CN214830645U - Earphone box coating equipment - Google Patents

Abstract

A headphone box coating device comprises a non-coating part, a part to be coated and an opening part. The earphone box coating equipment comprises a coating equipment main body with a coating cavity and one or more coating shielding jigs. The one or more film coating shielding jigs are arranged in the film coating cavity of the film coating equipment main body, and each film coating shielding jig comprises a shielding cover and a shielding sleeve, wherein the shielding cover is suitable for being covered outside the non-film coating part of the earphone box; the shielding sleeve is suitable for being sleeved at the opening part of the earphone box, and the shielding sleeve can be hermetically jointed with the shielding cover, wherein when the shielding cover is jointed with the shielding sleeve, the coating shielding jig is used for hermetically shielding the non-coating part of the earphone box and openly exposing the part to be coated of the earphone box.

Description

Earphone box coating equipment

Technical Field

The utility model relates to a wireless headset technical field especially relates to an earphone box coating equipment.

Background

With the development of electronic technology, electronic devices such as mobile phones or earphones have been developed to meet the use requirements of users and improve the quality of life of users. The earphone is originally used for telephone and radio as a conversion unit, but with the prevalence of portable electronic devices, the earphone is also used for mobile phones, walkmans, radios or audio players. Although wireless headsets (such as bluetooth headsets or infrared headsets) are still new things in terms of development process of the whole headset industry, the development time is not long, but at present, the wireless headsets are still in an ascending period, and the demand and the expected value of users are continuously improved, especially the cruising ability of the wireless headsets.

As is well known, in consideration of ergonomic design after entering the ear, most wireless headsets (such as TWS headsets) need to be small and exquisite to meet the requirement of entering the ear or half entering the ear, which makes it difficult to make the battery capacity configured in the existing wireless headset itself large, and further results in short endurance time of the wireless headset and brings bad experience to users. In order to alleviate or solve the pain, before the battery technology breaks through, the only feasible solution seems to be an article only in charging, for example, a charging cabin is configured for an earphone box, so that after a user takes off the wireless earphone and puts in the earphone box, the earphone box charges the wireless earphone, and the wireless earphone can maintain long endurance to some extent, so as to make up the problem of poor endurance of the existing wireless earphone, and improve the use experience of the user.

However, the earphone box is used as an inseparable partner of the wireless earphone, and the user usually needs to carry the earphone box with him/her to store or charge the removed wireless earphone at any time. And in order to make this earphone box can charge for wireless earphone, thereby must set up various electronic components in this earphone box's the cabin that charges and so as to can contact this wireless earphone with the circular telegram and be used for charging for wireless earphone, but these electronic components receive water stain, sweat stain and greasy dirt etc. pollution easily, and this working property and the life that just makes current earphone box are difficult to satisfy the demand in current market.

SUMMERY OF THE UTILITY MODEL

An advantage of the utility model is that a headphone case coating equipment is provided, it can be guaranteed right the inside electronic components of headphone case carries out the coating film protection.

Another advantage of the present invention is to provide a coating apparatus for earphone box, which can ensure that the casing of earphone box does not generate color difference due to coating.

Another advantage of the present invention is to provide a coating apparatus for an earphone box, wherein, in an embodiment of the present application, the coating shielding jig can shield the non-coating portion of the earphone box, and only expose the coating portion of the earphone box to be coated, so that only the coating portion of the earphone box to be coated is precisely coated for protection, and the original characteristic of the non-coating portion of the earphone box is not affected.

Another advantage of the present invention is to provide a headphone case coating apparatus, wherein, in an embodiment of the present application, the coating film covers the jig without scratching under the condition of the headphone case, tightly covers the non-coating film portion of the headphone case, so as to avoid the non-coating film portion of the headphone case is permeated with the film, which helps to ensure the original appearance effect of the headphone case.

Another advantage of the present invention is to provide a plating apparatus for an earphone box, wherein, in an embodiment of the present application, the profiling structure of the plating shielding jig can be used to ensure the optimal shielding protection effect, so as to prevent the problems of film infiltration during plating.

Another advantage of the present invention is to provide a headphone case coating apparatus, wherein, in an embodiment of the present application, the coating film shields the jig and enables the headphone case coating apparatus to be only the headphone case to treat the coating film part for coating film, not only can accomplish under the condition that does not occupy the structural space of the electronic product, effectively prevent infiltration such as water, sweat stain, greasy dirt, but also can avoid the non-coating film part of the headphone case takes place to ooze the membrane.

Another advantage of the present invention is to provide an earphone box coating apparatus, wherein, in an embodiment of the present invention, the coating film shielding jig can make the earphone box coating apparatus is right the earphone box is precisely coated with a film, so as to improve when the protection precision of the earphone box is improved, the earphone box can be ensured to have a good appearance effect.

Another advantage of the present invention is to provide a coating apparatus for earphone box, wherein, in an embodiment of the present invention, the coating shielding jig can conveniently shield the non-coating portion of earphone box, so as to perform coating protection on a large number of earphone boxes, which helps to satisfy the requirement of industrial mass production and reduce the protection cost.

