CN110485132B - Independent drying module and clothes airing assembly - Google Patents

Abstract

The invention discloses an independent drying module and a clothes drying assembly, which comprises a long cylindrical shell and heating parts distributed along the length direction of an inner cavity, wherein air outlet holes are distributed on the upper wall of the long cylindrical shell, the heating parts comprise a heating body and a heat conducting part, the heat conducting part comprises a hollow part for accommodating the heating body and a plurality of radiating fins with air holes, the radiating fins are integrally formed with the hollow part and are in a radial shape, an upper air flow cavity is formed between the radiating fins and the upper wall of the long cylindrical shell, and a lower air flow cavity is formed between the radiating fins and the lower wall of the long cylindrical shell; the air flow in the upper air flow cavity and the lower air flow cavity is heated under the action of the heating component and flows upwards and out of the air outlet holes, so that the upper air flow cavity and the lower air flow cavity form negative pressure relative to the outside of the shell to suck the air flow outside the shell, and the air flow inside and outside the shell is formed.

Description

Independent drying module and clothes airing assembly

Technical Field

The invention relates to the field of clothes drying, in particular to an independent drying module in the field of clothes airing machines.

Background

In some areas with less illumination or in the rainy season, the clothes are difficult to dry, and the clothes airing machine with the drying function can be used. The clothes airing machine with the drying function can enable clothes to be dried in a short time.

The clothes airing machine with the drying function and the authorization bulletin number CN203212891U is characterized in that a drying module of the structure is arranged on a main machine part, and a hot air outlet on the main machine part blows hot air downwards, so that the drying effect on clothes below is poor.

The patent of application number 2018216610148 of the same applicant describes a "airing machine drying module and airing machine", wherein the heating module of the drying module is installed above the fan module, the fan module is distributed in a large section area in the middle of the shell, the fan module is used for air intake from the side wall or the bottom of the shell, and then the air is blown out from the upper side of the shell after passing through the heating module, so as to dry the clothes.

The patent with the application number 2019203344381 of the same applicant describes a clothes airing machine and a lower-arranged drying module, wherein the drying module is positioned at the side of an area where clothes are hung on the clothes airing rack, an infrared heating component in the drying module adopts a heat radiation mode, and the infrared heating component emits heat and radiates the clothes from the side of the clothes so as to perform radiation type drying treatment on the clothes.

The application publication number is CN 108330660A's stand alone type stoving module and stoving underlying clothes-horse, and this stoving module is located the below of clothes hanger, from bottom to top dries the clothing. Specifically, the structure of this stoving module includes the casing, and the air outlet has been seted up to the upper surface on the casing, and the tip of casing is equipped with fan and heating module, and the fan is located heating module's outside, and the fan is blown out from the air outlet of casing upper surface after long tubular casing both ends suction air through heating module.

The drying module is used as the power of airflow flowing through the fan, and meanwhile, the fan can accelerate the energy loss caused by the excessively fast airflow. When the fan of the drying module works, noise can be generated, and in addition, the fan is positioned beside the heating module, and the performance of the motor can be influenced by higher temperature.

Disclosure of Invention

The invention aims to solve the technical problem of providing an independent drying module and further provides a clothes airing machine with the independent drying module.

The technical scheme adopted for solving the technical problems is as follows: the independent drying module is characterized by comprising a long cylindrical shell and heating parts distributed along the length direction of an inner cavity, wherein air outlets are distributed in the upper wall of the long cylindrical shell, the heating parts comprise a heating body and a heat conducting part, the heat conducting part comprises a hollow part for accommodating the heating body and radiating fins with air holes integrally formed with the hollow part, an upper air flow cavity is formed between the radiating fins and the upper wall of the long cylindrical shell, and a lower air flow cavity is formed between the radiating fins and the lower wall of the long cylindrical shell.

