CN114190681B - Hair care hurricane cylinder - Google Patents

Abstract

The invention relates to the field of household appliances, in order to set up water ion module in the column type hurricane dryer, especially relate to a hair care hurricane dryer, including the body assembly, the body assembly defines the air current passageway inside, the air current upstream of the air current passageway has air current inlet that the air current enters, the air current downstream of the air current passageway has air current outlet of the exhaust air current, there is a fan unit used for making the air current enter the body assembly from the said air current inlet in the body assembly, wherein, still include the water ion module used for forming water ion, the body assembly takes the form of column design, there is accommodation space used for holding the said water ion module in the body assembly, the accommodation space has water ion outlet which communicates the external environment; the receiving space is located at the uppermost end of the housing assembly in the direction of the flow of the air in the air flow path.

Description

Hair care hurricane cylinder

Technical Field

The invention relates to the field of household appliances, in particular to a hair care hurricane drum.

Background

Most of the blowers on the market at present consist of a handle and a machine head, the handle is connected with the machine head, the whole blower is in a T shape, and because the blowers need to bear parts with larger installation space such as a fan unit and a heating assembly, the whole blower is larger in size and occupies larger storage space. The air flow inlet is arranged on the handle or the machine head, and the air flow outlet is arranged at the end part of the machine head.

For the hair dryer with the structure, the internal parts of the hair dryer are generally distributed in the handle and the machine head, and as part of parts can be arranged in the handle, a relatively large installation space can be obtained in the machine head, and the water ion module needs to occupy a certain space for installation, and is generally arranged in the machine head. The blower with the existing T-shaped structure has larger inner space, so that the installation position of the water ion module can be freely designed according to requirements.

Disclosure of Invention

The invention provides a columnar hair care hurricane dryer, which solves the problem that a water ion module is arranged in a small space so as to achieve the purpose of hair care.

A hair care hurricane comprising a housing assembly defining an airflow path therein, an airflow inlet upstream of the airflow path having an airflow outlet downstream of the airflow path for exhausting airflow, a fan unit disposed within the housing assembly for directing airflow from the airflow inlet into the housing assembly,

the water ion device comprises a shell assembly, a water ion module and a water ion outlet, wherein the shell assembly is in a columnar design, an accommodating space for accommodating the water ion module is arranged in the shell assembly, and the accommodating space is provided with the water ion outlet communicated with the external environment;

the receiving space is located at an uppermost end of the housing assembly in a direction of airflow in the airflow path.

The advantage is that be column design's casing subassembly, and the inner space is very much less than the hair-dryer of traditional T font design (handle plus aircraft nose's structure), and water ion module is also a comparatively big subassembly relatively, how make full use of casing subassembly's inner space, and the influence to the space of air current passageway reduces, is the problem that needs to solve, sets up at the top for can have great space installation water ion subassembly, and do not influence the amount of wind in through the air current passageway, guarantee the air current in the air current passageway in time from the air current export discharge.

Preferably, the water ion outlet is formed in a side wall of the housing assembly, the water ion module comprises a condensing rod for forming condensed water, and a discharge electrode group for discharging the condensing rod to form water ions, and the condensing rod is arranged towards the water ion outlet.

The condensing rod is closer to the external environment through the technical scheme, so that the condensing rod is convenient to quickly condense moisture in the air, and water vapor in the blowing process can enter the accommodating space through the water ion outlet and is attached to the condensing rod, so that the efficiency of condensing water drops on the condensing rod is improved, and the generation efficiency of water ions is further improved; and the formed water ions can be discharged from the water ion outlet rapidly through the shortest path, so that the loss of the water ions in the discharging process is reduced.

Preferably, the condensing bar is disposed at an angle to the axis of the housing assembly.

The water ion module installation structure has the advantages that the installation mode enables the installation of the water ion module to be matched with the inner space of the columnar shell assembly as far as possible, the volume of the containing space is relatively small, the installation space of other core structures is not occupied, the technical performance is not influenced, and the shell assembly with small size or volume can be obtained.

