阅读说明：本技术 冷凝容器及衣物处理设备 (Condensation container and clothes treatment equipment ) 是由 颜灵智 谢红伟 王翠莲 于 2021-09-13 设计创作，主要内容包括：本发明属于冷凝技术领域,具体涉及一种冷凝容器及衣物处理设备。本发明旨在解决冷凝温度不易控制的问题。该冷凝容器内的介质腔内设有第一阀门、第二阀门和热敏形变片,第一阀门用于控制与冷凝容器的介质进口连通的注液口的通断,第二阀门用于控制冷凝容器的介质出口的通断,热敏形变片与介质腔的内壁紧固连接,并且热敏形变片还与第一阀门及第二阀门均传动连接,热敏形变片被构造为在介质腔内的温度不低于第一预设温度时使第一阀门和第二阀门开启,且在介质腔内的温度低于第二预设温度时使第一阀门和第二阀门关闭。该衣物处理设备,包括上述的冷凝容器。通过上述设置,介质腔内的温度在第一预设温度与第二预设温度之间波动,利于冷凝温度的控制。(The invention belongs to the technical field of condensation, and particularly relates to a condensation container and clothes treatment equipment. The invention aims to solve the problem that the condensation temperature is not easy to control. The medium intracavity in this condensate container is equipped with first valve, second valve and thermal deformation piece, first valve is used for the break-make of the notes liquid mouth with the medium import intercommunication of condensate container, the second valve is used for the break-make of the medium export of control condensate container, the inner wall fastening connection in thermal deformation piece and medium chamber, and the thermal deformation piece still is connected with the equal transmission of first valve and second valve, the thermal deformation piece is constructed to make first valve and second valve open when the temperature in the medium intracavity is not less than first preset temperature, and make first valve and second valve close when the temperature in the medium intracavity is less than the second preset temperature. The clothes treatment equipment comprises the condensing container. Through the arrangement, the temperature in the medium cavity fluctuates between the first preset temperature and the second preset temperature, and the control of the condensation temperature is facilitated.)

1. A condensation container is characterized in that a medium cavity for storing a condensation medium is formed in the condensation container, and the upper part and the lower part of the condensation container are respectively provided with a medium inlet and a medium outlet which are communicated with the medium cavity;

the medium cavity is internally provided with a first valve, a second valve and a thermal deformation sheet, the first valve is used for controlling the on-off of a liquid injection port communicated with the medium inlet, the second valve is used for controlling the on-off of the medium outlet, the thermal deformation sheet is fixedly connected with the inner wall of the medium cavity, and the thermal deformation sheet is also in transmission connection with the first valve and the second valve;

the heat-sensitive deformation sheet is configured to open the first valve and the second valve when the temperature at the position thereof is not lower than a first preset temperature, and to close the first valve and the second valve when the temperature at the position thereof is lower than a second preset temperature;

wherein the first preset temperature is not lower than the second preset temperature.

2. A condensation container according to claim 1, wherein the thermo-deformable sheet is further configured to open the first valve and close the second valve when the temperature at the position thereof is lower than a third preset temperature and not lower than the second preset temperature;

wherein the first preset temperature is not lower than the third preset temperature.

3. A condensation vessel according to claim 1 or 2, wherein the heat sensitive deformation sheet is an arc-shaped sheet, the heat sensitive deformation sheet being configured such that the curvature increases when the temperature thereof is higher than the first preset temperature and the curvature decreases when the temperature thereof is lower than the second preset temperature.

4. A condensation vessel according to claim 3, wherein the thermo-deformable sheet comprises a first deformable layer and a second deformable layer formed on an inner surface of the first deformable layer, the first deformable layer having a thermal expansion coefficient greater than that of the second deformable layer;

or the thermosensitive deformation sheet is made of a memory alloy material.

5. A condensation vessel according to claim 3, wherein the first valve comprises a sliding rod, a guide sleeve, a conical plug and a first connecting rod;

the guide sleeve is fixedly connected to the inner wall of the medium cavity;

the sliding rod is connected with the guide sleeve in a sliding mode, can slide up and down along the guide sleeve and is positioned above the thermosensitive deformation sheet;

the conical plug is fixedly connected with the upper end of the sliding rod and is positioned right below the liquid injection port;

the upper end of the first connecting rod is hinged with the lower end of the sliding rod, and the lower end of the first connecting rod is hinged with the upper side of the thermosensitive deformation sheet;

the thermosensitive deformation sheet with the curvature change is used for driving the conical plug to move between the plugging of the liquid injection port and the position far away from the liquid injection port through the first connecting rod and the sliding rod.

6. A condensation vessel according to claim 5, wherein the lower end of the sliding rod is provided with a deflector for guiding the condensing medium flowing in from above to the outside of the heat sensitive deformation plate within the downward projection range of the deflector.

7. A condensation vessel according to claim 3, wherein the second valve comprises a sealing plate for closing off the medium outlet and a second connecting rod;

the sealing plate comprises a first side and a second side which are opposite, the first side is hinged with the corresponding side of the medium outlet, the second side is hinged with the lower end of the second connecting rod, and the upper end of the second connecting rod is hinged with the lower side of the thermosensitive deformation sheet;

the thermosensitive deformation piece with the curvature change is used for driving the second side to rotate between the side edge which is attached to the medium outlet and corresponds to the medium outlet and the side edge which is far away from the medium outlet and corresponds to the medium outlet through the second connecting rod.

8. A condensation vessel according to claim 7, wherein the bottom surface of the sealing plate is coated with an elastic sealing layer, the sealing plate being adapted to close off the medium outlet by means of the elastic sealing layer.

9. A laundry treating apparatus, comprising the condensation vessel of any one of claims 1 to 8;

a water replenishing pipe and a drying system are arranged in the clothes treatment equipment, a clothes taking and placing opening communicated with a clothes drying cavity is formed in the side wall of the clothes treatment equipment, a sealing door is arranged at the clothes taking and placing opening, the condensing container is arranged on the sealing door and is arranged on one side of the sealing door, which faces the clothes drying cavity, and the drying system is used for drying clothes in the clothes drying cavity;

the medium outlet is communicated with a drain pipe of the clothes treatment equipment, the medium inlet is communicated with a water outlet end of the water replenishing pipe, and the water outlet end of the water replenishing pipe is used as the liquid injection port.