Another advantage of the present invention is to provide a coating apparatus for an earphone box, wherein, in order to achieve the above object, the earphone box does not need to use expensive materials or complex structures. Therefore, the utility model discloses successfully and provide a solution effectively, not only provide simple earphone box coating film equipment, still increased simultaneously earphone box coating film equipment's practicality and reliability.

In order to realize above-mentioned at least advantage or other advantages and purpose, the utility model provides an earphone box coating equipment for carry out the coating film to the earphone box, wherein this earphone box includes an non-coating film part, a coating film part and an opening, wherein earphone box coating equipment includes:

the coating equipment comprises a coating equipment main body, a coating device and a control device, wherein the coating equipment main body is provided with a coating chamber; and

one or more coating shielding jigs, wherein the one or more coating shielding jigs are arranged in the coating chamber of the coating apparatus main body, and each of the coating shielding jigs includes:

the shielding cover is suitable for being covered outside the non-film-coated part of the earphone box; and

the shielding sleeve is suitable for being sleeved at the opening part of the earphone box and can be hermetically connected with the shielding cover, and when the shielding cover is connected with the shielding sleeve, the film-coated shielding jig is used for hermetically shielding the non-film-coated part of the earphone box and openly exposing the part to be coated of the earphone box.

According to one embodiment of the present application, the shielding sleeve comprises a hard shell and a soft lining, wherein the hard shell is provided with at least one plated through hole and an annular sleeve groove arranged around the plated through hole; the soft lining layer is arranged in the annular sleeve groove of the hard shell, when the shielding sleeve is sleeved at the opening part of the earphone box through the annular sleeve groove of the hard shell, the soft lining layer hermetically fills a gap between the hard shell and the earphone box, and the at least one coating through hole of the hard shell is used for communicating with the part to be coated of the earphone box so as to expose the part to be coated of the earphone box in an open manner through the at least one coating through hole of the hard shell.

According to an embodiment of the present application, the plated through hole of the hard case is chamfered to form a bell mouth structure.

According to an embodiment of the present application, the soft liner has a profiling structure for matching the opening of the earphone box.

According to an embodiment of the present application, the hard case includes an annular top wall, an annular inner wall extending downward from an inner periphery of the annular top wall, and an annular outer wall extending downward from an outer periphery of the annular top wall, wherein an inner surface of the annular inner wall defines the plated through hole of the hard case, and the annular inner wall and the annular outer wall are spaced apart from each other to define the annular groove of the hard case together by an outer surface of the annular inner wall and an inner surface of the annular outer wall.

According to an embodiment of the present application, the shielding cover comprises an air bag and an elastic ring disposed at the mouth of the air bag, wherein the air bag of the shielding cover is adapted to wrap the shell of the earphone box, and the elastic ring of the shielding cover is flexibly sleeved on the hard shell of the shielding cover.

According to an embodiment of the present application, the hard shell of the shielding sleeve further comprises one or more anti-slip members, wherein the anti-slip members are disposed on the annular outer wall for blocking the elastic ring from slipping off the annular outer wall.

According to an embodiment of the application, the natural length of the elastic ring of the screening cap is smaller than the outer circumference of the annular outer wall of the hard shell, and the anti-slip means is embodied as a protrusion extending outwardly from the outer surface of the annular outer wall of the hard shell.

According to an embodiment of the application, the protrusion extends annularly along the outer circumference of the annular outer wall to form a loop around the annular pocket of the hard shell.

According to an embodiment of the present disclosure, the coating apparatus main body further includes a rotating frame, an air supply and exhaust system, and one or more excitation systems, wherein the rotating frame is rotatably disposed in the coating chamber of the coating apparatus main body for placing a plurality of earphone boxes shielded by the coating shielding jig; the gas supply and exhaust system is in communicated connection with the coating chamber and is used for supplying gas inwards to supply chemical monomer gas to the coating chamber while exhausting gas outwards to form a preset vacuum degree in the coating chamber; the excitation system is used for generating an excitation electromagnetic field in the coating chamber to ionize the chemical monomer gas to form plasma, so that the plasma is deposited on the part to be coated of the earphone box to form a uniform film layer.

According to an embodiment of the present application, the rotating frame includes one or more planetary shelves revolving around a rotation axis, wherein each of the planetary shelves includes a rotation axis and one or more stages rotating around the rotation axis, and a plurality of the coating shielding jigs are annularly arranged on the stages around the rotation axis of the planetary shelves.

According to an embodiment of the application, the coating through holes of the hard shell in the coating shielding jig are arranged outwards along the radial direction of the rotation shaft of the planet carrier.

According to an embodiment of the application, the coating film shields the tool and is fixed to through the mode of bonding or draw-in groove screens the planet supporter put on the thing platform.

Further objects and advantages of the invention will be fully apparent from the ensuing description and drawings.

These and other objects, features and advantages of the present invention will become more fully apparent from the following detailed description, the accompanying drawings and the appended claims.

Drawings

Fig. 1 is a schematic perspective view of a coating shielding jig according to an embodiment of the present application.

Fig. 2 shows an exploded view of the coating shielding jig according to the above embodiment of the present application.

Fig. 3A and 3B illustrate an exploded view of the shielding sleeve of the plating shielding jig according to the above-described embodiment of the present application.

