CN212147545U - Film sticking machine - Google Patents

Abstract

The utility model relates to a film sticking machine, it is used for attaching the protective layer for electronic equipment is by oneself, including supporting mechanism, supply membrane mechanism, transport mechanism, moving mechanism, first pad pasting mechanism, first positioning mechanism and second positioning mechanism, the supporting mechanism is connected with supplying membrane mechanism, transport mechanism, moving mechanism, first pad pasting mechanism, first positioning mechanism and second positioning mechanism in order to play the supporting role, and the supporting mechanism includes the first end that is located three different position, second end and third end, and first end and third end position are corresponding; first pad pasting mechanism and supply membrane mechanism to set up at first tip, moving mechanism sets up at the third tip, transport mechanism sets up at the second tip, and first pad pasting mechanism is located transport mechanism and supplies between the membrane mechanism, and first positioning mechanism sets up between first pad pasting mechanism and moving mechanism, and second positioning mechanism sets up around transport mechanism. The utility model provides a sticking film machine has the size little, advantage with low costs.

Description

Film sticking machine

[ technical field ] A method for producing a semiconductor device

The utility model relates to an electronic equipment pad pasting technical field, concretely relates to sticking film machine.

[ background of the invention ]

With the rise of mobile communication, electronic devices become an indispensable tool in daily life, and users often stick a protective film to protect the screen of the electronic devices. In order to improve the intellectualization of the film sticking, the self-service film sticking machine comes along. The self-service sticking film machine is usually placed in markets, schools and communities, but the existing self-service sticking film machine is huge in size and difficult to popularize.

[ Utility model ] content

In order to overcome the problems existing in the prior art, the utility model provides a film sticking machine.

The utility model provides a technical problem's scheme is to provide sticking film machine, it is used for the self-service attached protective layer of electronic equipment, including supporting mechanism, supply membrane mechanism, transport mechanism, moving mechanism, first pad pasting mechanism, first positioning mechanism and second positioning mechanism, the supporting mechanism is connected with supplying membrane mechanism, transport mechanism, moving mechanism, first pad pasting mechanism, first positioning mechanism and second positioning mechanism in order to play the supporting role, and the supporting mechanism includes the first end that is located three different position, second end and third end, and first end and third end position are corresponding; first pad pasting mechanism and supply membrane mechanism to set up at first tip, moving mechanism sets up at the third tip, transport mechanism sets up at the second tip, and first pad pasting mechanism is located transport mechanism and supplies between the membrane mechanism, and first positioning mechanism sets up between first pad pasting mechanism and moving mechanism, and second positioning mechanism sets up around transport mechanism.

Preferably, the film sticking machine comprises a second film sticking mechanism for sticking films for the second time, the second film sticking mechanism is arranged above the conveying mechanism, and the position of the second film sticking mechanism corresponds to that of the second positioning mechanism; the second film pasting mechanism comprises a cavity cover with one side provided with an opening, a cavity is arranged in the opening, and an inflatable air bag capable of completely covering the protective layer is arranged in the cavity.

Preferably, the film sticking machine comprises a cleaning bag mechanism for providing a cleaning bag, which is arranged between the film supplying mechanism and the moving mechanism; one side of the film supply mechanism far away from the conveying mechanism is provided with a sliding groove for the cleaning bag to slide out of the film sticking machine.

Preferably, the film supply mechanism comprises at least two different protective films, each protective film comprises a protective layer and an encapsulation layer, the protective layer is positioned on the encapsulation layer, and the size of the encapsulation layer is larger than that of the protective layer; the protective layers of different protective films have the same or different sizes, and the packaging layers have the same shape and size; a set distance L is formed between one end of the protective layer and the end corresponding to the packaging layer, and the set distances L of different protective films are the same.

Preferably, the film supply mechanism comprises a plurality of film storage cavities for storing the protective films, and the plurality of film storage cavities are distributed in the vertical plane direction; the film storage cavities are the same in shape and size, different protective films are stored in the film storage cavities, each protective film comprises a protective layer and a packaging layer, the protective layers are positioned on the packaging layers, and the different protective films are all limited in the film storage cavities through the packaging layers.

Preferably, a stripping plate is arranged at the bottom of the film supply mechanism close to one end of the moving mechanism.

Preferably, the first positioning mechanism comprises a fixed seat, a top bead is protruded on the fixed seat and used for supporting the protective layer, the top bead is in rolling or fixed connection with the fixed seat, and the top beads are positioned in the same inclined plane so as to enable the protective layer to be obliquely supported; the first positioning mechanism further comprises a fixed seat and at least one movable plate, a fixed limiting plate is arranged on the fixed seat, and the movable plate and the limiting plate are matched to be used for positioning the protective layer.

Preferably, first pad pasting mechanism includes first pad pasting driving piece, presses the driving piece, presses splenium and absorption portion, pressing splenium and absorption portion mutually independent setting and pressing the splenium setting in absorption portion one end, first pad pasting driving piece drive absorption portion is linear motion, presses the driving piece drive to press the splenium to remove, absorption portion slope sets up.

Preferably, the conveying mechanism includes a movable conveying plate for placing the electronic device, the second positioning mechanism includes at least two movable clamping assemblies and a supporting assembly arranged around the conveying plate, and the clamping assemblies and the supporting assembly cooperate to position the electronic device.

Preferably, the film sticking machine further comprises a square outer shell, and the supporting mechanism, the film supplying mechanism, the conveying mechanism, the moving mechanism, the first film sticking mechanism, the first positioning mechanism and the second positioning mechanism are all arranged in the outer shell; the cleaning bag conveying mechanism is characterized in that a first opening, a second opening and a display screen are arranged on the outer shell, the conveying mechanism corresponds to the first opening in position to put in or take out electronic equipment, and the second opening is used for allowing the cleaning bag picked up by the moving mechanism to slide out.

Compared with the prior art, the utility model provides a sticking film machine is through setting up first pad pasting mechanism and confession membrane mechanism at first end, and moving mechanism sets up in the third end, and transport mechanism sets up at the second end, and just first pad pasting mechanism is located transport mechanism and supplies between the membrane mechanism, and first positioning mechanism sets up between first pad pasting mechanism and moving mechanism, and second positioning mechanism sets up around transport mechanism. The orientation configuration enables the whole size of the film sticking machine to be smaller, and the moving stroke of the corresponding mechanism to be reduced. The film pasting aging is improved. The utility model provides a sticking film machine cost is lower.

The second laminating mechanism sets up in the transport mechanism top, and it can cooperate in order to carry out the secondary with transport mechanism, improves the rate of reusability of mechanism, simplifies equipment structure, reduce cost. The second attaching device extrudes the electronic equipment through the air bag, the air bag is suitable for deformation of the surface of the electronic equipment, and even in the attaching process of the 3D film, the protective layer corresponding to the curved surface part of the electronic equipment can obtain balanced extrusion force so that the attaching process is tight and bubble-free.

The packaging layer of the protective film is larger than the protective layer, the packaging layer of different protective films has the same size, and the protective layers have the same or different sizes, so that the protective film can be conveniently produced, transported, stored, checked and recycled. Setting the distances L all the same can simplify the control procedure for peeling the encapsulation layer.

The film storage cavities are distributed on the vertical surface, so that the space utilization rate of the self-service film sticking machine is improved, and the packaging layers corresponding to the protective layers with different sizes are the same in size, so that the protective films can be limited in the film storage cavities through the packaging layers.

The self-service sticking film machine makes the contact between protective layer and the first location be the point contact through the setting of the top pearl on the fixing base. The point contact mode can prevent the protective layer from being scratched while ensuring that the protective layer is effectively supported. The top bead and the fixed seat are connected in a rolling manner, so that the friction between the protective layer and the first positioning mechanism in the positioning process is reduced to the minimum, and the viscosity on the protective layer is effectively protected from being damaged.

The first positioning mechanism realizes positioning through the matching of the limiting plate and the movable plate, and the second positioning mechanism realizes positioning of the electronic equipment through the matching of the abutting assembly and the clamping assembly.

The adsorption part of the first film sticking mechanism is obliquely arranged so that when the protective layer is moved to the surface of the electronic equipment, one end of the protective layer is firstly in surface contact with the electronic equipment, and when the adsorption part releases adsorption, the protective layer is gradually in surface contact with the electronic equipment, so that the problem of bubbles easily generated when the protective layer is attached to the surface of the electronic equipment at one time is solved. Further, the first film pasting mechanism comprises a pressing part, and the pressing part presses one end, which is in contact with the electronic equipment, of the corresponding protective layer so that the protective layer is attached to the surface of the electronic equipment. The pressing part is a roller, the surface of the pressing part is made of elastic materials, and the elastic materials can be suitable for surface deformation of electronic equipment so that the protective layer and the electronic equipment can be attached more tightly. The pressing part and the adsorption part are arranged independently, so that the flexibility of the film is improved.

[ description of the drawings ]

Fig. 1 is a schematic perspective view of a self-service film sticking machine according to a first embodiment of the present invention.

Fig. 2 is an internal schematic view of a self-service film sticking machine according to a first embodiment of the present invention.

Fig. 3 is a schematic structural view of a moving mechanism in a self-service film sticking machine according to a first embodiment of the present invention.

Fig. 4 is a schematic view of the film feeding mechanism and the peeling device in the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 5 is a schematic view of a planar structure of a protection film in a self-help laminator according to a first embodiment of the present invention.

Fig. 6 is a schematic view of a layered structure of a protective film in a self-help laminator according to a first embodiment of the present invention.

Fig. 7 is a schematic view of a layer structure of the deformation of the protection film in the self-help laminator according to the first embodiment of the present invention.

Fig. 8 is a schematic structural view of the first embodiment of the present invention when the protective film is placed on the film feeding mechanism in the self-help film sticking machine.

Fig. 9 is a schematic view of a part of the structure of a self-service film sticking machine according to the first embodiment of the present invention.

Fig. 10 is a schematic view illustrating the first embodiment of the present invention, wherein the picking member is picking up the film storing cavity and the mold picking operation is performed in the self-service film sticking machine.

