condensation water outlet pipe 116 are correspondingly disposed at the most protruding parts of the air inlet chamber 111 and the air outlet chamber 114 in a direction opposite to the second communication part 12.

One side of the first communication portion 11 is disposed opposite to the second communication portion 12, and the other side of the first communication portion 11 is disposed opposite to the second communication portion 12. In actual use, the other side of the first communication part 11 is arranged downward, so that an external condensate water pipeline is conveniently arranged.

The other side of the first communicating portion 11 is protruded from opposite ends of the air inlet chamber 111 and the air outlet chamber 114 toward the adjacent ends. The first condensation water outlet pipe 113 and the second condensation water outlet pipe 116 are correspondingly arranged at the end parts of the air inlet chamber 111 and the air outlet chamber 114, which are close to each other.

The other side of the first communication portion 11 is provided with an inwardly recessed separation groove 117, which separates the interior of the first communication portion 11 into an independent air inlet chamber 111 and an independent air outlet chamber 114. The partition groove 117 penetrates both side walls adjacent to the other side of the first communication portion 11.

The other sides of the air inlet chamber 111 and the air outlet chamber 114 are protruded obliquely outwards from the two ends of the length extending direction of the first communicating portion 11 to the middle part to form an inclined structure, and then extend to the separation groove 117 along the length extending direction to form a plane structure. The first condensation water outlet pipe 113 and the second condensation water outlet pipe 116 are respectively arranged on the plane structures of the other sides of the air inlet chamber 111 and the air outlet chamber 114.

In actual use, the other side of the first communication portion 11 is disposed downward, and the inclined structure is used for guiding the condensed water collected in the air inlet chamber 111 and the air outlet chamber 114 to flow to the first condensation water outlet pipe 113 and the second condensation water outlet pipe 116 at the lowest positions.

Preferably, the second communicating portion 12 is a rectangular parallelepiped, the first communicating portion 11 is a boat shape, the partition groove 117 is concavely provided on the bottom side of the boat,

further, the air inlet chamber 111 is provided with an air inlet 112, and the air inlet 112 is disposed on a side wall of the first communicating portion 11 adjacent to the side having the first radiating pipe 13. The air outlet chamber 114 is provided with an air outlet 115, and the air outlet 115 is disposed on a side wall of the first communicating portion 11 adjacent to the side having the second radiating pipe 14.

The air inlet 112 and the air outlet 115 are disposed on the same side wall of the first communicating portion 11.

As shown in fig. 10 to 11, the present utility model also provides a washing and caring apparatus 3 having the condenser body 1 as described above.

The washing and caring apparatus 3 further includes a cabinet 31, a processing unit 32, a first passage 22, a second passage 23, and a rotary dehumidifier 2. The processing unit 32 is provided in the housing 31 for washing and/or drying the articles. The rotary dehumidifier 2 is arranged in a casing 31 outside the processing unit 3.

In one embodiment, as shown in fig. 10, the wheel dehumidifier 2 includes a housing 21 and a wheel, wherein the housing 21 has a receiving chamber (not shown) and the wheel is rotatably supported in the receiving chamber. The accommodating cavity comprises an adsorption area 211 and a desorption area 212, a position of the rotating wheel moves back and forth between the adsorption area 211 and the desorption area 212, and the rotating wheel rotates to the desorption area 212 to be separated after the adsorption area 211 adsorbs moisture in the accommodating cavity.

Both ends of the first passage 22 are respectively communicated with the processing unit 32. One end of the first channel 22 is an air inlet (not shown) for introducing moisture in the processing unit 32 into the first channel 22. The other end of the first passage 22 is an air outlet (not shown) for directing dry air into the processing unit 32.

The second passage 23 has an air inlet at one end and an air outlet at the other end for introducing dry air into the processing unit 32.

The adsorption area 211 is communicated with the first channel 22 and is used for adsorbing moisture inside the first channel 22;

the desorption region 212 communicates with the second passage 23 for desorbing moisture from the adsorption region 211 by air in the second passage 23. The condenser body 1 is arranged on the second channel 23 on the air outlet side of the desorption zone 212.