Fig. 4A and 4B respectively show schematic cross-sectional views of the plating masking jig according to the above-described embodiment of the present application.

Fig. 5 shows a first flow diagram of the method of manufacturing the shading sleeve according to the above-described embodiment of the present application.

Fig. 6 shows a second flow diagram of the method of manufacturing the shading sleeve according to the above-described embodiment of the present application.

Fig. 7 shows a third schematic flow chart of the manufacturing method of the shielding sleeve according to the above-described embodiment of the present application.

Fig. 8 is a block diagram of an earphone box coating apparatus according to an embodiment of the present application.

Fig. 9 shows an example of the earphone box coating apparatus according to the above-mentioned embodiment of the present application.

Fig. 10 is a schematic layout diagram of a film coating shielding jig in the earphone box film coating apparatus according to the above embodiment of the present application.

Fig. 11 is a flowchart illustrating a method for shielding an earphone box according to an embodiment of the present application.

Fig. 12 shows an example of masking the earphone box using the coating masking jig.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in a generic and descriptive sense only and not for purposes of limitation, as the terms are used in the description to indicate that the referenced device or element must have the specified orientation, be constructed and operated in the specified orientation, and not for the purposes of limitation.

In the present application, the terms "a" and "an" in the claims and the description should be understood as meaning "one or more", that is, one element or a plurality of elements may be included in one embodiment or a plurality of elements may be included in another embodiment. The terms "a" and "an" and "the" and similar referents are to be construed to mean that the elements are limited to only one element or group, unless otherwise indicated in the disclosure.

In the description of the present invention, it is to be understood that the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, it should be noted that, unless explicitly stated or limited otherwise, the terms "connected" and "connected" should be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Referring to fig. 1 to 4B of the drawings, a film coating shielding jig according to an embodiment of the present invention is illustrated, wherein the film coating shielding jig 1 is used for shielding an earphone box 40, and the earphone box 40 includes an un-coated portion 401, a portion to be coated 402 and an opening 403. Specifically, the film-coated shielding jig 1 may comprise a shielding cover 10 and a shielding sleeve 20, wherein the shielding cover 10 is adapted to be covered outside the non-film-coated portion 401 of the earphone box 40, wherein the shielding sleeve 20 is adapted to be covered on the opening 403 of the earphone box 40, and the shielding sleeve 20 is sealably coupled to the shielding cover 10 to isolate the non-film-coated portion 401 and the to-be-coated portion 402 of the earphone box 40 from each other.

More specifically, as shown in fig. 3A to 4B, the shielding sleeve 20 of the film coating shielding jig 1 may include a hard case 21 and a soft liner 22, wherein the hard case 21 has at least one film coating through hole 2101 and an annular sleeve groove 2102 extending around the at least one film coating through hole 2101; wherein the soft lining layer 22 is disposed inside the annular groove 2102 of the hard case 21, wherein when the shielding sleeve 20 is sleeved in the opening 403 of the earphone box 40 through the annular groove 2102 of the hard case 21, the soft lining layer 22 hermetically fills a gap between the hard case 21 and the earphone box 40, and the at least one coating through hole 2101 of the hard case 21 is used for communicating with the to-be-coated portion 402 of the earphone box 40; accordingly, when the shielding cover 10 is coupled to the shielding cover 20, the film-coated shielding jig 1 is used for hermetically shielding the non-film-coated portion 401 of the earphone box 40, and the film-coated shielding jig 1 is used for exposing the to-be-coated portion 402 of the earphone box 40 through the at least one film-coated through hole 2101 of the hard case 21.

It is worth noting that, this application the coating film shields tool 1 shield cover 20 hard shell 21's material hardness is greater than soft lining 22's material hardness, so that pass through soft lining 22 plays better sealed and prevent the fish tail effect when, the coating film shields tool 1 can pass through hard shell 21 provides better support, in order to make things convenient for the dismouting shield cover 20 extremely earphone box 40 not only helps improving dismouting efficiency, but also is convenient for use repeatedly shield cover 20, with the manufacturing cost who reduces the tool.

In addition, when the earphone box 40 shielded by the film-coating shielding jig 1 is coated by, for example, a nano-coating technique, the portion 402 to be coated of the earphone box 40 is coated with a film by being openly exposed to form a protective film layer for water resistance, sweat resistance, and oil resistance. Meanwhile, the non-coated part 401 of the earphone box 40 is shielded in a sealed manner and is not coated, so that the problem that the non-coated part 401 of the earphone box 40 has different colors and the like is solved, and the requirement of a user for pursuing extremely attractive appearance or decoration effect is met.

For example, as shown in fig. 2, a semi-finished earphone box of a wireless earphone is taken as the earphone box 40, and the earphone box 40 may include a charging cabin 41 configured with electronic components 410 and a housing 42 disposed outside the charging cabin 41. That is, the earphone box 40 of the present invention is a semi-finished earphone box that does not seal the charging chamber and exposes the electronic component 410. It can be understood that the electronic component 410 in the charging chamber 41 of the earphone box 40 needs to be used as the portion to be plated 402 of the earphone box 40 to be plated with a protective film layer, because the electronic component is easily contaminated by water stain, sweat stain, oil stain, and the like; the outer surface of the outer shell 42 of the earphone box 40 is used as the non-plated part 401 of the earphone box 40 to prevent the problem of color difference caused by plating because the outer surface needs to maintain the original beauty.

