CN219564194U - Glass fiber cloth laminating equipment - Google Patents

Abstract

The utility model discloses glass fiber cloth laminating equipment, which comprises: the glass fiber cloth fixing device comprises a first support column, a cylinder arranged on the first support column, a movable mould assembly for placing a shell of glass fiber cloth to be attached and a fixed mould assembly for placing glass fiber cloth, wherein the movable mould assembly is located above the fixed mould assembly, and the cylinder is used for driving the movable mould assembly to move up and down towards the fixed mould assembly so as to attach the glass fiber cloth to the shell. Compared with the prior art, the utility model enhances the stability and operability of the glass fiber cloth attaching production process, improves the production yield and reduces the production cost.

Description

Glass fiber cloth laminating equipment

Technical Field

The utility model relates to the technical field of glass fiber cloth lamination, in particular to glass fiber cloth lamination equipment.

Background

With the rise of smart phones, people recognize and use smart phones, and corresponding mobile phone shells are also layered endlessly, and the market mobile phone shells mainly comprise the following materials and processes: PC injection molding cell-phone shell, PU cell-phone shell, transparent TPU injection molding cell-phone shell, genuine leather cell-phone shell, liquid silica gel cell-phone shell. The PC injection molding mobile phone shell is easy to crack in the disassembly and assembly process, the transparent TUP injection molding mobile phone shell is single in color and poor in hand feeling, the requirements of customers cannot be met, and the genuine leather mobile phone shell is over-priced and is difficult to accept by consumers. The liquid silica gel mobile phone shell adopts a structure that the lining superfine fibers are formed by injection molding in the PC and silica gel mold, the holding hand feeling is comfortable, the mobile phone shell is good in elasticity and low in aging, the service life is long, the style and the colors are various, the mobile phone is convenient to assemble and disassemble, the lining superfine fibers protect the mobile phone body from being scratched in the process of disassembly and assembly, and the mobile phone is well protected by buffering and damping when being dropped. However, the mobile phone is limited by the structure of the mobile phone and the trend of the design of the mobile phone in the light and thin direction, the positions of the keys and the USB arch bridge of the liquid silica gel mobile phone shell are weak, so that the service life of the liquid silica gel mobile phone shell is prolonged, and the weak positions of the keys and the USB arch bridge are attached with a layer of glass fiber cloth, so that the problem of insufficient edge strength of the keys and the USB can be effectively solved, and the position toughness is provided. Accordingly, a glass fiber cloth bonding apparatus has been developed. The technology of the existing glass fiber cloth laminating equipment is as follows: 1. pre-positioning glass fiber cloth by a manual soldering iron, and pressing the jig; 2. and 5, manually discharging and taking the parts by semi-automatic equipment, and laminating the equipment.

The existing glass fiber cloth laminating equipment mainly has the following defects:

1. pre-positioning glass fiber cloth by a manual soldering iron, and pressing the jig; the manual soldering iron is used for pre-positioning the glass fiber cloth, the glass fiber cloth is light and thin, difficult to position, easy to deviate in the manual positioning process, high in operating difficulty of workers, uneven in product quality, long in pre-positioning time, low in efficiency, and needs to take parts for a second time to increase the operation time.

2. And 5, manually discharging and taking the parts by semi-automatic equipment, and laminating the equipment. The equipment has high manufacturing cost and long equipment development and manufacturing period, and cannot meet the requirement of mass product lamination in a short time.

Disclosure of Invention

The utility model mainly aims to provide glass fiber cloth laminating equipment, which aims to enhance the stability and operability of a production process, improve the production yield and reduce the production cost.

In order to achieve the above object, the present utility model provides a glass fiber cloth bonding apparatus, comprising: the glass fiber cloth laminating machine comprises a first support column (2-8), a cylinder (1) arranged on the first support column (2-8), a movable mould assembly (2) for placing a shell (17) of glass fiber cloth (18) to be laminated and a fixed mould assembly (3) for placing the glass fiber cloth (18), wherein the movable mould assembly (2) is positioned above the fixed mould assembly (3), and the cylinder (1) is used for driving the movable mould assembly (2) to move up and down towards the fixed mould assembly (3) so as to laminate the glass fiber cloth (18) on the shell (17).

