CN110897299A

CN110897299A - Ion hair drier

Info

Publication number: CN110897299A
Application number: CN201811072185.1A
Authority: CN
Inventors: 禄鹏媛; 韩路; 屈恒
Original assignee: Beijing Xiaomi Mobile Software Co Ltd
Current assignee: Beijing Xiaomi Mobile Software Co Ltd
Priority date: 2018-09-14
Filing date: 2018-09-14
Publication date: 2020-03-24

Abstract

The disclosure discloses an ion hair drier, and belongs to the field of household appliances. The ion blower comprises an outer barrel and an ion generator; an ion airflow channel is arranged in the outer barrel, the ion generator is arranged in the ion airflow channel, a state display lamp and a lamp cover are arranged on the outlet side of the ion airflow channel, and a first opening is formed in the lamp cover; and the state display lamp is configured to indicate the working state of the ion generator through light penetrating through the lamp cover when the ion blower is in the ion wind working state. This is disclosed through set up state display lamp and lamp lid in ion airflow channel's outlet side, and the operating condition of ion generator can be instructed to the light of the state display lamp that sees through the lamp lid, has consequently solved the problem that the operating condition of ion generator can't be shown directly perceivedly to the ion hair-dryer among the correlation technique, has improved the use convenience of ion hair-dryer.

Description

Ion hair drier

Technical Field

The disclosure relates to the field of household appliances, in particular to an ion blower.

Background

The ion blower is a blower provided with an ion generator. When the ion hair dryer works, the electric fan generates air flow to blow generated ions onto a user, and the generated ions can neutralize electric charges on hair and skin, so that the aims of smoothing out messy hair and eliminating static electricity are fulfilled.

Disclosure of Invention

The embodiment of the disclosure provides an ion blower to solve the problem that the ion blower provided in the related art cannot intuitively display the working state of an ionizer. The technical scheme is as follows:

in one aspect, embodiments of the present disclosure provide an ion blower including an outer tub and an ionizer;

an ion airflow channel is arranged in the outer barrel, the ion generator is arranged in the ion airflow channel, a state display lamp and a lamp cover of the state display lamp are arranged on the outlet side of the ion airflow channel, the lamp cover is provided with a first opening, and the first opening is used for enabling airflow flowing through the ion airflow channel to flow out;

the ion generator is configured to generate ions when the ion blower is in an ion wind operating state;

the state display lamp is configured to indicate the working state of the ion generator through light penetrating through the lamp cover when the ion blower is in the ion wind working state.

In an alternative embodiment, the ionic blower further comprises an inner barrel and an electric fan assembly;

the inner cylinder is arranged in a first cavity in the outer cylinder, a first air inlet and a first air outlet are respectively arranged at two sides of the first cavity, the ion airflow channel is formed in the inner cylinder, and a second air inlet and a second air outlet are respectively arranged at two sides of the ion airflow channel;

the lamp cover is arranged at the position of the second air outlet and is fixedly connected with the inner barrel;

the electric fan assembly is disposed in the first chamber and configured to generate an air flow entering from the first air inlet and exiting from the first air outlet and the second air outlet when the ion blower is in an operating state.

In an alternative embodiment, the lamp cover comprises a first annular structure having the first opening and a second annular structure being a transparent or translucent structure.

In an optional embodiment, a mesh enclosure is further disposed at the position of the first air outlet, and the mesh enclosure is fixedly connected with the second annular structure of the lamp cover.

In an optional embodiment, the second annular structure includes a bottom and a protrusion, the bottom is provided with a buckle, the lamp cover is clamped with the inner barrel through the buckle, the protrusion is embedded into the second opening of the mesh enclosure, and the mesh enclosure is fixedly connected with the bottom.

In an alternative embodiment, the lamp cover is a high temperature resistant plastic material.

In an optional embodiment, a fixing cap is further arranged at the position of the second air outlet;

the second annular structure comprises a bottom and a bulge, the bottom is embedded into the groove of the fixing cap, and the bulge is embedded into the second opening of the mesh enclosure;

the top end of the groove of the fixing cap is fixedly connected with the mesh enclosure, so that the lamp cover is fixed between the mesh enclosure and the fixing cap, a third opening is formed in the bottom of the groove of the fixing cap, and the third opening is aligned with the first opening.