Preferably, the axis of the water ion module is disposed at an angle to the axis of the housing assembly.

The advantage is that the arrangement mode is to make the installation of the water ion module match with the internal space of the columnar shell assembly as far as possible, the volume of the containing space is relatively smaller, the shell component does not occupy the installation space of other core structures, does not affect the technical performance, and can be smaller in size or volume.

Preferably, the air flow outlet is positioned on the side wall of the shell component and is arranged in the same direction as the water ion outlet, and the water ion outlet is positioned above the air flow outlet.

The advantage is, through this technical scheme combination column casing subassembly's design, in the use, compare in traditional T type hair-dryer, has overcome the axial distance overlength of aircraft nose among the prior art, makes user's arm apart from the hair distance great, and the arm lasts the drawback of power, and this technical scheme's setting mode shortens the distance between arm and the hair, reduces the tired degree of blowing the in-process, accords with human engineering. The air flow outlet and the water ion outlet are positioned on the same side, so that the hair is dried, meanwhile, the moisture and the negative ions are supplemented for the hair, and the generation of frizziness and dryness after the hair is dried is reduced, so that the hair is glossy and smooth. The water ion outlet is positioned above the airflow outlet, so that the complexity of the structural design of the internal airflow passage is reduced.

Preferably, the air flow path includes a cold air flow path in which a heating unit for heating an air flow is provided, and a hot air flow path into which an external air flow enters through the air flow inlet by the fan unit, and into which the external air flow enters downstream of the fan unit and is discharged from the water ion outlet and the air flow outlet, respectively, the water ion module is provided in the cold air flow path, the accommodation space is formed as at least a part of the cold air flow path, and the cold air flow path and the hot air flow path are thermally isolated.

The water ion module has the advantages that through the design of the cold air flow passage, water ions generated by the water ion module are rapidly discharged from the water ion outlet, and the efficiency of supplementing water to hair is improved; the cold air flow path is thermally isolated from the hot air flow path, preventing hot air from entering the accommodating space, making it difficult to form water ions.

Preferably, the accommodating space is located above the hot gas flow path.

The hot air flow passage and the accommodating space are two independent spaces, and hot air is not easy to enter the accommodating space, so that the water ion module can stably and reliably form water ions.

Preferably, the housing assembly includes an outer housing and an inner housing located within the outer housing, the cold air flow path is located between the inner housing and the outer housing, the hot air flow path is formed within the inner housing, and the receiving space is located between the inner housing and the outer housing.

Preferably, the inner casing comprises a first inner casing for fixing the fan unit, and a second inner casing which is arranged above the first inner casing and connected with the first inner casing, wherein an air flow reversing structure is arranged on the second inner casing and used for enabling air flowing along the axial direction of the casing assembly to be discharged from the air flow outlet in a direction changing manner, the accommodating space is arranged between the second inner casing and the outer casing, and the accommodating space is arranged above the air flow reversing structure.

The air flow reversing structure has the advantages that through the design of the air flow reversing structure, the wind resistance is reduced, and the air flow is guided by the air flow reversing structure to change the direction and is discharged from the air flow outlet; through this technical scheme, the assembly of the spare part in the inner shell of still being convenient for, abundant, reasonable utilization casing assembly's inner space to obtain less volumetric casing assembly, can realize the installation of water ion module, can pass through the structure of inner shell, shell again, construct cold air current passageway, hot air current passageway.

Preferably, the water ion module further comprises a discharge electrode group, a semiconductor refrigeration piece and a heat dissipation unit, wherein the discharge electrode group, the semiconductor refrigeration piece and the heat dissipation unit are all arranged in the accommodating space and electrically connected with the high-voltage power supply, the refrigeration surface of the semiconductor refrigeration piece is in contact with the condensation rod, the heating surface of the semiconductor refrigeration piece is attached to the heat dissipation unit, and the discharge electrode group discharges to the condensation rod to form water ions.

