CN209937893U - A waterproof ventilated membrane subassembly for electronic equipment - Google Patents

Abstract

The utility model provides a waterproof breathable film component for electronic equipment, which comprises a layer of waterproof breathable film; the waterproof breathable film comprises a middle breathable part and an annular mounting part surrounding the breathable part; the annular mounting part is attached with an annular hot melt adhesive layer with the same shape as the annular mounting part; the middle of the hot melt adhesive layer is provided with an air hole corresponding to the air permeable part of the waterproof air permeable membrane; the other side of the waterproof breathable film opposite to the hot melt adhesive layer is covered with a pull sheet layer. The utility model discloses an above-mentioned waterproof ventilated membrane subassembly, except utilizing the characteristic of waterproof ventilated membrane itself, still utilize the hot melt adhesive layer of being convenient for production, bonding operation, through the mode of pressurization heating solidification, form excellent waterproof bonding structure in connection structure part, can avoid bonding part's gap to leak, can carry out mass production and obtain reliable water-proof effects through the technology of optimizing moreover.

Description

A waterproof ventilated membrane subassembly for electronic equipment

Technical Field

The present invention relates to an accessory for an electronic device, in particular to a waterproof and breathable accessory for a speaker, a microphone or an earpiece of an electronic device, in particular to a waterproof and breathable membrane assembly for an electronic device.

Background

Electronic equipment such as cell-phone, notebook computer, intercom, bluetooth headset, outdoor watch-dog, function bracelet, intelligent wrist-watch for reduce the damage that leads to the fact electronic equipment when aquatic sports, outdoor environment and daily life water, generally at electronic equipment's speaker, microphone or earphone department assembly waterproof ventilated membrane.

For example, CN 108559418A discloses a breathable waterproof film for mobile phones and a preparation process thereof, comprising: the protective layer, the waterproof layer and the supporting layer are sequentially connected from top to bottom; the protective layer is release paper and is bonded with the waterproof layer through viscose; the waterproof layer is a PTFE (polytetrafluoroethylene) film, the porosity of the PTFE film is more than or equal to 80%, and the PTFE film contains a conductive material; the supporting layer also contains a conductive material; the waterproof membrane is integrally arranged in a circular or rectangular shape. Among this prior art, pass through viscose and waterproof layer bonding from type paper, in the time of the use, remove from type paper, then utilize the viscose with waterproof layer and supporting layer laminating around electronic components.

The waterproof layer of the prior art achieves the dustproof and waterproof effect, which is actually determined by the characteristics of the PTFE film itself, and is not peculiar in itself. Meanwhile, the waterproof layer is attached to the mobile phone through the adhesive, and the adhesive and the waterproof layer and the adhesive and the mobile phone are in a bonding structure, so that the bonding structure is more relevant to the final waterproof and breathable performance of the mobile phone. The prior art does not provide a technical solution to the sealing problem of the waterproof layer combined with the mobile phone through the adhesive, and the prior art also does not provide a production process for industrially producing the breathable waterproof film with waterproof and breathable effects, so that a person skilled in the art cannot easily obtain the waterproof and breathable film which can be used for mass production of electronic equipment such as mobile phones through the content disclosed by the prior art.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the present invention is to provide a waterproof and breathable membrane module for electronic devices to reduce or avoid the aforementioned problems.

In order to solve the technical problem, the utility model provides a waterproof breathable film component for electronic equipment, which comprises a layer of waterproof breathable film; the waterproof breathable film comprises a middle breathable part and an annular mounting part surrounding the breathable part; the annular mounting part is attached with an annular hot melt adhesive layer with the same shape as the annular mounting part; air holes are formed in the middle of the hot melt adhesive layer corresponding to the air permeable part of the waterproof air permeable membrane; and the other side of the waterproof breathable film, which is opposite to the hot melt adhesive layer, is covered with a pull sheet layer.