According to a further technical scheme, the movable die assembly (2) comprises a movable die core (2-6) connected with the output end of the air cylinder (1), and a groove for placing the shell (17) is formed in the movable die core (2-6).

The utility model further adopts the technical scheme that the movable die assembly (2) further comprises a first guide post (2-1), a first guide sleeve (2-2), a movable die bottom plate (2-7), a cylinder transfer block (2-3), a first movable die carrier plate (2-9) and a second movable die carrier plate (2-10);

the movable die bottom plate (2-7) is fixedly arranged on the first supporting column (2-8), the first movable die supporting plate (2-9) is movably arranged at the bottom of the movable die bottom plate (2-7), the first guide sleeve (2-2) is arranged on the movable die bottom plate (2-7), the first guide column (2-1) penetrates through the first guide sleeve (2-2), the first guide sleeve penetrates through the first guide sleeve and then is connected with the movable die bottom plate (2-7), and the output end of the air cylinder (1) is connected with the first movable die supporting plate (2-9) through the air cylinder adapter (2-3); the second movable mould carrier plate (2-10) is fixedly arranged at the bottom of the first movable mould carrier plate (2-9), and the movable mould core (2-6) is arranged at the bottom of the second movable mould carrier plate (2-10).

According to a further technical scheme, the movable die assembly (2) further comprises a first quick connector (2-4) and a sealing rubber ring (2-5), the first quick connector (2-4) is connected with a vacuum generator, and the sealing ring (2-5) is arranged between the first quick connector (2-4) and the movable die core (2-6).

The utility model further adopts the technical scheme that the fixed die assembly (3) comprises: the device comprises a first fixed die carrier plate (3-7), a second fixed die carrier plate (3-8), a moving fixed die positioning pin (3-9), a shovel base (3-22), a supporting plate (3-23), a spring (3-24), a spring supporting needle (3-26) and a limiting block (3-25);

the fixed die comprises a first fixed die carrier plate (3-7), a second fixed die carrier plate (3-8), a supporting plate (3-23) and a spring, wherein the supporting plate is arranged at the top of the first fixed die carrier plate (3-7), a profiling block (3-20) is arranged on the supporting plate (3-23), a positioning frame (3-18) for placing glass fiber cloth (18) is arranged on the profiling block, a moving die positioning pin (3-9) is used for positioning the supporting plate (3-23) and a moving die core (2-6), a limiting block (3-25) is arranged between the supporting plate (3-23) and the first fixed die carrier plate (3-7), the spring (3-24) is sleeved on a spring supporting needle (3-26), one end of the spring (3-24) is abutted against the first fixed die carrier plate (3-7), and the other end of the spring (3-24) is abutted against the first fixed die carrier plate (3-7).

The utility model further adopts the technical scheme that the fixed die assembly (3) further comprises: the novel shovel comprises a sliding block (3-16), a sliding block insert (3-17) and a sliding block spring (3-2), wherein the sliding block insert (3-17) is connected with the sliding block (3-16), one end of the sliding block spring (3-2) is abutted to the sliding block (3-16), and the other end of the sliding block spring is abutted to the shovel base (3-22).

The utility model further adopts the technical scheme that the fixed die assembly (3) further comprises: the heating device comprises a first heating rod (3-1), a first thermocouple (3-4), a second heating rod (3-3) and a second thermocouple (3-21), wherein the first heating rod (3-1) is connected with the first thermocouple (3-4), the second heating rod (3-3) is connected with the second thermocouple (3-21), the first heating rod is used for heating the sliding block (3-16) and the sliding block insert (3-17), and the second heating rod (3-3) is used for heating the profiling block.

