CN113103365A - Touch pad processing shaping sword mechanism - Google Patents

Abstract

The invention discloses a touch pad processing and forming cutter mechanism which comprises an upper mold frame, an upper mold plate, a lower mold frame, a lower mold plate and a plurality of groups of forming cutter devices, wherein the lower mold plate is arranged on the lower mold frame, the forming cutter devices are arranged on the upper mold plate, a forming groove is formed in the lower mold plate, a conveying device for conveying a touch pad is arranged between the upper mold plate and the lower mold plate, a driving device is arranged at the end part of the conveying device, the driving device drives the conveying device to perform intermittent conveying, a demolding device is arranged on the lower mold plate, and a first conveying belt is arranged below. The touch screen cutting device is provided with a forming cutter device, a pneumatic assembly drives a cutting cabin to move downwards to cut the touch screen, when a cutting knife is abraded or deformed, a conveying device fixes and conveys the touch screen, a demoulding device is arranged on a lower template, when the cut part is hung on the cutting knife, a demoulding piece is adopted to cut the cut part and push the cut part down, an alarm is given out, and the cutting knife is replaced in time.

Description

Touch pad processing shaping sword mechanism

Technical Field

The invention relates to the field of touch pad production and processing, in particular to a touch pad processing and forming cutter mechanism.

Background

The cutting device of the notebook touch pad is a device for cutting and processing the notebook touch pad, is widely used in the production occasions of the notebook touch pad, has better use effect, and can meet the use requirements of people as the cutting requirements of people on the notebook touch pad become stricter and stricter, so that the cutting device of the notebook touch pad which is more convenient to use is needed; the conventional touch panel cutting apparatus has the following problems,

(1) when the existing stamping equipment stamps the cutting knife, the shape of the forming knife is the same as that of the knife hole, when the forming knife stamps the touch pad, the cut part can be slightly deformed by the cutting edge or the head part of the cutting knife, the cut part is easy to hang on the cutting knife and can not be separated from the cutting knife, the touch pad processing equipment provided by the prior art provides a push knife to push the cut part down from the cutting knife, but when the end part of the cutting knife is outwards deformed, the cut part is difficult to push down from the cutting knife through the push knife;

(2) the existing forming cutter is worn or cannot be replaced in time due to slight deformation after being used for a long time, so that the final quality of a cut product is influenced;

(3) the existing cutting device needs to manually place the touch screen below the cutting device, the cutting device is started to cut the touch screen, the working efficiency is low, the touch screen can slightly move in the cutting process, and the cutting of the touch screen is affected.

Disclosure of Invention

Therefore, the invention provides a touch pad processing forming cutter mechanism which effectively solves the problems that in the prior art, a cut part is difficult to push down from a cutting knife through a push cutter, the forming cutter cannot be replaced in time, and a touch screen may slightly move in the cutting process.

In order to solve the technical problems, the invention specifically provides the following technical scheme: a touch pad processing and forming cutter mechanism comprises an upper mold frame, an upper mold plate, a lower mold frame, a lower mold plate and a plurality of groups of forming cutter devices, wherein the upper mold plate and the lower mold frame are arranged on the upper mold frame;

the forming cutter device comprises a forming cutter plate arranged on the upper template and a cutting cabin arranged in the forming cutter plate in a sliding mode, cutting cutters are connected to two sides of the cutting cabin through connecting components, a pneumatic component is arranged above the cutting cabin, and the pneumatic component and the connecting components control the cutting cutters to move downwards and draw inwards to cut the touch pad;

the conveying device comprises a second conveying belt arranged between the upper template and the lower template and a plurality of conveying seats arranged on the second conveying belt, wherein a transfer table is arranged at one end of the second conveying belt, a containing groove is formed in the conveying seat, a containing assembly for temporarily containing the touch screen is arranged in the containing groove, a conveying plate is arranged on the transfer table, and a pushing assembly is arranged at one end of the conveying plate;

the demolding device comprises a demolding cutting piece arranged in the lower template and an alarm arranged on the demolding cutting piece, and the demolding cutting piece cuts cut materials to enable the materials to fall onto the first conveying belt after being separated from the cutting knife.