Fig. 11 is a schematic view illustrating the first embodiment of the present invention for peeling the passivation layer and the encapsulation layer from the self-help film laminator.

Fig. 12 is a schematic structural view of a cleaning bag mechanism and a chute in the self-service laminator according to the first embodiment of the present invention.

Fig. 13 is a schematic view of a part of the structure of the cleaning bag mechanism in the self-service laminator according to the first embodiment of the present invention.

Fig. 14 is a schematic view of a partial structure of a self-service film sticking machine according to a first embodiment of the present invention.

Fig. 15 is a schematic structural view of the first positioning mechanism in the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 16 is a schematic structural view of the first positioning mechanism in the self-service laminator according to the first embodiment of the present invention at another viewing angle.

Fig. 17 is a schematic structural view of a second positioning mechanism in the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 18 is a schematic structural view of the second positioning mechanism in the self-service laminator according to the first embodiment of the present invention at another viewing angle.

Fig. 19A is a schematic structural view of the first film sticking mechanism and the mechanism matched with the first film sticking mechanism in the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 19B is a schematic view of a part of the structure of the first film sticking mechanism in the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 20 is a schematic structural diagram of another variation of the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 21 is a schematic structural view of a second film sticking mechanism and a mechanism matched with the second film sticking mechanism in the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 22 is a schematic cross-sectional view of the second film sticking mechanism in the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 23 is a schematic diagram of a comparative structure of a chamber and an electronic device in a self-service laminator according to a first embodiment of the present invention.

Fig. 24 is a flow chart of a film sticking method of a self-help film sticking machine according to a first embodiment of the present invention.

Fig. 25 is a schematic structural view of the film sticking of the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 26 is a specific flowchart of step S1 in the film sticking method of the self-service film sticking machine according to the first embodiment of the present invention.

Fig. 27 is a schematic diagram of a modular structure of a self-service film sticking machine according to a second embodiment of the present invention.

Fig. 28 is a flow chart of a film sticking method of a self-service film sticking machine according to a second embodiment of the present invention.

Fig. 29 is a detailed flowchart of step S20 in fig. 28.

FIG. 30 is a detailed flowchart of a film sticking method of the self-help film sticking machine according to the second embodiment.

Description of the drawings: 1. a self-help film sticking machine; 11. a support mechanism; 12. a recovery mechanism; 121. a camera; 21. a transport mechanism; 31. a film supply mechanism; 41. a cleaning bag mechanism; 51. a moving mechanism; 61. a first positioning mechanism; 71. a second positioning mechanism; 81. a first film sticking mechanism; 91. a second film sticking mechanism; 111. an outer housing; 112. a support platform; 1111. a first opening; 1112. a second opening; 1113. a display screen; 1114. a control area; 1115. a baffle plate; 1116. a chute; 211. a transfer rail; 212. a transfer plate; 311. a film storage cavity; 3111. a limiting structure; 3112. a limiting column; 312. reinforcing ribs; 313. stripping the plate; 411. a base plate; 412. a side plate; 511. an x-axis drive assembly; 512. a y-axis drive assembly; 513. a z-axis drive assembly; 514. picking up the part; 5111. an x-axis drive; 5112. an x-axis mount; 5113. an x-axis guide; 5121. a y-axis drive; 5122. a y-axis mount; 5123. a y-axis guide bar; 5131. a z-axis drive; 5132. a z-axis mount; 611. a fixed seat; 612. a top bead; 613. a first moving plate; 614. a second moving plate; 6121. a limiting plate; 615. a first driving member; 616. A second driving member; 617. a first sensor; 618. a second sensor; 619. a first fixing plate; 620. a second fixing plate; 621. a support bar; 711. a clamping assembly; 712. a holding assembly; 7111. a third moving plate; 7112. a third driving member; 7113. A third fixing plate; 7114. a third sensor; 7121. a fourth moving plate; 7122. a fourth drive; 7213. a fourth fixing plate; 7124. a fourth sensor; 811. pasting a film structure; 8111. an adsorption part; 8112. a pressing part; 812. a first film driving member; 8121. an output shaft; 813. a double-shaft mechanism; 81a, a first film sticking mechanism; 810a, a first film pasting driving piece; 820a, a pressing driving member; 8112a, a pressing part; 8111a, an adsorption part; 911. a chamber cover; 9111. a chamber; 9111a, a first space; 9111b, a second space; 9112. an air bag; 912. a second film driving member; 913. a support plate; 914. a first air hole; 915. a second air hole;

A. an electronic device; B. a protective film; b1, a protective layer; b2, packaging layer; b3, a holding part; C. a cleaning bag.

[ detailed description ] embodiments

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and the embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Referring to fig. 1 and 2, the present invention provides a film sticking machine, especially a self-service film sticking machine 1, which is mainly suitable for self-service film sticking to an electronic device a needing film sticking, i.e. automatically sticking a protection film on the electronic device a, as follows: automatically sticking a toughened film to the mobile phone; inconvenience brought through manpower pad pasting in order to solve now to helping hand industrial intelligent production, good article accuse during the casting pad pasting.

This self-service sticking film machine 1 includes supporting mechanism 11, transport mechanism 21, moving mechanism 51, first positioning mechanism 61, second positioning mechanism 71, first sticking film mechanism 81, second sticking film mechanism 91 and controller (not shown), wherein transport mechanism 21, moving mechanism 51, first positioning mechanism 61, second positioning mechanism 71 and first sticking film mechanism 81, second sticking film mechanism 91 all with controller electric connection, the controller can be industrial computer or PLC, its accessible external connection host computer debugs the utility model discloses all mechanical action explained below is all carried out through the controller, because the controller belongs to technical characteristics of this field of personnel, the utility model discloses do not describe one by one when mechanical action moves to controller (the following omission).

The supporting mechanism 11 is used for supporting the conveying mechanism 21, the moving mechanism 51, the first positioning mechanism 61, the second positioning mechanism 71 and the first film pasting mechanism 81, the conveying mechanism 21 is used for conveying the electronic device A to a set position, the moving mechanism 51 is used for picking up the type of the corresponding type of the protective film B according to the selection of a user, the first positioning mechanism 61 is used for positioning the protective film B, the second positioning mechanism 71 is used for positioning the electronic device A, and the first film pasting mechanism 81 is used for picking up and attaching the protective film B positioned by the first positioning mechanism 61 to the electronic device A in the second positioning mechanism 71 so as to finish the film pasting operation of the electronic device A.

This self-service sticking film machine 1 is through carrying out self-service pad pasting to electronic equipment A, and the user need not to master the pad pasting skill, only needs to trigger self-service sticking film machine 1 and acquires the authority that its self-service sticking film machine 1 operated, and then puts into transport mechanism 21 with electronic equipment A, can carry out the pad pasting through self-service sticking film machine 1 completely, and the pad pasting operation is more convenient, and is more intelligent, and wherein trigger the mode of self-service sticking film machine 1 operation not be limited to sweep the sign indicating number and trigger, long-range trigger, or input key.

Further, self-service sticking film machine 1 still includes and supplies membrane mechanism 31 and clean package mechanism 41, and supporting mechanism 11 provides the support for supplying membrane mechanism 31 and clean package mechanism 41, supplies membrane mechanism 31 to be used for depositing protection film B, and clean package mechanism 41 is used for depositing clean package C. When the self-service film pasting operation is performed, the moving mechanism 51 firstly moves to the position corresponding to the cleaning bag mechanism 41 and picks up a cleaning bag C, so that a user can manually clean the surface of the electronic equipment A to be filmed through the cleaning bag C; after the user selects the type of the protective film B and transfers the electronic device a to the set position by the transfer mechanism 21, the moving mechanism 51 moves to the position corresponding to the film supplying mechanism 31 and picks up the protective film B of the type set by the user. Pick up clean package C through moving mechanism 51 to supply the user to utilize clean package C to clean electronic equipment A screen, thereby guarantee the pad pasting quality of self-service sticking film machine 1.

It is understood that the electronic device a includes, but is not limited to, a cell phone, a tablet, a display, and the surface to be filmed includes, but is not limited to, a screen, a back surface, or other surfaces thereof. The present invention is described by taking the surface of the film to be pasted as a screen as an example. The cleaning pack C includes, but is not limited to, alcohol wipes, iodine wipes, distilled water wipes, the protective film B types include, but are not limited to, tempered film, privacy film, frosted film, and each type of protective film B includes a plurality of different sizes, such as 4.3 inches, 4.7 inches, 5.0 inches, 5.7 inches, etc.

In the present embodiment, the film supply mechanism 31 includes the protective film B, which is stored in the film supply mechanism 31 in advance for a worker, so that when the user performs self-service film pasting, the moving mechanism 51 directly picks up the protective film B from the film supply mechanism 31.

As a preferred structural arrangement, the support mechanism 44 includes a first end portion, a second end portion and a third end portion, which are located at three different orientations, and the first end portion and the third end portion correspond in position; first pad pasting mechanism 81 and supply membrane mechanism 31 to set up at first end, moving mechanism 51 sets up at the third end, transport mechanism 21 sets up at the second end, and first pad pasting mechanism 81 is located transport mechanism 21 and supplies between the membrane mechanism 31, and first positioning mechanism 61 sets up between first pad pasting mechanism 81 and moving mechanism 51, and second positioning mechanism 71 sets up around transport mechanism 21. The second film sticking mechanism 91 is disposed above the conveying mechanism 21 at a position corresponding to the second positioning mechanism 71. The cleaning bag mechanism is arranged between the film supply mechanism and the moving mechanism.

The supporting mechanism 11 includes an outer casing 111 and a supporting platform 112, the outer casing 111 surrounds the supporting platform 112, and fixes the supporting platform 112 on the outer casing 111, and the conveying mechanism 21, the moving mechanism 51, the first positioning mechanism 61, the second positioning mechanism 71, the first film pasting mechanism 81, the film supply mechanism 31 and the cleaning bag mechanism 41 are all disposed on the supporting platform 112.

