CN114290071A

CN114290071A - IC automated production processing is with cutting sculpture all-in-one

Info

Publication number: CN114290071A
Application number: CN202210075836.2A
Authority: CN
Inventors: 李小琴; 皮剑兵
Original assignee: Shenzhen Hongshengda Technology Co ltd
Current assignee: Shenzhen Hongshengda Technology Co ltd
Priority date: 2022-01-23
Filing date: 2022-01-23
Publication date: 2022-04-08
Anticipated expiration: 2042-01-23
Also published as: CN114290071B

Abstract

The invention discloses a cutting and carving integrated machine for automatic production and processing of an IC (integrated circuit), which comprises a processing table, wherein a carving component, a rotating wheel cutting component, a waste material cutting component and a waste material transmission structure are respectively arranged on the upper side of the processing table along a processing direction; the present case has abandoned prior art will be to the cutting of IC-card and the mode that the sculpture separately set up, by feeding transmission assembly to the connection transmission between runner cutting assembly and the sculpture subassembly to the realization reduces occupation space to the cutting of IC-card and glyptic integration, has improved the production efficiency to the IC-card.

Description

IC automated production processing is with cutting sculpture all-in-one

Technical Field

The invention relates to the technical field of IC (integrated circuit) production, in particular to a cutting and carving integrated machine for automatic IC production and processing.

Background

The IC card is also called as intelligent card, microcircuit card or microchip card, it embeds a microelectronic chip into the card base which accords with the standard, and makes the card form, the communication mode between IC card and reader-writer can be contact type, also can be non-contact type; because the IC card has the characteristics of small volume, convenient carrying, large storage capacity, high reliability, long service life, strong confidentiality, high safety and the like, the IC card combines the microelectronic technology and the computer technology together, and improves the modernization degree of work and life of people. At present, in the production process of an IC, the IC card needs to be subjected to profile cutting and surface engraving.

The IC card cutting device with the application number of CN201410030718.5 comprises a rack, wherein a working platform for placing a material plate is arranged on the rack, an XY motion platform is arranged above the rack, and a laser generator which can be driven by the XY motion platform to move on a horizontal plane and is used for cutting the material plate is arranged on the XY motion platform;

the IC card laser engraving system with the exhaust structure comprises a body of an engraving machine, wherein a conveyor belt for conveying cards is arranged on the body, a laser head for engraving the cards is arranged on the body, and a transparent cover for wrapping the laser head is arranged on the body;

however, the prior art has the following problems:

1. the cutting and the carving of the IC card can not be integrated, the occupied space of the equipment is large, and the production efficiency of the IC card is reduced;

2. in the cutting process of the IC card, the prior art needs to stop positioning the transmission of the IC card plate, and the continuous and uninterrupted cutting of the IC card cannot be realized;

3. in the process of cutting the IC card, the cutting head cannot be adjusted according to the difference of the distribution columns and numbers of the IC card;

4. the waste material plate that produces in the cutting process of IC-card is not convenient for accomodate the arrangement.

Disclosure of Invention

The invention aims to solve the problems and provide a cutting and carving all-in-one machine for automatic production and processing of an IC (integrated circuit), aiming to overcome the defects of the prior art.

In order to achieve the purpose, the invention provides the following technical scheme:

the invention provides a cutting and carving integrated machine for automatic IC production and processing, which comprises a processing table, wherein a carving component, a rotating wheel cutting component, a waste material cutting component and a waste material transmission structure are respectively arranged on the upper side of the processing table along a processing direction;

the rotating wheel cutting assembly comprises a first wheel shaft, one end of the first wheel shaft is driven to rotate by a first motor, a plurality of rotating wheel cutting structures are detachably connected to the first wheel shaft along the axial direction of the first wheel shaft, the outer sides of the two ends of the first wheel shaft are connected with limit stop rings through bolts, a digital display control panel is arranged on the outer side of the processing table, and the output end of the digital display control panel is electrically connected to the input end of the first motor.