The utility model further adopts the technical scheme that the fixed die assembly (3) further comprises: the second guide sleeve (3-5), the second guide sleeve (3-6), the line pressing plate (3-10), the pressing block (3-11), the wear pad (3-12), the second support column (3-13), the pressing block line (3-14), the distance screw (3-15) and the second quick connector (3-19), the second guide sleeve (3-6) is arranged on the first fixed die supporting plate (3-7), the second guide sleeve (3-5) is arranged at the position of the supporting plate (3-23) corresponding to the second guide sleeve (3-5), the distance screw (3-15) is arranged between the supporting plate (3-23) and the first fixed die supporting plate (3-7), the line pressing plate (3-11) is arranged on the supporting plate (3-23), the pressing block (3-11) and the wear pad (3-12) are arranged on the first fixed die supporting plate (3-7), the pressing block line (3-14) and the pressing block line (3-11) and the second fixed die supporting plate (3-7) are arranged between the first fixed die supporting plate (3-7) and the first fixed die supporting plate (3-7), the second quick connector is connected with the vacuum generator.

The utility model further adopts the technical scheme that the intelligent vacuum protection device further comprises a protection cover (15) arranged outside the first support column (2-8), wherein the protection cover (15) is provided with a double-control point-acting switch (4-1), a double-control point-acting switch (4-2), an emergency stop button (5), a vacuum starting switch (6), a counter (7), a timer (8), a first mold temperature controller (9), a second mold temperature controller (10), a main switch (11), a first temperature controller switch (12), a second temperature controller switch (13), a grating (14) and an electric control box (16).

The glass fiber cloth laminating equipment has the beneficial effects that: the utility model adopts the technical scheme that: the glass fiber cloth laminating device comprises a first support column (2-8), a cylinder (1) arranged on the first support column (2-8), a movable mould assembly (2) for placing a shell (17) of glass fiber cloth (18) to be laminated and a fixed mould assembly (3) for placing the glass fiber cloth (18), wherein the movable mould assembly (2) is positioned above the fixed mould assembly (3), the cylinder (1) is used for driving the movable mould assembly (2) to move up and down towards the fixed mould assembly (3), so that the glass fiber cloth (18) is laminated on the shell (17), the stability and operability of the glass fiber cloth laminating production process are enhanced, the production yield is improved, and the production cost is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a front view of a preferred embodiment of a glass cloth bonding apparatus of the present utility model without a protective cover;

FIG. 2 is a side view of a preferred embodiment of a glass cloth bonding apparatus of the present utility model without a protective cover;

FIG. 3 is a top view of a preferred embodiment of a glass cloth bonding apparatus of the present utility model without a protective cover;

FIG. 4 is a front view of a preferred embodiment of the glass cloth bonding apparatus of the present utility model with a protective cover;

FIG. 5 is a left side view of a preferred embodiment of the glass cloth bonding apparatus of the present utility model with a protective cover;

FIG. 6 is a right side view of a preferred embodiment of the glass cloth bonding apparatus of the present utility model with a protective cover;

FIG. 7 is a schematic structural view of a protective cover;

FIG. 8 is a schematic perspective view of a glass fiber cloth bonding apparatus according to a preferred embodiment of the present utility model with a protective cover at a first angle;

FIG. 9 is a second angular perspective view of a preferred embodiment of a glass cloth bonding apparatus with a protective cover according to the present utility model;

FIG. 10 is a schematic structural view of a fiberglass cloth;

FIG. 11 is a schematic view showing a state of placement of a glass fiber cloth in a glass fiber cloth bonding apparatus of the present utility model;

FIG. 12 is a schematic view showing a pressure maintaining state of glass fiber cloth in the glass fiber cloth bonding apparatus of the present utility model;

fig. 13 is a schematic view showing a use state of the glass fiber cloth bonding apparatus of the present utility model.

The achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that, if directional indications (such as up, down, left, right, front, and rear … …) are included in the embodiments of the present utility model, the directional indications are merely used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present utility model, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" as it appears throughout includes three parallel schemes, for example "A and/or B", including the A scheme, or the B scheme, or the scheme where A and B are satisfied simultaneously. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

The utility model provides glass fiber laminating equipment, which aims to:

through the design of glass fiber cloth laminating equipment, research and development of glass fiber laminating equipment is applicable to the products that local reinforcement needs to be done to various upper surfaces, and inside PC laminating glass fiber cloth.

Through the design of glass fiber cloth laminating equipment, the stability and the operability of the production process are increased, so that the yield is improved, and the cost is reduced.