In an optional embodiment, the top end of the groove is welded with the mesh cover.

In an alternative embodiment, the lamp cover is a high temperature resistant glass material.

In an alternative embodiment, the inner barrel is an insulating material.

The beneficial effects brought by the technical scheme provided by the embodiment of the disclosure at least comprise:

set up state display lamp and lamp lid through the outlet side at ion airflow channel, the operating condition that can instruct ion generator through the light of the state display lamp of lamp lid, consequently solved the problem that the operating condition of ion hair-dryer among the correlation technique can't show ion generator directly perceivedly, improved ion hair-dryer's use convenience.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present disclosure, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present disclosure, and it is obvious for those skilled in the art to obtain other drawings based on the drawings without creative efforts.

Fig. 1 is a schematic structural view of an ion blower provided in the related art;

fig. 2 is a schematic structural diagram of an ion blower provided in an exemplary embodiment of the present disclosure;

fig. 3 is a schematic structural diagram of an ion blower provided in an exemplary embodiment of the present disclosure;

FIG. 4 is a schematic view of a status indicator light as provided by an exemplary embodiment of the present disclosure;

fig. 5 is a diagram illustrating an effect of fixing a lamp cover and a mesh enclosure according to an exemplary embodiment of the present disclosure;

FIG. 6 is a schematic diagram of a lamp cover provided in an exemplary embodiment of the present disclosure;

FIG. 7 is a schematic diagram of a lamp cover provided in an exemplary embodiment of the present disclosure;

FIG. 8 is a schematic structural view of an inner barrel provided in accordance with an exemplary embodiment of the present disclosure;

fig. 9 is a diagram illustrating an effect of fixing and connecting a lamp cover and a mesh enclosure according to an exemplary embodiment of the present disclosure.

Detailed Description

To make the objects, technical solutions and advantages of the present disclosure more apparent, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings.

Referring to fig. 1, a schematic diagram of an ion blower provided in the related art is shown. As shown in fig. 1, the related art provides an ion blower 100 including a first housing 110, a second housing 120, an ion emitter 130, a fan assembly 140, and an electric heating element 150.

The second housing 120 is disposed in the main chamber 101 in the first housing 110, an inner chamber in the second housing 120 is the main air duct 102, and a secondary air duct 103 is disposed between an inner wall of the first housing 110 and an outer wall of the second housing 120. The main chamber 101 has a main air inlet 1011 and a main air outlet 1012 on both sides thereof, the main air duct 102 has an inner air inlet 1021 and an inner air outlet 1022 on both sides thereof, and the secondary air duct 103 has a secondary air inlet 1031 and a secondary air outlet 1032 on both sides thereof. The plane of the inner outlet 1022 and the plane of the main outlet 1012 have a larger distance d, which is at least larger than the diameter of the inner outlet 1022.

The upper portion of the first housing 110 is provided with an ion airflow channel 104, and two sides of the ion airflow channel 104 are an ion inlet 1041 and an ion outlet 1042, respectively. An ion emitter 130 is disposed in ion gas flow passage 104 and is configured to generate ions when ion blower 100 is in operation. For example, the ions may be negative ions or water ions, or the like. Preferably, the ion blower 100 generates water ions when operating, the water ions are negative ions wrapped by water, and the water ions have a relatively high water content and are not easy to combine with oxygen in the air and disappear. Preferably, the inner cylinder separation structure can ensure that the water ion channel is isolated from the heating wire and ensure the low-temperature working temperature of the water ions.

The electric fan assembly 140 includes a motor 141 and a blade 142 fixedly coupled to a rotation shaft of the motor 141. The electric fan assembly 140 is disposed in the main chamber 101 and configured to rotate the blades 142 by the motor 141 to generate an air flow flowing through the main air inlet 1011, the inner air inlet 1021, the secondary air inlet 1031, the ion air inlet 1041, the ion air outlet 1042, the secondary air outlet 1032, the inner air outlet 1022, and the main air outlet 1012 when the ion blower 100 is in an operating state. When the airflow flows out of the ion outlet 1042, the airflow carries the ions generated by the ion generator 130 to form an ion airflow.

The electric heating element 150 is disposed in the main air duct 102, and configured to heat the air flowing through the inner air inlet 1021 and the inner air outlet 1022 when the ion blower 100 is in a hot air operating state, so as to form a main hot air flow, and the main hot air flow and the air flowing through the secondary air inlet 1031 and the secondary air outlet 1032 converge, so as to form a hot air flow flowing out of the main air outlet 1012.