10. The laundry treating apparatus according to claim 9, wherein the sealing door includes a door rim, an outer housing, and an inner housing;

the door ring is installed at the clothes taking and placing opening in an openable and closable manner;

the outer cover is arranged on the surface of the door ring facing the outer side of the clothes treatment equipment, and the outer cover is an anti-scald cover;

the inner shell is basin-shaped and extends into the clothes taking and placing opening, the inner shell is made of stainless steel materials, and the basin opening of the inner shell is fixedly connected with the surface of the door ring facing the clothes drying cavity;

the door ring, the outer cover and the inner shell define the medium cavity, and the medium inlet and the medium outlet are arranged on the peripheral wall of the inner shell;

the liquid injection port is arranged on the inner wall of the clothes taking and placing port, and is arranged right above the medium inlet at intervals, and the opening degree of the medium inlet is larger than that of the liquid injection port.

Technical Field

The invention belongs to the technical field of condensation, and particularly relates to a condensation container and clothes treatment equipment.

Background

Condensation refers to the condensation of a gas or liquid upon cooling. In production and life, the moisture in the gas is often removed by condensation. The condensation container is a device which is used for containing water or other heat-absorbing condensation media to condense the damp and hot air flowing through the surface of the condensation container, and further to separate out the moisture in the gas.

Among the prior art, be equipped with the medium import and the medium export with medium chamber intercommunication in it on the condensing vessel, annotate condensing medium to the medium intracavity through the notes liquid mouth that communicates with the medium import, medium import and medium exit set up the feed liquor valve of control condensing medium inflow and the play liquid valve of control condensing medium exhaust respectively, after the condensing medium endotherm in the medium intracavity, the temperature can rise, treat after the temperature of condensing medium rises to the take the altitude, can't condense to the damp and hot air on condensing vessel surface again, at this moment, need open out the liquid valve, discharge the condensing medium of medium intracavity high temperature, and open the feed liquor valve, add microthermal condensing medium to the medium intracavity again, so that can continue to condense.

The existing condensing container is not easy to control the time of switching the liquid inlet valve and the liquid outlet valve, and when the condensing medium in the medium cavity is replaced, the temperature fluctuation of the condensing container and the condensing medium in the condensing container is large, and the condensing temperature is not easy to control.

Disclosure of Invention

In order to solve the problems in the prior art, namely, to solve the problems that when the condensing medium in the medium cavity is replaced, the temperature fluctuation of the condensing container and the condensing medium in the condensing container is large, and the condensing temperature is not easy to control, the invention provides a condensing container.

The medium cavity is internally provided with a first valve, a second valve and a thermal deformation sheet, the first valve is used for controlling the on-off of a liquid injection port communicated with the medium inlet, the second valve is used for controlling the on-off of a medium outlet, the thermal deformation sheet is tightly connected with the inner wall of the medium cavity, and the thermal deformation sheet is also in transmission connection with the first valve and the second valve.

The heat sensitive deformation sheet is configured to open the first valve and the second valve when a temperature at a position thereof is not lower than a first preset temperature, and to close the first valve and the second valve when the temperature at the position thereof is lower than a second preset temperature.

Wherein the first preset temperature is not lower than the second preset temperature.

In a preferred embodiment of the above-described condensation vessel, the heat-sensitive deformation sheet is further configured to open the first valve and close the second valve when the temperature at the position thereof is lower than a third preset temperature and not lower than a second preset temperature.

Wherein the first preset temperature is not lower than the third preset temperature.

In a preferred embodiment of the above-described condensation container, the heat-sensitive deformation piece is an arc-shaped piece, and the heat-sensitive deformation piece is configured such that the curvature increases when the temperature thereof is higher than a first preset temperature and the curvature decreases when the temperature thereof is lower than a second preset temperature.

In the above-described preferred embodiment of the condensation container, the heat-sensitive deformation sheet includes a first deformation layer and a second deformation layer formed on an inner surface of the first deformation layer, and a thermal expansion coefficient of the first deformation layer is larger than a thermal expansion coefficient of the second deformation layer.

Alternatively, the thermo-deformable sheet is made of a memory alloy material.

In the preferred technical scheme of the condensation container, the first valve comprises a sliding rod, a guide sleeve, a conical plug and a first connecting rod.

The guide sleeve is tightly connected to the inner wall of the medium cavity.

The slide bar is connected with the guide sleeve in a sliding mode, the slide bar can slide up and down along the guide sleeve, and the slide bar is located above the thermosensitive deformation sheet.

The conical plug is fixedly connected with the upper end of the sliding rod and is positioned right below the liquid injection port.

The upper end of the first connecting rod is hinged with the lower end of the sliding rod, and the lower end of the first connecting rod is hinged with the upper side of the thermosensitive deformation sheet.

The thermosensitive deformation sheet with the curvature change is used for driving the conical plug to move between the plugging liquid injection port and the far liquid injection port through the first connecting rod and the sliding rod.

In the preferred technical scheme of the condensation container, the lower end of the sliding rod is provided with the air guide sleeve, the heat-sensitive deformation sheet is in the downward projection range of the air guide sleeve, and the air guide sleeve is used for guiding the condensation medium flowing into the air guide sleeve from the upper part of the air guide sleeve to the outer side of the heat-sensitive deformation sheet.

In a preferred embodiment of the above-mentioned condensation vessel, the second valve comprises a sealing plate and a second connecting rod, the sealing plate being used to close off the medium outlet.

The sealing plate comprises a first side and a second side which are opposite, the first side is hinged with the corresponding side of the medium outlet, the second side is hinged with the lower end of the second connecting rod, and the upper end of the second connecting rod is hinged with the lower side of the thermosensitive deformation sheet.

The thermosensitive deformation sheet with the curvature change is used for driving the second side to rotate between the side edge corresponding to the attached medium outlet and the side edge far away from the medium outlet through the second connecting rod.

In the preferred technical scheme of above-mentioned condensation container, the bottom surface of closing plate coats the elasticity sealing layer, and the closing plate is used for through the export of elasticity sealing layer shutoff medium.

The present invention also provides a laundry treating apparatus including the condensing container described above.

Dispose moisturizing pipe and drying system in the clothing treatment facility, be equipped with the clothing of intercommunication clothing stoving chamber on the lateral wall of clothing treatment facility and get and put the mouth, the clothing is got and is put a mouthful department and dispose sealing door, on condensing vessel located sealing door, and condensing vessel locates one side of sealing door towards clothing stoving chamber, and drying system is used for drying the clothing of clothing stoving intracavity.

The medium outlet is communicated with a drain pipe of the clothes treatment equipment, the medium inlet is communicated with a water outlet end of the water replenishing pipe, and the water outlet end of the water replenishing pipe is used as a liquid injection port.