By eliminating the manual soldering iron working section, the process flow is simplified, the operation difficulty is reduced, the labor cost is saved, the product is improved, and the economic benefit is increased.

By designing the glass fiber cloth laminating equipment, the equipment development period is shortened, the equipment cost is reduced, and the requirement of mass production products is met in a short period.

Specifically, referring to fig. 1 to 13, a preferred embodiment of the glass fiber cloth bonding apparatus of the present utility model includes a first support column (2-8), a cylinder (1) disposed on the first support column (2-8), a movable mold assembly (2) for placing a housing (17) to be bonded with a glass fiber cloth (18), and a fixed mold assembly (3) for placing the glass fiber cloth (18), wherein the movable mold assembly (2) is located above the fixed mold assembly (3), and the cylinder (1) is used for driving the movable mold assembly (2) to move up and down towards the fixed mold assembly (3) so as to bond the glass fiber cloth (18) on the housing (17).

Further, in this embodiment, the movable mold assembly (2) includes a movable mold core (2-6) connected to the output end of the cylinder (1), and a groove for placing the housing (17) is provided on the movable mold core (2-6).

Further, in this embodiment, the movable mold assembly (2) further includes a first guide post (2-1), a first guide sleeve (2-2), a movable mold bottom plate (2-7), a cylinder adapter block (2-3), a first movable mold carrier plate (2-9) and a second movable mold carrier plate (2-10).

The movable die bottom plate (2-7) is fixedly arranged on the first supporting column (2-8), the first movable die supporting plate (2-9) is movably arranged at the bottom of the movable die bottom plate (2-7), the first guide sleeve (2-2) is arranged on the movable die bottom plate (2-7), the first guide column (2-1) penetrates through the first guide sleeve (2-2), the first guide sleeve penetrates through the first guide sleeve and then is connected with the movable die bottom plate (2-7), and the output end of the air cylinder (1) is connected with the first movable die supporting plate (2-9) through the air cylinder adapter (2-3); the second movable mould carrier plate (2-10) is fixedly arranged at the bottom of the first movable mould carrier plate (2-9), and the movable mould core (2-6) is arranged at the bottom of the second movable mould carrier plate (2-10).

Further, in this embodiment, the movable mold assembly (2) further includes a first quick connector (2-4) and a sealing rubber ring (2-5), the first quick connector (2-4) is connected with the vacuum generator, and the sealing ring (2-5) is disposed between the first quick connector (2-4) and the movable mold core (2-6).

Further, in the present embodiment, the stationary mold assembly (3) includes: the device comprises a first fixed die carrier plate (3-7), a second fixed die carrier plate (3-8), a moving fixed die locating pin (3-9), a shovel base (3-22), a supporting plate (3-23), a spring (3-24), a spring supporting needle (3-26) and a limiting block (3-25).

The fixed die comprises a first fixed die carrier plate (3-7), a second fixed die carrier plate (3-8), a supporting plate (3-23) and a spring, wherein the supporting plate is arranged at the top of the first fixed die carrier plate (3-7), a profiling block (3-20) is arranged on the supporting plate (3-23), a positioning frame (3-18) for placing glass fiber cloth (18) is arranged on the profiling block, a moving die positioning pin (3-9) is used for positioning the supporting plate (3-23) and a moving die core (2-6), a limiting block (3-25) is arranged between the supporting plate (3-23) and the first fixed die carrier plate (3-7), the spring (3-24) is sleeved on a spring supporting needle (3-26), one end of the spring (3-24) is abutted against the first fixed die carrier plate (3-7), and the other end of the spring (3-24) is abutted against the first fixed die carrier plate (3-7).

Further, in this embodiment, the stationary mold assembly (3) further includes: the novel shovel comprises a sliding block (3-16), a sliding block insert (3-17) and a sliding block spring (3-2), wherein the sliding block insert (3-17) is connected with the sliding block (3-16), one end of the sliding block spring (3-2) is abutted to the sliding block (3-16), and the other end of the sliding block spring is abutted to the shovel base (3-22).