It should be noted that, although the present application takes a semi-finished earphone box of a wireless earphone as an example to illustrate the advantages and features of the film-coating shielding fixture 1, it is only an example and does not limit the scope of protection of the present application. For example, in other examples of the present application, the earphone box 40 may also be implemented as a box for containing other electronic devices.

In particular, in an application scenario of a semi-finished earphone box of a wireless earphone, the casing 42 of the earphone box 40 may have a containing space 421 and an opening 422, wherein the opening 422 of the casing 42 communicates the containing space 421 of the casing 42 with an external space of the casing 42, and the charging chamber 41 is contained in the containing space 421 of the casing 42, so as to expose the electronic component 410 of the charging chamber 41 through the opening 422 of the casing 42.

It is understood that the portion of the earphone box 40 corresponding to the opening 422 of the housing 42 is implemented as the opening 403 of the earphone box 40, for example, the top of the housing 42 as shown in fig. 2. In this way, when the shielding sleeve 20 of the film-coating shielding jig 1 is sleeved on the opening 403 of the earphone box 40, and the shielding cover 10 is coupled to the shielding sleeve 20 after being covered on the housing 42 of the earphone box 40, the outer surface of the housing 42 of the earphone box 40 is hermetically shielded by the film-coating shielding jig 1 to serve as the non-film-coating portion 401 of the earphone box 40, and the electronic component 410 in the charging cabin 41 of the earphone box 40 is not shielded by the film-coating shielding jig 1 to serve as the to-be-film-coating portion 402 of the earphone box 40.

It should be noted that, according to the above-mentioned embodiment of the present application, the hard shell 21 of the shielding sleeve 20 of the coating shielding jig 1 may be, but is not limited to be, made of hard plastic, and the soft lining 22 of the shielding sleeve 20 may be, but is not limited to be, made of soft rubber material. For example. The hard plastic of the present application may be, but is not limited to, implemented as ABS resin, PC (polycarbonate), or PVC (polyvinyl chloride), etc., and the soft plastic material may be, but is not limited to, implemented as TPU (thermoplastic polyurethane elastomer rubber), or TPR (thermoplastic elastomer), etc.

Preferably, the coating through hole 2101 of the hard case 21 of the shielding sleeve 20 is chamfered to form a bell mouth structure, so as to prevent the shielding sleeve 20 from shielding the charging compartment 41 of the earphone box 40, which helps to promote the circulation of coating materials.

More preferably, as shown in fig. 3A and 3B, the hard case 21 of the shielding sleeve 20 may include an annular top wall 211, an annular inner wall 212 extending downward from an inner periphery of the annular top wall 211, and an annular outer wall 213 extending downward from an outer periphery of the annular top wall 211, wherein an inner surface of the annular inner wall 212 defines the plated through hole 2101 of the hard case 21, and the annular inner wall 212 and the annular outer wall 213 are spaced apart from each other to define the annular sleeve groove 2102 of the hard case 21 by an outer surface of the annular inner wall 212 and an inner surface of the annular outer wall 213.

According to the above-mentioned embodiments of the present application, the shielding cover 10 of the filming shielding jig 1 is preferably made of an elastic material, for example, the elastic material of the shielding cover 10 may be, but is not limited to be, implemented by latex, rubber, plastic or aluminum foil.

Preferably, as shown in fig. 4A and 4B, the shielding cover 10 of the film-coated shielding jig 1 may be, but not limited to, implemented as an air ball, and as shown in fig. 4A and 4B, the shielding cover 10 may include an air bag 11 and an elastic ring 12 disposed at a mouth of the air bag 11, wherein the air bag 11 of the shielding cover 10 is adapted to wrap the outer shell 42 of the earphone box 40, and the elastic ring 12 of the shielding cover 10 is captively sleeved on the hard shell 21 of the shielding cover 20 to sealingly connect the shielding cover 10 and the shielding cover 20, so that the air bag 11 of the shielding cover 10 is sealingly wrapped on an outer surface of the outer shell 42 of the earphone box 40. It will be appreciated that in other examples of the present application, the shield 10 may also be sealably connected to the shield sleeve 20, such as by strapping or the like. It is noted that the elastic ring 12 of the shield 10 is preferably implemented as a rubber ring.

More preferably, the natural length of the elastic ring 12 of the shielding cover 10 is smaller than the outer circumference of the annular outer wall 213 of the hard case 21 of the shielding sleeve 20, so that the elastic ring 12 of the shielding cover 10 can tightly bind to the outer surface of the annular outer wall 213 of the hard case 21 by its elastic deformation, thereby hermetically connecting the shielding cover 10 and the shielding sleeve 20.

It should be noted that, as shown in fig. 2 to 4B, the hard case 21 of the shielding sleeve 20 of the filming shielding jig 1 of the present application may further include one or more anti-dropping elements 214, wherein the anti-dropping elements 214 are disposed on the annular outer wall 213 to prevent the shielding cover 10 from being unintentionally or accidentally dropped from the hard case 21 of the shielding sleeve 20.