In a preferred embodiment of the above laundry treating apparatus, the sealing door includes a door ring, an outer case, and an inner case.

The door ring can be opened and closed and is arranged at the clothes taking and placing opening.

The surface of door circle towards the clothing treatment facility outside is located to the dustcoat, and the dustcoat is for preventing scalding the cover.

The inner shell is basin-shaped and extends into the clothes taking and placing opening, the inner shell is made of stainless steel materials, and the basin opening of the inner shell is fixedly connected with the surface of the door ring facing the clothes drying cavity.

The door ring, the outer cover and the inner shell define a medium cavity, and the medium inlet and the medium outlet are arranged on the peripheral wall of the inner shell.

The liquid filling port is arranged on the inner wall of the clothes taking and placing port and is arranged right above the medium inlet at intervals, and the opening degree of the medium inlet is larger than that of the liquid filling port.

As can be understood by those skilled in the art, the laundry treating apparatus of the present invention includes a first valve, a second valve and a thermal deformation sheet disposed in a medium chamber of the laundry treating apparatus, the first valve is used for controlling on/off of a liquid injection port communicated with a medium inlet, the second valve is used for controlling on/off of a medium outlet, the thermal deformation sheet is fastened to an inner wall of the medium chamber, and the thermal deformation sheet is also in transmission connection with both the first valve and the second valve, the thermal deformation sheet is configured to open the first valve and the second valve when a temperature at a position of the thermal deformation sheet is not lower than a first preset temperature, and close the first valve and the second valve when the temperature at the position of the thermal deformation sheet is lower than a second preset temperature, wherein the first preset temperature is not lower than the second preset temperature.

Through the arrangement, in the condensation process, the condensation medium in the medium cavity absorbs heat to enable the temperature in the medium cavity to rise, the thermosensitive deformation sheet deforms along with the temperature change at the position of the thermosensitive deformation sheet, when the temperature at the position of the thermosensitive deformation sheet rises to be not lower than a first preset temperature, the deformation of the thermosensitive deformation sheet enables the first valve and the second valve to be opened, the condensation medium in the medium cavity is discharged through the medium outlet, the condensation medium flowing out of the liquid injection port enters the medium cavity through the medium inlet to replace the condensation medium in the medium cavity, the temperature in the medium cavity gradually decreases along with new condensation medium flowing in from the liquid injection port, when the temperature at the position of the thermosensitive deformation sheet is reduced to be lower than a second preset temperature, the deformation of the thermosensitive deformation sheet enables the first valve and the second valve to be closed, and the replacement of the condensation medium is completed, and repeating the step of replacing the condensing medium until the temperature of the position of the thermosensitive deformation sheet is not lower than the preset temperature. So, at the in-process of condensation, the temperature of medium intracavity fluctuates between first preset temperature and second preset temperature, can control the condensation temperature between first preset temperature and second preset temperature, the condensation effect is more balanced, also can not cause the condensation to break off, and in some equipment that need carry out the recovery to the heat of the outside gas of condensation container or liquid, accessible control condensation temperature, avoid the condensation temperature to hang down a large amount of losses of the heat of the outside gas of condensation container or liquid that cause.

Drawings

Preferred embodiments of a laundry treating apparatus of the present invention are described below with reference to the accompanying drawings. The attached drawings are as follows:

FIG. 1 is a schematic diagram of an embodiment of a condensation container according to the present invention when the temperature at the heat sensitive deformation sheet is lower than a second predetermined temperature;

FIG. 2 is a schematic diagram of an embodiment of a condensation container according to the present invention when the temperature at the heat sensitive deformation sheet is not lower than a first preset temperature;

FIG. 3 is a schematic diagram of an embodiment of a condensation container according to the present invention when the temperature at the heat-sensitive deformation sheet is lower than a third predetermined temperature and not lower than a second predetermined temperature;

FIG. 4 is a schematic view of a heat sensitive deformable sheet of an embodiment of a condensation vessel as proposed by the present invention;

FIG. 5 is a schematic view of a seal plate of an embodiment of the proposed condensation vessel;

FIG. 6 is a schematic view of an embodiment of a clothes treating apparatus according to the present invention when a temperature at the thermo-sensitive deformation sheet is lower than a third preset temperature and not lower than a second preset temperature;

FIG. 7 is a schematic view of an embodiment of a clothes treating apparatus according to the present invention when a temperature at the thermo-sensitive deformation sheet is lower than a second preset temperature;

FIG. 8 is a schematic view of an embodiment of a clothes treating apparatus according to the present invention when a temperature at the thermo-sensitive deformation sheet is not lower than a first preset temperature;

fig. 9 is a schematic view of a water separator of an embodiment of a laundry treating apparatus according to the present invention.

In the drawings: 100. a condensing vessel; 110. a media chamber; 120. a media outlet; 130. a media inlet; 140. a liquid injection port; 150. a heat-sensitive deformable sheet; 151. a first deformable layer; 152. a second deformation layer; 200. a first valve; 210. a first link; 220. a sliding rod 230, a guide sleeve; 240. conical plugging; 250. a pod; 300. a second valve; 310. a second link; 320. a sealing plate; 321. an elastomeric sealing layer; 410. a water replenishing pipe; 420. a clothes taking and placing opening; 430. a sealing door; 431. a door ring; 432. an inner shell; 440. a drain pipe; 441. draining pump; 450. a clothes drying chamber; 451. an inner cavity; 452. an outer cavity; 461. an inner barrel; 462. an outer cylinder; 470. a drying system; 471. an air duct; 472. a fan heating module; 473. a condenser; 474. a water inlet pipe; 480. a seal ring; 500. a water separator; 510. a water storage cavity; 520. a water inlet; 530. and a water diversion port.

Detailed Description

First, it should be understood by those skilled in the art that these embodiments are merely for explaining the technical principles of the present invention, and are not intended to limit the scope of the present invention. And can be adjusted as needed by those skilled in the art to suit particular applications.