Further, in this embodiment, the stationary mold assembly (3) further includes: the heating device comprises a first heating rod (3-1), a first thermocouple (3-4), a second heating rod (3-3) and a second thermocouple (3-21), wherein the first heating rod (3-1) is connected with the first thermocouple (3-4), the second heating rod (3-3) is connected with the second thermocouple (3-21), the first heating rod is used for heating the sliding block (3-16) and the sliding block insert (3-17), and the second heating rod (3-3) is used for heating the profiling block.

Further, in this embodiment, the stationary mold assembly (3) further includes: the second guide sleeve (3-5), the second guide sleeve (3-6), the line pressing plate (3-10), the pressing block (3-11), the wear pad (3-12), the second support column (3-13), the pressing block line (3-14), the distance screw (3-15) and the second quick connector (3-19), the second guide sleeve (3-6) is arranged on the first fixed die supporting plate (3-7), the second guide sleeve (3-5) is arranged at the position of the supporting plate (3-23) corresponding to the second guide sleeve (3-5), the distance screw (3-15) is arranged between the supporting plate (3-23) and the first fixed die supporting plate (3-7), the line pressing plate (3-11) is arranged on the supporting plate (3-23), the pressing block (3-11) and the wear pad (3-12) are arranged on the first fixed die supporting plate (3-7), the pressing block line (3-14) and the pressing block line (3-11) and the second fixed die supporting plate (3-7) are arranged between the first fixed die supporting plate (3-7) and the first fixed die supporting plate (3-7), the second quick connector is connected with the vacuum generator.

Further, in this embodiment, fine cloth laminating equipment of glass still including set up in safety cover (15) outside first support column (2-8), be provided with on safety cover (15) two accuse point move switch (4-1), two accuse point move switch (4-2), scram button (5), inhale vacuum start switch (6), counter (7), time-recorder (8), first mould temperature controller (9), second mould temperature controller (10), master switch (11), first temperature controller switch (12), second temperature controller switch (13), grating (14) and electric control box (16).

The working principle of the glass fiber cloth laminating equipment of the utility model is as follows:

the glass fiber cloth (18) comprises a hot melt adhesive (18-1) and a glass fiber cloth body (18-2) arranged at the bottom of the hot melt adhesive, the glass fiber cloth (18) has good elasticity and flexibility, when the temperature reaches more than 100 ℃ and the hot melt adhesive (18-1) is activated, automatic bending is completed through the cooperative movement of the sliding block insert (3-17), the profiling block (3-20) and the shell (17), after the time reaches 12 seconds set by the timer (8), the glass fiber cloth (18) is completely attached to the shell (17) to achieve the effect of increasing the strength and toughness of a product, and the equipment temperature and the time parameter can be set according to actual materials and capacity requirements.

Specifically, the working steps of the glass fiber cloth laminating equipment are as follows:

step S10, the master switch (11) is turned on, the glass fiber cloth laminating equipment is electrified and aerated, the first temperature controller switch (12) and the second temperature controller switch (13) are sequentially started, the first mold temperature controller (9) and the first mold temperature controller (10) are set to be 115 ℃, the first mold temperature controller (9) heats the sliding block (3-16) and the sliding block insert (3-17) to 115 ℃ through the first heating rod (3-1), the second mold temperature controller (10) heats the dummy block (3-20) to 115 ℃ through the second heating rod (3-3), the timer (8) is set to be 12 seconds, the vacuum suction starting switch (6) is pressed, the movable mold core (2-6) and the dummy block (3-20) start to perform air suction operation, and the sliding block insert (3-17) and the dummy block (3-20) are subjected to step S20 after the temperature of the sliding block insert (3-17) and the dummy block (3-20) reaches the step S20.

Step S20: the shell (17) is placed in a groove of the movable die core (2-6), the shell (17) is adsorbed and fixed in the groove of the movable die core (2-6) through vacuum suction, then the glass fiber cloth (18) is placed in the positioning frame (3-18) (the hot melt adhesive (18-1) is placed face up), and the glass fiber cloth (18) is adsorbed and fixed on the sliding block insert (3-17) and the profiling block (3-20) through vacuum suction.