It is easy to see that the ion blower provided by the user through the related art can not intuitively acquire the working state of the ionizer; meanwhile, the internal structure of the ion blower can be directly exposed outside through the main air outlet, the secondary air outlet and the inner air outlet, and is not beautiful; meanwhile, the ionic air flow and the air flow of the ionic air blower flow out through the independent air channels, the ionic air flow cannot be converged with the air flow blown out from the main air outlet, the static electricity eliminating effect of the ionic air flow is poor due to insufficient wind power, and meanwhile, the volume of the ionic air blower is large due to the fact that an independent ionic air flow channel needs to be arranged.

Referring to fig. 2, a schematic structural diagram of an ion blower according to an exemplary embodiment of the present disclosure is shown. As shown in fig. 2, the ion blower 200 includes an outer tub 210, an inner tub 220, an ionizer 130, a status display lamp 280, a lamp cover 230, and a motor-fan assembly 140.

The inner barrel 220 is disposed in the first chamber 201 within the outer barrel 210. A first air inlet 2011 and a first air outlet 2012 are respectively arranged at two sides of the first chamber 201; an ion airflow channel 202 is formed in the inner barrel 220, and a second air inlet 2021 and a second air outlet 2022 are respectively formed at two sides of the ion airflow channel 202. The ion flow path 202 may be provided inside the inner cylinder 220, or between the inner wall of the outer cylinder 210 and the outer wall of the inner cylinder 220.

Optionally, a distance d between a plane where the first outlet 2012 is located and a plane where the second outlet 2022 is located is smaller than the distance threshold. For example, the distance threshold may be a diameter of the second outlet 2022, or, when the second outlet 2022 is rectangular, the distance threshold may be a length of the second outlet 2022, or, when the second outlet 2022 is oval, the distance threshold may be a major axis of the second outlet 2022; alternatively, when the second outlet 2022 is an equilateral triangle, the distance threshold may be a side length of the second outlet 2022.

An ionizer 130 is disposed in the ion airflow path 202 and is configured to generate ions when the ion blower 200 is in an ion wind operating state. The ionizer 130 may be provided inside the inner cylinder 220, or between the inner wall of the outer cylinder 210 and the outer wall of the inner cylinder 220.

A status indicator light 280 is disposed on the outlet side of the ion airflow channel 202 near the second air outlet 2022, and is configured to indicate the operating status of the ionizer 130 by lighting when the ion blower 200 is in the ion wind operating status.

The working state of the ion blower 200 comprises an ion wind working state and an air working state, when the ion blower 200 is in the ion wind working state, the ion generator 130 generates ions, the state display lamp 280 indicates the working state of the ion generator 130, and the second air outlet 2022 of the ion blower 200 blows out an ion airflow; when the ion blower 200 is in the air operation state, the ion generator 130 and the state display lamp 280 are not operated, and the air flow blown out from the second air outlet 2022 of the ion blower 200.

The lamp cover 230 is disposed at the outlet of the ion airflow channel 202, i.e. the position of the second air outlet 2022, the lamp cover 230 is fixedly connected to the inner cylinder 220, and a first opening 231 is disposed at the center thereof, so that the ion airflow can flow out from the opening 241. When the ion blower 200 is in the ion wind operation state, the lamp cover 230 can be penetrated by the light of the state display lamp 280, and the user can observe the operation state of the ion generator 130 by the light penetrating the lamp cover 230.

The electric fan assembly 140 includes a motor 141 and a blade 142 fixedly coupled to a rotation shaft of the motor 141. The electric fan assembly 140 is disposed in the first chamber 201 and configured to generate an air flow entering from the first air inlet 2011 and exiting from the first air outlet 2012 and the second air outlet 2022 when the ion blower 200 is in an operating state.

For example, the ionizer 130, the status indicator light 280 and the electric fan assembly 140 may be electrically connected to the control circuit board of the ion blower 200 through wires, and the control circuit board of the ion blower 200 controls and supplies power to the ionizer 130, the status indicator light 280 and the electric fan assembly 140.