The invention further adopts the technical scheme that: the radiating fins comprise first radiating fins and second radiating fins which are symmetrical to the hollow part and incline upwards, and the upper airflow cavity is formed among the first radiating fins, the second radiating fins and the upper wall; the cooling fin also comprises a third cooling fin and a fourth cooling fin which are symmetrical to the hollow part and obliquely downward, and the lower airflow cavity is formed between the third cooling fin and the fourth cooling fin.

The invention further adopts the technical scheme that: the two sides of the heating component in the inner cavity of the long cylindrical shell are provided with a first heat insulation cavity and a second heat insulation cavity.

The invention further adopts the technical scheme that: the heat conduction component is characterized in that a first heat insulation plate and a second heat insulation plate are arranged on two sides of the heat conduction component, the first heat insulation plate and the first side wall of the long cylindrical shell form a first heat insulation cavity, and the second heat insulation plate and the second side wall of the long cylindrical shell form a second heat insulation cavity.

The invention further adopts the technical scheme that: the first heat insulation plate is fixed at the free ends of the first radiating fins and the third radiating fins, and the second heat insulation plate is fixed at the free ends of the second radiating fins and the fourth radiating fins.

The invention further adopts the technical scheme that: the heat insulation cavity is communicated with the upper airflow cavity and the lower airflow cavity, and the heat radiation fan introduces external airflow to blow the hot airflow of the heat insulation cavity into the upper airflow cavity and the lower airflow cavity.

The invention further adopts the technical scheme that: at least one end of the shell is provided with a heat radiation fan, the inner side of the heat radiation fan is provided with an air guide part, and the air guide part guides air flow generated by the heat radiation fan into the first heat insulation cavity and the second heat insulation cavity, so that hot air flow in the heat insulation cavity is blown into the upper air flow cavity and the lower air flow cavity.

The invention further adopts the technical scheme that: the lower wall of the shell is provided with air inlets.

The invention further adopts the technical scheme that: the heating body is an electric heating wire or PTC heating module, and the heat conduction component is made of aluminum alloy.

Another subject is: the clothes airing component is characterized by comprising a clothes airing component and an independent drying module, wherein the clothes airing component is connected with the independent drying module through a telescopic component.

Compared with the prior art, the invention has the advantages that the upward flow characteristic is realized by simply utilizing the hot air flow, the air flows in the upper air flow cavity and the lower air flow cavity are heated under the action of the heating component, and the heated air flows upward and flows out from the air outlet hole on the long cylindrical shell; after the airflows of the lower airflow cavity and the upper airflow cavity are heated and risen, a negative pressure environment is formed relative to the outer space of the long cylindrical shell, so that the external airflows can be sucked into the lower airflow cavity and the upper airflow cavity from the air inlet under the action of negative pressure; the air flow is heated and has the upward flowing characteristic so as to drive the air flow to circulate inside and outside the long cylindrical shell, thereby reducing the parts of the drying module and ensuring that the whole structure is more concise; meanwhile, the defect that noise is generated when the fan works is overcome; in addition, the temperature generated by the heating component arranged beside the fan is prevented from affecting the performance of the motor on the fan.

Drawings

The invention will be described in further detail below in connection with the drawings and the preferred embodiments, but it will be appreciated by those skilled in the art that these drawings are drawn for the purpose of illustrating the preferred embodiments only and thus should not be taken as limiting the scope of the invention. Moreover, unless specifically indicated otherwise, the drawings are merely schematic representations, not necessarily to scale, of the compositions or constructions of the described objects and may include exaggerated representations.

Fig. 1 is a structural exploded view of a drying module;

FIG. 2 is a schematic diagram showing the direction of air flow in the drying module;

FIG. 3 is a second schematic diagram of the airflow direction in the drying module;

FIG. 4 is a structural exploded view of the heat generating components and the housing in the drying module;

FIG. 5 is a side view of the connection between the clothes drying component and the drying module;

FIG. 6 is a schematic diagram I of a connection structure between a clothes drying component and a drying module;

fig. 7 is a schematic diagram II of a connection structure between the clothes airing component and the drying module.