Specifically, the anti-slip part 214 of the hard case 21 may be, but is not limited to, implemented as a protrusion 2140 extending outward from the outer surface of the annular outer wall 213 of the hard case 21, for blocking the elastic ring 12 of the shield cover 10 from sliding on the outer surface of the annular outer wall 213, so as to prevent the elastic ring 12 of the shield cover 10 from sliding off the annular outer wall 213 of the hard case 21.

Preferably, the protrusion 2140 extends annularly along the outer circumference of the annular outer wall 213 to form a ring buckle 2141 surrounding the annular groove 2102 of the hard case 21, so as to enhance the sealing performance of the connection between the shield cover 10 and the shield sleeve 20 while preventing the elastic ring 12 of the shield cover 10 from slipping off.

Exemplarily, in an example of the present application, as shown in fig. 3A to 4B, the one or more anti-release members 214 of the hard case 21 of the shield cover 20 may be implemented as three anti-release members 214, wherein three anti-release members 214 are arranged at intervals on the outer surface of the annular outer wall 213 to form an annular groove 2142 between adjacent two anti-release members 214, so that the elastic ring 12 of the shield cover 10 can be buckled in the annular groove 2142, which helps to further enhance the coupling strength and sealing performance between the shield cover 10 and the shield cover 20.

Of course, in other examples of the present application, the anti-slip part 214 of the hard shell 21 of the shielding sleeve 20 may also be implemented as a groove recessed inwards from the outer surface of the annular outer wall 213 of the hard shell 21 for accommodating the elastic ring 12 of the shielding cover 10, and still function to prevent the elastic ring 12 of the shielding cover 10 from slipping off the annular outer wall 213 of the hard shell 21.

It should be noted that, as shown in fig. 2 to fig. 4B, the electronic component 410 in the charging compartment 41 of the earphone box 40 generally includes a flexible circuit board 411 (such as a flexible board, etc.), and the flexible circuit board 411 generally has a plurality of connection sites 4110 thereon for electrically connecting with a wireless earphone to charge the wireless earphone, and the connection sites 4110 on the flexible circuit board 411 also need to be the non-plated portion 401 of the earphone box 40 and cannot be plated with a film. Considering that the length of the flexible circuit board 411 of the charging cabin 41 is longer, the charging cabin 41 can be extended out in general, so the application can fold the flexible circuit board 411 to make the connection point 4110 be outside the housing 42 of the earphone box 40, and further shield the connection point 4110 by the shielding cover 10 of the film-plating shielding jig 1, so as to prevent the connection point 4110 of the flexible circuit board 411 from being plated with a film.

Preferably, the hard case 21 of the shielding case 20 may further include one or more preformed grooves 215, wherein the preformed grooves 215 are disposed on the outer surface of the annular outer wall 213 for accommodating the folded flexible circuit board 411, so that the folded flexible circuit board 411 passes through the anti-falling piece 214 to prevent the folded flexible circuit board 411 from forming a gap between the shielding cover 10 and the shielding case 20 to affect the sealing effect between the shielding cover 10 and the shielding case 20.

More preferably, the protrusion 2140 of the hard case 21 of the shielding sleeve 20 intermittently extends along the outer circumference of the annular outer wall 213 to form the pre-groove 215 on the ring buckle 2141 of the hard case 21, so that the folded flexible circuit board 411 passes through the ring buckle 2141, which helps to ensure a better sealing effect between the shielding cover 10 and the shielding sleeve 20 while shielding the connection site 4110 of the flexible circuit board 411.

It should be noted that, when the preformed groove 215 is not disposed on the hard case 21 of the shielding sleeve 20, the flexible circuit board 411 in the charging compartment 41 of the earphone box 40 of the present application may directly protrude from the plated through hole 2101 of the hard case 21 of the shielding sleeve 20 without being folded; meanwhile, the connection sites 4110 on the flexible circuit board 411 may be shielded by an additional tool or means, such as coating with a sealing cloth, so that the connection sites 4110 on the flexible circuit board 411 are prevented from being coated with a film without being shielded by the film coating shielding jig 1.

It should be noted that the soft liner 22 of the shielding sleeve 20 of the film coating shielding jig 1 of the present application preferably has a profiling structure to match the opening 403 of the earphone box 40, which helps to tightly fill the gap between the opening 403 of the earphone box 40 and the annular groove 2102 of the hard case 21, so as to achieve a better shielding effect.

In addition, the shielding sleeve 20 of the coating shielding jig 1 of the present application can be manufactured by, but not limited to, molding twice and integrally. Illustratively, in the first example of the present application, as shown in fig. 5, the method for manufacturing the shielding sleeve 20 of the plating shielding jig 1 may include the steps of:

s110: molding a rigid plastic to form a rigid housing 21, wherein said rigid housing 21 has at least one plated through hole 2101 and an annular nest 2102 extending around said at least one plated through hole 2101; and

s120: molding a soft rubber material in the annular groove 2102 of the hard shell 21 through a profiling mold to form a soft lining layer 22 with a profiling structure, thereby forming the shielding sleeve 20 suitable for being sleeved at the opening 403 of the earphone box 40.