Next, it should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "inside", "outside", and the like are based on the direction or positional relationship shown in the drawings, which are merely for convenience of description, and do not indicate or imply that a device or a member must have a specific orientation, be configured in a specific orientation, and operate, and thus, should not be construed as limiting the present invention.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "connected" and "connected" should be interpreted broadly, e.g., as being fixedly connected, detachably connected, or integrally connected; the two components can be directly connected or indirectly connected through an intermediate medium, and the two components can be communicated with each other. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The existing condensing container usually adopts a whole replacing mode when the high-temperature condensing medium in the medium cavity is replaced, namely the high-temperature condensing medium in the medium cavity is completely discharged, and then the low-temperature condensing medium is injected into the medium cavity again. Therefore, the temperature fluctuation in the medium cavity is large, the condensing temperature is not easy to control, and the condensing effect is influenced. In addition, when the mode of replacing all the condensing mediums is adopted, after all the condensing mediums in the medium cavity are discharged, if the injected condensing mediums are not supplemented in time, the interruption of condensation can be caused. In addition, for some equipment which needs to recover the heat of the gas or the liquid outside the condensation container, after the condensation medium is completely replaced, the temperature of the condensation container is low, and a large amount of heat loss of the gas or the liquid outside the condensation container can be caused.

In order to solve the problems, the inventor arranges a first valve, a second valve and a thermal deformation sheet in a medium cavity of a condensation container, wherein the first valve is used for controlling the on-off of a liquid injection port communicated with a medium inlet, the second valve is used for controlling the on-off of a medium outlet, the thermal deformation sheet is fixedly connected with the inner wall of the medium cavity and is also in transmission connection with the first valve and the second valve, the thermal deformation sheet is constructed to open the first valve and the second valve when the temperature of the position of the thermal deformation sheet is not lower than a first preset temperature, and close the first valve and the second valve when the temperature of the position of the thermal deformation sheet is lower than a second preset temperature, wherein the first preset temperature is not lower than the second preset temperature.

In the process of condensation, the condensation medium in the medium cavity absorbs heat, so that the temperature in the medium cavity rises, the thermosensitive deformation sheet deforms along with the temperature change at the position of the thermosensitive deformation sheet, when the temperature at the position of the thermosensitive deformation sheet rises to be not lower than a first preset temperature, the first valve and the second valve are both opened by the deformation of the thermosensitive deformation sheet, the condensation medium in the medium cavity is discharged through the medium outlet, the condensation medium flowing out from the liquid injection port enters the medium cavity through the medium inlet to replace the condensation medium in the medium cavity, the temperature in the medium cavity gradually decreases along with new condensation medium continuously flowing in from the liquid injection port, when the temperature at the position of the thermosensitive deformation sheet is reduced to be lower than a second preset temperature, the first valve and the second valve are both closed by the deformation of the thermosensitive deformation sheet, the replacement of the condensation medium is completed until the temperature at the position of the thermosensitive deformation sheet rises to be not lower than the preset temperature again, the above-described replacement step of the condensing medium is repeated. So, at the in-process of condensation, the temperature of medium intracavity fluctuates between first preset temperature and second preset temperature, can control the condensation temperature between first preset temperature and second preset temperature, the condensation effect is more balanced, also can not cause the condensation to break off, and in some equipment that need carry out the recovery to the heat of the outside gas of condensation container or liquid, accessible control condensation temperature, avoid the condensation temperature to hang down a large amount of losses of the heat of the outside gas of condensation container or liquid that cause.

The preferred embodiments of the condensing container and the laundry treating apparatus according to the present invention will be described with reference to the accompanying drawings.

Fig. 1 is a schematic view of an embodiment of the proposed condensation container when the temperature at the heat-sensitive deformation piece is lower than a second preset temperature, and fig. 2 is a schematic view of an embodiment of the proposed condensation container when the temperature at the heat-sensitive deformation piece is not lower than the first preset temperature.

As shown in fig. 1 and 2, in the embodiment of the condensation container of the present invention, a medium chamber 110 for storing a condensation medium is formed in the condensation container 100, and a medium inlet 130 and a medium outlet 120 communicating with the medium chamber 110 are respectively formed at an upper portion and a lower portion of the condensation container 100.

The medium cavity 110 is internally provided with a first valve 200, a second valve 300 and a thermal deformation sheet 150, the first valve 200 is used for controlling the on-off of the liquid injection port 140 communicated with the medium inlet 130, the second valve 300 is used for controlling the on-off of the medium outlet 120, the thermal deformation sheet 150 is fixedly connected with the inner wall of the medium cavity 110, and the thermal deformation sheet 150 is also in transmission connection with the first valve 200 and the second valve 300.

The thermo-deformable sheet 150 is configured to open the first and second valves 200 and 300 when the temperature at the position thereof is not lower than a first preset temperature, and to close the first and second valves 200 and 300 when the temperature at the position thereof is lower than a second preset temperature.

Wherein the first preset temperature is not lower than the second preset temperature.

It is understood that the first preset temperature and the second preset temperature are higher than the temperature of the condensing medium injected through the injection port 140, and the first preset temperature and the second preset temperature may be set according to a desired condensing temperature, and the thermal deformation sheet 150 controls the first valve 200 and the second valve 300 through deformation occurring when the temperature changes.

In the above embodiment, during condensation, the condensed medium in the medium chamber 110 absorbs heat, so that the temperature in the medium chamber 110 rises, the thermal deformation sheet 150 deforms along with the temperature change at the position of the thermal deformation sheet 150, when the temperature at the position of the thermal deformation sheet 150 rises to be not lower than the first preset temperature, the deformation of the thermal deformation sheet 150 opens both the first valve 200 and the second valve 300, the condensed medium in the medium chamber 110 is discharged through the medium outlet 120, the condensed medium flowing out of the liquid injection port 140 enters the medium chamber 110 through the medium inlet 130, the condensed medium in the medium chamber 110 is replaced, the temperature in the medium chamber 110 gradually decreases along with the new condensed medium continuously flowing in from the liquid injection port 140, when the temperature at the position of the thermal deformation sheet 150 falls to be lower than the second preset temperature, the deformation of the thermal deformation sheet 150 closes both the first valve 200 and the second valve 300, this replacement of the condensing medium is completed until the temperature at the position where the heat sensitive deformation piece 150 is located is again increased to not lower than the preset temperature, and the above replacement step of the condensing medium is repeated. So, at the in-process of condensation, the temperature in the medium chamber 110 fluctuates between first preset temperature and the second preset temperature, can control the condensation temperature between first preset temperature and the second preset temperature, the condensation effect is more balanced, also can not cause the condensation to break, and in some equipment that need carry out the recovery to the heat of the gas of condenser vessel 100 outside or liquid, accessible control condensation temperature, avoid the condensation temperature to hang down a large amount of losses of the heat of the gas of condenser vessel 100 outside or liquid that cause excessively.