Referring to fig. 1, the outer casing 111 is provided with a first opening 1111, a second opening 1112 and a display screen 1113, the transmission mechanism 21 is disposed in the outer casing 111 and is located corresponding to the first opening 1111 for placing in or taking out the electronic device a, the display screen 1113 is used for displaying a film pasting process and/or advertising, and may also be a man-machine interaction interface, and the man-machine interaction content includes but is not limited to purchasing the protection film B, paying and clicking to browse internet information, and the like. The first opening 1111 is further provided with a baffle 1115, the size of the baffle 1115 is matched with the size of the first opening 1111, and the baffle 1115 can be magnetically adsorbed at the first opening 1111 of the outer shell 111 to close the first opening 1111, so that dust and other dirt can be prevented from entering the outer shell 111 through the opening, and the situation that personnel are injured due to misoperation in the film pasting process can be prevented. The second opening 1112 is used for sliding out the cleaning bag C picked up by the moving mechanism 51, so that the user can clean the electronic device a by using the sliding-out cleaning bag C.

Further, still be equipped with control area 1114 on shell body 111 to supply the user to control through control area 1114 and start self-service sticking film machine 1, and then put into electronic equipment A among transport mechanism 21, make self-service sticking film machine 1 carry out the pad pasting to electronic equipment A among transport mechanism 21, simultaneously, still can control self-service sticking film machine 1 through control area 1114 and select the type, the size of electronic equipment A and need carry out the protection film B type of pad pasting, improve self-service sticking film machine 1's application scope, increase the user and select. In this embodiment, the display screen 1113 is a touch screen, and the control area 1114 is integrated in the touch screen, so that a user can touch the control area 1114 in the touch screen to perform a self-help film pasting operation.

The transmission mechanism 21 includes a transmission rail 211 and a transmission plate 212, the transmission rail 211 is disposed on the supporting platform 112, the transmission plate 212 is disposed on the transmission rail 211, the transmission plate 212 is used for placing the electronic device a, and the transmission rail 211 transmits the transmission plate 212 to move, so as to achieve the purpose of transmitting the electronic device a.

Referring to fig. 3, the moving mechanism 51 includes an x-axis driving component 511, a y-axis driving component 512, a z-axis driving component 513 and a picking component 514, the x-axis driving component 511 is fixed on the supporting platform 112, the y-axis driving component 512 is disposed on the x-axis driving component 511, and can drive the y-axis driving component 512 to move through the x-axis driving component 511, the z-axis driving component 513 is disposed on the y-axis driving component 512, and can drive the z-axis driving component 513 to move through the y-axis driving component 512, and the picking component 514 is disposed on the z-axis driving component 513 to move, and can drive the picking component 514 to move through the z-axis driving component 513. Through the mutual cooperation of the x-axis driving component 511, the y-axis driving component 512, the z-axis driving component 513 and the picking piece 514, the picking piece 514 finishes the operation of picking up the cleaning bag C and the protective film B, so that a user can carry out self-help film pasting.

Referring to the directions of the coordinate axes in fig. 3, the x-axis driving component 511 can drive the y-axis driving component 512 to move along the x-axis direction, the y-axis driving component 512 can drive the z-axis driving component 513 to move along the y-axis direction, and the z-axis driving component 513 can drive the picking member 514 to move along the z-axis direction.

It is understood that the x-axis drive assembly 511 includes an x-axis drive 5111 and an x-axis mount 5112, the y-axis drive assembly 512 includes a y-axis drive 5121 and a y-axis mount 5122, and the z-axis drive assembly 513 includes a z-axis drive 5131 and a z-axis mount 5132. The x-axis fixing member 5112 is fixed on the supporting platform 112, the x-axis driving member 5111 is disposed on the x-axis fixing member 5112, and the x-axis driving member drives the y-axis fixing member 5122 to move along the x-axis direction; as an example, the y-axis fixing member 5122 is a member disposed in the y-direction. The y-axis driving member 5121 is disposed on the y-axis fixing member 5122 and connected to the z-axis fixing member 5132 to drive the z-axis fixing member 5132 to move along the y-axis direction; the z-axis driving member 5131 is disposed on the z-axis fixing member 5132 and connected to the picking member 514 to drive the picking member 514 to move along the z-axis direction.

In this embodiment, the x-axis drive member 5111 and the y-axis drive member 5121 are both a motor and pulley arrangement. Preferably, an x-axis guide 5113 is disposed on the x-axis fixing member 5112 to provide guidance and support for the y-axis fixing member 5122, a y-axis guide 5123 is disposed on the y-axis fixing member 5122 to provide guidance and support for the z-axis fixing member 5132, the motor is preferably a stepping motor to save cost, the z-axis driving member 5131 is an air cylinder to drive the picking member 514 to move along the z-axis direction, and the picking member 514 performs picking operation by using a suction cup, and combines with an external pneumatic pump to adjust and sense the suction force of the suction cup.

It is understood that the x-axis mount 5112 may be omitted and the x-axis drive 5111 may be directly fixed to the support platform 112, which drives the y-axis mount 5122 connected thereto to move in the x-direction. As a variation, the y-axis fixing member 5122 is a member for connecting the y-axis guide 5123 and the x-axis guide 5113, and the structure thereof is not limited as long as the connection is performed. As a variation, the x-axis driving member 5111 and the y-axis driving member 5121 may be fixed to the x-axis guide 5113 and the y-axis guide 5123, respectively. The z-axis mount 5132 can also be directly fixed to the y-axis guide 5123.

The picking member 514 includes any one of a robot arm and a suction cup to grasp the cleaning pack C, the protective film B by the robot arm or to suck the cleaning pack C, the protective film B by the suction cup. The x-axis driving member 5111, the y-axis driving member 5121 and the z-axis driving member 5131 can be cylinders, or can be a combination of a motor and a lead screw, or a combination of a motor and a pulley, so that the x-axis driving member 5111 drives the y-axis fixing member 5122 to move, the y-axis driving member 5121 drives the z-axis fixing member 5132 to move, and the z-axis driving member 5131 drives the picking member 514 to move.

Referring to fig. 4, the film supplying mechanism 31 is erected on the supporting platform 112, and is integrally cabinet-shaped, and a film storing cavity 311 is disposed on a side of the film supplying mechanism facing the moving mechanism 51, and the film storing cavities 311 are arranged in a matrix; optionally, each film storage cavity 311 is the same size, so as to facilitate production and processing and reduce manufacturing cost.

Specifically, the film supply mechanism 31 is provided with an opening toward one end of the moving mechanism 51, and the internal space of the opening is divided into at least m layers (where m is 2) in the height direction, i.e., the direction parallel to the y-axis guide 5123, and each layer is further divided into at least n small regions (where n is 2) in the length direction, i.e., the direction parallel to the x-axis guide, so that the space inside the entire film supply mechanism 31 is divided into m times n small regions, each of which is the above-mentioned "film storage chamber 311".

It can be understood, because self-service sticking film machine 1 is put in the market more, school, the district, its whole self-service sticking film machine 1's size should not be too big, supply membrane mechanism 31 make full use of space through the mode of erectting, a plurality of deposit membrane chamber 311 distribute on the vertical plane direction (for the horizontal plane), with the size of reduction equipment, improve space utilization, make comparatively small and exquisite that self-service sticking film machine 1 can set up, play the effect of saving space, and supply membrane mechanism 31 can arrange m and take advantage of n and deposit membrane chamber 311, every independent deposit membrane chamber 311 presents the opening form, can place different specifications or size's protection film B, thereby guarantee that its self-service sticking film machine 1 can adapt to the user comparatively extensively, the commonality is stronger, and the screen of the multiple different models of adaptation.

As a modification, a plurality of film storage cavities 311 may be arranged in the horizontal plane direction. The storage cavity 311 is also not limited in size and can have a variety of dimensions. The structure thereof is not limited as long as it can function to accommodate the protective film B.

Further, a reinforcing rib 312 is disposed on a side surface of the film supplying mechanism 31, and the reinforcing rib 312 can increase the stability of the film supplying mechanism 31 to prevent the film supplying mechanism 31 from tilting, collapsing and the like, thereby affecting the film attaching quality.

It can be understood that self-service sticking film machine 1 is when giving electronic equipment A pad pasting, and it needs certain degree of accuracy, and self-service sticking film machine 1 leads to supplying the slope of membrane mechanism 31 or collapse and arouses protection film B aversion, slope etc. in the transportation or in the use, and moving mechanism 51 is unstable easily when adsorbing protection film B, and the quality is not good when follow-up pad pasting, appears pasting partially, the insecure condition.

When the moving mechanism 51 picks up the protection film B from supplying membrane mechanism 31 using picking up piece 514, need to guarantee that picking up piece 514 picks up equal rigidity every time, picking up piece 514 and picking up the position of protection film B and need be accurate promptly, in order to prevent follow-up pad pasting deviation, and the protection film B of different grade type corresponds different sizes and places again in corresponding depositing membrane chamber 311, if can not uniform position, picking up piece 514 and picking up various protection film B and need dispose different procedures, thereby the research and development degree of difficulty has been increaseed and the cost has been raised, and because the iterative speed of electronic equipment A is very fast, the protection film B that leads to required adaptation also needs the adaptability to be changed, thereby lead to moving mechanism 51 need constantly set up the procedure when getting the membrane, for solving this problem, the utility model provides the following technical scheme:

referring to fig. 5 and 6, the protective film B is configured to include a protective layer B1 and a packaging layer B2, the packaging layer B2 is larger than the protective layer B1, and the protective layer B1 is positioned on the packaging layer in a manner including, but not limited to, adsorption and/or adhesion; such as silicone gel electrostatic adsorption and/or adhesion. The protective layer B1 of different protective films B have different or the same size.

It is understood that the protective layer B1 is mainly used to cover the screen of the electronic device a, so as to protect, prevent wear, explosion, water, dust, peep, and radiation of the electronic device a, which is exemplified by: a tempered glass layer, a privacy glass layer, a resin layer, and an encapsulation layer B2 for protecting the adsorption and/or adhesion properties of the protective layer B1, which may also be referred to as a release layer or peelable layer.