Preferably, the tab layer has a main body portion covering the waterproof breathable membrane and a handle end extending from the main body portion beyond the waterproof breathable membrane and the hot melt adhesive layer.

Preferably, the body portion conforms to the shape of the waterproof breathable membrane.

Preferably, a plurality of the waterproof breathable membrane assemblies are placed on a layer of bearing substrate, and the hot melt adhesive layers of the waterproof breathable membrane assemblies are attached to the bearing substrate.

The utility model discloses a waterproof ventilated membrane subassembly for electronic equipment, except utilizing the characteristic of waterproof ventilated membrane itself, still utilize the hot melt adhesive layer of being convenient for production, bonding operation, can form excellent waterproof bonding structure at the connection structure part through the mode of pressurization heating solidification, can avoid bonding part's gap to leak, improved the water-proof effects of equipment, can carry out mass production and obtain reliable water-proof effects through the technology of optimizing moreover.

Drawings

The drawings are only intended to illustrate and explain the present invention and do not limit the scope of the invention. Wherein,

fig. 1 is an exploded perspective view of a waterproof breathable membrane assembly for an electronic device according to an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of the waterproof breathable membrane assembly of FIG. 1;

FIG. 3 is a schematic view of a plurality of waterproof, breathable membrane assemblies of the present invention disposed on a carrier substrate;

fig. 4 is a schematic view showing a process flow of manufacturing a waterproof, breathable membrane assembly for an electronic device according to an embodiment of the present invention;

FIG. 5a is a schematic cross-sectional view of the first membrane module formed in FIG. 4;

FIG. 5b is a schematic cross-sectional view of the second module formed in FIG. 4;

FIG. 5c is a schematic cross-sectional view showing the vent formed after die cutting of the second module;

FIG. 5d is a schematic cross-sectional view of the third module formed in FIG. 4;

FIG. 5e is a schematic cross-sectional view of the third die set after die cutting;

FIG. 5f is a schematic cross-sectional view of the fourth module formed in FIG. 4;

FIG. 5g is a schematic cross-sectional view of the fifth module formed in FIG. 4;

FIG. 5h is a schematic cross-sectional view of the sixth module formed in FIG. 4;

FIG. 5i shows a schematic cross-sectional view of the resulting waterproof breathable membrane assembly of FIG. 4.

Detailed Description

In order to clearly understand the technical features, objects, and effects of the present invention, embodiments of the present invention will be described with reference to the accompanying drawings. Wherein like parts are given like reference numerals.

As described in the background section, there exist waterproof breathable films for electronic devices in the prior art, for example, the waterproof breathable film used in the prior art in the background is made of PTFE (polytetrafluoroethylene), and the excellent waterproof breathable films in the market mainly include: the waterproof and breathable material is a professional waterproof and breathable material which is exclusively developed by international material suppliers such as GORE-TEX (developed by Goll corporation, USA), OMNI-TECH (developed by COLUMBIA corporation, USA), FIRST-TEX (developed by FBA International group, USA), EVENT, TEXPORE (developed by JACKWOLFSKIN corporation, Germany) and the like.

However, the existing waterproof breathable film is required to achieve a real waterproof breathable effect, and is closely related to the structure and process of mounting the waterproof breathable film on the electronic device, for example, if the bonding structure between the waterproof breathable film and the electronic device is in a problem, the real waterproof breathable effect cannot be achieved even if the waterproof breathable material has excellent performance. Moreover, due to the large output of consumer electronic devices and the trend of light and thin, it is difficult to mass-produce membrane modules with excellent waterproof and breathable effects.

Based on the above-mentioned defect of prior art, the utility model provides a waterproof ventilation membrane subassembly for electronic equipment, it can be used to such as on the electronic equipment of cell-phone, notebook computer, intercom, bluetooth headset, outdoor watch-dog, function bracelet, intelligent wrist-watch etc..