As a preferred scheme of the invention, the connecting assembly comprises a fixed column arranged in the cutting cabin and an inner push rod rotatably arranged on the fixed column, the cutting knife is arranged at the lower end of the inner push rod through a fixed bolt, and an outward push spring is connected between the inner push rods;

and limiting plates are connected to two ends of the upper die frame and control the moving track of the inner push rod.

As a preferred scheme of the invention, one side of the limiting plate, which is close to the cutting knife, is provided with a certain gradient;

the outer side of the cutting cabin is provided with a lifting block, the forming cutting board is provided with a sliding groove for the lifting block to slide, and the cutting cabin slides up and down in the forming cutting board through the lifting block.

As a preferable scheme of the invention, the pneumatic assembly comprises a lifting gear rod connected above the cutting cabin and a first transmission gear arranged at the upper end of the lifting gear rod, a second transmission gear is meshed at the side edge of the first transmission gear, a translation gear plate is arranged below the second transmission gear, a fixed plate is arranged on the upper die frame, and the first transmission gear and the second transmission gear are both connected to the fixed plate through a connecting column.

As a preferable aspect of the present invention, the storage assembly includes a rotating column disposed in the storage groove and a pair of storage clips connected to the rotating column, the touch screen is placed between the storage clips, and a clamping spring is connected to an outer side of the storage clips and is connected to the storage groove through the clamping spring.

As a preferable scheme of the invention, a conveying wheel is arranged in the second conveying belt, an adjusting component for controlling the containing clips to be in a furled state is arranged at the lower end of the second conveying belt, the adjusting component comprises a connecting plate arranged on the lower template and below the second conveying belt and an arc-shaped plate connected to the right end of the connecting plate, a pair of abutting plates are vertically arranged on the inner side surfaces of the connecting plate and the arc-shaped plate, the upper ends of the abutting plates are respectively contacted with the containing clips on two sides and press the containing clips into the containing grooves, and the distance between the abutting plates is gradually increased close to the upper ends of the arc-shaped plates.

As a preferred scheme of the invention, the conveying seat is arranged on the side edge of the arc-shaped plate, the connecting groove is formed in the upper end of the arc-shaped plate and between the abutting plates, the conveying plate is provided with a conveying groove, the pushing assembly comprises a feeding cabin arranged at one end of the conveying plate far away from the transfer table and a pushing plate arranged in the feeding cabin, one end of the pushing plate is connected to the inner wall of the conveying groove through a pushing spring, the pushing plate is connected with a connecting rod, the upper end of the connecting rod is connected with a feeding plate, the upper end of the feeding cabin is provided with a feeding hole, the feeding plate is arranged on the feeding hole, the upper end of the feeding plate is connected with a stirring sheet, the feeding groove is formed in the upper end of the feeding cabin, and the feeding plate is connected to.

As a preferable scheme of the present invention, the driving device includes a push rod disposed on the transfer table and a push sheet disposed on the push rod, one end of the push rod is connected to the air cylinder, the push rod is connected to the L-shaped connecting rod, and one end of the L-shaped connecting rod is connected to the translation gear plate.

As the preferable scheme of the invention, both sides of the forming groove are provided with demoulding grooves, the demoulding and cutting piece comprises a demoulding block rotationally arranged in the demoulding grooves and a demoulding bulge arranged at the end part of the demoulding block, the demoulding module is connected with the inner wall of the demoulding groove through a rotating rod, the rotating rod is connected with a micro rotating motor, the lower end of the lower template is connected with an induction channel, an inductor is arranged in the induction channel, a cutting through groove is arranged on the side wall of the induction channel, the lower end of the lower template is provided with a cutting piece, the cutting piece is connected with a gear rod, the rotating rod is provided with a first connecting gear, a second connecting gear is meshed on the first connecting gear, a gear block is arranged on the second connecting gear, the gear block is meshed with the gear rod, and the radius of the gear block is larger than that of the second connecting gear.