Further, at least two protective films are stored in the film supply mechanism, the protective layers B1 of the at least two protective films B are different in size, and the packaging layers B2 are the same in shape and size. This may allow different types or sizes of protective layers B1 to be unified in overall size. This greatly facilitates the production, packaging, transportation, storage and organization of the protective film B. For example, the protective film B can be mass-produced in production, and the protective film B can be packaged in the same size, and the overall size is consistent whether in a packaged state or an unpackaged state, so that the protective film B is convenient to transport, store and organize. The plurality of film storage cavities 311 may also be substantially uniform in size. Preferably, the film storage cavity 311 is the same in shape and size as the packaging layer B2, and the protective film B is limited in the film storage cavity 311 by the packaging layer B2.

Furthermore, a set distance L is formed between one end T of the protection layer B1 and the corresponding end T' of the packaging layer B2, and the set distances L of different protection films B are the same. Preferably, the distance L is set to 1.8cm to 4cm, more preferably 2 to 3.5 cm. An operation area is formed between one end T of the protective layer B1 and one end T' corresponding to the packaging layer B2, so that the peeling operation between the protective layer B1 and the packaging layer B2 can be carried out. For example, the operation area can be pressed against the external object, and the peeling operation can be completed by moving the protective layer B1. The same peeling operation can be used with different protective films B, with the same set distance L. To facilitate peeling, the hardness of the encapsulation layer B2 is greater than the hardness of the protective layer B1.

It is understood that the protective layer B1 is the portion attached to the electronic device a, that is, the protective film B1 mentioned above may be 4.3 inches, 4.7 inches, 5.0 inches, 5.7 inches, etc., and the encapsulation layer B2 functions to protect the protective layer B1, where the encapsulation layer B2 needs to be larger than the maximum size of all the protective layers B1 to protect the protective layer B1, as exemplified by: if the maximum size that this self-service sticking film machine 1 can adapt to is 6.5 cun, and encapsulation layer B2 needs to exceed 6.5 cun promptly, and simultaneously, protective layer B1 and encapsulation layer B2 are located same center for it is more convenient when picking up protection film B that piece 514 is picked up.

As a preferred embodiment, the packaging layer B2 has a certain thickness, and one side of the packaging layer B2 close to the protective layer B1 is provided with a groove B21 with the shape and size consistent with those of the protective layer B1, the protective layer B1 is positioned in the groove, and the front and back sides of the protective film B are flat, so that stacking of a plurality of protective films B is facilitated.

Referring to fig. 7, further, a supporting portion B3 extends from an edge of the package layer B2. It is understood that the abutting portion B3 is provided in different forms of the operation region. The abutting portion B3 is defined as a portion from which the encapsulation layer B2 protrudes, for use in subsequently separating the protection layer B1 and the encapsulation layer B2. The abutting portion B3 can be considered as a part of the packaging layer B2, i.e. the packaging layer B2 is larger than the protection layer B1. The shape and size of the region of the encapsulation layer B2 except for the abutting portion B3 can be completely consistent with those of the protection layer B1, and preferably, the size of the region of the encapsulation layer B2 except for the abutting portion B3 is larger than that of the protection layer B1.

Referring to fig. 8, a position-limiting structure 3111 is disposed on an inner side of the film storage cavity 311, i.e. a side of the film storage cavity facing away from the entering direction of the picking member 514, and when the protective film B is placed, the protective film B is limited by the position-limiting structure 3111 and the packaging layer B2.

It can be understood that, when the protection films B are placed in the film storage cavities 311, since the protection layers B1 are different in size for different users, and are limited to have the same size of the packaging layer B2, each protection film B can be placed at the same position of each film storage cavity 311 only by comparing the packaging layer B2 with the limiting structure 3111, and this way has the advantage that each time the moving mechanism 51 picks up the protection film B from the film supply mechanism 31 by using the picking piece 514, only a uniform way needs to be adopted, the operation procedure of the moving mechanism 51 is simplified, the cost is reduced from the side, and the operation speed is increased. The plurality of film storage cavities 311 may be the same or different in size without limitation.

Further, the position-limiting structure 3111 may be configured as at least one position-limiting post 3112 standing upright on the film storage cavity 311 to limit the position of the protective film B in the film storage cavity 311.

Specifically, the abutting portions B3 are arranged to be at least two and spaced from each other, optionally two, and gaps between the limiting post 3112 and the abutting portions B3 are adapted to each other, so that the protective film B is clamped on the limiting post 3112, and the position of the protective film B in the film storage cavity 311 is fixed.

The approach employed in some embodiments is: the position-limiting post 3112 is provided with a groove 31111 adapted to the corner of the packaging layer B2, that is, the shape of the groove 31111 should be adapted to the contour of the corner of the packaging layer B2, so that the protective film B can be just placed in the area enclosed by the position-limiting post 3112, thereby fixing the position of the protective film B in the film storage cavity 311.

The structure size of the abutting part B3 of the protective film B with different sizes is the same, and the structure of the limiting column 3112 in the different film storage cavities 311 is also the same, so that a worker placing the protective film B only needs to correspond the protective film B to the film storage cavity 311 matched with the protective film B or does not need to distinguish the film storage cavity 311, the direct integral placement can complete the loading, the operation mode is very simple, and the labor intensity is reduced.

It can be understood that any one or combination of the above manners is adopted, so that the position of the protective film B is fixed, and the protective film B is within the range covered by the utility model.

The protective films B of different models are provided with the abutting parts B3 different in any one or combination of color, size and shape, and the abutting parts B3 of the protective films B of different sizes are optionally provided with consistent widths which are matched with different lengths according to different models, so that the protective films B are prevented from being misplaced.

Referring to fig. 9 (for clarity, a part of the structure is omitted in the figure), wherein a peeling device is disposed at the bottom of the film supplying mechanism 31, i.e. at a side close to the supporting platform 112, the peeling device is a peeling plate 313, the material of the peeling plate 313 is not limited, and it can be regarded as a raised thin plate for separating the protective layer B1 of the protective film B from the encapsulation layer B2; the operation area of the encapsulation layer B2 is held against the bottom of the peeling plate 313, and the peeling operation is completed by moving the protective layer B1 upward. The set distances L corresponding to the operation areas of the protective films B with different sizes are the same, so that the lengths of the protective films B extending into the bottom of the stripping plate 313 can be fixed, the program is simplified, the universality of the equipment is improved, and the control is simplified. The supporting platform 112 has an inner hole 1121, and one end of the peeling plate 313 is fixedly connected to the film supplying mechanism 31, and the other end thereof extends out and hangs in the air, that is, extends out and hangs in the air from the inner edge of the inner hole 1121.

Referring to fig. 10, after the protective film B is stacked with the protective layer B1 facing upward and stored in the film storage cavity 311, the picking member 514 is moved into the film storage cavity 311 from the opening of the film supplying mechanism 31, and the protective film B is taken out.

The concrete mode is as follows: taking any one of the film storage cavities 311 as an example, the picking member 514 moves along the z-axis direction to a position above the picking member 514 and the protective film B under the action of the z-axis driving assembly 513, and moves down along the y-axis direction under the action of the x-axis driving member 5111 until the protective layer B1 contacting the protective film B continuously moves down, the pneumatic pump externally connected to the picking member 514 is provided with a pressure sensor (not shown), when the pressure sensor senses that the air pressure reaches a preset threshold value, the self-help laminator 1 determines that the protective film B has been adsorbed, and at this time, the picking member 514 moves out under the action of the opposite direction of the z-axis, so that the whole film picking process is completed. The pressure sensor can be omitted, and the picking piece 514 is vacuumized within a set time length to complete the picking of the protective film B. Preferably, the position where the pick-up member 514 sucks the protective film B is the center position thereof.

It can be understood that, based on the above setting and the situation that the protective film B is stored in the fixed position of the film storage cavity 311, each time the picking member 514 picks up the protective film B in the film storage cavity 311, the above operations are only required to be performed, and for the different types of protective films B, no additional program is required, so as to simplify the process, and as an embodiment, the surface of the encapsulation layer B1 away from the protective layer B1 is a non-smooth surface. If the protective film B is placed reversely, that is, the encapsulation layer B2 faces upward, when the picking piece 514 contacts the encapsulation layer B2, because the encapsulation layer B2 is not a smooth surface, the air pressure of the picking piece cannot reach the preset threshold value, and at this time, the picking piece 514 cannot adsorb the protective film B, the operation is stopped and an alarm is given until a worker repairs the protective film B, so that the accident that the electronic equipment is damaged due to an error in the subsequent film sticking process is avoided.

After the protective film B is adsorbed by the picking member 514, the protective film B is moved to the peeling plate 313 by the operation of the moving mechanism 51 to perform the function of peeling the protective layer B1 and the encapsulating layer B2.

Since the peeling plate 313 is set at the lower side of the film supplying mechanism 31, the moving mechanism 51 can move the picking member 514 to the peeling plate 313 only by a small stroke, thereby reducing the operation time of the moving mechanism 51, accelerating the film sticking efficiency and shortening the waiting time of a user.

Referring to fig. 9 and fig. 11, the step of peeling the passivation layer B1 and the encapsulation layer B2 includes the following steps:

stripping step 1: the pick-up member 514 picks up the protective film B to cover the peeling plate 313 on the operation area of the encapsulation layer B1;

a stripping step 2: the picking member 514 is moved in a first direction relative to the stripper plate B2 to partially or wholly separate the coverlay B1 and the encapsulation layer B2; and

a stripping step 3: the picking member 514 is moved in a second direction relative to the stripper plate B2 to separate the resist B1 and the encapsulation layer B2 as a unit.

Optionally, the "first direction" is a direction perpendicular to the surface of the peeling plate 313, and the "second direction" is a direction parallel to the surface of the peeling plate 313. "moving in a first direction relative to stripper plate B2 and moving in a second direction relative to stripper plate B2" is to be understood as meaning that the picking member 514 can be moved, the stripper plate 313 can be stationary, or the picking member 514 can be stationary, the stripper plate 313 can be moved, and both the picking member 514 and the stripper plate 313 can be moved; it is sufficient to satisfy the result caused by the above movement, that is, in some embodiments, if the peeling plate 313 is adopted to move, the present invention also falls within the scope of the present invention.