Detailed Description

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. Those skilled in the art will appreciate that these descriptions are merely illustrative, exemplary, and should not be construed as limiting the scope of the invention.

It should be noted that: like reference numerals denote like items in the following figures, and thus once an item is defined in one figure, it may not be further defined and explained in the following figures.

In the description of the present invention, it should be noted that, the azimuth or positional relationship indicated by the terms "inner", "outer", etc. are based on the azimuth or positional relationship shown in the drawings, or the azimuth or positional relationship in which the inventive product is conventionally put in use, are merely for convenience of describing the present invention and simplifying the description, and are not indicative or implying that the apparatus or element to be referred to must have a specific azimuth, be configured and operated in a specific azimuth, and therefore, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

The clothes airing machine comprises a clothes airing component 10 and a drying module 20, wherein the drying module 20 is connected with the clothes airing component 10 through a telescopic component 30. Wherein for the drying module 20:

the drying module 20 includes a long cylindrical casing 23, in which a heat generating part 21 and a fan assembly are installed in the long cylindrical casing 23, and an air outlet hole 22 and an air inlet hole 28 are opened at an upper wall 232 and a lower wall 233 of the long cylindrical casing 23, respectively. Normally, in actual operation, the blower assembly is started, air is sucked through the air inlet hole 28 of the long cylindrical housing 23, heated by the heat generating part 21, and discharged through the air outlet hole 22 to dry the laundry located above the drying module 20. The heat generated by the heat generating component 21 can make the side wall of the long cylindrical housing 23 have a high temperature, and the user may be scalded by the side wall of the long cylindrical housing 23. Accordingly, a specific description of the solution for improving the heat dissipation performance in the drying module 20 is preferred.

As shown in fig. 1 to 3, the heat dissipation system of the drying module includes a housing having an air outlet hole 22 at an upper wall 232, a heat generating part 21 and a heat dissipation fan 24 inside the housing; preferably, there may be two heat dissipation fans 24 distributed at both ends of the housing. An upper airflow cavity 101 is formed between the heating component 21 and the upper wall 232 of the shell, two heat insulation cavities 102 are formed between the heating component 21 and the two side walls of the shell, the heat insulation cavities 102 are communicated with the upper airflow cavity 101, and the heat dissipation fan 24 blows air in the heat insulation cavities 102 into the upper airflow cavity 101. Preferably, the housing on the drying module 20 is a long cylindrical housing 23. Of course, in practical operation, those skilled in the art may also use a housing having a cross-section in the shape of a sector, an ellipse, a rectangle, etc.

Through the heat dissipation system, the air flow sucked by the heat dissipation fan 24 is simultaneously and intensively led into the heat insulation cavity 102, and the air flow rushed into the heat insulation cavity 102 can disperse the air flow originally remained in the heat insulation cavity 102, so that the air flow in the heat insulation cavity 102 can be dispersed and dredged and extruded into the air flow cavity 101 of the drying module 20, and the air flow flowing into the air flow cavity 101 is heated by the heating component 21; thereby not only evacuating and circulating the air flow in the narrow space of the heat insulation cavity 102, but also preventing the heat flow stasis in the heat insulation cavity 102 from scalding the shell of the drying module 20 and avoiding the user from being scalded unintentionally; and the heating speed of the drying module 20 can be increased, and the efficiency of drying clothes of the airing machine can be improved.

Of course, the following embodiments may be adopted for the internal structure of the drying module 20: the independent drying module 20 comprises a long cylindrical shell 23 and heating parts 21 distributed along the length direction of an inner cavity, wherein air outlets 22 are distributed on the upper wall 232 of the long cylindrical shell 23, the heating parts 21 comprise a heating body T and a heat conducting part 212, the heat conducting part 212 comprises a hollow part 2121 for accommodating the heating body T and a plurality of radiating fins P with air holes, the radiating fins P and the hollow part 2121 are integrally formed into a radial shape, an upper air flow cavity 101 is formed between the radiating fins P and the upper wall 232 of the long cylindrical shell, and a lower air flow cavity 103 is formed between the radiating fins P and the lower wall 233 of the long cylindrical shell 23.