It is understood that the liquid injection port 140 may be coincident with the medium inlet 130 to form an opening, and the first valve 200 blocks the coincident opening of the medium inlet 130 and the liquid injection port 140; the liquid filling port 140 may be disposed at an interval right above the medium inlet 130, and the first valve 200 may seal the liquid filling port 140 through the medium inlet 130

Fig. 3 is a schematic diagram of an embodiment of the proposed condensation container when the temperature at the heat-sensitive deformation sheet is lower than a third preset temperature and not lower than a second preset temperature. As shown in fig. 3 in combination with fig. 1 and 2, in some possible embodiments, the heat sensitive deformation sheet 150 is further configured to open the first valve 200 and close the second valve 300 when the temperature at the position is lower than the third preset temperature and not lower than the second preset temperature.

Wherein the first preset temperature is not lower than the third preset temperature.

With this arrangement, the third preset temperature can be set to be higher than the temperature of the thermal deformation sheet 150 when the injection port 140 starts injecting the condensing medium into the medium chamber 110 in which the condensing medium is not stored. When the injection of the condensing medium is started, the temperature of the position of the thermal deformation sheet 150 in the medium chamber 110 where the condensing medium is not stored is lower than the third preset temperature and higher than the second preset temperature, the first valve 200 is opened, and the second valve 300 is closed, so that the condensing medium can be conveniently injected into the medium chamber 110, and the injected condensing medium can be stored in the medium chamber 110. After the condensed medium is injected into the medium cavity 110, the liquid level in the medium cavity 110 gradually rises, after the liquid level rises to the position where the thermal deformation sheet 150 is arranged, the thermal deformation sheet 150 is in an environment where the temperature of the condensed medium is lower than a second preset temperature, the temperature of the thermal deformation sheet 150 is lower than the second preset temperature, the thermal deformation sheet 150 controls the opened first valve 200 to be closed, and the injection of the condensed medium into the medium cavity 110 is stopped.

For example, the thermally deformable sheet 150 is disposed at the middle or middle upper portion of the medium chamber 110.

Fig. 4 is a schematic view of a heat-sensitive deformation sheet of an embodiment of the proposed condensation container, as shown in fig. 4, in some possible embodiments, the heat-sensitive deformation sheet 150 is an arc-shaped sheet, and the heat-sensitive deformation sheet 150 is configured such that the curvature increases when the temperature thereof is higher than a first preset temperature and the curvature decreases when the temperature thereof is lower than a second preset temperature.

So configured, the first valve 200 and the second valve 300 can be driven to switch between the closed state and the open state according to the change of the curvature of the thermal deformation sheet 150.

As shown in fig. 4, in some possible embodiments, the heat sensitive deformation sheet 150 includes a first deformation layer 151 and a second deformation layer 152 formed on an inner surface of the first deformation layer 151, and a thermal expansion coefficient of the first deformation layer 151 is greater than that of the second deformation layer 152.

In this arrangement, when the temperature rises, the heat-sensitive deformable sheet 150 is bent inward to increase the curvature of the heat-sensitive deformable sheet 150, and when the temperature falls, the heat-sensitive deformable sheet 150 is straightened outward to decrease the curvature of the heat-sensitive deformable sheet 150. The heat-sensitive deformation sheet 150 has a curvature that increases with increasing temperature and decreases with decreasing temperature.

For example, before the filling port 140 starts to fill the condensed medium into the medium chamber 110 without the condensed medium, the curvature of the thermal deformation sheet 150 causes the first valve 200 to open, the second valve 300 to close, after the condensed medium starts to be filled to raise the liquid level in the medium chamber 110 to the position of the thermal deformation sheet 150, the thermal deformation sheet 150 is cooled, the curvature decreases to cause the first valve 200 to close and the closed second valve 300 to close more tightly, the temperature at the thermal deformation sheet 150 gradually increases along with the heat absorption of the condensed medium in the medium chamber 110, the curvature of the thermal deformation sheet 150 gradually increases until the temperature at the thermal deformation sheet 150 increases to not lower than the first preset temperature, the curvature of the thermal deformation sheet 150 increases to a degree that drives the first valve 200 and the second valve 300 to open, the first valve 200 and the second valve 300 open, and the replacement of the condensed medium in the medium chamber 110 starts, after the condensed medium in the medium chamber 110 starts to be replaced, the temperature in the medium chamber 110 gradually decreases, the curvature of the thermal deformation sheet 150 gradually decreases, and when the temperature at the thermal deformation sheet 150 is lower than the second preset temperature, the curvature of the thermal deformation sheet 150 decreases to a degree that the first valve 200 and the second valve 300 are driven to close, so that the first valve 200 and the second valve 300 are closed.

In some examples, the first and second deforming layers 151 and 152 may be made of metal materials having different coefficients of thermal expansion, facilitating the first and second deforming layers 151 and 152 to be integrally formed

In some possible embodiments, the thermo-deformable sheet 150 is made of a memory alloy material. In this manner, the control of the first and second valves 200 and 300 is more precise.

As shown in fig. 1-3, in some possible embodiments, the first valve 200 includes a sliding rod 220, a guiding sleeve 230, a conical plug 240, and a first connecting rod 210, the guiding sleeve 230 is tightly connected to the inner wall of the medium chamber 110, the sliding rod 220 is slidably connected to the guiding sleeve 230, the sliding rod 220 can slide up and down along the guiding sleeve 230, the sliding rod 220 is located above the heat-sensitive deformation sheet 150, the conical plug 240 is tightly connected to the upper end of the sliding rod 220, the conical plug 240 is located right below the liquid injection port 140, the upper end of the first connecting rod 210 is hinged to the lower end of the sliding rod 220, the lower end of the first connecting rod 210 is hinged to the upper side of the heat-sensitive deformation sheet 150, and the heat-sensitive deformation sheet 150 with a changed curvature is used for driving the conical plug 240 to move between the liquid injection port 140 and away from the liquid injection port 140 through the first connecting rod 210 and the sliding rod 220.

It is understood that the thermally deformable sheet 150 is a curved surface extending upward and downward and curved.

With such an arrangement, when the curvature of the thermal deformation sheet 150 increases, the upper side of the thermal deformation sheet 150 moves downward, the conical plug 240 is driven by the first connecting rod 210 and the sliding rod 220 to move downward, and the liquid inlet 140 can be opened. When the curvature of the thermal deformation sheet 150 is reduced, the upper side of the thermal deformation sheet 150 moves upwards, the first connecting rod 210 and the sliding rod 220 drive the conical plug 240 to move upwards, and the conical plug 240 can block the liquid injection port 140 after passing through the medium inlet 130. The guide sleeve 230 can ensure that the sliding rod 220 and the conical plug 240 move up and down, and ensure that the conical plug 240 can accurately plug the liquid injection port 140.