The waterproof and breathable assembly of the present invention is shown in fig. 1-2, wherein fig. 1 is an exploded perspective view of a waterproof and breathable membrane assembly for an electronic device according to an embodiment of the present invention; FIG. 2 is a schematic cross-sectional view of the waterproof breathable membrane assembly of FIG. 1.

Referring to the drawings, the waterproof breathable film assembly for electronic equipment of the present invention comprises a layer of waterproof breathable film 1, as shown in fig. 1, the waterproof breathable film 1 of the present invention comprises a middle breathable part 11 (the part indicated in the dotted line) and an annular mounting part 12 (the part indicated outside the dotted line) surrounding the breathable part 11, the annular mounting part 12 is attached with an annular hot-melt adhesive layer 2 having the same shape as the central breathable part, the breathable part 11 corresponding to the waterproof breathable film 1 in the middle of the hot-melt adhesive layer 2 is formed with a vent hole 21, and the other side of the waterproof breathable film 1 opposite to the hot-melt adhesive layer 2 is covered with a layer of zipper 3; the pull sheet layer 3 has a main body part 31 covering the waterproof breathable film 1 and a pull handle end 32 extending from the main body part 31 to the outside of the waterproof breathable film 1 and the hot melt adhesive layer 2, wherein the main body part 31 is in accordance with the shape of the waterproof breathable film 1, and the waterproof breathable film 1 can be entirely covered and protected from pollution. The handle end 32 is raised by the main body 31 of the waterproof breathable film 1 and the hot melt adhesive layer 2, so that the handle end 32 can be easily clamped (for example, clamped by a tool such as tweezers) in the subsequent process of installing the waterproof breathable film assembly, and the whole piece of the pull sheet layer 3 is peeled off from the waterproof breathable film 1 to expose the breathable part 11 covered and shielded by the pull sheet layer, thereby achieving the breathable function.

As can be seen from the specific embodiment in the figure, the annular hot-melt adhesive layer 2 coincides with the annular mounting portion 12 of the waterproof breathable film 1, and due to the blocking of the hot-melt adhesive layer 2, the annular mounting portion 12 of the waterproof breathable film 1 is not breathable, so that the hot-melt adhesive layer 2 needs to be firmly bonded with the edge of the breathable hole of the electronic device in a hot-pressing manner during use, so as to prevent moisture and the like from permeating into the electronic device through the hot-melt adhesive layer 2 and the structural edge portion of the electronic device.

Use acrylic acid material's gluing agent among the prior art CN 108559418A to bond the waterproof membrane to electronic equipment on, but certain curing time is required when acrylic acid material's gluing agent bonds, and the homogeneity on bonding surface is difficult to guarantee, produces the gap easily to lead to moisture content to get into inside electronic equipment from the bonding gap easily. In addition, in order to shorten the curing time, the acrylic adhesive often needs to use a volatile solvent, and the pollution to the operating environment is also great.

The hot melt adhesive layer of the utility model can adopt 3232 hot melt adhesive of America Rodges company, Tesa 8711 and Tesa58471 hot melt adhesive of Germany Desha company, EM9002 and LC2824H hot melt adhesive of Germany Hangao company, or hot melt adhesive obtained by combining one of the hot melt adhesives or the hot melt adhesives. The utility model discloses a hot melt adhesive's advantage is that it does not possess viscidity under normal atmospheric temperature, aims at easily during the bonding, and convenient operation through the pressure heating bonding, can be as an organic whole with waterproof ventilated membrane 1 and electronic equipment's the peripheral firm connection in hole under 130 supplyes one's centigrade scope, forms excellent waterproof bonding structure. That is, the utility model discloses in, except utilizing the characteristic of waterproof ventilated membrane 1 itself, still utilize the hot melt adhesive layer 2 of being convenient for production, bonding operation, through the mode of pressure heating solidification, formed excellent waterproof bonding structure in connection structure part, can avoid bonding part's gap, improved the water-proof effects of equipment.