The water ion module has the advantages that by the aid of the water ion module, condensate water can be formed on the surface of the condensing rod, and water ions can be obtained; all the parts forming the water ion module in the technical scheme are positioned in the accommodating space, so that the water ion module is convenient to assemble.

Drawings

Fig. 1 is a schematic view of a hurricane canister according to the present invention.

Fig. 2 is an exploded view of a hurricane canister according to the present invention.

Fig. 3 is a cross-sectional view of the duct structure of the hurricane canister of the present invention.

Fig. 4 is an enlarged view of a portion indicated by a in fig. 3.

Fig. 5 is a further cross-sectional view of the wind tunnel structure of the hurricane drum of the present invention.

Fig. 6 is an exploded view of the inner wall of the present invention and the components within the inner wall.

Fig. 7 is a schematic structural view of the water ion module of the present invention.

Fig. 8 is a schematic view of the radial dimensions of the housing assembly of the present invention.

The names of the components marked in the figures are as follows:

1. a housing assembly; 101. an inner wall; 1011. a first inner wall; 1012. a second inner wall; 102. an outer wall; 103. a housing; 2. An air flow inlet; 3. an air flow outlet; 301. a hot air outlet; 302. a water ion outlet; 4. a heating unit; 5. a fan unit; 6. a hot gas flow path; 7. a cold air flow path; 8. a control assembly; 9. an anti-scalding isolation layer; 10. an airflow reversing structure; 1001. an arc-shaped blade; 1002. a partition wall surface; 11. a water ion module; 1101. a condensing rod; 1102. A discharge electrode group; 1103. a semiconductor refrigeration sheet; 1104. a heat radiation unit; 12. an accommodation space; 13. a cool air inlet; 14. a high voltage power supply; 15. a cylindrical portion.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings.

As shown in fig. 1 to 8, a hurricane cartridge comprises a housing assembly 1, the housing assembly 1 defining an air flow path therein, an air flow inlet 2 upstream of the air flow path having an air flow inlet, an air flow outlet 3 downstream of the air flow path having an air flow outlet 3 for discharging air flow, a fan unit 5 for causing air flow from the air flow inlet 2 into the housing assembly 1 being provided in the housing assembly 1,

the water ion device further comprises a water ion module 11 for forming water ions, wherein the shell assembly 1 is in a columnar design, a containing space 12 for containing the water ion module 11 is arranged in the shell assembly 1, and the containing space 12 is provided with a water ion outlet 302 communicated with the external environment;

the accommodating space 12 is located at the uppermost end of the housing assembly 1 in the direction of the airflow in the airflow path.

In the foregoing embodiments, the respective components constituting the water ion module 11 may be located entirely in the accommodating space 12, or may be located partially in the accommodating space 12.

In the foregoing embodiments, the accommodating space 12 may or may not have an airflow passing therethrough.

In the foregoing technical solution, the water ion module 11 may generate water ions in different manners, that is, the components of the water ions are different, and in one manner, the water ion module 11 includes a condensation rod 1101, a high-voltage power supply 14, a semiconductor refrigeration sheet 1103, and a heat dissipation unit 1104, the high-voltage power supply 14 is electrically connected to the discharge electrode group 1102, a refrigeration surface of the semiconductor refrigeration sheet 1103 contacts with the condensation rod 1101, a heating surface of the semiconductor refrigeration sheet 1103 is attached to the heat dissipation unit 1104, and the discharge electrode group 1102 discharges to the condensation rod 1101 to form water ions; it is also possible that the water ion module 11 comprises a condensing bar 1101, a high voltage power supply 14, and during use of the hurricane canister, water molecules or water vapor enter the accommodating space 12 through the water ion outlet 302, and the discharge electrode group 1102 attached to the condensing bar 1101 discharges to the condensing bar 1101 to form water ions.

Further, the shell component 1 is in a columnar design, and the maximum radial effective size of the shell component 1 is D (shown in FIG. 8), wherein D is more than or equal to 20mm and less than or equal to 60mm; obtaining a hurricane barrel with small volume and small occupied storage space; when D is smaller than 20mm, the internal space of the shell component 1 is too small to meet the power requirements of the fan unit 5 and the heating unit 4, so that the hair drying efficiency and the water ion discharging efficiency are reduced; when D is larger than 60mm, the shell assembly 1 is oversized, so that the shell assembly is inconvenient to hold and poor in use experience; preferably d=48 mm.