In some examples, the plug 240 is a resilient plug. So, the shutoff effect is better. For example, the surface of the rigid structure may be coated with an elastic rubber layer to form an elastic plug.

In some examples, the guide sleeve 230 is securely attached to the inner wall of the media chamber 110 by a connection bracket. In this way, the sliding rod 220, the conical plug 240, the medium inlet 130, the liquid injection port 140 and the like can be arranged at positions closer to the middle of the medium chamber 110, and the arrangement is more flexible.

For example, the heat sensitive deformation sheet 150 may be a semi-cylindrical shape with a horizontal axis, and the convex middle portion of the heat sensitive deformation sheet 150 is tightly connected with the inner wall of the media chamber 110.

In some possible embodiments, the lower end of the sliding rod 220 is provided with a guide cover 250, the heat-sensitive deformation sheet 150 is within a downward projection range of the guide cover 250, and the guide cover 250 is used for guiding the condensing medium flowing above the heat-sensitive deformation sheet 150 to the outside.

For example, the pod 250 may be umbrella-shaped.

With such an arrangement, when the condensing medium is filled through the medium inlet 130, the condensing medium directly erodes the thermal deformation sheet 150 caused by the thermal deformation sheet 150 to deform, and the thermal deformation sheet 150 can be ensured to deform along with the change of the temperature of the condensing medium rising to the position.

In some possible embodiments, the second valve 300 includes a sealing plate 320 and a second connecting rod 310, the sealing plate 320 is used for sealing the medium outlet 120, the sealing plate 320 includes a first side and a second side opposite to each other, the first side is hinged to a corresponding side of the medium outlet 120, the second side is hinged to a lower end of the second connecting rod 310, an upper end of the second connecting rod 310 is hinged to a lower side of the heat-sensitive deformation sheet 150, and the heat-sensitive deformation sheet 150 with the changed curvature is used for driving the second side to rotate between a side close to the medium outlet 120 and the corresponding side and a side far away from the medium outlet 120 and the corresponding side through the second connecting rod 310.

With this arrangement, when the curvature of the heat-sensitive deformation piece 150 is increased, the lower side of the heat-sensitive deformation piece 150 moves upward, and the second side of the sealing plate 320 is pulled up by the second link 310, thereby opening the medium outlet 120. When the curvature of the thermal deformation sheet 150 is reduced, the lower side of the thermal deformation sheet 150 moves downward, the second connecting rod 310 pushes the second side of the sealing plate 320 to be attached to the corresponding side edge of the medium outlet 120, so that the medium outlet 120 can be blocked, and the control is convenient.

Fig. 5 is a schematic view of a sealing plate of an embodiment of the proposed condensation vessel. As shown in fig. 5, in some possible embodiments, the bottom surface of the sealing plate 320 is covered with an elastic sealing layer 321, and the sealing plate 320 is used for blocking the medium outlet 120 by the elastic sealing layer 321.

So set up, the shutoff of closing plate 320 is effectual, and closes the back at closing plate 320, can also further compress tightly, does benefit to and opens, the second valve 300 off state to the first valve 200 and the second valve 300 conversion of off state at first valve 200.

For example, the elastic sealing layer 321 may be a rubber layer.

Fig. 6 is a schematic view of the embodiment of the proposed laundry treating apparatus when the temperature at the heat-sensitive deformation sheet is lower than the third preset temperature and is not lower than the second preset temperature, fig. 7 is a schematic view of the embodiment of the proposed laundry treating apparatus when the temperature at the heat-sensitive deformation sheet is lower than the second preset temperature, and fig. 8 is a schematic view of the embodiment of the proposed laundry treating apparatus when the temperature at the heat-sensitive deformation sheet is not lower than the first preset temperature.

As shown in fig. 6-8 in combination with fig. 1-5, the clothes treatment apparatus of the present invention includes the above-mentioned condensation container 100, wherein the condensation container 100 is the condensation container 100 in any of the above-mentioned embodiments.

A water replenishing pipe 410 and a drying system 470 are arranged in the clothes treatment device, a clothes taking and placing opening 420 communicated with the clothes drying cavity 450 is arranged on the side wall of the clothes treatment device, a sealing door 430 is arranged at the clothes taking and placing opening 420, a condensing container 100 is arranged on the sealing door 430, the condensing container 100 is arranged on one side of the sealing door 430 facing the clothes drying cavity 450, and the drying system 470 is used for drying clothes in the clothes drying cavity 450.

The medium outlet 120 is communicated with a drain pipe 440 of the clothes treatment device, the medium inlet 130 is communicated with a water outlet end of the water replenishing pipe 410, and the water outlet end of the water replenishing pipe 410 is used as a liquid injection port 140.

It is understood that the laundry treating apparatus may be a dryer, or may be various laundry treating apparatuses having a drying function, such as a washing and drying machine.

In the above embodiment, in the condensation process, the temperature in the medium cavity 110 fluctuates between the first preset temperature and the second preset temperature, the condensation temperature can be controlled between the first preset temperature and the second preset temperature, the condensation effect is more balanced, the condensation is not interrupted, the heat loss of the gas in the clothes drying cavity 450 caused by condensation can be reduced by controlling the condensation temperature, and the burden of the drying system 470 is reduced.

In addition, in the clothes processing equipment with drying function such as the existing dryer, washing and drying integrated machine, hot air is sent into the clothes drying cavity 450 by the drying system 470, the hot air dries the clothes in the clothes drying cavity 450, and the humidity of the air in the clothes drying cavity 450 is high, which causes the problems of low drying efficiency, long drying time, high energy consumption and the like. In addition, the sealing door 430 of the conventional clothes treating apparatus directly contacts with the hot air in the clothes drying chamber 450, and the sealing door 430 has a high temperature in the drying process, so that a user is easily scalded, and the environmental temperature is also easily increased greatly. If the drying system 470 employs a condensing type drying system, the condensing type drying system directly contacts with the humid air by continuously supplying condensing water to condense the humid air, separate out moisture in the humid air, and then heat the condensed air and send the air back into the clothes drying chamber 450 to exchange heat with the clothes, thereby evaporating moisture on the clothes. In the process of drying, for guaranteeing the condensation effect to the inspiratory air, condensing drying system need last, a large amount of condensation water that supplies, condensation water and humid air contact the back, and direct inflow clothes treatment facility's drain pipe 440 discharges, and the drying process water consumption is big, and water waste is serious, and because with condensation water direct contact during air condensation, condensing drying system sends into the humidity of the air in clothing stoving chamber 450 still very big. In addition, the air sucked by the condensing drying system is heated after being condensed by a large amount of condensation water, the heat loss of the sucked air is large, a heater of the condensing drying system needs to continuously operate above 1.8kW for a long time, and the energy consumption is high.