As a preferable scheme of the present invention, the cylinder, the sensor and the micro-rotating motor are all connected to a controller.

Compared with the prior art, the invention has the following beneficial effects:

(1) according to the invention, the forming cutter device is arranged on the upper template, wherein the connecting assembly ensures the connection between the cutting cutters at two sides, the pneumatic assembly drives the cutting cabin to move downwards to cut the touch screen, and when the cutting cutters are worn or deformed, the cutting cutters are replaced in time, so that the quality of a cut product is ensured;

(2) the touch screen is fixed and conveyed through the conveying device, so that the problem that the cutting position of the touch screen is wrong due to slight movement in the cutting process is solved, the intermittent conveying of the touch screen is realized through the conveying device, and the automatic cutting production of the device is facilitated;

(3) the lower template is provided with the demoulding device, when the cut part is hung on the cutting knife, the cut part is pushed downwards through the demoulding cutting piece, when the cut part is not influenced by the pushing force, the cut part is cut and pushed down by the demoulding cutting piece, and the cutting knife is timely replaced by alarming through the alarm.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

Fig. 1 is a schematic structural diagram of a touch panel processing and forming knife mechanism according to an embodiment of the present invention;

FIG. 2 is a schematic structural view of a linkage assembly and a pneumatic assembly in an embodiment of the invention;

FIG. 3 is a schematic side view of a forming blade device according to an embodiment of the present invention;

FIG. 4 is a schematic structural view of a receiving assembly according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of an adjustment assembly in an embodiment of the present invention;

FIG. 6 is a schematic view of a part of the structure of a transfer device in an embodiment of the present invention;

FIG. 7 is a schematic structural diagram of a pushing assembly according to an embodiment of the present invention;

fig. 8 is a schematic structural view of a die release cut in an embodiment of the present invention.

The reference numerals in the drawings denote the following, respectively:

1-mounting a mould frame; 2, mounting a template; 3-lower die carrier; 4-a lower template; 5-forming a cutter device; 6-a conveying device; 7-a drive device; 8-a demoulding device; 9-a first conveyor belt; 10-forming a groove; 11-a fixed plate;

51-forming a cutting board; 52-cutting the cabin; 53-a connecting assembly; 54-a cutting knife; 55-a pneumatic assembly; 56-lifting block;

61-a second conveyor belt; 62-a transfer seat; 63-a transfer station; 64-a receiving assembly; 65-a conveying plate; 66-a pushing assembly; 67-a receiving groove; 68-an adjustment assembly; 69-connecting grooves;

71-a push rod; 72-a push sheet; 73-a cylinder; a 74-L shaped connecting rod;

81-demolding and cutting; 82-an alarm; 83-a stripping groove;

531-fixed column; 532-inner push rod; 533-fixing bolt; 534-an out-pushing spring; 535-a limiting plate;

551-lifting gear rod; 552-a first drive gear; 553 — a second transmission gear; 554-a translation gear rod;

641-rotating cylinder; 642-receiving clip; 643-sandwiching a spring;

661-feeding compartment; 662-push plate; 663-thrust spring; 664-connecting rod; 665-a feed plate; 666-plectrum; 667-feed chute; 668-a return spring;

681-connection plate; 682-an arc plate; 683-resisting board;

811-demoulding of the module; 812-a demolding bulge; 813-rotating rods; 814-sense channel; 815-cutting slices; 816-gear lever; 817-first connecting gear; 818-a second connecting gear; 819-gear block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, the invention provides a touch panel processing and forming cutter mechanism, which comprises an upper mold frame 1, an upper mold plate 2 arranged on the upper mold frame 1, a lower mold frame 3, a lower mold plate 4 arranged on the lower mold frame 3 and a plurality of groups of forming cutter devices 5 arranged on the upper mold plate 2, wherein a forming groove 10 is formed in the lower mold plate 3, a conveying device 6 for conveying a touch panel is arranged between the upper mold plate 2 and the lower mold plate 4, a driving device 7 is arranged at the end part of the conveying device 6, the driving device 7 drives the conveying device 6 to intermittently convey, a demolding device 8 is arranged on the lower mold plate 4, a first conveying belt 9 is arranged below the demolding device 8, and a touch screen finished product is conveyed out by the first conveying belt 9.