It can be understood that the separation from the protective layer is realized by the elastic deformation of the packaging layer B2 by utilizing the characteristics of the hard material film, and the process is simple. As an embodiment, the encapsulation layer B2 may also be made of a soft material, and it is within the scope of the present invention to achieve the same effect by using the above method.

The self-help laminator 1 further comprises a recycling mechanism 12, wherein the recycling mechanism 12 is disposed at the lower side of the peeling plate 313, specifically, at the lower side of the inner hole 1121, so that after the protective layer B1 and the encapsulation layer B2 are completely separated, the protective layer B1 is still adsorbed on the picking piece 514, and at this time, the encapsulation layer B2 falls into the recycling mechanism 12. The encapsulation layer B2 may be reused.

In some embodiments, the recycling mechanism 12 further includes a camera 121, and the camera 121 is disposed between the recycling mechanism 12 and the peeling plate 313, and is used for detecting whether the packaging layer B2 falls to determine whether the next process can be performed.

Referring to fig. 12 and 13, the cleaning bag mechanism 41 includes a bottom plate 411 and at least two side plates 412, wherein the side plates 412 are U-shaped, the bottom plate 411 is disposed on the supporting platform 112, the two U-shaped side plates 412 are oppositely disposed at intervals to form a cavity for placing the cleaning bags C, and the cleaning bags C are stacked in the cavity so as to be picked up by the picking member 514.

The side plate 412 is U-shaped, and can limit the cleaning bag C in the cavity to prevent the cleaning bag C from being separated from the cavity. The side panels 412 are erected on the support platform 112 to increase the number of cleaning packs C that can be stacked in the cavity, thereby reducing the number of times that workers replenish the cleaning packs C.

It is understood that the side plate 412 and the bottom plate 411 may be integrally formed, welded, screwed, etc. and the partition 413 and the bottom plate 411 may be integrally formed, welded, screwed, etc. As a modification, the bottom plate 411 is a part of the supporting platform 112, and the side plates 412 and the partition 413 are directly disposed on the supporting platform 112.

A sliding slot 1116 is further disposed in the outer housing 111, the position of the sliding slot 1116 corresponds to the second opening 1112, and the sliding slot 1116 is disposed in an inclined manner, so that the picking member 514 can place the picked cleaning bag C into the sliding slot 1116 and slide out from the second opening 1112.

When the picking member 514 performs the operation of picking up the cleaning bag C, first, the y-axis driving member 5121 drives the z-axis fixing member 5132 to move to a position slightly higher than the side plate 412; then, the y-axis fixing member 5122 is driven to move by the x-axis driving member 5111, and the z-axis driving member 5131 drives the picking member 514 to move, so that the position of the picking member 514 corresponds to the accommodating cavity; further, the y-axis driving member 5121 drives the z-axis fixing member 5132 to move toward the cleaning bag C, and when the picking member 514 contacts the cleaning bag C, the suction cup is controlled by the air pump to suck air, so that the contacted cleaning bag C is sucked; further, the y-axis driving member 5121 drives the z-axis fixing member 5132 to move reversely, so as to take out the cleaning bag C from the chamber; finally, the z-axis driving member 5131 drives the pick-up member 514 to move toward the sliding slot 1116, and the pneumatic pump controls the suction cup to deflate, so that the cleaning bag C picked up by the pick-up member 514 falls into the sliding slot 1116 and slides out from the second opening 1112, and thus the user can use the cleaning bag C to scrub the screen of the electronic device a. It will be appreciated that the specific path of travel for the cleaning C pack is not limited, as long as the picking member 514 can pick up the cleaning C pack and place the cleaning C pack into the chute 1116.

To the utility model discloses the self-service sticking film machine that explains, this action of "clean package C transport to user" and "tear film" action can not go on in proper order, also can go on in step, as long as its mode is unanimous or satisfies the effect of equivalence, all belongs to the utility model discloses the within range that covers.

Referring to fig. 14, the contact portion of the first positioning mechanism 61 and the passivation layer B1 is located in the same inclined plane so that the passivation layer B1 is supported by the first positioning mechanism B1 in an inclined manner. The first positioning mechanism 61 is used for positioning the protective layer B1, the second positioning mechanism 71 is used for positioning the electronic device A, when the picking piece 514 is subjected to film tearing, only the protective layer B1 is picked at the moment, and the protective layer B1 is moved to the first positioning mechanism 61 under the action of the moving mechanism 51 for positioning. After the user places electronic equipment A into self-service sticking film machine, place electronic equipment A on conveying board 212, carry to second positioning mechanism 71 through conveying track 211 and fix a position to it is accurate to realize the pad pasting.

It is understood that the actions of positioning the protective layer B1 and positioning the electronic device a may be performed in different orders or simultaneously, and all fall within the scope of the present invention as long as the actions are consistent or equal.

Referring to fig. 15 and 16, the first positioning mechanism 61 includes a top bead 612, a fixing seat 611, and at least one movable plate, optionally two movable plates, namely a first movable plate 613 and a second movable plate 614, wherein the fixing seat 611 is disposed on the supporting platform 112, the top bead 612 is disposed on the fixing seat 611 and protrudes from a plane of the fixing seat 611, the top bead 612 is made of any one of stainless steel, ceramic, silicone, and aluminum, the first movable plate 613 and the second movable plate 614 are movable relative to the fixing seat 611, and as an embodiment, the movable plates are slidably connected to the fixing seat 611. After the protective film B picked up by the moving mechanism 51 peels off the sealing layer B2, the protective layer B1 is placed on the holder 611, and the protective layer B1 is supported by the top bead 612 to prevent the adhesive of the protective layer B1 from losing its adhesiveness. The first moving plate 613 and the second moving plate 614 move to position the protective layer B1, so that the first film attaching mechanism 81 can accurately attach the positioned protective layer B1 to the electronic device a.

Further, the fixing seat 611 is square, and two adjacent side edges are provided with a limit plate 6121, wherein the first moving plate 613, the second moving plate 614 and the limit plate 6121 are disposed on four directions of the fixing seat 611;

the top beads 612 are protruded from the fixing base 611 to the same height, and the top surfaces of the top beads 612 define an inclined plane, so that the protection layer B1 can be obliquely placed on the top beads 612, i.e. the top beads 612 are located in the same inclined plane, so that the protection layer is obliquely supported. The inclination angle of the inclined plane is 3-20 degrees. Since the top bead 612 is in point contact with the protective layer B1, it can protect its cleanliness and tackiness.

Further, the top bead 612 is connected to the fixed seat 611 in a rolling manner, so that when the first moving plate 613 and the second moving plate 614 move the protective layer B1, the top bead 612 moves along with the protective layer B1, thereby converting sliding friction between the top bead 612 and the protective layer B1 into rolling friction, and further preventing the adhesive of the protective layer B1 from losing viscosity. As a variation, the top bead 612 may also be stationary. Further, the outer surface of the top bead 612 is coated with a PTFE layer to reduce the coefficient of friction of the surface, and further prevent the adhesive of the protective layer B1 from losing its adhesiveness.

It is to be understood that the four top beads 612 may be arranged in a manner corresponding to the corners of the protective layer B1, or in a manner corresponding to four sides of the protective layer B1, or in an irregular manner, as long as the four top beads 612 can stably support the protective layer B1, and in other embodiments, the number of the top beads 612 may be three or more than four.

Specifically, the limit plate 6121 is in an "L" shape, the limit plate 6121 is matched with the adjacent long edge and short edge of the electronic device a, the first moving plate 613 and the second moving plate 614 are respectively disposed on the other two adjacent sides of the fixing seat 611, so that after the protective layer B1 is placed on the top bead 612, the first moving plate 613 and the second moving plate 614 linearly push the protective layer B1 from two directions, so that two adjacent edges of the protective layer B1, which are close to the limit plate 6121, are respectively aligned with the limit plate 6121, thereby centering the protective layer B1 and preventing the protective layer B1 from deflecting in the horizontal direction, when the adjacent two sides of the protective layer B1 abut against the limit plate 6121, the position of the protective layer B1 is defined, that is, to complete the positioning of the protective layer B.

It is understood that the first positioning mechanism 61 further includes a first driving element 615 and a second driving element 616, the first driving element 615 is connected to the first moving plate 613 for driving the first moving plate 613 to move, and the second driving element 616 is connected to the second moving plate 614 for driving the second moving plate 614 to move. The first driving element 615 may be an air cylinder, or a combination of a motor and a lead screw, or a combination of a motor belt, and the second driving element 616 may be an air cylinder, or a combination of a motor and a lead screw, or a combination of a motor belt. As an example, when the first moving plate 613 and the second moving plate 614 position the protective layers B1 with different sizes, the first moving plate 613 and the second moving plate 614 move by different distances, and the position where the protective layer B1 is picked up by the first film sticking mechanism 81 is determined according to the moving distances of the first moving plate 613 and the second moving plate 614.

As a modification, the first positioning mechanism 61 includes a first sensor 617 and a second sensor 618, the first sensor 617 is provided on the first moving plate 613, and when the first moving plate 613 moves and the side edge of the protective layer B1 contacts the first moving plate 613, the first sensor 617 is triggered to control the first moving plate 613 to stop moving. And the other side of the protective layer B1 contacts the second moving plate 614, the second sensor 618 is triggered to stop the movement of the second moving plate 614. The first moving plate 613 and the second moving plate 614 are both stopped to complete the positioning of the protective layer B1. After the positioning is completed, the first moving plate 613 and the second moving plate 614 move in opposite directions. The first sensor 617 and the second sensor 618 include, but are not limited to, one or more of a pressure sensor and a micro switch, and the positions thereof are not limited, and it is only necessary that they can function to sense that the protection layer B1 is in contact with the movable plate.

In this embodiment, the first positioning mechanism 61 further includes a first fixing plate 619, a second fixing plate 620 and a supporting rod 621, the first fixing plate 619 and the second fixing plate 620 are vertically disposed, the supporting rod 621 is four, and is fixed on the supporting platform 112 to provide support for the first fixing plate 619, the fixing seat 611 is fixed on the first fixing plate 619, and the first driving member 615 is installed on the first fixing plate 619 and connected to the first moving plate 613 to drive the first moving plate 613 to move along the x-axis direction, and the second driving member is installed on the second fixing plate 620 and connected to the second moving plate 614 to drive the second moving plate 614 to move along the z-axis direction.