In the above embodiment, the condensation container 100 is disposed on the sealing door 430, the water supply pipe 410 is disposed in the clothes treatment apparatus, when drying is performed, the sealing door 430 is closed, cold water is supplied into the medium chamber 110 from the water supply pipe 410 through the medium inlet 130, and the condensation container 100 storing the cold water can condense air flowing through the surface of the condensation container 100 in the clothes drying chamber 450 to separate out moisture in the air. When the water in the medium cavity 110 absorbs heat to raise the temperature in the medium cavity 110 to a first preset temperature, the water in the medium cavity 110 is automatically replaced until the temperature in the medium cavity 110 is lowered to a second preset temperature, the replacement of the water in the medium cavity 110 is completed, and the temperature of the condensation container 100 is always kept between the first preset temperature and the second preset temperature.

Therefore, the condensing container 100 arranged on the sealing door 430 can condense the air in the clothes drying cavity 450, reduce the humidity of the air entering the clothes drying cavity 450, improve the drying efficiency, shorten the drying time and reduce the energy consumption. When the drying system 470 adopts a condensing type drying system, the condensing water supplied in the condensing type drying system condenses the sucked air and then directly discharges the condensed air, and the cold water supplied in the medium cavity 110 remains in the medium cavity 110 to absorb heat, and is replaced after the temperature is raised to a certain temperature, so that the utilization rate of the water supplied in the medium cavity 110 is higher, the amount of the condensing water supplied in the condensing type drying system can be reduced, and more water is saved. In addition, after the cold water in the condensation container 100 absorbs the heat at the sealing door 430, the sealing door 430 can be prevented from being overheated, which can cause scalding of users or cause a significant increase in the ambient temperature.

It is understood that both the air supply end and the air intake end of drying system 470 are in communication with laundry drying chamber 450. The drying system 470 includes an air duct 471 and a fan heating module 472 disposed in the air duct 471, the fan heating module 472 includes a fan and a heater, and an air supply end and an air inlet end of the air duct 471 are both communicated with the clothes drying chamber 450. The drying system 470 may be a condensing type drying system or a hot air type drying system, when the drying system 470 is a condensing type drying system, the drying system 470 further includes a condenser 473, an air inlet end of the condenser 473 is used as an air inlet end of the drying system 470 to communicate with the clothes drying chamber 450, an air outlet end of the condenser 473 communicates with an air inlet end of the air duct 471, an water outlet end of the condenser 473 communicates with a drain pipe 440 of the clothes processing device, and in addition, in order to realize water supply and drainage, a drain pump 441 may be disposed on the drain pipe 440.

In the embodiment of drying system 470 employing a condensing type drying system, since the amount of condensing water supplied into the condensing type drying system is reduced, the amount of heat in the air taken away by the flowing condensing water is reduced, and the amount of heat recovered by the air entering the condensing type drying system is large, the load of the heater in the condensing type drying system can be reduced and/or the temperature of the air fed into clothes drying chamber 450 can be increased, which can achieve the effect of saving energy and/or improving drying efficiency. In addition, the air is condensed in two sections through the condensing type drying system and the condensing container 100 on the sealing door 430, so that the condensing path of the air is prolonged, and the condensing effect of the air is better.

In some possible embodiments, the sealing door 430 includes a door ring 431, an outer cover, and an inner shell 432. The door ring 431 is openably and closably installed at the laundry taking and putting opening 420. The outer cover is arranged on the surface of the door ring 431 facing the outer side of the clothes treatment equipment, the inner shell 432 is basin-shaped and extends into the clothes taking and placing opening 420, the basin opening of the inner shell 432 is fixedly connected with the surface of the door ring 431 facing the clothes drying cavity 450, the door ring 431, the outer cover and the inner shell 432 define a medium cavity 110, and the medium inlet 130 and the medium outlet 120 are arranged on the peripheral wall of the inner shell 432.

By such an arrangement, the condensation container 100 is directly formed on the sealing door 430 without any other structure, and the manufacturing is convenient and the cost is low.

In some examples, the inner housing 432 is a small-mouthed, upright tub-like structure with the tub bottom facing the laundry drying chamber 450, and the peripheral wall of the inner housing 432 slopes medially from the tub mouth to the tub bottom.

So set up, do benefit to the drop of water that inner shell 432 surface condensation formed and slide through the gravity of drop of water self, sliding speed is fast.

In some examples, the enclosure is an anti-burn enclosure. In this manner, the temperature of the outside of the sealing door 430 can be minimized.

In some examples, the inner housing 432 is made of a stainless steel material. Thus, the condensation effect on the surface of the inner case 432 can be enhanced.

In some examples, one side of the door ring 431 may be hinged with a position corresponding to the laundry access opening 420. In this manner, the opening and closing of the sealing door 430 is facilitated.

In some possible embodiments, the liquid filling opening 140 is disposed on the inner wall of the clothes placing opening 420 and spaced right above the medium inlet 130, and the opening degree of the medium inlet 130 is larger than that of the liquid filling opening 140.

It will be appreciated that the pour opening 140 is directed towards the media inlet 130 directly below it.

So set up, make things convenient for sealing door 430's setting and switch, annotate liquid mouth 140 to medium import 130 water injection convenience, efficient, the anti-spillage spatters.

In some examples, such as a drum-type dryer or a washing and drying machine, an outer drum 462 and an inner drum 461 are provided in the laundry processing apparatus, the inner drum 461 is rotatably installed in the outer drum 462, a plurality of water passing holes are provided on the inner drum 461, the laundry drying chamber 450 includes an inner chamber 451 located in the inner drum 461 and an outer chamber 452 located between the outer drum 462 and the inner drum 461, the laundry taking and placing port 420 is communicated with both the inner chamber 451 and the outer chamber 452, laundry to be dried is accommodated in the inner drum 461, the bottom of the outer chamber 452 has a water discharge port communicated with the water discharge pipe 440, and the medium outlet 120 is communicated with the outer chamber 452.