Adopt above-mentioned structure, during the use, the feeding transmission subassembly transmits the IC cardboard material that needs cutting process, when transmitting sculpture subassembly below, carve the card position department of IC cardboard material by the sculpture subassembly, then the retransmission rotates the continuity cutting to IC cardboard material between runner cutting assembly and the cutting rotation support subassembly, wherein the finished product IC card that runner cutting structure can cut removes the finished product transmission subassembly on, transmit the finished product IC card by the finished product transmission subassembly, wherein remaining rectangular panel waste material is cut by the waste material cutting subassembly and is smashed, and transmit the collection by waste material transmission structure.

Preferably, the rotating wheel cutting structure comprises a central wheel disc, the middle of the first wheel shaft is in a hexagonal cylinder shape, two end positions of the first wheel shaft are in a cylinder shape, a hexagonal through hole matched and connected with the first wheel shaft is formed in the center position of the central wheel disc, an outer sleeve ring is detachably connected to the outer side of the central wheel disc, a plurality of cutting knife rings which are uniformly distributed are formed in the outer side of the outer sleeve ring along the circumferential direction of the outer sleeve ring, the outer shape of each cutting knife ring is in a square shape, and the output end of the digital display control panel is electrically connected to the input end of the vacuum pump.

Preferably, a plurality of telescopic cavities which are uniformly distributed at equal angles are formed in the outer side of the central wheel disc along the circumferential direction of the central wheel disc, one ends of the telescopic cavities penetrate through the outer ring and are communicated with the outside, telescopic sliders are slidably arranged in the telescopic cavities, cylinders used for driving the telescopic sliders to slide are fixedly arranged in the telescopic cavities, vacuum suction heads are convexly arranged at the outer side edges of the opening ends, close to the telescopic cavities, of the telescopic sliders, vacuum air pumps and infrared sensors are respectively arranged in the telescopic sliders, the output ends of the infrared sensors are electrically connected to the input end of the digital display control panel, and the output end of the digital display control panel is electrically connected to the input end of the vacuum air pumps.

Preferably, the finished product conveying assembly comprises a conveying support, the bottom side of the conveying support is fixedly arranged on the upper side of the processing table, the cross section of the conveying support is U-shaped, a first conveying belt is arranged between two side plates of the conveying support, and the conveying direction of the first conveying belt is consistent with the axial direction of the first wheel shaft.

Preferably, the waste cutting assembly comprises a support with a U-shaped appearance, the U-shaped opening of the support faces downwards, two ends of the lower portion of the support are fixedly arranged on the upper side of the processing table, a tool rest is arranged between two side plates of the support, the upper end of the tool rest is rotatably connected with an abutting rotating wheel, the lower end of the tool rest is detachably connected with a cutting knife, an elastic reset structure is arranged between two sides of the tool rest and the support, a second motor is fixedly arranged on the top side of the support, an eccentric wheel is fixedly connected with an output shaft of the second motor, an opening groove used for penetrating through the abutting rotating wheel is formed in the top side of the support, the eccentric wheel and the abutting rotating wheel abut against each other, and a cutting knife groove matched with the cutting knife is formed in the upper side of the processing table.

Preferably, the elastic reset structure comprises guide blocks fixedly arranged on two sides of the tool rest respectively, the two guide blocks are arranged in sliding grooves formed in two side plates of the support respectively in a sliding mode, an axially vertical guide shaft is fixedly arranged in each sliding groove, and a guide hole matched with the guide shaft to slide is formed in each guide block in a penetrating mode.

Preferably, the feeding transmission assembly comprises a plurality of driven transmission wheels which are uniformly distributed, a driving transmission wheel is arranged above the driven transmission wheels, one end of the driving transmission wheel is driven to rotate by a third motor which is fixedly mounted on the processing table, a second limiting check ring is arranged on the outer side of the driving transmission wheel in an axial sliding mode, a bolt which is used for being fixedly abutted against the outer side of the driving transmission wheel is in threaded connection with the outer side of the second limiting check ring, a first limiting check ring is arranged on the outer side of the driven transmission wheel in an axial sliding mode, and a bolt which is used for being fixedly abutted against the outer side of the driven transmission wheel is in threaded connection with the outer side of the first limiting check ring.