As shown by the arrow in fig. 2, when the ion blower 200 is in an operating state, the motor 141 rotates the vane 142 to generate an air flow, which enters the first chamber 201 from the first air inlet 2011 and enters the ion air flow channel 202 from the second air inlet 2021. The airflow entering the first chamber 201 flows out of the first outlet 2012 after passing through the air passage 203 between the inner wall of the outer tub 210 and the outer wall of the inner tub 220; the airflow entering the ion airflow channel 201 carries the ions generated by the ion generator 130 to form an ion airflow, which flows out from the second outlet 2022, and is blown onto the user after being converged with the air airflow flowing out from the first outlet 2012.

In summary, in the embodiment of the present disclosure, the state indicator lamp and the lamp cover are disposed on the outlet side of the ion airflow channel, and the light passing through the state indicator lamp of the lamp cover can indicate the operating state of the ion generator, so that the problem that the operating state of the ion generator cannot be intuitively displayed by the ion blower in the related art is solved, and the convenience of use of the ion blower is improved.

Optionally, in the embodiment of the present disclosure, the ion generator is disposed in the ion airflow channel in the inner cylinder located in the outer cylinder, so that the ion airflow flowing out of the second air outlet of the inner cylinder and the airflow flowing out of one air outlet of the outer cylinder can be converged, the ion airflow can have greater wind power, and the effect of eliminating static electricity by the ion airflow is improved; meanwhile, because the inner barrel provided with the ion generator is arranged in the outer barrel, an extra air duct for arranging ion airflow is not needed, and the volume of the ion blower is reduced.

Optionally, in the embodiment of the present disclosure, by setting the distance between the plane where the first air outlet is located and the plane where the second air outlet is located to be smaller than the distance threshold, the second air outlet is closer to the user, so that the effect of eliminating static electricity by the ion airflow is improved.

Referring to fig. 3, a schematic structural diagram of an ion blower according to an exemplary embodiment of the present disclosure is shown. As shown in fig. 3, the ion blower 300 includes an outer tub 210, an inner tub 220, an ionizer 130, a status display lamp 280, a lamp cover 230, a mesh cover 240, an electric heating element 250, an air flow guide 260, and an electric fan assembly 140. Wherein the airflow directing mechanism 260 is an optional structure.

The inner barrel 220 is disposed in the first chamber 201 within the outer barrel 210. A first air inlet 2011 and a first air outlet 2012 are respectively arranged at two sides of the first chamber 201; an ion airflow channel 202 is formed in the inner barrel 220, two sides of the ion airflow channel 202 are respectively a second air inlet 2021 and a second air outlet 2022, and optionally, a distance d between a plane where the first air outlet 2012 is located and a plane where the second air outlet 2022 is located is smaller than a distance threshold. For example, the distance threshold may be a diameter of the second outlet 2022, or, when the second outlet 2022 is rectangular, the distance threshold may be a length of the second outlet 2022, or, when the second outlet 2022 is oval, the distance threshold may be a major axis of the second outlet 2022; alternatively, when the second outlet 2022 is an equilateral triangle, the distance threshold may be a side length of the second outlet 2022.

Ionizer 130 is disposed in ion airflow channel 202 and is configured to generate ions when ion blower 300 is in an ion wind operating state.

The electric fan assembly 140 includes a motor 141 and a blade 142 fixedly coupled to a rotation shaft of the motor 141. The fanner assembly 140 is disposed in the first chamber 201 and configured to generate an airflow entering from the first inlet 2011 and exiting from the first outlet 2012 and the second outlet 2022 when the ion blower 300 is in an operating state. Optionally, a portion of the motor 141 is located in the ion gas flow channel 202, and the ion gas flow channel 202 may support the motor 141.

The status indicator lamp 280 is disposed at the outlet side of the ion airflow channel 202, near the second air outlet 2022, and configured to indicate the operating status of the ionizer 130 by a lamp when the ion blower 300 is in the ion wind operating status. Illustratively, an annular protrusion structure is disposed in the ion airflow channel 202 near the second air outlet 2022, and the status indicator light 280 and the printed circuit board on which the status indicator light 280 is disposed may be fixedly connected to the annular protrusion structure.

The working state of the ion blower 300 comprises an ion wind working state and an air working state, when the ion blower 300 is in the ion wind working state, the ion generator 130 generates ions, the state display lamp 280 indicates the working state of the ion generator 130, and the second air outlet 2022 of the ion blower 300 blows out an ion airflow; when the ion blower 300 is in the air operation state, the ion generator 130 and the state display lamp 280 are not operated, and the air flow blown out from the second air outlet 2022 of the ion blower 300 is generated.