According to the utility model, the wet air led out from the processing unit 32 is dehumidified through the adsorption area 211 in the accommodating cavity, so that the air with large air quantity and low concentration water vapor can be concentrated into the air with small air quantity and high concentration water vapor, dehumidification is realized, the interior of the washing and protecting equipment 3 is prevented from being wet and breeding peculiar smell and bacterial mould, the dehumidification effect is improved, the drying efficiency of the washing and protecting equipment 3 is improved, the dehumidified dry air is led back to the dry object in the processing unit 32, the desorption area 212 receives the moisture in the adsorption area 211 and then is desorbed into the second channel 23, and after the condenser body 1 is utilized for dehumidification, the desorption efficiency of the desorption area 212 can be improved, so that the adsorption efficiency of the adsorption area 211 is improved, the dehumidification efficiency is further improved, and the cost is reduced; on the other hand, the condenser body 1 has the advantages of simple structure, good dehumidification effect and low cost, and can discharge the dehumidified dry air, avoid discharging the wet air, improve the user experience, or guide the dehumidified dry air with a certain temperature back to the processing unit 32, further improve the drying effect of the inside or inside articles of the processing unit 32, and has the characteristics of good drying effect, low cost and low noise.

The first channel 22 is provided with a first fan 221 for guiding the moisture in the processing chamber into the first channel 22 and guiding the air dried by the moisture transfer member back into the processing chamber.

The second channel 23 is provided with a second fan 232 for driving the air in the second channel 23 to flow.

The second passage 23 is provided with a heater 231 for increasing the temperature of the desorption region 212 to thereby increase the desorption effect.

Preferably, the heater 231 is disposed near an air outlet side of the heater 231.

In another embodiment, as shown in fig. 11, the wheel dehumidifier 2 includes a housing 21, a wheel, and a dehumidifying chamber 34.

The dehumidifying chamber 34 is disposed outside the processing unit 32, and the housing 21 and the rotating wheel are disposed in the dehumidifying chamber 34.

The housing 21 has a receiving cavity (not shown) in which the wheel is rotatably supported.

The accommodating cavity comprises an adsorption area 211 and a desorption area 212, a position of the rotating wheel moves back and forth between the adsorption area 211 and the desorption area 212, and the rotating wheel rotates to the desorption area 212 to be separated after the adsorption area 211 adsorbs moisture in the accommodating cavity.

Both ends of the first passage 22 are respectively communicated with the processing unit 32. One end of the first channel 22 is an air inlet for introducing the moisture in the processing unit 32 into the first channel 22; the other end of the first passage 22 is an air outlet for directing dry air into the processing unit 32.

The adsorption zone 211 is communicated with the first channel 22, the air inlet 112 of the adsorption zone 211 is communicated with the first channel 22 through the inlet of the dehumidifying chamber 34, and the air outlet side of the adsorption zone 211 is communicated with the first channel 22.

One end of the second channel 23 is an air inlet, which is connected to the air outlet side of the desorption zone 212, and is used for introducing the moisture in the desorption zone 212. The condenser body 1 is disposed on the second channel 23, dehumidifies the moisture in the second channel 23, and the other end of the second channel 23 is an air outlet for discharging or guiding the dry air into the processing unit 32.

The condenser body 1 may be disposed in the dehumidifying chamber 34 or may be disposed outside the dehumidifying chamber 34.

The first channel 22 is provided with a first fan 221 for guiding the moisture in the processing chamber into the first channel 22 and guiding the air dried by the moisture transfer member back into the processing chamber.

The second channel 23 is provided with a second fan 232 for driving the air in the second channel 23 to flow.

The second passage 23 is provided with a heater 231 for increasing the temperature of the desorption region 212 to thereby increase the desorption effect.

Preferably, the heater 231 is disposed near an air outlet side of the heater 231.

Further, the washing and caring apparatus 3 further includes a water collecting box 33 for receiving condensed water generated from the condenser body 1.

More preferably, the housing 31 is provided with an inlet and an outlet, and the water collecting box 33 is arranged in a drawable manner through the inlet and the outlet, and is used for being pushed into the housing 31 or being pulled out of the housing 31.

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 (12)

1. A condenser assembly for a washing apparatus, comprising: comprising the steps of (a) a step of,

The condenser body is used for discharging dry air after air intake condensation and dehumidification;

the spray shell is internally provided with a containing cavity, and the containing cavity comprises a spray cavity, a heat exchange cavity and a drainage cavity which are sequentially communicated from a water inlet end to a water outlet end in an extending mode;

the spraying chamber is used for guiding the water to spray to the heat exchange chamber;

the condenser body is arranged in the heat exchange cavity, and the heat exchange cavity is used for reducing the temperature of the condenser body through spray water;

the drainage chamber is used for collecting spray water and draining the spray water;

the inner diameter of the heat exchange chamber is reduced along the extending direction, and the heat exchange chamber is arranged close to the condenser body and used for guiding spray water onto the condenser body.