Preferably, the cutting rotation support assembly comprises a support rotating wheel, the support rotating wheel is rotatably arranged in a rotation cavity formed in the processing table, the upper side of the rotation cavity is open, a lifting chute is formed in the side wall, close to the two ends of the support rotating wheel, of the rotation cavity, lifting blocks are arranged in each lifting chute in a vertically sliding mode, a second wheel shaft is rotatably connected to the central axis of the support rotating wheel, the two ends of the second wheel shaft are respectively fixed with the two lifting blocks, a hydraulic cylinder is fixedly arranged on the inner bottom surface of each lifting chute, a push rod head end of the hydraulic cylinder is fixedly connected to the lower side of each lifting block, a lifting rod is fixedly arranged on the inner top surface of each lifting chute, and the lower end of each lifting rod is slidably connected into a guide hole formed in the top side of each lifting block.

Preferably, the carving assembly comprises a three-axis driving assembly, a plurality of laser carving heads are arranged on the three-axis driving assembly, and the number of the laser carving heads is consistent with that of the rotating wheel cutting structures.

Preferably, the scrap conveying structure includes an inclined slide table inclined from high to low along the processing direction, and a second conveyor belt is provided at a low position of the inclined slide table.

Has the advantages that:

1. the scheme abandons the mode that the IC card is cut and carved separately in the prior art, and the feeding transmission component is used for transmitting the connection between the rotating wheel cutting component and the carving component, so that the IC card is cut and carved integrally, the occupied space is reduced, and the production efficiency of the IC card is improved;

2. in the cutting process of the IC card, the rotating wheel cutting assembly is matched with the cutting rotating support assembly, so that the continuous uninterrupted cutting of the IC card can be realized, the cutting efficiency of the IC card is greatly improved, the carry movement of the IC card material in the cutting process is realized, and the problem of poor quality caused by inaccurate cutting positioning of the IC card is avoided;

3. in the cutting process of the IC card, the number of the laser engraving heads on the engraving assembly is adjusted by the consistency of the number of the laser engraving heads and the number of the rotating wheel cutting structures and the detachable installation of the rotating wheel cutting structures along the axial direction of the first wheel shaft, so that the adjustment can be carried out according to the difference of the distribution columns and numbers of the IC card;

4. the waste material plate generated in the cutting process of the IC card can be cut through the waste material cutting assembly, and the waste material plate generated by cutting can be stored and conveyed by the inclined sliding table and the second conveying belt, so that the waste material can be conveniently sorted and summarized;

5. the rotary wheel cutting assembly, the finished product conveying assembly, the waste material cutting assembly, the carving assembly, the feeding conveying assembly, the cutting rotating supporting assembly, the second conveying belt and the like are mutually cooperated and matched, so that the automatic cutting and carving integration of the IC card is realized, the automatic uninterrupted continuous cutting of the IC card is realized, and the functions of crushing, arranging and summarizing the waste strip plates after cutting and the like are realized to form an integral body which can not be divided.

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 is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a front view of the present invention;

FIG. 2 is a left side view of FIG. 1 of the present invention;

FIG. 3 is a right side view of FIG. 1 of the present invention;

FIG. 4 is a cross-sectional view taken along line A-A of FIG. 1 in accordance with the present invention;

FIG. 5 is an enlarged view of a portion of the invention at C of FIG. 4;

FIG. 6 is a cross-sectional view taken along line B-B of FIG. 2 in accordance with the present invention;

FIG. 7 is an enlarged view of a portion of the invention at D of FIG. 1;

fig. 8 is a perspective view of fig. 1 of the present invention.