The main innovation points of the invention are a forming cutter device 5, a conveying device 6 and a demoulding device 8, wherein the forming cutter device 5 is arranged on an upper template 2, a pneumatic component 55 drives a cutting cabin 52 to move downwards to cut a touch screen, when the cutting cutter 54 is worn or deformed, the cutting cutter 54 is replaced in time, the touch screen is fixed and conveyed through the conveying device 6, the intermittent conveying of the touch screen is realized through the conveying device 6, the demoulding device 8 is arranged on a lower template 4, when the cut part is hung on the cutting cutter 54, the cut part is pushed downwards through a demoulding cutting piece 81, and when the cut part is not influenced by thrust, the cut part is cut by the demoulding cutting piece 81 and pushed down.

The forming cutter device 5 comprises a forming cutter plate 51 arranged on the upper template 2 and a cutting cabin 52 arranged in the forming cutter plate 51 in a sliding mode, two sides of the cutting cabin 52 are connected with a cutting cutter 54 through a connecting assembly 53, a pneumatic assembly 55 is arranged above the cutting cabin 52, and the pneumatic assembly 55 and the connecting assembly 53 control the cutting cutter 54 to move downwards and inwards furl to cut the touch pad.

As shown in fig. 2 and 3, the connecting assembly 53 includes a fixing column 531 arranged in the cutting cabin 52 and an inner push rod 532 rotatably arranged on the fixing column 531, the cutting knife 54 is mounted at the lower end of the inner push rod 532 through a fixing bolt 533, an outward push spring 534 is connected between the inner push rods 532, two ends of the upper die carrier 1 are connected with limiting plates 535, the limiting plates 535 control the moving track of the inner push rod 532, one side of the limiting plate 535, which is close to the cutting knife 54, is provided with a certain gradient, the outer side of the cutting cabin 52 is provided with a lifting block 56, and a sliding groove for the lifting block 56 to slide is formed on the forming.

Without the inward pushing force of the limiting plate 535, the cutting knives 54 are only subjected to the outward elastic force of the outward pushing spring 534, under the action of the limiting plate 535, the cutting knives 54 on both sides are gradually folded inward, the lower ends of the cutting knives 54 form a blade to cut the touch pad, and in the process of moving up and down, the cutting cabin 52 slides up and down in the forming knife plate 51 through the lifting block 56.

In order to punch the cutting chamber 52, the invention is provided with a pneumatic assembly 55, the pneumatic assembly 55 comprises a lifting gear rod 551 connected above the cutting chamber 52 and a first transmission gear 552 arranged at the upper end of the lifting gear rod 551, the side edge of the first transmission gear 552 is engaged with a second transmission gear 553, a translation gear plate 554 is arranged below the second transmission gear 553, the upper die carrier 1 is provided with a fixed plate 11, and the first transmission gear 552 and the second transmission gear 553 are both connected on the fixed plate 11 through a connecting column.

The translation gear plate 554 moves leftwards to drive the second transmission gear 553 to rotate clockwise, so as to drive the first transmission gear 552 to rotate anticlockwise, the first transmission gear 552 drives the lifting gear rod 551 to move downwards, the cutting cabin 52 moves downwards to drive the cutting knife 54 to move downwards through the connecting component 53, and the cutting knife 54 gradually folds to cut the touch screen in the moving downwards process.

Need convey the touch-sensitive screen to shaping sword device 5 below through conveyer 6 before cutting the touch-sensitive screen, conveyer 6 is including setting up second conveyer belt 61 between cope match-plate pattern 2 and lower bolster 4 and setting up a plurality of conveying seat 62 on second conveyer belt 61, second conveyer belt 62 one end is provided with transfer platform 63, the groove 67 has been seted up and has been accomodate on the conveying seat 62, it is provided with the subassembly 64 of accomodating that temporarily accomodates the touch-sensitive screen to accomodate in the groove 67, install transfer board 65 on the transfer platform 63, transfer board one end is provided with and promotes subassembly 66.