Step S30: the double-control point moving switch (4-1) and the double-control point moving switch (4-2) are synchronously pressed down, the equipment starts to act, the moving module (2) and the shell (17) are pushed to move downwards towards the fixed module (3) by the air cylinder (1), the moving module (2) brings the glass fiber cloth (18) into the grooves of the profiling block (3-20) when moving towards the fixed module (3), the shell (17) descends to be in contact with the supporting plate (3-23), the spring (3-24) is compressed by the supporting plate (3-23), meanwhile, the shovel base (3-22) and the supporting plate (3-23) drive the sliding block (3-16) and the sliding block insert (3-17), the sliding block (3-16) brings the sliding block spring (3-2) into the grooves of the profiling block (3-20) when the sliding block insert (3-17) moves, and when the sliding block (3-16) is in contact with the profiling block (3-20), the sliding block (3-17) is folded and the sliding block (3-17) is pressed down, and the sliding block (3-17) is pressed down to be in contact with the profiling block (3-20) when the profiling block (3-20) is pressed, the cylinder (1) starts to set pressure maintaining for 12 seconds according to the timer (8), the vacuum sucking operation of the movable die core (2-6) and the profiling block (3-20) is stopped by an electrical element of the electrical control box (16) within 12 seconds of the pressure maintaining operation, the cylinder (1) drives the movable die assembly (2) to reset after the expected pressure maintaining time of 12 seconds is reached, meanwhile, the shovel base (3-22) and the supporting plate (3-23) are reset under the elastic force of the spring (3-24), the sliding block (3-16) and the sliding block insert (3-17) are reset under the elastic force of the sliding block spring (3-2), and the step S30 is completed when the supporting plate (3-23) is restored to the limiting position of the distance screw (3-15).

And step S40, taking out the finished product from the groove of the supporting plate (3-23), and completing the operation.

The glass fiber cloth laminating equipment has the beneficial effects that: the utility model adopts the technical scheme that: the glass fiber cloth laminating device comprises a first support column (2-8), a cylinder (1) arranged on the first support column (2-8), a movable mould assembly (2) for placing a shell (17) of glass fiber cloth (18) to be laminated and a fixed mould assembly (3) for placing the glass fiber cloth (18), wherein the movable mould assembly (2) is positioned above the fixed mould assembly (3), the cylinder (1) is used for driving the movable mould assembly (2) to move up and down towards the fixed mould assembly (3), so that the glass fiber cloth (18) is laminated on the shell (17), the stability and operability of the glass fiber cloth laminating production process are enhanced, the production yield is improved, and the production cost is reduced.

The foregoing description is only of the preferred embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structural changes made by the specification and drawings of the present utility model or direct/indirect application in other related technical fields are included in the scope of the present utility model.

Claims (8)

1. Glass fiber cloth laminating equipment, its characterized in that includes: the glass fiber cloth laminating machine comprises a first support column (2-8), a cylinder (1) arranged on the first support column (2-8), a movable mould assembly (2) for placing a shell (17) of glass fiber cloth (18) to be laminated and a fixed mould assembly (3) for placing the glass fiber cloth (18), wherein the movable mould assembly (2) is positioned above the fixed mould assembly (3), and the cylinder (1) is used for driving the movable mould assembly (2) to move up and down towards the fixed mould assembly (3) so as to laminate the glass fiber cloth (18) on the shell (17).

2. The glass fiber cloth laminating equipment according to claim 1, wherein the movable die assembly (2) comprises a movable die core (2-6) connected with the output end of the air cylinder (1), and a groove for placing the shell (17) is formed in the movable die core (2-6).

3. The glass fiber cloth attaching device according to claim 2, wherein the movable mold assembly (2) further comprises a first guide post (2-1), a first guide sleeve (2-2), a movable mold bottom plate (2-7), a cylinder transfer block (2-3), a first movable mold carrier plate (2-9) and a second movable mold carrier plate (2-10);

the movable die bottom plate (2-7) is fixedly arranged on the first supporting column (2-8), the first movable die supporting plate (2-9) is movably arranged at the bottom of the movable die bottom plate (2-7), the first guide sleeve (2-2) is arranged on the movable die bottom plate (2-7), the first guide column (2-1) penetrates through the first guide sleeve (2-2), the first guide sleeve (2-2) is connected with the movable die bottom plate (2-7), and the output end of the air cylinder (1) is connected with the first movable die supporting plate (2-9) through the air cylinder switching block (2-3); the second movable mould carrier plate (2-10) is fixedly arranged at the bottom of the first movable mould carrier plate (2-9), and the movable mould core (2-6) is arranged at the bottom of the second movable mould carrier plate (2-10).