In this solution, it is particularly emphasized that a water ion module 11 is arranged in a cylindrical housing assembly 1 with a certain limit on the radial maximum dimension.

Further, as shown in fig. 1, 3, 4, 5 and 7, the water ion outlet 302 is provided on a side wall of the housing assembly 1, the water ion module 11 includes a condensing rod 1101 for forming condensed water, and a discharge electrode group 1102 for discharging the condensing rod 1101 to form water ions, and the condensing rod 1101 is disposed toward the water ion outlet 302.

Further, as shown in fig. 3 and 4, the condensing bar 1101 is disposed at an angle, preferably at an obtuse angle, to the axis of the housing assembly 1, and a shorter length of the housing assembly 1 can be obtained.

Further, as shown in fig. 3 and 4, the axis of the water ion module 11 is arranged at an angle, preferably at an obtuse angle, to the axis of the housing assembly 1, whereby a shorter length of the housing assembly 1 can be obtained.

Further, as shown in fig. 1, the air flow outlet 3 is located on the side wall of the housing assembly 1 and is disposed in the same direction as the water ion outlet 302, and the water ion outlet 302 is located above the air flow outlet 3.

Further, as shown in fig. 3, 4 and 5, the air flow path includes a cold air flow path 7 and a hot air flow path 6, a heating unit 4 for heating an air flow is provided in the hot air flow path 6, an external air flow enters the air flow path through the air flow inlet 2 by the fan unit 5, and enters the cold air flow path 7 and the hot air flow path 6 respectively downstream of the fan unit 5 and is discharged from the water ion outlet 302 and the air flow outlet 3 respectively, the water ion module 11 is provided in the cold air flow path 7, the accommodation space 12 is formed as at least a part of the cold air flow path 7, and the cold air flow path 7 and the hot air flow path 6 are thermally isolated. The receiving space 12 is discharged from the water ion outlet 302 by a cold air flow which is not heated to carry water ions.

The volume of the hot air flow passage 6 is larger than that of the cold air flow passage 7, heat generated by the heating unit 4 is taken away in time, the heating efficiency is improved, the hot spot generation probability can be reduced, and the heating unit 4 can be installed in a larger space, so that the heating unit 4 has larger heating power, and the heating rate is improved. The area of the hot air outlet 301 is larger than that of the water ion outlet 302, and the air flow formed by the operation of the fan unit 5 is mainly or entirely used for entering the hot air flow passage 6, so that the hot air flow is discharged timely through the technical scheme, the hair drying efficiency is improved, and the occurrence probability of the condition that the high-temperature air flow accumulated in the shell assembly 1 cannot be discharged timely to cause burning of internal parts is reduced as much as possible.

The cold gas flow path 7 is located outside the hot gas flow path 6 and extends along the hot gas flow path 6. The inner space of the shell assembly 1, especially the space in the radial direction, can be fully utilized, and the radial dimension of the shell assembly 1 is reduced without obviously weakening the power of the heating unit 4; the hot air flow will raise the temperature of part of the outer surface of the housing assembly 1, making part of the outer surface of the housing assembly 1 hotter, and during operation there is a high probability that a hand may touch the hotter part of the outer surface, so by means of the solution the cold air flow path 7 is located outside the hot air flow path 6, lowering the temperature of the part of the outer surface of the housing assembly 1. Further, in this example, the cold air flow path 7 is located at one side of the hot air flow path 6, and the cold air flow path 7 is disposed opposite to the air flow outlet 3. It will be appreciated that the cold air flow path 7 extends around the hot air flow path 6 and that the water ion outlet 302 is located outside the hot air outlet 301.