It can be seen that the drying module 20 of the above embodiments eliminates the fan assembly commonly used in conventional drying modules. Simply, by utilizing the characteristic that the hot air flow has upward flow, the air flows in the upper air flow cavity 101 and the lower air flow cavity 103 are heated under the action of the heating component 21, and the heated air flows out from the air outlet holes 22 on the long cylindrical shell 23; the air flows of the lower air flow cavity 103 and the upper air flow cavity 101 are heated and lifted to form a negative pressure environment with the outer space of the long cylindrical shell 23, so that the external air flow is sucked from the air inlet hole 28 to be supplemented into the lower air flow cavity 103 and the upper air flow cavity 101 under the action of the negative pressure; i.e. the air flow is heated to have the upward flow characteristic so as to drive the air flow to circulate inside and outside the long cylindrical shell 23. Thereby reducing the parts of the drying module 20 and simplifying the whole structure thereof; meanwhile, the defect that noise is generated when the fan works is overcome; in addition, the temperature generated by the heating component 21 arranged beside the fan is prevented from affecting the performance of the motor on the fan.

Preferably, a lower airflow cavity 103 is formed between the heat generating component 21 and the lower wall 233 of the long cylindrical housing 23, the heat insulating cavity 102 communicates with the lower airflow cavity 103, and the heat dissipating fan 24 blows the airflow in the heat insulating cavity 102 into the lower airflow cavity 103.

It should be noted that, the upper airflow cavity 101 and the lower airflow cavity 103 are drying areas of the heat generating component 21. In the upper air flow cavity 101 or the lower air flow cavity 103, the air flow flowing in from the heat insulating chamber 102 is heat treated by the heat generating member 21.

The heat-generating component 21 is provided with a heat-insulating plate 25 on a side portion thereof, and a heat-insulating chamber 102 is formed between the heat-insulating plate 25 and a side wall 231 of the long cylindrical housing 23. The air flow in the heat insulating chamber 102 is timely dredged into the upper air flow cavity 101 and the lower air flow cavity 103 so that the heat generating component 21 heats the inflowing air flow. Cool air outside the long cylindrical shell 23 can be continuously supplemented into the heat insulation cavity 102, so that the air temperature of the heat insulation cavity 102 is lower, the outer wall of the long cylindrical shell 23 is prevented from being scalded, and accidental scalding of a user is avoided.

The heat radiation fan 24 is mounted on the end of the long cylindrical casing 23, and an air guide member 26 is provided in the casing inside the heat radiation fan 24, and the air guide member 26 guides the air flow introduced from the heat radiation fan 24 into the heat insulation chamber 102 simultaneously and intensively.

The insulating plate 25 is spaced from the upper wall 232 of the elongated tubular housing 23 to form an upper air flow inlet F1 which communicates the insulating chamber 102 with the upper air flow cavity 101.

The insulating plate 25 is spaced from the lower wall 233 of the elongated tubular housing 23 to form a lower airflow inlet F2 that communicates the insulating chamber 102 with the lower airflow cavity 103.

When the drying module is started, the heat dissipation fan 24 concentrates and simultaneously sucks air flow outside the long cylindrical shell 23 into the heat insulation cavity 102, a large amount of air flow can be dispersed and dredged from the air flow originally remained in the heat insulation cavity 102, the air flow flows into the upper air flow cavity 101 and the lower air flow cavity 103 through the upper air flow inlet F1 and the lower air flow inlet F2 respectively, and the inflow air flow is heated through the heating component 21; thereby accelerating the flow of air in the drying module 20, improving the drying efficiency of the drying module 20, and improving the heat dissipation performance in the drying module 20.