So set up, at the in-process of drying, inner tube 461 can drive the clothing rotation of treating the stoving, and is more abundant with the hot-air contact, and drying efficiency is higher.

In some possible embodiments, the lower edge of the condensation vessel 100 is outside the inner cavity 451.

For example, in embodiments where the media chamber 110 is defined by the inner housing 432, the outer cover, and the door ring 431, the lower edge of the inner housing 432 is outside of the inner chamber 451.

With such an arrangement, the condensed water condensed on the surface of the condensation container 100 flows into the drain pipe 440 through the outer cavity 452 between the inner cylinder 461 and the outer cylinder 462, thereby facilitating the drainage of the condensed water condensed on the surface of the condensation container 100, and simultaneously preventing the condensed water from entering the inner cavity 451 to reduce the drying efficiency.

In some examples, the water outlet end of the condenser 473 of the condensing type drying system is disposed in the outer cavity 452 between the inner cylinder 461 and the outer cylinder 462, and is communicated with the drain 440 through the outer cavity 452. So set up, the drainage is convenient, and can not influence the drying efficiency of clothing.

In some examples, a sealing ring 480 is disposed at the clothes inlet 420 to connect an outer wall of the clothes treating apparatus with a wall of the clothes drying chamber 450, the sealing ring 480 serves as an inner wall of the clothes inlet 420, the water outlet end of the water replenishing pipe 410 passes through the sealing ring 480 from top to bottom, and the liquid filling port 140 is formed on the sealing ring 480. In the embodiment having the inner drum 461 and the outer drum 462, the sealing ring 480 is provided between the outer drum 462 and the outer wall of the laundry treating apparatus, and the sealing ring 480 connects the outer drum 462 and the outer wall of the laundry treating apparatus. So configured, water at the laundry inlet 420 can flow into the outer cavity 452 along with the surface of the sealing ring 480.

Fig. 9 is a schematic view of a water separator of an embodiment of the proposed laundry treating apparatus. As shown in fig. 9, in some possible embodiments, the laundry treating apparatus further includes a water separator 500, the drying system 470 is a condensation type drying system, a water storage cavity 510 is formed in the water separator 500, a water inlet 520 is formed in an upper portion of the water storage cavity 510, the water inlet 520 is used for communicating with a water supply device, a water separation port 530 is formed in a side wall of the water storage cavity 510, the water separation port 530 is communicated with a water inlet end of the water replenishing pipe 410, a water inlet end of a water inlet pipe 474 of the condensation type drying system extends into the water storage cavity 510, a water inlet end of the water inlet pipe 474 of the condensation type drying system is communicated with the water storage cavity 510, a water inlet end of the water inlet pipe 474 of the condensation type drying system is above the water separation port 530, and an area of the water inlet 520 is smaller than an area of the water inlet end of the water inlet pipe 474 of the condensation type drying system.

With such arrangement, the water supplied through the water inlet 520 is firstly decompressed in the water storage chamber 510, and then is respectively supplied to the water replenishing pipe 410 and the water inlet pipe 474 of the condensing type drying system, so as to avoid the situation that the water outlet end of the water replenishing pipe 410 is splashed or cannot be blocked due to overlarge pressure of the supplied water when the water replenishing pipe 410 is directly connected with the tap water pipe. When the water level in the water storage cavity 510 reaches the water inlet end of the water inlet pipe 474 of the condensing type drying system, the water in the water storage cavity 510 flows into the water inlet end of the water inlet pipe 474 of the condensing type drying system, the water level in the water storage cavity 510 can be limited by the water inlet end of the water inlet pipe 474 of the condensing type drying system, and then the pressure of the water entering the water replenishing pipe 410 can be limited. For example, in the embodiment where the first valve 200 includes the sliding rod 220, the guiding sleeve 230, the conical plug 240 and the first connecting rod 210, the situation that the conical plug 240 cannot block the liquid inlet 140 due to the fact that the water pressure applied to the conical plug 240 is greater than the force generated by the deformation of the thermal deformation sheet 150 can be avoided, and the requirement on the strength of the material of the thermal deformation sheet 150 is lower. In addition, the area of the water inlet 520 is smaller than the area of the water inlet end of the water inlet pipe 474 of the condensation type drying system, so that the excessive water can flow into the water inlet pipe 474 of the condensation type drying system.

In some possible embodiments, the water inlet end of the water inlet pipe 474 of the condensation drying system is upward, and the downward projection of the water inlet 520 comprises a first region within the range of the water inlet end of the water inlet pipe 474 of the condensation drying system and a second region outside the range of the water inlet end of the water inlet pipe 474 of the condensation drying system, and the area of the first region is larger than that of the second region.

So set up, the water that flows in through water inlet 520 mostly gets into condensing drying system's inlet tube 474, the subtotal is stored in water storage chamber 510, and flow into moisturizing pipe 410 through water storage chamber 510, can be great very much at the pressure that supplies water from water inlet 520, when singly leaning on water storage chamber 510 pressure release capacity not enough, the end of intaking through condensing drying system's inlet tube 474 carries out the pressure release, the pressure release is effectual, can guarantee that the water pressure that flows into moisturizing pipe 410 is not more than the pressure that the water level of the end of intaking of condensing drying system's inlet tube 474 produced.

In some possible embodiments, the air supply end of drying system 470 is disposed at a side of clothes drying cavity 450 where clothes taking and placing opening 420 is disposed, the air supply end of drying system 470 is disposed above condensing container 100, the air supply direction of the air supply end of drying system 470 is inclined downward and faces into the clothes processing apparatus, and condensing container 100 is on the air supply path of the air supply end of drying system 470.

So set up, the hot-blast contact with the clothing after the condensation of condensation vessel 100 of the surface that is sent out by drying system 470's air supply end earlier, can improve condensation efficiency, and the air in the clothing stoving chamber 450 is drier, and the stoving effect is better.

In some possible embodiments, the air inlet end of drying system 470 is disposed at a side of clothes drying chamber 450 opposite to clothes taking and placing opening 420, and the air inlet end of drying system 470 is disposed at an upper portion of clothes drying chamber 450. Therefore, the utilization efficiency of hot air is improved.

For example, the air inlet end and the water outlet end of the condenser 473 of the condensing type drying system are communicated with the outer cavity 452 between the outer cylinder 462 and the inner cylinder 461 through an opening.

So far, the technical solutions of the present invention have been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Equivalent changes or substitutions of related technical features can be made by those skilled in the art without departing from the principle of the invention, and the technical scheme after the changes or substitutions can fall into the protection scope of the invention.