The flow rate of the air flow in the cold air flow path 7 is smaller than the flow rate of the air flow in the hot air flow path 6. The air flow in the hot air flow passage 6 is discharged quickly, so that heat generated by the heating unit 4 is taken away, the hair drying efficiency is improved, and the occurrence probability of the condition that high-temperature air flow accumulated in the shell assembly 1 cannot be discharged in time to cause burning of internal parts is reduced as much as possible; the air flow in the cold air flow passage 7 is slowly discharged, so that a fluid heat insulation cavity is formed, the speed of the temperature rise of the local surface of the shell assembly 1 is reduced, and a good anti-scalding effect is obtained; on the other hand, the cold air flow path 7 is provided so as to reduce the probability of occurrence of hot spots, and so as not to significantly reduce the temperature of the air flow blown out from the hot air outlet 301, thereby avoiding as much as possible a significant reduction in hair drying efficiency.

Further, the accommodating space 12 is located above the hot gas flow path 6.

As shown in fig. 2 to 6, the housing assembly 1 includes an inner wall 101 and an outer wall 102 located outside the inner wall 101, the cold air flow path 7 is located between the inner wall 101 and the outer wall 102, the hot air flow path 6 is formed inside the inner wall 101, and the accommodating space 12 is located between the inner wall 101 and the outer wall 102.

The inner wall 101 comprises a first inner wall 1011 for fixing the fan unit 5, and a second inner wall 1012 which is positioned above the first inner wall 1011 and connected with the first inner wall, the second inner wall 1012 is provided with an air flow reversing structure 10 for changing the direction of the air flow flowing along the axial direction of the housing assembly 1 to be discharged from the air flow outlet 3, the accommodating space 12 is positioned between the second inner wall 1012 and the outer wall 102, and the accommodating space 12 is positioned above the air flow reversing structure 10. By the arrangement of the airflow reversing structure 10, wind resistance is reduced, and loss of airflow is reduced.

The hurricane cartridge further comprises an anti-scalding isolation layer 9 and a housing 103, the outer wall 102 and the inner wall 101 are both positioned in the housing 103, the outer surface of the housing assembly 1 comprises the entire outer surface of the housing 103, the anti-scalding isolation layer 9 is positioned outside the cold air flow path 7, and the anti-scalding isolation layer 9 is positioned between the outer wall 102 and the housing 103. The anti-scalding isolation layer 9 is made of a material capable of insulating heat, such as sponge or mica paper, and in this example, the anti-scalding isolation layer 9 is arranged on the inner wall 101 of the housing 103, and preferably the anti-scalding isolation layer 9 covers all the inner walls 101 of the positions of the housing 103 corresponding to the hot air flow passage 6.

In this case the airflow path comprises a hot airflow path 6 and a cold airflow path 7, said airflow reversing structure 10 reversing the airflow in both said cold airflow path 7 and said hot airflow path 6. The reversing of the air flows in the two air flow passages is realized through the same structural member, the internal structural member is reduced, the radial blowing size of the shell assembly 1 is reduced, and the shell assembly 1 with smaller size or volume is obtained.

More specifically, the airflow reversing structure 10 includes a plurality of curved blades 1001, which are disposed at intervals along the axial direction of the housing assembly 1 and curved toward the airflow outlet 3, wherein at least one of the curved blades 1001 simultaneously reverses the airflow in the cold airflow path 7 and the hot airflow path 6. Depending on the arrangement of the cold air flow path 7 and the hot air flow path 6, the different arc-shaped blades 1001 participate in reversing the air flows in the cold air flow path 7 and the hot air flow path 6 at the same time, and may be the uppermost arc-shaped blade 1001 or the lowermost arc-shaped blade 1001, in this example, the water ion outlet 302 and the hot air outlet 301 are both located on the side wall of the housing assembly 1, and the water ion outlet 302 is located above the hot air outlet 301, and the cold air flow path 7 passes through the hot air flow path 6 and is discharged from the water ion outlet 302, so that the uppermost arc-shaped blade 1001 in this example is used for reversing the air flows in the cold air flow path 7 and the hot air flow path 6 at the same time.