The storage assembly 64 fixes the touch screen, the storage assembly 64 includes a rotating column 641 disposed in the storage groove 67 and a pair of storage clips 642 connected to the rotating column 641, the touch screen is placed between the storage clips 642, a clamping spring 643 is connected to the outer side of each storage clip 642, the storage clips 643 are connected to the storage groove 67 through the clamping springs 643, and the storage clips 642 are folded inwards to clamp the touch screen under the action of the clamping springs 643.

In addition, a conveying wheel is arranged in the second conveying belt 61, an adjusting assembly 68 for controlling the storage clips 642 to be in a furled state is arranged at the lower end of the second conveying belt 61, the adjusting assembly 68 comprises a connecting plate 681 arranged on the lower template 4 and below the second conveying belt 61 and an arc plate 682 connected to the right end of the connecting plate 681, a pair of abutting plates 683 are vertically arranged on the inner side faces of the connecting plate 681 and the arc plate 682, the upper ends of the abutting plates 683 are respectively in contact with the storage clips 642 on the two sides and press the storage clips 642 to the storage groove 67, and the distance between the abutting plates 683 is gradually increased close to the upper end of the arc plate 682.

As shown in fig. 5, the main operation principle of the adjusting assembly 68 is that when the transmission seat 62 moves to above the connecting plate 681, the pressing plate 683 just enters the accommodating groove 67 to contact with the accommodating clamp 642, and when the transmission seat 62 is transmitted from the connecting plate 681 to the arc-shaped plate 682, the distance between the pressing plates 683 gradually increases to gradually press the accommodating clamp 642 into the accommodating groove 67, so that a sufficient space is left at the opening of the accommodating groove 67 for the touch screen to pass through into the accommodating groove 67.

In order to smoothly enter the touch screen into the accommodating groove 67, the conveying seat 62 is arranged on the side of the arc plate 682, the upper end of the arc plate 682 is provided with a connecting groove 69 between the abutting plates 683, the conveying plate 65 is provided with a conveying groove, as shown in fig. 6 and 7, the pushing assembly 66 comprises a feeding chamber 661 arranged at one end of the conveying plate 65 far away from the transfer table 63 and a push plate 662 arranged in the feeding chamber 661, one end of the push plate 662 is connected to the inner wall of the conveying groove through a thrust spring 663, the push plate 662 is connected to a connecting rod 664, the upper end of the connecting rod 664 is connected to the feeding plate 665, the upper end of the feeding chamber is provided with a feeding hole, the feeding plate 665 is arranged on the feeding hole, the upper end of the feeding plate 665 is connected to a shifting plate 666, a feeding groove 667 is arranged in the upper end of.

In the conveying process, the push plate 662 in the conveying groove pushes a plurality of touch screens to the joint of the horizontal part and the vertical part on the conveying plate 65, the driving device 7 is adopted to push the touch screens from the horizontal part of the conveying plate 65 to the accommodating groove 67, under the action of the thrust spring 663, the push plate 662 generates thrust to the touch screen in the conveying groove, when a touch screen on the vertical portion of transport plate 65 is pushed into receiving slot 67, a charge is required on the vertical portion of transport plate 65 to continue pushing the touch screen at the end to the horizontal portion of transport plate 65, paddle 666 is moved to feed plate 665 into feed slot 667, the push plate 662 moves to the leftmost end along the connecting rod 664, the touch screen is placed into the feeding port, the touch screen enters the feeding chamber 661 and enters the conveying groove, releasing paddle 666, feed plate 665 and push plate 662 return to the home position and continue to push the touch screen to the level within transport plate 65.