More specifically, in actual operation, a drying region is formed between the heat generating member 21 and the upper wall 232 of the long cylindrical housing 23, and between the heat generating member 21 and the lower wall 233 of the long cylindrical housing 23, to heat-treat the air flow flowing in from the heat insulating chamber 102.

More specifically, the heat generating member 21 includes a heat generating body T and a heat conducting member 212, and the heat conducting member 212 includes a hollow portion 2121 accommodating the heat generating body T and a plurality of radiating fins P with ventilation holes formed integrally with the hollow portion 2121 in a radial shape.

Preferably, the heat generating members 21 are distributed along the length of the inner cavity of the long cylindrical housing 23.

The heat sink P includes a first heat sink P1 and a second heat sink P2 symmetrical to the hollow 2121 and inclined upward, and an upper air flow cavity 101 is formed between the first heat sink P1, the second heat sink P2 and the upper wall 232; the fins P further include a third fin P3 and a fourth fin P4 symmetrical to the hollow 2121 and inclined downward, and a lower air flow cavity 103 is formed between the third fin P3 and the fourth fin P4.

More specifically, as shown in fig. 1 to 3, both sides of the heat generating component 21 in the inner cavity of the long cylindrical housing 23 are provided with a first heat insulating chamber 1021 and a second heat insulating chamber 1022.

The heat conducting member 212 has a first heat insulating plate 251 and a second heat insulating plate 252 on both sides thereof, the first heat insulating plate 251 and the first side wall 2311 of the long cylindrical housing 23 form a first heat insulating chamber 1021, and the second heat insulating plate 252 and the second side wall 2312 of the long cylindrical housing 23 form a second heat insulating chamber 1022.

The first heat insulating plate 251 is fixed to the free ends of the first heat sink P1 and the third heat sink P3, and the second heat insulating plate 252 is fixed to the free ends of the second heat sink P2 and the fourth heat sink P4.

The heat insulation cavity 102 is communicated with the upper airflow cavity 101 and the lower airflow cavity 103, and the heat radiation fan 24 introduces external airflow to blow the hot airflow in the heat insulation cavity 102 into the upper airflow cavity 101 and the lower airflow cavity 103.

The inner sides of the heat dissipation fans 24 at the two ends of the long cylindrical shell 23 are respectively provided with an air guide part 26, and the air guide parts 26 guide air flows generated by the heat dissipation fans 24 into the first heat insulation cavity 1021 and the second heat insulation cavity 1022, so that hot air flows in the heat insulation cavities 102 are blown into the upper air flow cavity 101 and the lower air flow cavity 103.

Preferably, the heating body T is a heating wire or PTC heating module, and the heat conductive member 212 is made of aluminum alloy.

The clothes airing machine comprises a clothes airing component 10 and a drying module 20, wherein the drying module 20 is connected with the clothes airing component 10 through a telescopic component 30. Wherein for the connection structure between the clothes airing component and the drying module:

as shown in fig. 5 to 7, a connection structure 100 between a clothes drying component and a drying module comprises a clothes drying component 10 and a drying module 20 which is internally provided with a heating component 21 and the upper surface of which is provided with an air outlet hole 22, wherein a foldable telescopic component 30 is arranged between the clothes drying component 10 and the drying module 20; the upper surface middle part of the drying module 20 is provided with a holding area 40 which extends along the length direction of the drying module 20 and is concave, and at least a part of the telescopic assembly 30 is held in the holding area 40 in the holding state. I.e., the receiving area 40 may conceal the retraction assembly 30 that is not flat enough after folding.

A containing area 40 is arranged between the clothes airing component 10 and the drying module 20, and a telescopic component 30 between the clothes airing component 10 and the drying module 20 can be contained in the containing area 40 between the clothes airing component 10 and the drying module 20 after folding and containing, and the telescopic component 30 after folding and containing can be shielded; the storage area of the telescopic assembly 30 is tidier, and the whole clothes airing machine is more attractive, so that the use experience of a user is improved.