The reference numerals are explained below: 1. a processing table; 2. a support plate; 3. a wheel cutting assembly; 301. a rotating wheel cutting structure; 301a, a central wheel disc; 301b, an outer ferrule; 301c, a telescoping chamber; 301d, a cylinder; 301e, a telescopic slider; 301f, vacuum air pump; 301g, cutting a cutter ring; 301h, vacuum suction head; 301i, an infrared sensor; 302. a first motor; 303. a limit stop ring; 304. a first axle; 4. a finished product transport assembly; 4a, a transmission support; 4b, a first conveyor belt; 5. a scrap cutting assembly; 501. an eccentric wheel; 502. a second motor; 503. a support; 504. an elastic reset structure; 504a, a guide block; 504b, a guide shaft; 504c, a spring; 505. abutting against the rotating wheel; 506. a tool holder; 507. a cutting knife; 6. an engraving assembly; 6a, a three-axis driving assembly; 6b, laser engraving head; 7. a feed transport assembly; 7a, a third motor; 7b, a driving transmission wheel; 7c, a driven transmission wheel; 7d, a first limiting retainer ring; 7e, a second limit retainer ring; 8. cutting the rotary support assembly; 801. supporting the rotating wheel; 802. a second wheel axle; 803. a lifting rod; 804. a lifting block; 805. a hydraulic cylinder; 806. rotating the chamber; 9. inclining the sliding table; 10. a second conveyor belt; 11. a digital display control panel; 12. and cutting the cutter groove.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be described in detail below. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the examples given herein without any inventive step, are within the scope of the present invention.

Referring to fig. 1 to 8, the invention provides a cutting and engraving all-in-one machine for automatic IC production and processing, which comprises a processing table 1, wherein a engraving component 6, a rotating wheel cutting component 3, a waste material cutting component 5 and a waste material transmission structure (the processing direction is the direction shown by the arrow in fig. 1 of the specification) are respectively arranged on the upper side of the processing table 1 along the processing direction, a feeding transmission component 7 is arranged between the engraving component 6 and the rotating wheel cutting component 3, a finished product transmission component 4 is arranged on one side of the rotating wheel cutting component 3, and a cutting rotation supporting component 8 is arranged below the rotating wheel cutting component 3 in a lifting and adjusting manner; the rotating wheel cutting assembly 3 comprises a first wheel shaft 304, one end of the first wheel shaft 304 is driven to rotate by a first motor 302, a plurality of rotating wheel cutting structures 301 are detachably connected to the first wheel shaft 304 along the axial direction of the first wheel shaft, the outer sides of the two ends of the first wheel shaft 304 are connected with limit stop rings 303 through bolts, a digital display control panel 11 is arranged on the outer side of the processing table 1, and the output end of the digital display control panel 11 is electrically connected to the input end of the first motor 302.

Referring to fig. 1, 4 and 5 of the specification, the wheel cutting structure 301 includes a central wheel disc 301a, the middle portion of the first wheel shaft 304 is in a hexagonal cylinder shape, two end portions of the first wheel shaft 304 are in a cylindrical cylinder shape, a hexagonal through hole matched and connected with the first wheel shaft 304 is formed at the central position of the central wheel disc 301a, in practical applications, the first wheel axle 304 can rotate to drive the central wheel disc 301a to rotate, the center wheel disc 301a can be detachably connected in a sliding manner along the axial direction of the first wheel shaft 304, the outer side of the center wheel disc 301a is detachably connected with an outer ring 301b, a plurality of cutting knife rings 301g which are uniformly distributed are formed on the outer side of the outer ring 301b along the circumferential direction, the cutting knife rings 301g are square in shape, in the rotation process of the central wheel disc 301a, the cutting cutter ring 301g is matched with the cutting rotation supporting component 8 to cut the IC card board. A plurality of telescopic cavities 301c with equal angle uniform distribution are arranged on the outer side of the central wheel disc 301a along the circumferential direction, one end of each telescopic cavity 301c penetrates through the outer ring 301b and is communicated with the outside, a telescopic sliding block 301e is arranged in each telescopic cavity 301c in a sliding manner, a cylinder 301d used for driving the telescopic sliding block 301e to slide is fixedly arranged in each telescopic cavity 301c, a vacuum suction head 301h is arranged on the outer side edge of the opening end of each telescopic sliding block 301e close to the telescopic cavity 301c in a protruding manner, a vacuum air pump 301f and an infrared sensor 301i are respectively arranged in each telescopic sliding block 301e, the output end of each infrared sensor 301i is electrically connected to the input end of the digital display control panel 11, and the output end of the digital display control panel 11 is electrically connected to the input end of the vacuum air pump 301 f. Through the specific structural design, when the IC plate is cut, the cut IC card is located at the opening of the cutting knife ring 301g, when the infrared sensor 301i detects the cut IC card, an electric signal can be transmitted to the digital display control panel 11, the digital display control panel 11 controls the opening of the cylinder 301d, the push rod of the cylinder 301d stretches and retracts to drive the retractable slider 301e to extend outwards, at this time, the vacuum suction head 301h contacts with the cut IC card, the vacuum air pump 301f realizes the absorption of the cut IC card through the vacuum suction head 301h, the cut IC card is absorbed to rotate along with the central wheel disc 301a, when the central wheel disc 301a rotates a certain angle to be located above the finished product transmission assembly 4, the digital display control panel 11 controls the closing of the vacuum air pump 301f, the cut IC card falls onto the first transmission belt 4b of the finished product transmission assembly 4, and (5) conveying to the subsequent process for processing.