4. A glass fiber cloth laminating apparatus according to claim 3, wherein the movable mould assembly (2) further comprises a first quick connector (2-4) and a sealing rubber ring (2-5), the first quick connector (2-4) is connected with a vacuum generator, and the sealing rubber ring (2-5) is arranged between the first quick connector (2-4) and the movable mould core (2-6).

5. The glass fiber cloth bonding apparatus according to claim 4, wherein the stationary mold assembly (3) comprises: the device comprises a first fixed die carrier plate (3-7), a second fixed die carrier plate (3-8), a moving fixed die positioning pin (3-9), a shovel base (3-22), a supporting plate (3-23), a spring (3-24), a spring supporting needle (3-26) and a limiting block (3-25);

the fixed die comprises a first fixed die carrier plate (3-7), a second fixed die carrier plate (3-8), a supporting plate (3-23) and a spring, wherein the supporting plate is arranged at the top of the first fixed die carrier plate (3-7), a profiling block (3-20) is arranged on the supporting plate (3-23), a positioning frame (3-18) for placing glass fiber cloth (18) is arranged on the profiling block, a moving die positioning pin (3-9) is used for positioning the supporting plate (3-23) and a moving die core (2-6), a limiting block (3-25) is arranged between the supporting plate (3-23) and the first fixed die carrier plate (3-7), the spring (3-24) is sleeved on a spring supporting needle (3-26), one end of the spring (3-24) is abutted against the first fixed die carrier plate (3-7), and the other end of the spring (3-24) is abutted against the first fixed die carrier plate (3-7).

6. The glass fiber cloth bonding apparatus according to claim 5, wherein the stationary mold assembly (3) further comprises: the novel shovel comprises a sliding block (3-16), a sliding block insert (3-17) and a sliding block spring (3-2), wherein the sliding block insert (3-17) is connected with the sliding block (3-16), one end of the sliding block spring (3-2) is abutted to the sliding block (3-16), and the other end of the sliding block spring is abutted to the shovel base (3-22).

7. The glass fiber cloth bonding apparatus according to claim 6, wherein the stationary mold assembly (3) further comprises: the heating device comprises a first heating rod (3-1), a first thermocouple (3-4), a second heating rod (3-3) and a second thermocouple (3-21), wherein the first heating rod (3-1) is connected with the first thermocouple (3-4), the second heating rod (3-3) is connected with the second thermocouple (3-21), the first heating rod is used for heating the sliding block (3-16) and the sliding block insert (3-17), and the second heating rod (3-3) is used for heating the profiling block.

8. The glass fiber cloth bonding apparatus according to claim 7, wherein the stationary mold assembly (3) further comprises: the second guide sleeve (3-5), the second guide sleeve (3-6), the line pressing plate (3-10), the pressing block (3-11), the wear pad (3-12), the second support column (3-13), the pressing block line (3-14), the distance screw (3-15) and the second quick connector (3-19), the second guide sleeve (3-6) is arranged on the first fixed die supporting plate (3-7), the second guide sleeve (3-5) is arranged at the position of the supporting plate (3-23) corresponding to the second guide sleeve (3-5), the distance screw (3-15) is arranged between the supporting plate (3-23) and the first fixed die supporting plate (3-7), the line pressing plate (3-10) is arranged on the supporting plate (3-23), the pressing block (3-11) and the wear pad (3-12) are arranged on the first fixed die supporting plate (3-7), the pressing block line (3-14) and the pressing block line (3-11) and the adjacent to the first fixed die supporting plate (3-7) are arranged between the first fixed die supporting plate (3-7) and the first fixed die supporting plate (3-7), the second quick connector is connected with the vacuum generator.