The drying module 20 includes a long cylindrical housing 23 provided with air outlet holes 22, and a receiving area 40 is provided on an upper surface of the long cylindrical housing 23. When the drying module 20 is to be stored upwards, the drying module 20 is gradually lifted upwards, and then the telescopic assembly 30 is gradually folded until the telescopic assembly 30 is completely folded and stored in the storage area 40, and meanwhile, the drying module 20 is also completely propped against and stored on the lower side surface of the clothes drying component 10. Thereby reduce and accomodate the back, the clearance between clothes-horse part and the stoving module. The whole appearance of the clothes airing machine is tidier and more attractive.

The two sides of the long cylindrical housing 23 are protruded so that the middle part forms a concave receiving area 40. The two sides of the long cylindrical shell 23 are provided with protruding parts f along the length direction, and the protruding parts f on the two sides and the middle concave part form a containing area 40, so that the telescopic assembly 30 can be contained in the containing area 40.

The lower ends of the telescopic assemblies 30 are connected to the two end portions of the drying module 20, and the accommodating areas 40 are distributed in the areas of the telescopic assemblies 30 between the connecting portions of the drying module 20. Specifically, the telescopic assemblies 30 are fixedly connected to the two ends, the a end and the b end, of the drying module 20, and the accommodating area 40 is distributed between the a end and the b end.

The air outlet holes 22 comprise a plurality of air outlet grooves H which are distributed in parallel and have the extending direction consistent with the width of the drying module 20.

The recessed receiving area 40 has a cross-section in the form of an inverted trapezoidal, rectangular or fan-shaped structure.

The height of the folded retraction assembly 30 is equal to or greater than the depth of the receiving area 40. So that the telescopic component 30 can be completely contained and accommodated in the accommodating area 40, and the overall appearance of the clothes airing machine is tidier.

The telescopic assembly 30 comprises a folding rod 31 with two ends respectively connected to the drying module 20 and the clothes drying component 10 in a shaft way, and the folding rod 31 has at least two-section structure.

Preferably, the telescopic assembly 30 is formed by pivotally connecting two folding bars 31, and when the telescopic assembly 30 needs to be stored and folded, the connection parts between the two folding bars 31 rotate mutually, so that the two folding bars 31 can be folded mutually. Specifically, the drying module 20 is lifted upwards, and the connection parts of the folding rods 31, the drying module 20 and the clothes airing component 10 are rotated, so that the folding rods 31 are folded, and the drying module 20 and the clothes airing component 10 are also mutually closed and stored.

The long cylindrical case 23 is made of an aluminum alloy. The overall quality of the drying module 20 is light, and the appearance and luster are clean and beautiful. Preferably, the clothes drying assembly 10 and the telescopic assembly 30 may also be made of aluminum alloy materials.

Preferably, the clothes airing component 10 comprises a clothes airing rod 11, a hanging plate Y is fixed on the lower side of the clothes airing rod 11, and a clothes airing hole 12 for hanging clothes is formed in the hanging plate Y. Of course, the clothes rail 11 may be of a telescopic structure, and may extend laterally to increase the length of the clothes rail 11 when it is desired to hang more clothes.

Preferably, the clothes drying assembly comprises a connecting structure between the clothes drying component and the drying module. It should be noted that, in actual use, a magnet assembly is disposed between the clothes drying component 10 and the drying module 20. The drying module 20 is hung below the clothes drying part 10 through the telescopic assembly 30, and the drying module 20 blows hot air upwards to dry clothes hung on the clothes drying part 10; when the clothes do not need to be dried, the drying module 20 is lifted upwards by force, the telescopic assembly 30 is folded and then is accommodated in the accommodating area 40, and meanwhile, the drying module 20 is attracted to the lower side of the clothes drying component 10 through the magnet assembly, so that a gap between the clothes drying component 10 and the drying module 20 is reduced.