The air flow reversing structure 10 includes a partition wall surface 1002 extending in the axial direction of the housing assembly 1, and the cold air flow path 7 and the hot air flow path 6 are located on both sides of the partition wall surface 1002, respectively. Further, the housing assembly 1 includes an outer wall 102 that is sleeved outside the air flow reversing structure 10, and the cold air flow path 7 is defined by a first face of the partition wall face 1002 and an inner wall 101 face of the outer wall 102. The airflow reversing structure 10 further includes a plurality of arc-shaped blades 1001 extending between the hot air outlet 301 and a second surface of the partition wall 1002, the second surface being opposite to the first surface, the side walls of the arc-shaped blades 1001 abutting against the inner wall 101 surface of the outer wall 102, and the hot air flow path 6 being defined by the arc-shaped blades 1001, the second surface and the inner wall 101 surface of the outer wall 102. The plurality of arc-shaped blades 1001 are located at one side of the partition wall surface 1002.

The housing assembly 1 comprises an inner wall 101 and an outer wall 102 sleeved outside the inner wall 101, the inner wall 101 and the outer wall 102 cooperatively define the airflow passage, the airflow reversing structure 10 is formed as a part of the inner wall 101, the heating unit 4 is positioned between the airflow reversing structure 10 and the fan unit 5, and the fan unit 5 and the heating unit 4 are positioned in the inner wall 101. The inner wall 101 includes a first inner wall 1011 and a second inner wall 1012 which are divided up and down, the air flow reversing structure 10 is formed on the first inner wall 1011, the fan unit 5 is fixed in the second inner wall 1012, a cool air flow passage is defined by an outer wall 102 surface of the first inner wall 1011 and an inner wall 101 surface of the outer wall 102, and a cool air inlet 13 of the cool air flow passage is formed by a gap between the first inner wall 1011 and the second inner wall 1012. The first inner wall 1011 further includes a cylindrical portion 15 located below the airflow reversing structure 10, and the heating unit 4 is columnar and is fixed by the cylindrical portion 15.

In this example, as shown in fig. 7, the water ion module 11 includes a condensation bar 1101, a discharge electrode group 1102 electrically connected to the high-voltage power supply 14, a semiconductor cooling plate 1103, and a heat dissipation unit 1104, wherein a cooling surface of the semiconductor cooling plate 1103 contacts the condensation bar 1101, a heating surface of the semiconductor cooling plate 1103 is attached to the heat dissipation unit 1104, and the discharge electrode group 1102 discharges to the condensation bar 1101 to form water ions. Further, the high voltage power supply 14 may be located in the accommodating space 12, or may be located at another position, where the high voltage power supply 14 is located in the accommodating space 12.

The fan unit 5 comprises a motor and an impeller driven by the motor to rotate, the motor is a three-phase synchronous motor, the rotating speed of the motor is equal to or less than 80000rpm and equal to or less than 130000rpm, and the power of the heating unit 4 is equal to or less than P and equal to 1000W and equal to or less than 1800W.

Further, a hot air flow space for placing the heating unit 4 is further provided in the housing assembly 1, and the air flow formed by the action of the fan unit 5 enters the hot air flow space and the accommodating space 12 respectively.

Further, the volume of the accommodating space 12 is smaller than the volume of the hot gas flow space. The volume of the accommodation space 12 is larger than the volume of the water ion module 11.

The housing assembly 1 comprises an inner wall 101 and an outer wall 102 sleeved outside the inner wall 101, the fan unit 5 and the heating unit 4 are positioned in the inner wall 101, the accommodating space 12 is defined by the outer wall 102 surface of the inner wall 101 and the inner wall 101 surface of the outer wall 102, and the hot air flow space is at least defined by the inner wall 101 surface of the inner wall 101. The inner wall 101 abuts against the outer wall 102 in the axial direction of the housing assembly 1 to thermally isolate the accommodating space 12 from the hot gas flow space. The inner wall 101 and the outer wall 102 cooperate to define the airflow path including a hot airflow path 6 through the hot airflow space and a cold airflow path 7 through the receiving space 12, the cold airflow path 7 being located outside the hot airflow path 6. The inner wall 101 includes a first inner wall 1011 and a second inner wall 1012 which are divided up and down, the fan unit 5 is fixed in the second inner wall 1012, the cool air flow path 7 is defined by an outer wall 102 surface of the first inner wall 1011 and an inner wall 101 surface of the outer wall 102, and the cool air inlet 13 of the cool air flow path 7 is formed by a gap between the first inner wall 1011 and the second inner wall 1012. The fan unit 5, the heating unit 4, and the water ion module 11 are disposed in this order along the direction of the air flow in the air flow path.