In a preferred embodiment of the present invention, in order to facilitate mass production, a plurality of waterproof and breathable film assemblies shown in fig. 1-2 are preferably placed on a layer of carrier substrate 4, wherein the placement direction is to attach the hot-melt adhesive layer 2 of the waterproof and breathable film assemblies to the carrier substrate 4, so that on one hand, the hot-melt adhesive layer 2 is prevented from being contaminated and the bonding effect is reduced, on the other hand, the waterproof and breathable film assemblies can be placed on a production line by using the carrier substrate 4 as a transportation carrier, and each assembly is sucked away from the carrier substrate 4 and then is pressurized and hot-melted onto an electronic device through a mechanical arm.

Fig. 3 shows a schematic view of a carrier substrate 4 having 64 waterproof and breathable film assemblies, wherein a plurality of positioning holes 41 are formed on both sides of the carrier substrate 4 to facilitate alignment and transportation on the production line, so that the robot arm can precisely position each waterproof and breathable film assembly on the carrier substrate 4.

The following further describes a method for manufacturing a waterproof and breathable membrane module according to the present invention by way of specific embodiments, wherein fig. 4 is a schematic view showing a manufacturing process of a waterproof and breathable membrane module for electronic devices according to a specific embodiment of the present invention.

As shown in fig. 4, the method for manufacturing a waterproof and breathable film assembly for electronic devices of the present invention includes the following steps:

first, as shown in the lower left side of fig. 4, a first film group 10 is formed by laminating a waterproof breathable film 1 and a backsize-bearing tabbed layer 3 by rolling. Wherein a cross-sectional structure of the first module 10 is shown in fig. 5 a.

The waterproof breathable film 1 used in this step may be any waterproof breathable film sold in rolls, preferably a waterproof breathable film made of polytetrafluoroethylene, and particularly preferably a waterproof breathable film material purchased from international material vendors such as GORE-TEX (manufactured by GORE, usa), OMNI-TECH (manufactured by COLUMBIA, usa), FIRST-TEX (manufactured by FBA international group, usa), EVENT, TEX (manufactured by JACKWOLFSKIN, germany) or developed by an outdoor company, such as GAW337, GAW338, GAW333, GAW334, etc. of GORE, usa.

The pull sheet layer 3 can be made of plastic sheet such as PET, which is used to cover the side of the waterproof breathable film 1 and prevent the side of the waterproof breathable film 1 from being contaminated, and the adhesive on the back of the pull sheet layer 3 can slightly stick the waterproof breathable film 1, so that the whole waterproof breathable module can be taken down from the bearing substrate 4 through the pull sheet layer 3. That is, after the entire waterproof and breathable module is manufactured and placed on the carrier substrate 4, when the module is taken down by the robot arm, the robot arm can suck the pull sheet layer 3, and the entire module is taken down from the carrier substrate 4 by the adhesive force of the back adhesive of the pull sheet layer 3. When the module is attached to an electronic device by pressure heat fusion, the tab layer 3 is useless and the entire tab layer 3 needs to be pulled off the module, otherwise the tab layer 3 covered with the waterproof breathable film 1 fails to ventilate.

Simultaneously with the formation of the first module, a layer of hot melt adhesive layer 2 and a layer of first transition base paper 5 with gum are pressed together by rolling to form a second module 20, as shown in the upper left side of fig. 4. Wherein a cross-sectional structure of the second module 20 is shown in fig. 5 b.

The hot melt adhesive layer 2 used in the step can be any hot melt adhesive sheet sold in a roll, preferably an EVA hot melt adhesive made of ethylene-vinyl acetate copolymer, particularly preferably a 3232 hot melt adhesive purchased from, for example, Rogers corporation in America, or Tesa 8711 and Tesa58471 hot melt adhesives from Desha corporation in Germany, or EM9002 and LC2824H hot melt adhesives from Hangao corporation in Germany. The hot melt adhesive is particularly preferably used at a pressing temperature of 130-150 ℃, and can be hot-melted, glued and cured at the set pressing temperature to form a firm bonding structure.