Referring to fig. 17 and 18, the second positioning mechanism 71 includes two clamping assemblies 711 and two abutting assemblies 712, the two clamping assemblies 711 are symmetrically disposed on two opposite sides of the conveying track 211, the abutting assemblies 712 are disposed right above the conveying track 211, so that the clamping assemblies 711 and the abutting assemblies 712 form a U shape and are disposed around the conveying mechanism 21, when the electronic device a moves to the second positioning mechanism 71 under the action of the conveying track 211, the two clamping assemblies 711 disposed oppositely clamp and position the long side direction of the electronic device a, and the abutting assemblies 712 abut and position the short side direction of the electronic device a.

Specifically, the clamping assembly 711 includes a third moving plate 7111, a third driving member 7112 and a third fixing plate 7113, and the holding assembly 712 includes a fourth moving plate 7121, a fourth driving member 7122, a fourth fixing plate 7213 and a fourth sensor 7124.

The third fixing plate 7113 is fixed to the supporting platform 112, the third driving member 7112 is fixed to the third fixing plate 7113 and connected to the third moving plate 7111 to drive the third moving plate 7111 to move along the x-axis direction, the fourth fixing plate 7213 is fixed to the first film sticking mechanism 81, and the fourth driving member 7122 is fixed to the fourth fixing plate 7213 and connected to the fourth moving plate 7121 to drive the fourth moving plate 7121 to move along the z-axis direction.

The electronic device a is simultaneously and linearly pushed by the two third moving plates 7111 and the fourth moving plate 7121, so that the two third moving plates 7111 clamp two long sides of the electronic device a to centralize the electronic device a, and the fourth moving plate 7121 abuts against one short side of the electronic device a, so that the position of the electronic device a on the conveying plate 212 is limited, and the positioning of the electronic device a is completed.

As a modification, the clamping module 711 may be provided with a third sensor 7114 and a fourth sensor 7124, the third sensor 7114 is provided on the third moving plate 7111, when the electronic device a is clamped and positioned, the third moving plate 7111 of the two clamping modules 711 moves, and the long side of the electronic device a contacts with the third moving plate 7111, and the third sensor 7114 is triggered to control the third moving plate 7111 to stop moving. When the short side of the electronic device a contacts the fourth moving plate 7121, the fourth sensor 7124 is triggered, which controls the fourth moving plate 7121 to stop moving. The positioning of the electronic device a is completed after the third moving plate 7111 and the fourth moving plate 7121 stop moving. Alternatively, the third moving plate 7111 and the fourth moving plate 7121 may be moved in opposite directions after the positioning is completed.

As an embodiment, when the third moving plate 7111 and the fourth moving plate 7121 position the electronic devices a with different sizes, the distances to which the third moving plate 7111 and the fourth moving plate 7121 move are different, and the position at which the first film sticking mechanism 81 attaches the protective layer B1 to the electronic devices a is finally determined according to the moving distances of the third moving plate 7111 and the fourth moving plate 7121.

In summary, by providing a sensor thereon to detect whether the clamping component 711 and the abutting component 712 are in contact with the electronic device a, whether the clamping component 711 and the abutting component 712 are clamped or not is detected, so as to adapt to electronic devices a with different sizes, and the occurrence of misoperation and malicious operation can be prevented, as exemplified by: when the user selects the wrong model of the electronic device a, the third sensor 7114 and the fourth sensor 7124 can protect the electronic device a through the sensors, and the electronic device a is prevented from being damaged.

The third driving member 7112 may be an air cylinder, or a combination of a motor and a screw rod, or a combination of a motor and a belt, and the fourth driving member 7122 may be an air cylinder, or a combination of a motor and a screw rod, or a combination of a motor and a belt. The third sensor 7114 and the fourth sensor 7124 include, but are not limited to, one or more of a pressure sensor, a microswitch.

Referring to fig. 19A, the first film pasting mechanism 81 is disposed on the upper side of the first positioning mechanism 61 and is mainly responsible for the 2D surface attachment of the surface to be pasted, and the second film pasting mechanism 91 is disposed on the upper side of the second positioning mechanism 71 and is mainly responsible for the 2D surface attachment of the surface to be pasted, such as 2.5D and 3D, so that the first film pasting mechanism 81 and the second film pasting mechanism 91 can be adapted to the type of the screen of the electronic device a.

Wherein the "2D surface" is a pure plane. The 2.5D surface is a surface with a small number of arcs at the edge part, the other parts of the mobile phone screen are still pure planes, the 3D surface is a larger arc surface nonplanar surface, the other parts are still pure planes, and the 2D surface, the 2.5D surface and the 3D surface are respectively provided with a 2D film, a 2.5D film and a 3D film in a similar way, wherein the protective layer B1 is a hard or soft 2D or 2.5D film.

With reference to fig. 19A, the first film sticking mechanism 81 includes a film sticking structure 811, a first film driving member 812 and a dual-axis mechanism 813, wherein the film sticking structure 811 and the first film driving member 812 are connected to the dual-axis mechanism 813, so that the film sticking structure 811 and the first film driving member 812 can move in the x direction and the y direction.

In some embodiments, the two-axis mechanism 813 can be replaced by a three-axis mechanism, such that the film structure 811, the first film driving component 812 can move in the x-direction, the y-direction, and the z-direction; also all fall within the scope covered by the present invention.

It will be appreciated that since the dual axis mechanism 813 is well known in the art and is generally similar in functional features to the moving mechanism (not shown), the present embodiment will not be described in greater detail. Furthermore, the key difference between the dual-axis mechanism 813 and the moving mechanism is that the dual-axis mechanism 813 is driven by a servo motor, and the moving mechanism is driven by a stepping motor, the reason is that the servo motor is superior to the stepping motor in many aspects of performance, such as control precision, overload capacity, running performance and the like, from the above, the moving mechanism only needs to execute the mold taking and film tearing and does not require precise displacement commands, the double-shaft mechanism 813 is responsible for film pasting, the requirement on film pasting accuracy is high, factors in multiple aspects such as control requirements and cost are comprehensively considered, in the present embodiment, therefore, the device for moving the protective film B is divided into the biaxial mechanism 813 and the moving mechanism to be separately performed, and it is understood here that, if the moving mechanism is directly driven by a servo motor, the double-shaft mechanism 813 may not be required, and a plurality of operations may be performed by only the moving mechanism.

After the electronic device a and the protective layer B1 are respectively positioned, the electronic device a on the transport plate 212 moves to a preset first position under the action of the transport track 211, the film attaching structure 811 moves downward along the y-axis to adsorb the protective layer B1 on the first positioning mechanism 61, and moves upward to a certain height, the film attaching structure 811 moves in the direction of the electronic device a, that is, in the x-axis direction, and then the protective layer B1 is attached to the electronic device a, wherein the moving track of the electronic device a on the transport plate 212 is perpendicular to the moving direction of the film attaching structure 811 in the direction of the electronic device a, so that the required operation of the film attaching structure 811 is simple, the process is simplified, and the film attaching efficiency is increased.

Referring to fig. 19A and 19B, the film structure 811 includes an absorption portion 8111 and a pressing portion 8112, the absorption portion 8111 mainly absorbs the protective layer B1 by air pressure through an external air pressure pump, and the pressing portion 8112 is used for rolling during subsequent film pasting; the pressing portion 8112 is disposed at one end of the absorption portion 8111, and the whole film sticking structure 811 inclines downward with the pressing portion 8112, that is, the pressing portion 8112 is located at the lower end of the absorption portion 8111, and the inclination angle of the pressing portion 8112 with respect to the horizontal plane is 1-8 °, and preferably 0.5-2 °.

The absorption portion 8111 is slidably connected with the pressing portion 8112, the first film driving member 812 is fixedly connected between the double-shaft mechanism 813 and the pressing portion 8112, the first film driving member 812 includes an output shaft 8121 facing the pressing portion 8112, and the output shaft 8121 is retractable to push the pressing portion 8112 to move in a direction away from the absorption portion 8111, so that the pressing portion 8112 can press the protection layer B1 downwards.

The pressing portion 8112 is a roller, and the surface thereof is made of an elastic material, preferably silica gel, foam, or the like. As an example, the length of the pressing part 8112 is equal to or greater than the width of the protective layer B1 so that it can sufficiently press the protective layer B1 during the pressing process. As an embodiment, when the surface of the pressing portion 8112 is made of an elastic material, the length of the pressing portion 8112 is greater than the width of the protection layer B1, and the elastic material is elastically deformed during the pressing process, so that the pressing portion can be better adapted to the surface to be film-pasted of the electronic device a, and the attaching effect is optimized, for example, when the surface to be film-pasted is a 2.5D curved surface, a better film-pasting effect can be obtained.

It can be understood that the film structure 811 is a fixed tilting structure, i.e. it does not need to be driven to tilt by a driving device, so that the equipment cost can be greatly reduced.

When the films required by the electronic device a are 2D and 2.5D, the method for attaching the protective layer B1 to the electronic device a, that is, the film attaching method, is specifically as follows:

first film pasting step 1: the adsorption part 8111 picks up the protective layer B1, the protective layer B1 is in an inclined state, and the protective layer B1 moves to the upper part of the electronic device a;

a first film pasting step 2: the lower end of the protective layer B1 is brought into contact with the electronic device a by the adsorption portion 8111, and the end is pressed against the electronic device a by the pressing portion 8111;

a first film pasting step 3: the pressing part 8112 presses the end of the protective layer B1 for a preset time period t; the adsorption portion 8111 releases the adsorption, and the protective layer B1 moves toward the electronic device a; and

a first film pasting step 4: the pressing portion 8112 rolls from one end of the protective layer B1 to the other end until passing through the entire protective layer B1.

It can be understood that, in the processes of the first film-pasting step 1 to the first film-pasting step 2, the protective layer B1 may be inclined at an angle c with respect to the electronic device a, and then the protective layer B1 may be moved to the upper side of the electronic device a and moved downward until one end of the pressing portion 8112 contacts and presses the electronic device a.