Referring to fig. 6 in the specification, the finished product conveying assembly 4 comprises a conveying support 4a, the bottom side of the conveying support 4a is fixedly arranged at the upper side of the processing table 1, the cross section of the conveying support 4a is in a U shape, a first conveying belt 4b is arranged between two side plates of the conveying support 4a, and the conveying direction of the first conveying belt 4b is consistent with the axial direction of the first wheel shaft 304.

Referring to the accompanying

drawings

1, 3, 6 and 7 in the specification, the scrap cutting assembly 5 comprises a support 503 with a U-shaped appearance, the U-shaped opening of the support 503 faces downwards, two lower ends of the support are fixedly arranged on the upper side of the processing table 1, a tool rest 506 is arranged between two side plates of the support 503, the upper end of the tool rest 506 is rotatably connected with an abutting rotating wheel 505, the lower end of the tool rest 506 is detachably connected with a cutting knife 507, an elastic reset structure 504 is arranged between two sides of the tool rest 506 and the support 503, a second motor 502 is fixedly arranged on the top side of the support 503, an eccentric wheel 501 is fixedly connected with an output shaft of the second motor 502, a through hole groove for passing through the abutting rotating wheel 505 is formed in the top side of the support 503, the eccentric wheel 501 and the abutting rotating wheel 505 abut against each other, and a cutting knife groove 12 matched with the cutting knife 507 is formed in the upper side of the processing table 1. The elastic reset structure 504 comprises guide blocks 504a fixedly arranged on two sides of the tool rest 506 respectively, the two guide blocks 504a are arranged in sliding grooves formed in two side plates of the support 503 in a sliding manner respectively, an axial vertical guide shaft 504b is fixedly arranged in each sliding groove, and a guide hole matched with the corresponding guide shaft 504b in a sliding manner is formed in each guide block 504a in a penetrating manner. In practical application, the output shaft of the second motor 502 rotates to drive the eccentric wheel 501 to rotate, the eccentric wheel 501 rotates to push the tool holder 506 and the cutting knife 507 to move downwards through the abutting rotating wheel 505, at the moment, the spring 504c of the elastic reset structure 504 is in a compressed state, so that in the rotating process of the eccentric wheel 501, the elastic reset structure 504 can realize the upward movement reset of the cutting knife 507, the reciprocating up-and-down movement of the cutting knife 507 is realized, the cutting and crushing of the residual long laths are realized after the rotating wheel cutting assembly 3 is cut, and the collection and the induction of the residual long laths are facilitated and the transmission of the residual long laths is carried out by the second transmission belt 10.