The first transition base paper 5 is a material supporting belt for transition and can be removed in the manufacturing process. It may be made of any conventional backing paper, preferably transparent or translucent flexible plastic film material, for optical transmission positioning in a production line, and for easy removal of the cut waste by adhesive tape bonding (as will be further described below).

After the second module 20 is formed, as shown in fig. 4, the second module 20 may be die-cut by the first die-cutting roller 100 to cut the vent 21 located in the middle of the waterproof and breathable film assembly, and for subsequent positioning, a first positioning hole may be cut at a side edge of the first transition base paper 5 at the time of die-cutting. The location of the first positioning hole is not shown, but it will be understood by those skilled in the art that the location coincides with the location of the positioning hole 41 shown in fig. 3, i.e. the first transitional base paper 5 is slightly wider and extends beyond the edge of the hot melt adhesive layer 2 on both sides, so as to cut the first positioning hole. The waste material in the small holes cut at the time of die-cutting the airing holes 21 can be discharged from the position of the first die-cutting roll 100, and the related waste material discharging structure is not specifically shown in fig. 4. Fig. 4 is a cross-sectional view of the second film assembly 20 after die cutting to form the vent holes 21, which is shown in fig. 5 c.

Thereafter, as shown in fig. 4, the second module 20 cut with the vent holes 21 and the first module 10 are thermally pressed together by a hot press roller 200 to form a third module 30 having a sectional structure as shown in fig. 5 d. Wherein, through the hot pressing, the hot melt adhesive layer 2 of the second module 20 is mutually attached with the waterproof ventilated membrane 1 of the first module 10.

In this step, the temperature at which the second module 20 and the first module 10 are combined together by hot pressing through the roller to form the third module 30 is required to be 110-. Of course, since the curing characteristic of the hot melt adhesive is irreversible, if the pressing temperature of 130-.

Then, as shown in fig. 4, the waterproof breathable film 1 and the hot-melt adhesive layer 2 are cut out in outline and the tab layer 3 is cut out in outline by die cutting with reference to the first positioning hole on the first intermediate base paper 5 by the second die-cutting roll 300, but a part of the tab layer 3 is left uncut. That is, after the die cutting by the second die cutting roller 300, the waterproof breathable film 1 and the hot melt adhesive layer 2 have formed the final contour shape as shown in fig. 1, the hot melt adhesive layer 2 also has the ventilation holes 21 in the middle, and the outer contour of the tab layer 3 is basically formed, but a part of the tab layer 3 is not cut, for example, the pull end 32 at the rightmost side of the tab layer 3 shown in fig. 1 can be left uncut. It is desirable to leave a portion of the tab layer 3 uncut to avoid taking the cut tab layer 3 away completely when subsequently removing waste material, so that the remaining components (including the tab layer 3 left after cutting) are out of position because they have no fastening structure (as will be further described later).

And cutting a second positioning hole on the side edge of the pull sheet layer 3 by taking the first positioning hole as a reference during the shape die cutting, wherein the step is used for transferring the first positioning hole on the first transition base paper 5 to the pull sheet layer 3 so as to be convenient for transferring and positioning through the pull sheet layer 3 after the first transition base paper 5 is subsequently removed. Similarly, the position of the second positioning hole is not shown, but those skilled in the art will understand that the position of the second positioning hole coincides with the position of the positioning hole 41 shown in fig. 3.