Of course, in the second example of the present application, as shown in fig. 6, the method for manufacturing the shielding sleeve 20 of the plating shielding jig 1 may also include the steps of:

s210: molding the soft rubber material through a profiling mold to form a soft lining layer 22 with a profiling structure; and

s220: hard plastic is molded on the outer surface of the soft lining layer 22 to form a hard shell 21, wherein the hard shell 21 has at least one plated through hole 2101 and an annular sleeve groove 2102 extending around the at least one plated through hole 2101, and the soft lining layer 22 is located in the annular sleeve groove 2102 of the hard shell 21, so as to form the shielding sleeve 20 suitable for being sleeved in the opening 403 of the earphone box 40.

In addition, in the third example of the present application, as shown in fig. 7, the method for manufacturing the shielding sleeve 20 of the plating shielding jig 1 may further include:

s310: molding a rigid plastic to form a rigid housing 21, wherein said rigid housing 21 has at least one plated through hole 2101 and an annular nest 2102 extending around said at least one plated through hole 2101;

s320: molding the soft rubber material through a profiling mold to form a soft lining layer 22 with a profiling structure; and

s330: the soft lining layer 22 is correspondingly assembled in the annular groove 2102 of the hard case 21 to form the shielding sleeve 20 suitable for being sleeved on the opening 403 of the earphone box 40.

It should be noted that in the step S330 of the manufacturing method of the shielding sleeve 20 of the third example of the present application, the soft underlayer 22 may be fitted into the annular sleeve groove 2102 of the hard shell 21 in a concave-convex manner, so as to enhance the bonding strength between the soft underlayer 22 and the hard shell 21. Of course, in other examples of the present application, the soft underlayer 22 may also be fixed in the annular groove 2102 of the hard shell 21 by means of a contour fit or glue bonding.

It is understood that the above step S310 and the step S320 may not be in a sequential order, that is, the step S310 and the step S320 may be performed simultaneously, or the step S310 may be performed first, and then the step S320 may be performed.

According to another aspect of the present application, as shown in fig. 1 to 10, an embodiment of the present application further provides an earphone box coating apparatus, configured to coat a film on the earphone box 40 shielded by the coating shielding jig 1, so that the to-be-coated portion 402 of the earphone box 40 is coated with a protective film layer to achieve better waterproof or oil-proof effects, and the non-coated portion 401 of the earphone box 40 is not coated with a film due to being shielded by the coating shielding jig 1 to maintain the original appearance.

Specifically, the earphone box coating equipment of this application can be including coating equipment main part 50 and a plurality of that have coating cavity 51 tool 1 is shielded in the coating, wherein is a plurality of tool 1 is shielded in the coating is arranged in coating equipment main part 50 in the coating cavity 51, and is a plurality of tool 1 is shielded in the coating is used for correspondingly shielding a plurality of earphone box 40, with through coating equipment main part 50 is to the via the coating shields the earphone box 40 after tool 1 shields carries out the coating.

For example, as shown in fig. 8, the coating apparatus main body 50 of the earphone box coating apparatus may further include a rotating frame 52, an air supply and exhaust system 53 and one or more excitation systems 54, wherein the rotating frame 52 is rotatably disposed in the coating chamber 51 for placing a plurality of earphone boxes 40 shielded by the coating shielding jig 1; wherein the gas supply and exhaust system 53 is communicably connected to the coating chamber 51 for supplying gas to the coating chamber 51 by supplying gas to the inside while exhausting gas to the outside to form a predetermined degree of vacuum in the coating chamber 51; the excitation system 54 is configured to generate an excitation electromagnetic field in the coating chamber 51 to ionize the chemical monomer gas to form a plasma, so that the plasma is deposited on the to-be-coated portion 402 of the earphone box 40 to form a uniform film layer, thereby completing the coating operation in batch, which is beneficial to meeting the industrial mass production requirement and reducing the protection cost.

Preferably, the excitation systems 54 of the coating apparatus main body 50 are implemented as ICP excitation systems, wherein the ICP excitation systems are respectively and correspondingly disposed at the outer sides of the coating chambers 51, and are used for generating an excitation magnetic field in the coating chambers 51 to ionize the chemical monomer gas to form an inductively coupled plasma, so that the inductively coupled plasma is deposited on the to-be-coated portion 402 of the earphone box 40 to form a uniform film layer.

More preferably, as shown in fig. 9, the rotating frame 52 generally comprises one or more planetary shelves 521 revolving around the rotating shaft, wherein each planetary shelf 521 comprises a revolving shaft and one or more stages, wherein the stages are stacked at intervals on the revolving shaft for revolving around the revolving shaft while revolving around the rotating shaft. It can be understood that each layer of the object placing table is suitable for placing one or more film coating shielding jigs 1, so that the object placing table drives the film coating shielding jigs 1 to rotate and revolve in the reaction chamber 10, so as to realize the film coating process in batches.

It is noted that, in some examples of the present application, the filming masking jig 1 may be, but is not limited to, placed on the placement table of the planetary placement frame 521 in a manner such as standing, hanging or lying. Preferably, the plurality of film-coating shielding jigs 1 may be annularly arranged on the object table around the rotation axis of the planetary rack 521.