Referring to the attached

drawings

2 and 6 in the specification, the feeding transmission assembly 7 comprises a plurality of driven transmission wheels 7c which are uniformly distributed, a driving transmission wheel 7b is arranged above the driven transmission wheels 7c, one end of the driving transmission wheel 7b is driven to rotate by a third motor 7a which is fixedly installed on the processing table 1, a second limit check ring 7e is arranged on the outer side of the driving transmission wheel 7b in a sliding mode along the axial direction of the driving transmission wheel 7b, a bolt which is used for being abutted and fixed with the outer side of the driving transmission wheel 7b is connected to the outer side of the second limit check ring 7e through a thread, a first limit check ring 7d is arranged on the outer side of the driven transmission wheel 7c in a sliding mode along the axial direction of the driven transmission wheel, and a bolt which is abutted and fixed with the outer side of the driven transmission wheel 7c is connected to the outer side of the first limit check ring 7d through a thread. In practical application, the upside at driven transmission wheel 7c is placed to the downside of IC-card panel, the transmission can be fixed a position along the border to IC-card panel to the first spacing retaining ring 7d that driven transmission wheel 7c outside was provided with, and can adjust according to the size of a dimension of IC-card panel, the initiative transmission wheel 7b that the output shaft of third motor 7a rotated and drives the connection rotates, initiative transmission wheel 7b realizes transmitting the removal to the IC-card panel of downside butt, thereby cooperation runner cutting assembly 3 realizes the cutting to IC-card panel, when removing runner cutting assembly 3 and cutting to IC-card panel, can close third motor 7a through digital display control panel 11 control, realize when cutting IC-card panel by runner cutting assembly 3, also realize the position transmission removal to IC-card panel.

Referring to fig. 4 and 6 in the specification, the cutting rotation supporting assembly 8 includes a supporting wheel 801, the supporting wheel 801 is rotatably disposed in a rotation chamber 806 formed in the processing table 1, an upper side of the rotation chamber 806 is open, a lifting chute is formed in a side wall of the rotation chamber 806 close to two ends of the supporting wheel 801, a lifting block 804 is slidably disposed in each lifting chute up and down, a second wheel shaft 802 is rotatably connected to a central axis of the supporting wheel 801, two ends of the second wheel shaft 802 are respectively fixed to the two lifting blocks 804, a hydraulic cylinder 805 is fixedly disposed on an inner bottom surface of the lifting chute, a push rod head end of the hydraulic cylinder 805 is fixedly connected to a lower side of the lifting block 804, a lifting rod 803 is fixedly disposed on an inner top surface of the lifting chute, and a lower end of the lifting rod 803 is slidably connected to a guide hole formed in a top side of the lifting block 804.

The engraving member 6 comprises a three-axis driving member 6a, a plurality of laser engraving heads 6b are arranged on the three-axis driving member 6a, and the number of the laser engraving heads 6b is consistent with that of the rotating wheel cutting structures 301. Triaxial drive assembly 6a adopts prior art in practical application, for X axle, Y axle and Z axle three-dimensional drive removal, realizes the drive removal to laser engraving head 6b three-dimensional to the realization is to the sculpture on IC card surface, and laser engraving head 6b is unanimous with runner cutting structure 301's quantity, can carry out laser engraving and subsequent cutting simultaneously to the IC card of corresponding quantity, has improved the production efficiency to the IC card greatly.

The scrap conveying structure comprises an inclined sliding table 9, the inclined sliding table 9 inclines from high to low along the processing direction, and a second conveying belt 10 is arranged at the low position of the inclined sliding table 9. After the waste cutting assembly 5 cuts the cut waste, the waste generated by cutting slides down onto the second conveyor belt 10 from the inclined sliding table 9 under the pushing of the subsequent plate, so that the cut waste is cut, collected and processed through the second conveyor belt 10.

The scheme abandons the mode that the IC card is cut and carved separately in the prior art, and the feeding transmission component 7 transmits the connection between the rotary cutting component 3 and the carving component 6, thereby realizing the integration of cutting and carving the IC card, reducing the occupied space and improving the production efficiency of the IC card; in the cutting process of the IC card, the rotating wheel cutting assembly 3 and the cutting rotary supporting assembly 8 are matched to realize continuous and uninterrupted cutting of the IC card, so that the cutting efficiency of the IC card is greatly improved, the carry movement of the IC card material in the cutting process is realized, and the problem of poor quality caused by inaccurate cutting and positioning of the IC card is avoided; in the cutting process of the IC card, the number of the laser engraving heads 6b on the engraving assembly 6 is adjusted by the consistency of the number of the laser engraving heads 6b and the number of the rotating wheel cutting structures 301 and the detachable installation of the rotating wheel cutting structures 301 along the axial direction of the first wheel shaft 304, so that the adjustment can be performed according to the difference of the distribution column number of the IC card; waste plates generated in the cutting process of the IC card can be cut by the waste cutting assembly 5, and the waste plates generated by cutting can be stored and conveyed by the inclined sliding table 9 and the second conveying belt 10, so that the waste can be conveniently sorted and summarized; runner cutting subassembly 3, finished product transmission subassembly 4, waste material cutting subassembly 5, sculpture subassembly 6, feeding transmission subassembly 7, cutting rotate between supporting component 8 and the second transmission band 10 etc. mutually in coordination, mutually support each other, realize the automatic cutout and the sculpture integration to the IC-card, to the automatic incessant continuous cutting of IC-card, to functions such as shredding and arrangement induction of the useless rectangular panel after the cutting, form an inseparable whole.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims

1. The utility model provides a IC automated production processing is with cutting sculpture all-in-one which characterized in that: the processing device comprises a processing table (1), wherein a carving component (6), a rotating wheel cutting component (3), a waste material cutting component (5) and a waste material transmission structure are respectively arranged on the upper side of the processing table (1) along the processing direction, a feeding transmission component (7) is arranged between the carving component (6) and the rotating wheel cutting component (3), a finished product transmission component (4) is arranged on one side of the rotating wheel cutting component (3), and a cutting rotation supporting component (8) is arranged below the rotating wheel cutting component (3) in a lifting and adjusting mode;

the rotating wheel cutting assembly (3) comprises a first wheel shaft (304), one end of the first wheel shaft (304) is driven to rotate by a first motor (302), the first wheel shaft (304) is axially and detachably connected with a plurality of rotating wheel cutting structures (301), the outer sides of two ends of the first wheel shaft (304) are connected with limit stop rings (303) through bolts, a digital display control panel (11) is arranged on the outer side of the processing table (1), and the output end of the digital display control panel (11) is electrically connected to the input end of the first motor (302).

2. The integrated machine of claim 1, wherein the integrated machine comprises: the rotating wheel cutting structure (301) comprises a central wheel disc (301a), the middle of a first wheel shaft (304) is in a hexagonal cylinder shape, two end positions of the first wheel shaft (304) are in a cylinder shape, a hexagonal perforation matched with the first wheel shaft (304) and connected with the central position of the central wheel disc (301a) is formed, the outer side of the central wheel disc (301a) is detachably connected with an outer ring (301b), a plurality of cutting knife rings (301g) uniformly distributed are formed on the outer side of the outer ring (301b) along the circumferential direction of the outer ring, the outer shapes of the cutting knife rings (301g) are in a square shape, and the output end of the digital display control panel (11) is electrically connected to the input end of a vacuum pump (301 f).

3. The integrated machine of claim 2, wherein the integrated machine comprises: a plurality of telescopic chambers (301c) which are uniformly distributed at equal angles are arranged on the outer side of the central wheel disc (301a) along the circumferential direction, one end of each telescopic chamber (301c) penetrates through the outer ring (301b) and is communicated with the outside, a telescopic sliding block (301e) is arranged in the telescopic cavity (301c) in a sliding manner, a cylinder (301d) for driving the telescopic sliding block (301e) to slide is fixedly arranged in the telescopic cavity (301c), the outer side edge of one end of the telescopic slide block (301e) close to the opening of the telescopic cavity (301c) is convexly provided with a vacuum suction head (301h), a vacuum air pump (301f) and an infrared sensor (301i) are respectively arranged in the telescopic sliding block (301e), the output end of the infrared sensor (301i) is electrically connected to the input end of the digital display control panel (11), the output end of the digital display control panel (11) is electrically connected to the input end of the vacuum pump (301 f).

4. The integrated machine of claim 1, wherein the integrated machine comprises: the finished product conveying assembly (4) comprises a conveying support (4a), the bottom side of the conveying support (4a) is fixedly arranged on the upper side of the processing table (1), the cross section of the conveying support (4a) is U-shaped, a first conveying belt (4b) is arranged between two side plates of the conveying support (4a), and the conveying direction of the first conveying belt (4b) is consistent with the axial direction of the first wheel shaft (304).