In some modifications, the film-pasting structure 811 is not disposed obliquely, but disposed obliquely by using the conveying plate 212, or the conveying plate 212 is tilted by adding a driving device, so long as the above-mentioned film-pasting manner is adopted, which also falls within the scope covered by the present invention.

As an embodiment, the protective layer B1 moves downward in the first film-pasting step 3, and the first film-pasting driving component 812 controls the pressing part 8112 to gradually change from the inclined state to the horizontal state.

As another example, in the first film-attaching step 3, the manner of moving down the protective layer B1 is as follows: the adsorption part 8111 is used for adsorbing the protective layer B1 and reducing air pressure or directly cutting off air pressure through an external air pressure pump, at this time, the protective layer B1 is not separated from the adsorption part 8111 due to insufficient air pressure, and one end of the protective layer B1 is pressed by the pressing part 8112, so that the protective layer B1 is bounced to the electronic device a and attached to the electronic device a. Alternatively, the pressing portion 8112 moves to press the protective layer B1 while the protective layer B is being pushed toward and bonded to the electronic device a.

As a modification, in the first film pasting step 4, the conveying plate 212 moves on the conveying rail 211 along the direction of the adsorption part 8111 toward the pressing part 8112, so that the pressing part 8112 is pressed from one end of the electronic device a to the other end while maintaining the pressing force on the protective layer B1, and thus the entire protective layer B1 is attached to the electronic device a under the pressure of the pressing part 8112, and the entire film pasting of the electronic device a is completed.

Referring to fig. 20, as a modified embodiment, the first film pasting mechanism 81a includes a first film pasting driving member 810a, a pressing driving member 820a, a pressing portion 8112a and an adsorbing portion 8111a, the first film pasting driving member 810a drives the adsorbing portion 8111a to make a linear motion, the pressing driving member 820a drives the pressing portion 8112a to move, and the pressing portion 8112a and the adsorbing portion 8111a are arranged independently of each other, that is, the pressing portion 8112a and the adsorbing portion 8111a move independently of each other, so that control is simplified and cost is reduced. In this embodiment, the adsorption part 8111a is fixed on the supporting mechanism 11 by the first film pasting driving part 810a, and the pressing part 8112a is fixed on the second film pasting mechanism 91 by the pressing driving part 820a, it can be understood that the pressing part 8112a can also be directly fixed on the supporting mechanism 11 by the pressing driving part 820 a. The absorption portion 8111a is disposed in an inclined manner, and defines a high end and a low end according to the position, and the pressing portion 8112a is disposed at the low end of the absorption portion 8111 a.

Referring to fig. 21 and 22, the second film pasting mechanism 91 includes a supporting plate 913, the supporting plate 913 is fixedly connected to the supporting platform 112, a cavity cover 911 is disposed between the supporting plate 913 and the supporting platform 112 of the second film pasting mechanism 91, and a second film pasting driving member 912 is disposed between the cavity cover 911 and the supporting plate 913, the second film pasting driving member 912 is fixedly connected between the supporting plate 913 and the cavity cover 911, so that the cavity cover 911 can move up and down under the driving of the second film pasting mechanism, and the second film pasting driving member 912 is preferably a servo motor to ensure the accuracy.

Furthermore, one end of the cavity cover 911 facing away from the second film driving member 912 is in a semi-enclosed shape, that is, an opening is formed on one side of the cavity cover facing away from the second film driving member 912, and a cavity 9111 is formed inside the opening; the cover 911 is moved down to cover the transfer plate 212, so that the chamber 9111 forms an enclosed space. The connection of the chamber cover 911 and the transfer plate 212 may be provided with a sealing ring (not shown) to increase the sealing of the enclosed space.

Wherein chamber 9111 is sized to fully receive electronic device a thereon when in a closed position with transfer plate 212, chamber 9111 is sized to be larger than 6 inches, and more preferably larger than 8 inches. To accommodate the size of most electronic devices a on the market, and thus to fully accommodate them.

An airbag 9112 (shown in black shading for clarity) is disposed within the interior of the chamber 9111; the cavity cover 911 is provided with a first air hole 914 and a second air hole 915, wherein the first air hole 914 is communicated with the airbag 9112, the second air hole 915 is communicated with the cavity 9111, and the first air hole 914 and the second air hole 915 can be respectively externally connected with an air pressure pump and a vacuum pump so as to respectively pressurize or depressurize the airbag 9112 and the cavity 9111.

The size of the airbag 9112 is larger than that of the electronic device a, so that when the chamber 9111 is covered with the transmission plate 212, the airbag 9112 can completely cover the protective layer B1 primarily attached to the electronic device a; the specific implementation mode is as follows:

referring to fig. 22, the airbag 9112 is fixedly connected within the chamber 9111 and completely encloses the chamber 9111 such that the chamber 9111 is divided into a first enclosed space 9111a and a second open space 9111 b; and the height of the second space 9111B is limited, that is, the distance between the second space 9111B and the opening of the chamber 9111 is limited to 3 mm-6 mm, the connection mode of the airbag 9112 in the chamber 9111 is not limited, the second space 9111B can be clamped and bonded, when the chamber 9111 is covered with the transmission plate 212, the electronic device a enters the second space 9111B from the opening, because the thickness of the electronic device a is about 6.5 mm-10 mm, the electronic device a can extrude the airbag 9112, and the protective layer B1 on the electronic device a is completely covered under the elastic deformation of the airbag 9112.

Preferably, the height of second space 9111b is less than the height of electronic device a, such that when the chamber is closed, the electronic device enters second space 9111b from the opening and squeezes the bladder.

As an embodiment, the first space 9111a is externally connected with a pneumatic pump, and the first space 9111a can be pumped outwards while the airbag 9112 is inflated, so that the inflation efficiency of the airbag 9112 is improved, the stay time of the process is reduced, and the waiting time of the user for the film sticking is reduced.

As another example, the air bags 9112 may be disposed on the end surface and both sides of the inner wall of the chamber 9111, i.e., in a shape of a "d" in conformity with the chamber 9111, and when the chamber 9111 is covered with the transfer plate 212, the air bags 9112 completely wrap the protective layer B1 on the electronic device a. As a modification, the airbag 9112 may be disposed only on two sides of the inner wall of the chamber 9111, and only cover the arc surface of the electronic device a, which also falls within the scope of the present invention. The airbag 9112 is an inflatable airbag, which is a variant in which an inner space is fixed, and it directly presses the electronic device a in a vacuum state of the chamber 9111.

Referring to fig. 24 and fig. 25 (for clarity, the protection layer B1 is shown in gray shade), when the required film of the electronic device a is 3D, the whole film sticking step of the self-help film sticking machine 1, i.e. the film sticking method, is as follows:

step S0: the first positioning mechanism and the second positioning mechanism are used for respectively positioning the protective layer and the electronic equipment;

step S1 (second film application step 1): the first film sticking mechanism obtains the protective layer from the first positioning mechanism and preliminarily sticks the protective layer to the electronic equipment;

step S2 (second film application step 2): the cavity cover of the second film sticking mechanism moves relative to the direction of the electronic equipment so as to completely contain the electronic equipment in the cavity; and

step S3 (second film application step 3): the second film pasting mechanism at least completes secondary pasting of the electronic equipment and the protective layer through the expansion of the air bag in the cavity and the extrusion of the protective layer on the electronic equipment.

Further comprising the step of S4, the step of,

step S4 (second film application step 4): the cavity cover moves relatively far away from the direction of the electronic equipment after secondary fitting, and the electronic equipment moves out.

Preferably, in step S2, the chamber is closed and the chamber is evacuated.

The concrete mode is as follows: air in the chamber 9111 is pumped out by the external vacuum pump of the second air hole 915, so that the absolute pressure in the chamber 9111 is lower than the atmospheric pressure, even if the chamber 9111 is in a negative pressure state (vacuum state), thereby eliminating air bubbles in the chamber 9111 and enabling the protective layer B1 primarily attached to the electronic device a to be attached more tightly; the duration of the negative pressure state is kept for the preset time T so as to more thoroughly clean bubbles and increase the quality of the film.

It is to be understood that, in step S2, after the electronic device a is moved to a position right below the cavity cover 911 by the transmission plate 212, the cavity cover 911 is moved downward by the second film driving component 912, and the cavity cover 911 and the transmission plate 212 are closed to close the cavity 9111, so as to completely accommodate the electronic device a to form an enclosed space.

In some embodiments, a third air hole (not shown) for communicating the chamber 9111 is formed in the cover 911, a nitrogen gas supply device is externally connected to the third air hole, the third air hole firstly discharges other gases in the chamber 9111 to the dry nitrogen gas inside the chamber 9111, and then the chamber 9111 is vacuumized through the second air hole 915.

In step S3, the air bag 9112 is inflated through the first air hole 914, so that the air bag 9112 is inflated to press the protective layer B1 on the electronic device a. The surface of the screen of the electronic equipment A is more matched with the screen of the electronic equipment A, so that the effect of secondary laminating is achieved, and the quality of the film is further improved.

In step S4, after the second attaching is completed, the cavity cover 911 is reset by the second film attaching driving member 912, the electronic device a with the film attached is moved to the first opening 1111 through the transmission plate 212 and is transmitted to the outside, the film attaching is completed, and the user takes the electronic device a.

Referring to fig. 26, as an embodiment, the step S3 includes the following steps:

step S31: the airbag 9112 begins to inflate;

step S32: during inflation of the air pockets 9112, the air pockets 9112 gradually move away from the protective layer B1;

step S33: after the airbag 9112 is completely inflated, the airbag 9112 is gradually moved toward the protective layer B1 to perform the second attachment.

It is understood that the significance of steps S31 to S33 is: because the heights of different types of electronic devices A are different, the airbag 9112 cannot be completely expanded, namely, after the electronic device A enters the chamber 9111, the space inside the chamber 9111 is insufficient to enable the airbag 9112 to be fully expanded, so that the effect of expected shaping cannot be achieved when the protective layer B1 on the electronic device A is extruded, the problem can be solved through the above mode, in the inflation process, the airbag 9112 is gradually far away from the protective layer B1, the airbag 9112 is vacated with sufficient space to be expanded, the protective layer B1 on the electronic device A is extruded after the airbag is expanded to the maximum degree, and the quality of the secondary film is improved. As a modification, the airbag 9112 may be moved in the direction of the electronic device a at all times and finally pressed.