According to the invention, the touch screen is pushed to the accommodating groove 67 from the horizontal part of the conveying plate 65 by adopting the driving device 7, the driving device 7 comprises a push rod 71 arranged on the transfer table 63 and a push sheet 72 arranged on the push rod 71, one end of the push rod 71 is connected with an air cylinder 73, the push rod 71 is connected with an L-shaped connecting rod 74, one end of the L-shaped connecting rod 74 is connected with the translation gear plate 554, the air cylinder 73 operates to drive the push sheet 72 to push the touch screen to the accommodating groove 67 through the push rod 72, in addition, the air cylinder 73 provides a power source for the pneumatic assembly 55 through the L-shaped connecting rod 74, when the air cylinder 73 pushes once, the second conveyor belt 61 moves once, and the touch screen which is not cut is just conveyed below the forming cutter device 5, the cutting knife 54 just moves to the upper end face of the.

As another embodiment of the invention, the air cylinder 73 retracts immediately after being pushed, and when the air cylinder may cause the cutting knife 54 to fail to completely cut the touch screen, a delay air cylinder with a certain time delay with the air cylinder 73 is arranged on the side of the air cylinder 73 and is connected with the L-shaped connecting rod 74, and when the air cylinder 73 starts to operate for 0.5 second, the delay air cylinder starts to operate to drive the pneumatic assembly 55 to drive the cutting knife 54 to cut the touch screen.

According to the invention, the cut part is demoulded by adopting the demoulding device 8, the demoulding device 8 comprises a demoulding piece 81 arranged in the lower template 4 and an alarm 82 arranged on the demoulding piece 81, and the demoulding piece 81 cuts the cut material to enable the material to fall on the first conveyor belt 9 by separating the cutting knife 54.

As shown in fig. 8, demolding grooves 83 are formed in two sides of the forming groove 10, the demolding part 81 comprises a demolding block 811 rotatably arranged in the demolding groove 83 and a demolding protrusion 812 arranged at the end of the demolding block 811, the demolding block 811 is connected to the inner wall of the demolding groove 83 through a rotating rod 813, a miniature rotating motor is connected to the rotating rod 813, a sensing channel 814 is connected to the lower end of the lower template 4, a sensor is arranged in the sensing channel 814, a cutting through groove is formed in the side wall of the sensing channel 814, a cutting sheet 815 is arranged at the lower end of the lower template 4, a gear rod 816 is connected to the cutting sheet 815, a first connecting gear 817 is arranged on the rotating rod 813, a second connecting gear 818 is meshed to the first connecting gear 817, a gear block 819 is arranged on the second connecting gear 818, the gear block 819 is meshed to the gear rod 816, and the radius of the gear block 819 is larger.

The main working principle of the demoulding cutting piece 81 is that after the cutting knife 54 cuts the touch screen, the cutting knife 54 drives the cut part to enter the forming groove, the micro rotating motor drives the rotating rod 813 to rotate to drive the demoulding module 811 to rotate, the demoulding bulge 812 pushes out the cut part on the cutting knife 54, the inductor in the induction channel 814 induces that the cut part falls down, and the micro rotating motor rotates in the opposite direction to drive the demoulding module 811 to reset to the initial position; when the inductor does not sense that the cut part falls down, the micro rotating motor continues to rotate and drives the second connecting gear 818 to rotate through the first connecting gear 817, the gear block 819 on the second connecting gear 818 moves to the lower side to be clamped with the gear rod 816 and drive the gear rod 816 to move rightwards, so that the cutting piece 815 moves rightwards to cut and push out the cut part until the inductor senses that the cut part falls down, and the micro rotating motor rotates in the opposite direction to drive the gear rod 816 and the demolding block 811 to reset to the initial position.

In the invention, the air cylinder 73, the inductor and the micro rotating motor are all connected with a controller, and the controller controls the air cylinder 73, the inductor and the micro rotating motor to drive.