The hurricane drum further comprises a control component 8 for controlling the operation of the hurricane drum, the control component 8 is fixed by the first inner wall 1011, the control component 8 is arranged upstream of the fan unit 5 (which is upstream of the airflow direction), and the control component 8 is overlapped with the airflow inlet 2.

The foregoing has shown and described the basic principles and main features of the present invention and the advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. A hair care hurricane comprising a housing assembly defining an airflow path therein, an airflow inlet upstream of the airflow path having an airflow outlet downstream of the airflow path for exhausting airflow, a fan unit disposed within the housing assembly for directing airflow from the airflow inlet into the housing assembly,

the water ion device is characterized by further comprising a water ion module for forming water ions, wherein the shell assembly is in a columnar design, a containing space for containing the water ion module is arranged in the shell assembly, and the containing space is provided with a water ion outlet communicated with the external environment;

the accommodating space is positioned at the uppermost end of the shell component along the flowing direction of the air flow in the air flow passage; the water ion outlet is formed in the side wall of the shell assembly, the water ion module comprises a condensing rod used for forming condensed water and a discharge electrode group used for discharging the condensing rod to form water ions, and the condensing rod is arranged towards the water ion outlet;

the condensing rod is disposed at an angle to an axis of the housing assembly.

2. The hurricane drum of claim 1, wherein the axis of said water ion module is disposed at an angle to the axis of said housing assembly.

3. The hurricane drum of claim 1, wherein said airflow outlet is located in a side wall of said housing assembly and is co-directional with said water ion outlet, said water ion outlet being located above said airflow outlet.

4. A hurricane duct according to claim 3, wherein the airflow path comprises a cold airflow path and a hot airflow path, a heating unit is provided in the hot airflow path for heating the airflow, an external airflow enters the airflow path through the airflow inlet under the action of the fan unit, and enters the cold airflow path and the hot airflow path respectively downstream of the fan unit and is discharged from the water ion outlet and the airflow outlet respectively, the water ion module is provided in the cold airflow path, the accommodation space is formed as at least a part of the cold airflow path, and the cold airflow path and the hot airflow path are thermally isolated.

5. The hurricane drum of claim 4, wherein said containment space is located above said hot gas flow path.

6. The hurricane drum of claim 4, wherein said housing assembly comprises an outer housing and an inner housing within said outer housing, said cold air flow path being located between said inner housing and said outer housing, said hot air flow path being formed within said inner housing, said containment space being located between said inner housing and said outer housing.

7. The hurricane drum of claim 6, wherein said inner housing comprises a first inner housing for securing said fan unit, and a second inner housing positioned above and connected to said first inner housing, said second inner housing having an air flow reversing structure positioned thereon for redirecting air flowing along the axis of said housing assembly for discharge from said air flow outlet, said receiving space being positioned between said second inner housing and said outer housing, and said receiving space being positioned above said air flow reversing structure.

8. The hurricane drum of any of claims 1 to 7, wherein the water ion module further comprises a discharge electrode set, a semiconductor refrigeration sheet, and a heat dissipation unit all disposed in the accommodating space and electrically connected to a high voltage power supply, the refrigeration surface of the semiconductor refrigeration sheet is in contact with the condensation bar, the heating surface of the semiconductor refrigeration sheet is attached to the heat dissipation unit, and the discharge electrode set discharges to the condensation bar to form water ions.