Then, as shown in fig. 4, a layer of second transition base paper 6 is compounded on the outer side of the pull tab layer 3 of the third module 30 in a rolling manner, so that the pull tab layer 3 is temporarily supported, and when the pull tab layer 3 is completely cut off, the pull tab layer 3, the waterproof breathable film 1 and the hot melt adhesive layer 2 above the pull tab layer can be supported, and the whole waterproof breathable film assembly is prevented from being dropped. Then, as shown in fig. 4, the first transitional base paper 5 on the third module 30 after die cutting is removed, and at this time, the cut first transitional base paper 5 takes the cut hot melt adhesive layer 2 and the waterproof breathable film 1 adhered together away from the tab layer 3, so as to form a cross-sectional structure as shown in fig. 5 e. And because the pull sheet layer 3 has a part not cut off, when removing the first transition bottom paper 5, can not take away the pull sheet layer 3 together, therefore can fix whole subassembly in original position motionless through the pull sheet layer 3 that links into one piece (the pull sheet layer 3 can be glued waterproof ventilated membrane 1 through the gum), avoid in the follow-up waste material process of getting rid of the subassembly displacement.

At this time, a small amount of the first transitional base paper 5 remains on the top surface of the remaining hot melt adhesive layer 2, as shown in fig. 5e, and the waste of the remaining first transitional base paper 5 can be removed by the adhesive roller 400 shown in fig. 4, for example, by tape adhesion. The fourth module 40 is formed after removing all the first transitional base paper 5 and the part of the surface of the hot melt adhesive layer 2, and its cross-sectional structure is shown in fig. 5 f.

As shown in fig. 5f, after the first transition backing paper 5 is removed, the top surface of the hot melt adhesive layer 2 is exposed, and in order to avoid the surface of the hot melt adhesive layer 2 being contaminated, a layer of third transition backing paper 7 needs to be laminated on the outer side of the hot melt adhesive layer 2 by rolling, as shown in fig. 4, so that the cross-sectional structure of the fifth module 50 shown in fig. 5g can be formed.

Then, as shown in fig. 4, die cutting is performed along the outer contour of the tab layer 3 by using the third die cutting roller 500 with reference to the second positioning hole on the tab layer 3, and then the portion of the tab layer 3 which is not cut is cut, and then the third transitional base paper 7 is removed, thereby forming the sixth die set 60 having the cross-sectional structure shown in fig. 5h, which shows a cut line in the right-hand direction compared to the state of the fourth die set 40 shown in fig. 5 f.

The third transitional base paper 7 used in the two steps is mainly used for covering the hot melt adhesive layer 2, so that the hot melt adhesive layer 2 is prevented from being polluted in the process of cutting the pull sheet layer 3. Of course, under the condition that the working environment is clean enough, or the quality requirement is not high, or the straight knife is adopted for the downward cutting, the third transitional base paper 7 is not needed in the process of cutting the pull sheet layer 3, the downward cutting can be directly carried out from the state of the fourth module 40 shown in fig. 5f, that is, the state of the fifth module 50 shown in fig. 5g is omitted, and the fourth module 40 directly presents the state of the sixth module 60 shown in fig. 5h after the cutting operation, so that the operation is also feasible.

Then, as shown in fig. 4, still using the second positioning hole on the pull-tab layer 3 as a reference, compounding a layer of the carrier substrate 4 on the outer side of the hot melt adhesive layer 2 of the sixth module 60 by rolling, so that the positioning hole 41 (as shown in fig. 1) on the carrier substrate 4 is aligned with the second positioning hole, then removing the second transition base paper 6 together with the excess part of the cut pull-tab layer 3 thereon, and finally obtaining a waterproof breathable film assembly, as shown in a cross-sectional structure diagram of fig. 5i, where the waterproof breathable film assembly is formed on the carrier substrate 4.

FIG. 5i shows a schematic cross-sectional view of the die-cut waterproof breathable film assembly of FIG. 4, which is substantially identical to FIG. 2, but with the orientation of the resulting product reversed from that shown in FIG. 2 due to the machine direction of the manufacturing facility of FIG. 4.