The main implementation mode of the invention is that the controller controls the operation of the cylinder 73 to push the touch screen into the receiving groove 67, simultaneously the poking sheet 666 conveys a new touch screen into the conveying groove, the cylinder 73 drives the pneumatic assembly 55 to operate, the pneumatic assembly 55 drives the cutting knife 54 to cut the touch screen downwards, after the cutting knife 54 cuts the touch screen, the demoulding cutter 81 pushes down or cuts the cut part on the cutting knife 54 and pushes down the cut part onto the first conveying belt 9, when the sensor does not sense the falling of the cut part immediately after the cutting is finished, the alarm 82 gives an alarm, the cylinder 73 is reset to the initial position after the cut part is pushed down to drive the cutting knife 54 to reset to the initial position, the fixing bolt 533 is dismounted to replace the cutting knife 54, the alarm 82 does not give an alarm under normal condition, the sensor senses the falling of the cut part after the cutting is finished, the air cylinder 73 immediately drives the cutter 54 to reset to the initial position, and then the air cylinder 73 continues to operate to cut the next touch screen and check the cutter 54.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.

Claims (10)

1. The touch pad processing and forming cutter mechanism is characterized by comprising an upper mold frame (1), an upper mold plate (2) arranged on the upper mold frame (1), a lower mold frame (3), a lower mold plate (4) arranged on the lower mold frame (3) and a plurality of groups of forming cutter devices (5) arranged on the upper mold plate (2), wherein a forming groove (10) is formed in the lower mold plate (3), a conveying device (6) for conveying the touch pad is arranged between the upper mold plate (2) and the lower mold plate (4), a driving device (7) is arranged at the end part of the conveying device (6), the driving device (7) drives the conveying device (6) to perform intermittent conveying, a demolding device (8) is arranged on the lower mold plate (4), and a first conveying belt (9) is arranged below the demolding device (8);

the forming cutter device (5) comprises a forming cutter plate (51) arranged on the upper template (2) and a cutting cabin (52) arranged in the forming cutter plate (51) in a sliding mode, two sides of the cutting cabin (52) are connected with a cutting cutter (54) through a connecting assembly (53), a pneumatic assembly (55) is arranged above the cutting cabin (52), and the pneumatic assembly (55) and the connecting assembly (53) control the cutting cutter (54) to move downwards and furl inwards to cut the touch pad;

the conveying device (6) comprises a second conveying belt (61) arranged between the upper template (2) and the lower template (4) and a plurality of conveying seats (62) arranged on the second conveying belt (61), one end of the second conveying belt (62) is provided with a transfer platform (63), a containing groove (67) is formed in the conveying seat (62), a containing assembly (64) for temporarily containing the touch screen is arranged in the containing groove (67), a conveying plate (65) is mounted on the transfer platform (63), and one end of the conveying plate is provided with a pushing assembly (66);

the demolding device (8) comprises a demolding piece (81) arranged in the lower template (4) and an alarm (82) arranged on the demolding piece (81), wherein the demolding piece (81) cuts cut materials to enable the materials to fall onto the first conveying belt (9) by the cutting knife (54).

2. A touch pad forming knife mechanism according to claim 1, characterized in that the connecting assembly (53) comprises a fixed column (531) arranged in the cutting cabin (52) and an inner push rod (532) rotatably arranged on the fixed column (531), the cutting knife (54) is mounted at the lower end of the inner push rod (532) through a fixed bolt (533), and an outward push spring (534) is connected between the inner push rods (532);

two ends of the upper die frame (1) are connected with limiting plates (535), and the limiting plates (535) control the moving track of the inner push rod (532).

3. A touch pad forming tool mechanism according to claim 2, wherein the side of the limiting plate (535) near the cutting tool (54) is provided with a slope;

the outer side of the cutting cabin (52) is provided with a lifting block (56), a sliding groove for the lifting block (56) to slide is formed in the forming cutter plate (51), and the cutting cabin (52) slides up and down in the forming cutter plate (51) through the lifting block (56).

4. The touch pad processing and forming cutter mechanism according to claim 3, wherein the pneumatic assembly (55) comprises a lifting gear rod (551) connected above the cutting cabin (52) and a first transmission gear (552) arranged at the upper end of the lifting gear rod (551), a second transmission gear (553) is meshed at the side edge of the first transmission gear (552), a translation gear plate (554) is arranged below the second transmission gear (553), a fixed plate (11) is arranged on the upper mold frame (1), and the first transmission gear (552) and the second transmission gear (553) are both connected on the fixed plate (11) through connecting columns.