More preferably, the airing machine comprises a main machine part 50 and an airing assembly connected with the main machine part 50. In the actual operation process, the power supply of the drying module 20 is taken from the main machine part 50, the power plug 60 of the drying module 20 is installed on the clothes drying part 10, and the power line of the drying module 20 is arranged inside the telescopic assembly 30 in a penetrating way and is connected with the power plug 60 installed on the clothes drying part 10. When the power plug 60 mounted on the clothes drying part 10 is plugged into the power socket on the main machine part 50, the drying module 20 can realize the power taking from the main machine part 50. And the power cord is worn inside the telescopic assembly 30, so that the layout of the power cord is tidier, and the mutual abrasion or breakage caused by the mutual winding of the power cord can be prevented.

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

The independent drying module and the clothes airing machine provided by the invention are described in detail, and specific examples are applied to explain the principle and the implementation mode of the invention, and the description of the examples is only used for helping to understand the invention and the core idea. It should be noted that it will be apparent to those skilled in the art that various modifications and adaptations of the invention can be made without departing from the principles of the invention and these modifications and adaptations are intended to be within the scope of the invention as defined in the following claims.

Claims (4)

1. The independent drying module is characterized by comprising a long cylindrical shell and heating parts distributed along the length direction of an inner cavity, wherein air outlets are distributed on the upper wall of the long cylindrical shell, the heating parts comprise a heating body and a heat conducting part, the heat conducting part comprises a hollow part for accommodating the heating body and a plurality of radiating fins with air holes, the radiating fins are integrally formed with the hollow part and are in a radial shape, an upper air flow cavity is formed between the radiating fins and the upper wall of the long cylindrical shell, and a lower air flow cavity is formed between the radiating fins and the lower wall of the long cylindrical shell; the radiating fins comprise first radiating fins and second radiating fins which are symmetrical to the hollow part and incline upwards, and the upper airflow cavity is formed among the first radiating fins, the second radiating fins and the upper wall; the radiating fins further comprise a third radiating fin and a fourth radiating fin which are symmetrical to the hollow part and obliquely downward, and the lower airflow cavity is formed between the third radiating fin and the fourth radiating fin; the two sides of the heating component in the inner cavity of the long cylindrical shell are provided with a first heat insulation cavity and a second heat insulation cavity; the heat conduction device comprises a heat conduction component, a first heat insulation board and a second heat insulation board, wherein the two sides of the heat conduction component are provided with the first heat insulation board and the first side wall of the long cylindrical shell to form a first heat insulation cavity, and the second heat insulation board and the second side wall of the long cylindrical shell to form a second heat insulation cavity; the first heat insulation plate is fixed at the free ends of the first radiating fins and the third radiating fins, and the second heat insulation plate is fixed at the free ends of the second radiating fins and the fourth radiating fins; the heat insulation cavity is communicated with the upper airflow cavity and the lower airflow cavity, and the heat radiation fan introduces external airflow to blow the hot airflow of the heat insulation cavity into the upper airflow cavity and the lower airflow cavity; at least one end of the shell is provided with a heat radiation fan, the inner side of the heat radiation fan is provided with an air guide part, and the air guide part guides air flow generated by the heat radiation fan into the first heat insulation cavity and the second heat insulation cavity, so that hot air flow in the heat insulation cavity is blown into the upper air flow cavity and the lower air flow cavity.

2. The self-contained drying module of claim 1, wherein the lower wall of the housing has air inlet openings distributed therein.

3. The independent drying module according to claim 1, wherein the heating element is a heating wire or a PTC heating module, and the heat conductive member is made of aluminum alloy.

4. The clothes airing assembly is characterized by comprising a clothes airing component and the independent drying module according to any one of claims 1-3, wherein the clothes airing component is connected with the independent drying module through a telescopic assembly.