The lamp cover 230 is disposed at the second outlet 2022, the lamp cover 230 is fixedly connected to the inner barrel 220, and a first opening 231 is disposed at the center thereof for allowing the ion airflow to flow out from the opening 241. When the ion blower 300 is in the ion wind operation state, the lamp cover 230 can be penetrated by the light of the state display lamp 280, and the user can observe the operation state of the ion generator 130 by the light penetrating the lamp cover 230. Illustratively, the light of the status display lamp 280 is displayed from bright to dark and then from dark to bright, and the display effect of the status display lamp 280 observed by the user through the lamp cover 230 is a breathing effect. If the work state of the ionizer 130 is normal, the time interval from light to dark and from dark to light is longer; if the ion generator 130 is not in normal operation, the time interval from light to dark and from dark to light is short, so as to prompt the user that the ion generator 130 is in abnormal operation.

The mesh enclosure 240 is disposed at the position of the first outlet 2012, the mesh enclosure 240 is annular and has a second opening, an outer diameter of the mesh enclosure 240 is substantially the same as a radius of the first outlet 2012, an inner diameter of the mesh enclosure 240 is substantially the same as an outer diameter of the lamp cover 230, the lamp cover 230 is embedded in the second opening, and the lamp cover 230 is fixedly connected to the mesh enclosure 240.

The electric heating element 250 is disposed in the air passage 203 between the outer wall of the inner tub 220 and the inner wall of the outer tub 210. The operation state of ion blower 300 further includes a cool air operation state and a hot air operation state, and when ion blower 300 is in the hot air operation state, electric heating element 250 heats the air flow passing through air passage 203. Optionally, the inner barrel 220 is made of a heat insulating material. Since the ionizer 130 works poorly in a high temperature environment, it is necessary to set the material of the inner tube 220 as a heat insulating material, so that the inner tube 220 can insulate the heat generated by the electric heating element 250 when the ion blower 300 is in a hot air working state.

The ion blower 300 may be in an ion wind operation state and a cold wind operation state, or an ion wind operation state and a hot wind operation state, or an air operation state and a cold wind operation state, or an air operation state and a hot wind operation state.

Optionally, the airflow guiding mechanism 260 is disposed at the first outlet 2012, the airflow guiding mechanism 260 is fixedly connected to the outer barrel 210, and a collected airflow channel 204 is formed inside the airflow guiding mechanism 260, and the collected airflow channel 204 is configured to guide and collect the airflow flowing out of the first outlet 2012 and the ion airflow flowing out of the second outlet 2022.

Optionally, the airflow guiding mechanism 260 is engaged with the outer barrel 210 at the position of the first outlet 2012, and the airflow guiding mechanism 260 is detachable from the ion blower 300.

For example, the ionizer 130, the electric fan assembly 140, the status display lamp 280 and the electric heating element 250 may be electrically connected to a control circuit board of the ion blower 300 through wires, and the control circuit board of the ion blower 300 controls and supplies power to the ionizer 130, the electric fan assembly 140, the status display lamp 280 and the electric heating element 250.

As shown by the arrow in fig. 3, when the ion blower 300 is in the cool air operation state, the motor 141 rotates the blade 142 to generate an air flow, which enters the first chamber 201 from the first air inlet 2011 and enters the ion air flow channel 202 from the second air inlet 2021. The airflow entering the first chamber 201 flows out of the first outlet 2012 after passing through the air passage 203 between the inner wall of the outer tub 210 and the outer wall of the inner tub 220; the airflow entering the ion airflow channel 201 carries the ions generated by the ion generator 130 to form an ion airflow, which flows out from the second outlet 2022, and is collected with the air airflow flowing out from the first outlet 2012 and blown onto the user. When the ion blower 300 is equipped with the airflow guide mechanism 260, the ion airflow and the air airflow are collected in the collected airflow passage 204 and then blown onto the user by being guided by the collected airflow passage 204.