Referring to fig. 27, 28 and 29, a second embodiment of the present invention provides a self-service film sticking machine, which provides a self-service film sticking for an electronic device with a 2D, 2.5D and 3D screen for a user, and can be divided into the following devices:

the supporting platform 100: the automatic film sticking machine comprises a supporting mechanism 11, a film sticking machine and a control device, wherein the supporting mechanism is used for supporting the automatic film sticking machine and interacting between a user and the automatic film sticking machine;

the mobile device 200: comprises a transmission mechanism 21 and a moving mechanism 51, and is used for displacing the electronic equipment A and the protective film B;

the storage device 300: comprises a cleaning bag mechanism 41 for storing a alcohol bag C, a film supply mechanism 31 for storing and tearing a protective film B, and a recovery mechanism 12 for secondary recovery;

the positioning device 400: the first positioning mechanism 61 and the second positioning mechanism 71 are included, and are respectively used for positioning the protective film B and the electronic device A.

Film pasting device 500: the film sticking device comprises a first film sticking mechanism 81, a second film sticking mechanism 91, a first positioning mechanism 61 and a second positioning mechanism 71, wherein the first film sticking mechanism 81 and the second film sticking mechanism 91 are respectively used for preliminarily sticking films and secondarily sticking the films to the electronic equipment A.

It is to be understood that the supporting mechanism 11, the conveying mechanism 21, the moving mechanism 51, the cleaning bag mechanism 41, the recovering mechanism 12, the first positioning mechanism 61, the second positioning mechanism 71, the first film attaching mechanism 81, and the second film attaching mechanism 91 mentioned in the present embodiment are all the same as those mentioned in the first embodiment.

The explanation of "interaction between the user and the self-service laminator 1" is as follows: the user accessible supporting platform 100 puts into, takes electronic equipment A, takes the alcohol bag to and select electronic equipment A model, trigger operations such as self-service sticking film machine 1 operation.

According to the functions of the devices and the type of the screen A of the electronic equipment of the user, when the self-service laminator 1 runs, the film laminating method comprises the following steps:

step S10: the user selects the type of the electronic equipment and triggers the self-service film sticking machine, and the user places the electronic equipment to the self-service film sticking machine;

step S20: the self-service film sticking machine operates a corresponding program according to the model selected by the user so as to stick a corresponding protective layer to the electronic equipment;

step S30: and the self-service film sticking machine sends out the electronic equipment stuck with the protective layer.

Referring to fig. 29 and fig. 30, when the electronic device is a 2D or 2.5D screen, the protective film B is a hard film, and the step S20 specifically includes:

step S20-1, picking up the protective film of the corresponding electronic device at the film supply mechanism through the moving mechanism, and tearing off the packaging layer through the stripping device to reserve the protective layer;

step S20-2, the electronic equipment and the protective film are respectively positioned by the positioning device;

step S20-3, attaching corresponding protective films to the electronic equipment through the film attaching device aiming at the electronic equipment with different models;

wherein, the step S20-2 specifically comprises:

step S20-21: moving the protective layer to a first positioning mechanism through a moving mechanism for positioning;

step S20-22: the electronic equipment moves to the second positioning mechanism by using the transmission mechanism to be positioned;

wherein, the step S20-3 is specifically as follows:

and S20-31, the first film sticking mechanism picks up the protective layer on the first positioning mechanism, the electronic equipment is conveyed to the first film sticking mechanism through the conveying mechanism, and the first film sticking mechanism sticks the protective layer to the electronic equipment.

In some embodiments, when the electronic device is a 2.5D screen or a 3D screen with a large screen edge arc angle, the step S20 adds the steps S20-32 on the basis of the 2D screen:

and step S20-32, the electronic equipment enters the second film sticking mechanism through the conveying mechanism, and the second film sticking mechanism carries out secondary sticking on the protective layer on the electronic equipment.

When the electronic device is a 2D or 2.5D screen, the protective film picked up in step S20-1 should be an elastic protective layer, such as a soft silicone film, a soft rubber film, a soft tempered film, or the like.

The step S20-1, i.e., the peeling step 1 to the peeling step 3, and the step S20-3, i.e., the steps S20-31 and S20-32, and S20-32 in the third embodiment are the second film laminating step 1 to the second film laminating step 4, and the step S20-31, i.e., the first film laminating step 1 to the first film laminating step 4.

Therefore, the utility model provides a self-service sticking film machine 1 has very strong commonality for the cost in production, manufacturing, maintenance is lower, and the consumer group who is suitable for is wider.

It is understood that in the present invention, the transfer plate is slidably connected to the transfer rail, the transfer rail defines a first position and a second position, and the preliminary attachment is performed at the first position; the second laminating is finished at the second position, and the second positioning mechanism is arranged corresponding to the second position.

It is understood that the flexible film should be slightly larger than the size of the screen of the electronic device a because the flexible film is to be attached to the 3D screen. The soft film can be made of soft silica gel, TPU material, PE material and other plastic materials. The flexible film and the electronic device a may be attached by electrostatic adsorption and/or adhesion, and the present embodiment may optionally use a combination of the two, that is, the side of the flexible film facing the electronic device a is coated with an adhesive substance and is electrostatically charged.

It can be understood that the utility model discloses well part mechanical structure can replace as required to become the scheme among the prior art. Part of the mechanical structure can be omitted, and the film sticking is not influenced. The method steps and the structure mentioned in the mechanical structure part of the self-service film sticking machine are all suitable for the film sticking method protected by the utility model.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, and improvements made within the principle of the present invention should be included within the protection scope of the present invention.

Claims (10)

1. Sticking film machine, it is used for the attached protective layer of electronic equipment by oneself, its characterized in that: the film laminating machine comprises a supporting mechanism, a film supplying mechanism, a conveying mechanism, a moving mechanism, a first film laminating mechanism, a first positioning mechanism and a second positioning mechanism, wherein the supporting mechanism is connected with the film supplying mechanism, the conveying mechanism, the moving mechanism, the first film laminating mechanism, the first positioning mechanism and the second positioning mechanism to play a supporting role; first pad pasting mechanism and supply membrane mechanism to set up at first tip, moving mechanism sets up at the third tip, transport mechanism sets up at the second tip, and first pad pasting mechanism is located transport mechanism and supplies between the membrane mechanism, and first positioning mechanism sets up between first pad pasting mechanism and moving mechanism, and second positioning mechanism sets up around transport mechanism.

2. The film laminator of claim 1, wherein: the film sticking machine comprises a second film sticking mechanism for secondary film sticking, the second film sticking mechanism is arranged above the conveying mechanism, and the position of the second film sticking mechanism corresponds to that of the second positioning mechanism;

the second film pasting mechanism comprises a cavity cover with one side provided with an opening, a cavity is arranged in the opening, and an inflatable air bag capable of completely covering the protective layer is arranged in the cavity.

3. The film laminator of claim 1, wherein: the film sticking machine comprises a cleaning bag mechanism for providing a cleaning bag, and the cleaning bag mechanism is arranged between the film supply mechanism and the moving mechanism;

one side of the film supply mechanism far away from the conveying mechanism is provided with a sliding groove for the cleaning bag to slide out of the film sticking machine.

4. The film laminator of claim 1, wherein: the film supply mechanism comprises at least two different protective films, each protective film comprises a protective layer and a packaging layer, the protective layers are positioned on the packaging layers, and the size of each packaging layer is larger than that of each protective layer; the protective layers of different protective films have the same or different sizes, and the packaging layers have the same shape and size;

a set distance L is formed between one end of the protective layer and the end corresponding to the packaging layer, and the set distances L of different protective films are the same.

5. The film laminator of claim 1, wherein: the film supply mechanism comprises a plurality of film storage cavities for storing the protective films, and the plurality of film storage cavities are distributed in the vertical plane direction;

the film storage cavities are the same in shape and size, different protective films are stored in the film storage cavities, each protective film comprises a protective layer and a packaging layer, the protective layers are positioned on the packaging layers, and the different protective films are all limited in the film storage cavities through the packaging layers.

6. The film laminator of claim 1, wherein: and a stripping plate is arranged at the bottom of one end, close to the moving mechanism, of the film supply mechanism.

7. The film laminator of claim 1, wherein: the first positioning mechanism comprises a fixed seat, a top bead is arranged on the fixed seat in a protruding mode and used for supporting the protective layer, the top bead is in rolling or fixed connection with the fixed seat, and the top bead is located in the same inclined plane so that the protective layer is obliquely supported;

the first positioning mechanism further comprises a fixed seat and at least one movable plate, a fixed limiting plate is arranged on the fixed seat, and the movable plate and the limiting plate are matched to be used for positioning the protective layer.

8. The film laminator of claim 1, wherein: first pad pasting mechanism includes first pad pasting driving piece, presses the driving piece, presses splenium and absorption portion, pressing splenium and absorption portion mutually independent setting and pressing the splenium setting in absorption portion one end, linear motion is to first pad pasting driving piece drive absorption portion, presses the driving piece drive to press the splenium to remove, absorption portion slope sets up.

9. The film laminator of claim 1, wherein: the conveying mechanism comprises a movable conveying plate for placing the electronic equipment, the second positioning mechanism comprises abutting components and at least two movable clamping components, the abutting components are arranged on the periphery of the conveying plate, and the clamping components and the abutting components are matched for positioning the electronic equipment.

10. The film laminator of claim 1, wherein: the film sticking machine further comprises a square outer shell, and the supporting mechanism, the film supply mechanism, the conveying mechanism, the moving mechanism, the first film sticking mechanism, the first positioning mechanism and the second positioning mechanism are all arranged in the outer shell;

the cleaning bag conveying mechanism is characterized in that a first opening, a second opening and a display screen are arranged on the outer shell, the conveying mechanism corresponds to the first opening in position to put in or take out electronic equipment, and the second opening is used for allowing the cleaning bag picked up by the moving mechanism to slide out.

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