5. A touch panel forming blade mechanism according to claim 1, wherein the receiving assembly (64) comprises a rotating post (641) disposed in the receiving groove (67) and a pair of receiving clips (642) connected to the rotating post (641), the touch screen is placed between the receiving clips (642), and a clip spring (643) is connected to the outer side of the receiving clips (642) and is connected in the receiving groove (67) through the clip spring (643).

6. The touch panel forming tool mechanism according to claim 5, a conveying wheel is arranged in the second conveying belt (61), an adjusting component (68) for controlling the containing clamp (642) to be in a folded state is arranged at the lower end of the second conveying belt (61), the adjusting assembly (68) comprises a connecting plate (681) arranged on the lower template (4) and below the second conveyor belt (61) and an arc-shaped plate (682) connected to the right end of the connecting plate (681), a pair of abutting plates (683) are vertically arranged on the inner side surfaces of the connecting plate (681) and the arc-shaped plate (682), the upper end of the abutting plate (683) is respectively contacted with the containing clips (642) at two sides and presses the containing clips (642) into the containing grooves (67), the distance between the abutting plates (683) is gradually increased close to the upper end of the arc-shaped plate (682).

7. The touch panel processing and forming cutter mechanism according to claim 6, wherein the conveying seat (62) is arranged at the side of the arc-shaped plate (682), the upper end of the arc-shaped plate (682) and the connecting groove (69) are formed between the abutting plates (683), the conveying plate (65) is provided with a conveying groove, the pushing assembly (66) comprises a feeding chamber (661) arranged at one end of the conveying plate (65) far away from the transfer table (63) and a pushing plate (662) arranged in the feeding chamber (661), one end of the pushing plate (662) is connected to the inner wall of the conveying groove through a pushing spring (663), the pushing plate (662) is connected with a connecting rod (664), the upper end of the connecting rod (664) is connected with a feeding plate (665), the upper end of the feeding chamber (661) is provided with a feeding hole, and the feeding plate (665) is mounted on the feeding hole, the feed plate (665) upper end is connected with plectrum (666), be provided with feed chute (667) in feed bin (661) upper end, feed plate (665) are connected through reset spring (668) feed chute (667) inner wall.

8. The touch panel processing and forming cutter mechanism according to claim 7, wherein the driving device (7) comprises a push rod (71) arranged on the transfer table (63) and a push sheet (72) arranged on the push rod (71), one end of the push rod (71) is connected with a cylinder (73), an L-shaped connecting rod (74) is connected onto the push rod (71), and one end of the L-shaped connecting rod (74) is connected with the translation gear plate (554).

9. The touch panel processing and forming cutter mechanism according to claim 8, wherein both sides of the forming groove (10) are provided with demolding grooves (83), the demolding part (81) comprises a demolding module (811) rotatably arranged in the demolding groove (83) and a demolding protrusion (812) arranged at the end of the demolding module (811), the demolding module (811) is connected to the inner wall of the demolding groove (83) through a rotating rod (813), the rotating rod (813) is connected with a micro rotating motor, the lower end of the lower template (4) is connected with an induction channel (814), an inductor is arranged in the induction channel (814), a cutting through groove is formed in the side wall of the induction channel (814), the lower end of the lower template (4) is provided with a cutting piece (815), the cutting piece (815) is connected with a gear rod (816), the rotating rod (813) is provided with a first connecting gear (817), a second connecting gear (818) is meshed with the first connecting gear (817), a gear block (819) is arranged on the second connecting gear (818), the gear block (819) is meshed with the gear rod (816), and the radius of the gear block (819) is larger than that of the second connecting gear (818).

10. A touch panel forming cutter mechanism according to claim 9, wherein the air cylinder (73), the sensor and the micro-rotating motor are all connected with a controller.

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