When the ion blower 300 is in the hot air operation state, the motor 141 rotates the vane 142 to generate an air flow, and the air flow enters the first chamber 201 from the first air inlet 2011 and enters the ion air flow channel 202 from the second air inlet 2021. After the airflow entering the first chamber 201 passes through the air channel 203 between the inner wall of the outer barrel 210 and the outer wall of the inner barrel 220, the airflow is heated by the electric heating element 250 to form a hot air airflow, and the hot air airflow flows out of the first air outlet 2012; the airflow entering the ion airflow channel 201 carries the ions generated by the ion generator 130 to form an ion airflow, which flows out from the second outlet 2022, and is collected with the hot air airflow flowing out from the first outlet 2012 and blown onto the user. When the ion blower 300 is equipped with the airflow guide mechanism 260, the ion airflow and the hot air airflow are collected in the collected airflow passage 204 and then blown onto the user through the guidance of the collected airflow passage 204.

Optionally, in the embodiment of the present disclosure, the mesh enclosure is disposed at the position of the first air outlet, so that impurities in the air flow can be filtered, and the wind power of the ion blower is improved.

Optionally, in the embodiment of the present disclosure, the material of the inner cylinder is set as the heat insulating material, so that the problem that the heat generated by the electric heating element affects the operation of the ion generator when the ion blower is in a hot air operation state is solved, and the operation effect of the ion generator is improved.

Optionally, in the embodiment of the present disclosure, the airflow guide mechanism is disposed at the position of the first air outlet, so that the ionic airflow and the air airflow can concentrate wind power, and on the basis of improving the concentration degree of the ionic airflow and the air airflow, the wind power and the accuracy of the ionic hair dryer are improved.

In the above embodiment, the lamp cover 230 can be fixed to the inner cylinder 220 in two ways.

As shown in fig. 4, the lamp cover 230 includes a bottom 232 and a protrusion 233, a fixing cap 270 is disposed at a position where the air outlet 2022 of the inner cylinder 220 is located, and a third opening 271 is disposed at a bottom of the fixing cap 270.

The radius of the bottom 232 is substantially the same as the radius of the groove 272 of the locking cap 270, and the bottom 232 is fitted into the groove 272; the radius of the protrusion 233 is substantially the same as the radius of the third opening 241 of the mesh enclosure 240, the protrusion 233 is inserted into the third opening 241, the top end 272 of the fixing cap 270 is fixedly connected with the mesh enclosure 240, so that the lamp cover 230 is fixed between the mesh enclosure 240 and the fixing cap 270, the bottom of the groove 272 of the fixing cap 270 is provided with a third opening 271, and the third opening 271 is aligned with the first opening 231. Optionally, the top end 272 of the fixing cap 270 is welded to the mesh cover 240.

The lamp cover 230 and the mesh enclosure 240 are installed in the following manner: the bottom 232 of the lamp cap 230 is first fixed in the groove 272 of the fixing cap 270, and then the second opening 241 of the mesh cap 240 is fitted to the periphery of the projection 233 of the lamp cap 230, and the mesh cap 240 is fixed to the top of the groove 272 by welding, such as spot welding, to firmly fix the lamp cap 230 between the mesh cap 240 and the fixing cap 270. The fixing effect of the lamp cover 230 and the mesh enclosure 240 is as shown in fig. 5, the bottom 232 of the lamp cover 230 is embedded into the fixing cap 270, and the fixing cap 270 is fixedly connected with the mesh enclosure 240, so that the lamp cover 230 is fixed between the fixing cap 270 and the mesh enclosure 240.

As shown in fig. 6, the lamp cover 230 includes a first annular structure 234 and a second annular structure 235, wherein the second annular structure 235 is the other part of the lamp cover 230 except the first annular structure 234, and the first opening 231 is disposed at the center of the first annular structure 234. The first annular structure 234 is a transparent structure and the second annular structure 235 is an opaque structure. Wherein the second annular structure 235 includes a bottom 232 and a protrusion 233.

Alternatively, the first and second

annular structures

234 and 235 may be provided as a transparent unitary structure, with the first annular structure 234 being printed using a translucent ink and the second annular structure 235 being printed using an opaque ink. Since the first annular structure 234 is a transparent structure and the second annular structure 235 is an opaque structure, it is difficult for a user to view the internal structure of the inner barrel 220 through the second annular structure 235 while ensuring that the light of the status display lamp 280 can penetrate out of the first annular structure 234.