More preferably, as shown in fig. 10, the coating through hole 2101 of the hard case 21 of the shielding sleeve 20 of the coating shielding jig 1 is disposed outward in a radial direction of the rotation shaft of the planetary carrier 521, so that plasma can more easily enter the charging compartment 41 of the earphone box 40 through the coating through hole 2101, which helps to improve coating efficiency and coating quality.

Of course. In other examples of the present application, the film-coating shielding jig 1 may also be fixed to the object-placing table of the planetary rack 521 by means of adhesion or clamping by a clamping groove; alternatively, the film-coating shielding jig 1 may be integrally formed on the object placing table of the planetary object placing frame 521.

It is worth mentioning that hydrophobicity generally requires the water contact angle of the material surface to be larger than 90 °, and superhydrophobicity generally requires the water contact angle of the material surface to be not smaller than 150 °. In nature, there are many super-hydrophobic phenomena, for example, when raindrops drop on lotus leaves or rice leaves, the raindrops can automatically slide along the surfaces of the lotus leaves or the rice leaves, and meanwhile, some dust attached to the surfaces is taken away. And a super-hydrophobic film layer is formed on the surface of the substrate, so that a super-hydrophobic effect can be achieved, and the super-hydrophobic film layer has great application prospects in the fields of fog prevention, corrosion prevention, self-cleaning and ice prevention, such as the field of solar cells, the field of display screen waterproofing, the field of building glass self-cleaning and the like.

At present, a common method for preparing an ultra-hydrophobic membrane layer is generally divided into two steps, firstly, a certain roughness is formed on the surface through modes of sand blasting, etching or electroplating and the like, and then a layer of low-surface-energy substance is modified through liquid-phase methods of spraying, spin coating or soaking and the like, so that the ultra-hydrophobic membrane layer is formed, and the ultra-hydrophobic effect is achieved. However, the steps of these preparation methods are often complicated, the utilization rate of raw materials is low, and the organic solvent used in the preparation process may have adverse effects on the environment and operators, for example, the liquid phase fluorosilane series used. These factors are not conducive to the large-scale industrial production of superhydrophobic film layers.

However, the above problems can be solved well by the earphone box coating device of the present application, on one hand, the earphone box coating device of the present application can further improve the density and uniformity of plasma, can better achieve the formation condition of a super-hydrophobic film, and is convenient for preparing a super-hydrophobic film layer with higher quality on the part 402 to be coated of the earphone box 40; on the other hand is because this application earphone box coating equipment can improve coating efficiency to change easily in batches earphone box 40 to a large amount of work pieces are processed, help satisfying the industrial mass production demand, reduce the coating cost, be convenient for promote application and the development of super hydrophobic membrane.

It should be noted that, according to another aspect of the present application, an embodiment of the present application further provides a method for shielding an earphone box, which mainly shields the earphone box 40 through the film-coating shielding jig 1. Specifically, as shown in fig. 11, the method for shielding an earphone box may include the steps of:

s410: a shielding sleeve 20 for covering a film-coating shielding jig 1 is provided at an opening 403 of the earphone box 40;

s420: a shielding cover 10 covering the film-coating shielding jig 1 is arranged on a non-film-coating part 401 of the earphone box 40; and

s430: the shielding cover 20 can be sealingly engaged with the shielding cover 10 to sealingly shield the non-coated portion 401 of the earphone box 40 and to openly expose the portion to be coated 402 of the earphone box 40.

It should be noted that, in the above embodiments of the present application, the step S410 and the step S420 are not in sequence, that is, the step S410 may be executed before the step S420, or may be executed after the step S420. Of course, in other examples of the present application, the step S410 and the step S420 may also be executed synchronously.

More specifically, according to the above embodiment of the present application, the step S410 of the method for covering an earphone box may include the steps of:

disposing a soft lining layer 22 of the shielding sleeve 20 in an annular groove 2102 of a hard shell 21 of the shielding sleeve 20; and

the annular groove 2102 of the hard case 21 is sleeved on the opening 403 of the earphone box 40, so that the soft lining 22 hermetically fills the gap between the hard case 21 and the earphone box 40.

According to the above embodiment of the present application, in the step S430 of the method for shielding an earphone box, an elastic ring 12 of the shielding cover 10 is fastened to an annular outer wall 213 of the hard case 21 to hermetically cover the non-plated portion 401 of the earphone box 40 through an air bag 11 of the shielding cover 10.

Preferably, as shown in fig. 11, the method for covering an earphone box may further include the steps of:

s440: at least one flexible circuit board 411 of a charging compartment 41 of the earphone box 40 is folded over at least one pre-groove 215 of the hard casing 21, so that a plurality of connection sites 4110 of the flexible circuit board 411 are located inside the shielding case 10.

Exemplarily, fig. 12 shows a process of shielding the earphone box 40 by the plating shielding jig 1: first, the shielding sleeve 20 is fitted over the opening 403 of the earphone box 40 so that the soft liner 22 hermetically fills the gap between the hard case 21 and the earphone box 40; then, at least one flexible circuit board 411 of a charging compartment 41 of the earphone box 40 is folded over at least one reserved slot 215 of the hard casing 21; then, the shielding cover 10 is covered on a shell 42 of the earphone box 40 and a plurality of connection sites 4110 of the flexible circuit board 411; finally, an elastic ring 12 of the shielding cover 10 is fastened to an annular outer wall 213 of the hard casing 21 to hermetically cover the housing 42 of the earphone box 40 and the connection sites 4110 via an air bag 11 of the shielding cover 10.