2. A condenser assembly for a washing apparatus according to claim 1, wherein: the two ends of the condenser body are respectively arranged close to the spraying chamber and the drainage chamber;

when the heat exchange chamber extends from one end of the communicating spraying chamber to the water outlet end, the inner diameter of the heat exchange chamber is reduced and gradually approaches to the condenser body, and then the heat exchange chamber extends to the water outlet end to be communicated with the drainage chamber.

3. A condenser assembly for a washing apparatus according to claim 2, wherein: one side of the condenser body is closely arranged with the inner wall of one side of the heat exchange chamber, and the other side of the condenser body is at least partially provided with a gap with the inner wall of the other side of the heat exchange chamber;

The distance between the two side walls of the condenser body gradually decreases from one end close to the spraying chamber to the other end close to the draining chamber.

4. A condenser assembly for a washing and caring apparatus according to any one of claims 1-3, wherein: the other side wall of the heat exchange chamber comprises a plurality of heat exchange chambers which are sequentially connected,

one end of the first connecting plate is connected with the spraying cavity, and a gap is reserved between the inner wall of the first connecting plate and the condenser body;

the second connecting plate is obliquely arranged from the other end of the first connecting plate to the direction of the condenser body;

and the inner wall of the third connecting plate is close to the condenser body.

5. A condenser assembly for a washing apparatus as claimed in claim 4, wherein: the condenser body comprises a plurality of condenser bodies,

the first communication part is independently provided with an air inlet cavity and an air outlet cavity, the air inlet cavity is used for feeding moisture, and the air outlet cavity is used for discharging condensed air;

the second communication part is internally provided with a hollow cavity, and the first communication part and the second communication part are oppositely arranged;

The first radiating pipe is arranged between the air inlet cavity and the opposite side of the hollow cavity in a straight extending mode;

the second radiating pipe is arranged between the opposite sides of the hollow cavity and the air outlet cavity in a straight extending mode;

the first communicating part and the second communicating part are arranged in the heat exchange cavity and are respectively close to the two ends of the spraying cavity and the draining cavity, and the inner diameter of the heat exchange cavity is gradually reduced to be close to the first radiating pipe and the second radiating pipe.

6. A condenser assembly for a washing apparatus according to claim 5, wherein: one side of the first communication part and one side of the second communication part are close to one side wall of the heat exchange chamber;

the first connecting plate is provided with a gap with the other side of the first communication part, and at least part of the first radiating pipe and the second radiating pipe connected with the first communication part are provided with the gaps;

the second connecting plate is gradually close to the first radiating pipe and the second radiating pipe;

the third connecting plate is closely arranged with the other side of the second communication part and the parts of the first radiating pipe and the second radiating pipe connected with the second communication part.

7. A condenser assembly for a washing apparatus according to claim 5, wherein: an air inlet and an air outlet are formed in the third connecting plate and are respectively used for spraying air in the shell and air out;

the second communication part is provided with an air inlet and an air outlet which are respectively communicated with the air inlet cavity and the air outlet cavity;

the air inlet and the air outlet are correspondingly communicated with the air inlet and the air outlet respectively.

8. A condenser assembly for a washing apparatus according to claim 7, wherein: the first communication part is provided with a first condensation water outlet pipe and a second condensation water outlet pipe which are correspondingly communicated with the air inlet cavity and the air outlet cavity, and the water outlet ends of the first condensation water outlet pipe and the second condensation water outlet pipe are communicated with the water discharge cavity and are used for discharging condensed water outwards;

the air inlet and the air outlet are arranged on the same side with the water outlet of the drainage cavity.

9. A condenser assembly for a washing apparatus according to claim 1, wherein: the inner diameter of the spraying cavity gradually increases from the direction close to the water inlet end to the direction of the water outlet end.

10. A condenser assembly for a washing apparatus according to claim 9, wherein: the spray cavity is in a horn-shaped structure from a water inlet end to a water outlet end.

11. A condenser assembly for a washing apparatus according to claim 10, wherein: the junction of spray cavity with the heat exchange cavity is equipped with the division board, be equipped with a plurality of holes that spray on the division board, spray hole intercommunication spray cavity and heat exchange cavity for separate into the water curtain with intaking, spray to in the heat exchange cavity.

12. A washing and caring device, characterized in that: a condenser assembly as claimed in any one of claims 1 to 11.