Alternatively, the lamp cover 230 is made of a high temperature resistant glass material, so that the lamp cover 230 can operate in a hot wind state of the

ion blower

200 or 300.

As shown in fig. 7, the lamp cover 230 includes a first annular structure 234 and a second annular structure 235, the second annular structure 235 is provided with a latch 236, the lamp cover 230 can be latched with the inner cylinder 220 through the latch 236, and the inner cylinder 220 corresponding to the lamp cover 230 has a structure as shown in fig. 8, the latch 236 can be latched with the slot 226 of the inner cylinder 220, so as to latch the lamp cover 230 with the inner cylinder 220.

As shown in fig. 9, the second annular structure includes a protrusion 233 and a bottom (not shown), the radius of the protrusion 233 is substantially the same as the radius of the second opening (i.e. the opening into which the protrusion 233 is inserted, not shown) of the mesh enclosure 240, and the protrusion 233 is inserted into the second opening so that the lamp cover 230 can fix the bottom 232 and the mesh enclosure 240 via the protrusion 233.

Optionally, the first annular structure 234 and the second annular structure 235 are not a unitary structure, the first annular structure 234 is a transparent material or a translucent material, the second annular structure 235 is provided as an opaque material, and the first annular structure 234 and the second annular structure 235 are stamped to form the lamp cover 230. Since the first annular structure 234 is a transparent material and the second annular structure 235 is an opaque material, it is difficult for a user to view the internal structure of the inner barrel 220 through the second annular structure 235 while ensuring that the light of the status indicator light 280 can penetrate out of the first annular structure 234.

Optionally, the lamp cover 230 is made of a high temperature resistant plastic material, so that the lamp cover 230 can operate in a hot air state of the

ion blower

200 or 300 on the basis of ensuring that the lamp cover 230 can be clamped with the inner barrel 220 by arranging the clamp 236.

It should be understood that reference to "a plurality" herein means two or more. "and/or" describes the association relationship of the associated objects, meaning that there may be three relationships, e.g., a and/or B, which may mean: a exists alone, A and B exist simultaneously, and B exists alone. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship.

The above-mentioned serial numbers of the embodiments of the present disclosure are merely for description and do not represent the merits of the embodiments.

It will be understood by those skilled in the art that all or part of the steps for implementing the above embodiments may be implemented by hardware, or may be implemented by a program instructing relevant hardware, where the program may be stored in a computer-readable storage medium, and the above-mentioned storage medium may be a read-only memory, a magnetic disk or an optical disk, etc.

The above description is only exemplary of the present disclosure and is not intended to limit the present disclosure, so that any modification, equivalent replacement, or improvement made within the spirit and principle of the present disclosure should be included in the scope of the present disclosure.

Claims

1. An ion blower is characterized by comprising an outer barrel and an ion generator;

an ion airflow channel is arranged in the outer barrel, the ion generator is arranged in the ion airflow channel, a state display lamp and a lamp cover are arranged on the outlet side of the ion airflow channel, the lamp cover is provided with a first opening, and the first opening is used for enabling airflow flowing through the ion airflow channel to flow out;

2. The ionic blower of claim 1, further comprising an inner barrel and an electric fan assembly;

3. The ionic blower of claim 2, wherein said light cover includes a first annular structure having said first aperture and a second annular structure, said first annular structure being a transparent or translucent structure and said second annular structure being an opaque structure.

4. The ion blower of claim 3, wherein a mesh enclosure is further disposed at the first air outlet, and the mesh enclosure is fixedly connected to the second annular structure of the lamp cover.

5. The ion blower of claim 4, wherein the second annular structure comprises a bottom and a protrusion, the bottom is provided with a buckle, the lamp cover is clamped with the inner barrel through the buckle, the protrusion is embedded into the second opening of the mesh enclosure, and the mesh enclosure is fixedly connected with the bottom.

6. The ionic blower of claim 4 or claim 5, wherein said light cover is a high temperature resistant plastic material.

7. The ionic hair dryer as claimed in claim 3, wherein a fixing cap is further arranged at the position of the second air outlet;

8. The ionic blower of claim 7, wherein the top of said recess is welded to said mesh enclosure.

9. The ionic blower of claim 7 or 8, wherein said lamp cover is a high temperature resistant glass material.

10. The ionic blower of any one of claims 1 to 8, wherein said inner barrel is a thermally insulating material.