It will be understood by those skilled in the art that the embodiments of the present invention as described above and shown in the drawings are given by way of example only and are not limiting of the present invention. The objects of the present invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the embodiments without departing from the principles, embodiments of the present invention may have any deformation or modification.

Claims (13)

1. Earphone box coating equipment for carry out the coating film to the earphone box, wherein this earphone box includes a non-coating film part, a part of treating coating film and an opening, its characterized in that, wherein coating film equipment includes:

the coating equipment comprises a coating equipment main body, a coating device and a control device, wherein the coating equipment main body is provided with a coating chamber; and

one or more coating shielding jigs, wherein the one or more coating shielding jigs are arranged in the coating chamber of the coating apparatus main body, and each of the coating shielding jigs includes:

the shielding cover is suitable for being covered outside the non-film-coated part of the earphone box; and

the shielding sleeve is suitable for being sleeved at the opening part of the earphone box and can be hermetically connected with the shielding cover, and when the shielding cover is connected with the shielding sleeve, the film-coated shielding jig is used for hermetically shielding the non-film-coated part of the earphone box and openly exposing the part to be coated of the earphone box.

2. The headset case plating apparatus of claim 1, wherein the shielding sleeve comprises a hard shell and a soft liner, wherein the hard shell has at least one plated through hole and an annular sleeve groove disposed around the at least one plated through hole; the soft lining layer is arranged in the annular sleeve groove of the hard shell, when the shielding sleeve is sleeved at the opening part of the earphone box through the annular sleeve groove of the hard shell, the soft lining layer hermetically fills a gap between the hard shell and the earphone box, and the at least one coating through hole of the hard shell is used for communicating with the part to be coated of the earphone box so as to expose the part to be coated of the earphone box in an open manner through the at least one coating through hole of the hard shell.

3. The headset case plating apparatus of claim 2, wherein the plated through hole of the hard case is chamfered to form a bell mouth structure.

4. The earphone box coating apparatus of claim 3, wherein the soft liner has a contour structure for matching the opening of the earphone box.

5. The headset case plating apparatus of claim 4, wherein the hard housing includes an annular top wall, an annular inner wall extending downward from an inner periphery of the annular top wall, and an annular outer wall extending downward from an outer periphery of the annular top wall, wherein an inner surface of the annular inner wall defines the plating through hole of the hard housing, and the annular inner wall and the annular outer wall are spaced apart from each other to define the annular groove of the hard housing together by an outer surface of the annular inner wall and an inner surface of the annular outer wall.

6. The earphone box coating apparatus of claim 5, wherein the shielding cover comprises an air bag and an elastic ring disposed at the mouth of the air bag, wherein the air bag of the shielding cover is adapted to wrap the outer shell of the earphone box, and the elastic ring of the shielding cover is flexibly sleeved on the hard shell of the shielding cover.

7. The earphone box coating apparatus of claim 6, wherein the hard case of the shielding sleeve further comprises one or more anti-slip members, wherein the anti-slip members are disposed on the annular outer wall for blocking the elastic ring from slipping off the annular outer wall.

8. The earphone box coating apparatus of claim 7, wherein the natural length of the elastic ring of the shield cover is smaller than the outer circumference of the annular outer wall of the hard case, and the release prevention member is implemented as a protrusion extending outward from the outer surface of the annular outer wall of the hard case.

9. The earphone box coating apparatus of claim 8, wherein the protrusion extends annularly along the outer circumference of the annular outer wall to form a loop around the annular groove of the hard case.

10. The earphone box coating apparatus of any one of claims 2-9, wherein the coating apparatus body further comprises a rotating frame, an air supply and exhaust system, and one or more excitation systems, wherein the rotating frame is rotatably disposed in the coating chamber of the coating apparatus body for placing a plurality of earphone boxes covered by the coating shielding fixture; the gas supply and exhaust system is in communicated connection with the coating chamber and is used for supplying gas inwards to supply chemical monomer gas to the coating chamber while exhausting gas outwards to form a preset vacuum degree in the coating chamber; the excitation system is used for generating an excitation electromagnetic field in the coating chamber to ionize the chemical monomer gas to form plasma, so that the plasma is deposited on the part to be coated of the earphone box to form a uniform film layer.

11. The headset case plating apparatus of claim 10, wherein the rotating frame comprises one or more planetary shelves revolving around a rotation axis, wherein each planetary shelf comprises a rotation axis and one or more stages rotating around the rotation axis, and a plurality of the plating masking jigs are annularly arranged on the stages around the rotation axis of the planetary shelves.

12. The earphone box coating apparatus of claim 11, wherein the coating through hole of the hard case in the coating shielding jig is disposed outward in a radial direction of the rotation axis of the planetary carrier.

13. The earphone box coating apparatus of claim 12, wherein the coating shielding jig is fixed to the placement table of the planetary rack by means of adhesion or clamping by a clamping groove.

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