A method of manufacturing the waterproof breathable membrane module of the present invention has been described in detail above by way of specific examples. Of course, it will be understood by those skilled in the art that the introduction of the various transitional base papers during the manufacturing process is for the purpose of locating and removing die-cutting waste, and therefore, the transitional base papers in the foregoing embodiments can be adjusted to the timing of their combination into the respective die sets according to the actual situation. For example, the second transition base paper 6 shown in fig. 4 is disposed behind the second die-cutting roll 300, but since the second transition base paper 6 is to hold the entire assembly from dropping, the same function can be achieved by combining the second transition base paper 6 just before the third die-cutting roll 500 cuts the pull-sheet layer 3. Therefore, the second transitional base paper 6 may be combined with the tab layer 3 before the third die-cutting roller 500 performs the die-cutting step, for example, the second transitional base paper 6 may be disposed in front of the second die-cutting roller 300 to be combined, or the second transitional base paper 6 may be combined with the third transitional base paper 7, as needed.

In addition, the introduction of the carrier substrate 4 is not a necessary step for the manufacturing method of the present invention, because the waterproof breathable film assembly of the present invention is basically already manufactured in the state of the sixth module 60 shown in fig. 5h obtained after passing through the third die-cutting roller 500 as the manufacturing of the separate waterproof breathable film assembly, and only the second transition base paper 6 together with the unnecessary portion of the tab layer 3 cut thereon needs to be removed. The utility model discloses a so last provide bearing substrate 4, on the one hand in order to stick a plurality of waterproof ventilative membrane subassemblies and be convenient for carry, on the other hand is in order to keep unanimous with end user's specification demand. That is, as a single waterproof breathable film assembly, it is possible to manufacture without the carrier substrate 4, but if a plurality of waterproof breathable film assemblies are to be transported, providing a carrier substrate 4 meeting the specification requirements of the end user can facilitate transportation on the production line, and also facilitate positioning with the installation equipment of the end user through the positioning holes 41.

Through the explanation to the manufacturing method of the present invention, those skilled in the art can perform the mass production of the waterproof breathable film assembly through the optimized process, and can obtain a reliable waterproof effect.

It is to be understood by those skilled in the art that while the present invention has been described in terms of several embodiments, it is not intended that each embodiment cover a separate embodiment. The description is given for clearness of understanding only, and it is to be understood that all matters in the embodiments are to be interpreted as including all technical equivalents which are encompassed by the claims.

The above description is only exemplary of the present invention, and is not intended to limit the scope of the present invention. Any equivalent changes, modifications and combinations that may be made by those skilled in the art without departing from the spirit and principles of the invention should be considered within the scope of the invention.

Claims (4)

1. A waterproof breathable membrane assembly for an electronic device, comprising a layer of waterproof breathable membrane (1); the method is characterized in that: the waterproof and breathable film (1) comprises a middle breathable part (11) and an annular mounting part (12) surrounding the breathable part (11); the annular mounting part (12) is attached with an annular hot melt adhesive layer (2) which is consistent with the annular mounting part in shape; the middle of the hot melt adhesive layer (2) is provided with a vent hole (21) corresponding to the ventilation part (11) of the waterproof breathable film (1); and the other side of the waterproof breathable film (1) opposite to the hot melt adhesive layer (2) is covered with a pull sheet layer (3).

2. The waterproof breathable film assembly of claim 1, wherein the tab layer (3) has a main portion (31) covering the waterproof breathable film (1) and a handle end (32) extending from the main portion (31) beyond the waterproof breathable film (1) and the hot melt adhesive layer (2).

3. The waterproof breathable film assembly of claim 2, wherein the main body portion (31) conforms to the shape of the waterproof breathable film (1).

4. The waterproof breathable film assembly according to one of claims 1 to 3, characterized in that a plurality of said waterproof breathable film assemblies are placed on a supporting substrate (4), the hot-melt adhesive layer (2) of said waterproof breathable film assemblies being conformed to said supporting substrate (4).

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