5. The integrated machine of claim 1, wherein the integrated machine comprises: the waste cutting assembly (5) comprises a bracket (503) with a U-shaped appearance, the U-shaped opening of the bracket (503) faces downwards, two ends of the lower part of the bracket are fixedly arranged at the upper side of the processing table (1), a knife rest (506) is arranged between the two side plates of the bracket (503), the upper end of the knife rest (506) is rotatably connected with an abutting rotating wheel (505), the lower end of the knife rest (506) is detachably connected with a cutting knife (507), an elastic reset structure (504) is arranged between the two sides of the tool rest (506) and the bracket (503), a second motor (502) is fixedly arranged on the top side of the bracket (503), an eccentric wheel (501) is fixedly connected with the output shaft of the second motor (502), a through hole groove used for penetrating the abutting rotating wheel (505) is formed in the top side of the bracket (503), the eccentric wheel (501) and the abutting rotating wheel (505) are abutted with each other, the upper side of the processing table (1) is provided with a cutting knife groove (12) matched with a cutting knife (507).

6. The integrated machine of claim 5, wherein the integrated machine comprises: the elastic reset structure (504) comprises guide blocks (504a) fixedly arranged on two sides of the tool rest (506), the two guide blocks (504a) are respectively arranged in sliding grooves formed in two side plates of the support (503) in a sliding mode, an axial vertical guide shaft (504b) is fixedly arranged in each sliding groove, and a guide hole matched with the corresponding guide shaft (504b) in a sliding mode is formed in each guide block (504a) in a penetrating mode.

7. The integrated machine of claim 1, wherein the integrated machine comprises: the feeding transmission assembly (7) comprises a plurality of driven transmission wheels (7c) which are uniformly distributed, a driving transmission wheel (7b) is arranged above the driven transmission wheels (7c), one end of the driving transmission wheel (7b) is driven to rotate by a third motor (7a) which is fixedly mounted on the processing table (1), the outer side of the driving transmission wheel (7b) is provided with a second limiting check ring (7e) along the axial sliding direction of the outer side, the outer side of the second limiting check ring (7e) is in threaded connection with a bolt which is used for being fixedly connected with the outer side of the driving transmission wheel (7b) in an abutting mode, the outer side of the driven transmission wheel (7c) is provided with a first limiting check ring (7d) in an axial sliding mode, and the outer side of the first limiting check ring (7d) is in threaded connection with a bolt which is used for being fixedly connected with the outer side of the driven transmission wheel (7c) in an abutting mode.

8. The integrated machine of claim 1, wherein the integrated machine comprises: the cutting rotating support assembly (8) comprises a support rotating wheel (801), the support rotating wheel (801) is rotatably arranged in a rotating chamber (806) formed in the processing table (1), the upper side of the rotating chamber (806) is opened, the lifting sliding grooves are formed in the side walls, close to two ends of the supporting rotating wheel (801), of the rotating cavity (806), lifting blocks (804) are arranged in each lifting sliding groove in a vertically sliding mode, a second wheel shaft (802) is connected to the central axis of the supporting rotating wheel (801) in a rotating mode, two ends of the second wheel shaft (802) are fixed to the two lifting blocks (804) respectively, a hydraulic cylinder (805) is fixedly arranged on the inner bottom face of each lifting sliding groove, the push rod head end of the hydraulic cylinder (805) is fixedly connected to the lower side of the lifting block (804), a lifting rod (803) is fixedly arranged on the inner top face of each lifting sliding groove, and the lower end of the lifting rod (803) is slidably connected into a guide hole formed in the top side of the lifting block (804).

9. The integrated machine of claim 1, wherein the integrated machine comprises: carving subassembly (6) are provided with a plurality of laser engraving head (6b) including triaxial drive assembly (6a) on triaxial drive assembly (6a), laser engraving head (6b) are unanimous with the quantity of runner cutting structure (301).

10. The integrated machine of claim 1, wherein the integrated machine comprises: the waste conveying structure comprises an inclined sliding table (9), wherein the inclined sliding table (9) inclines from high to low along the machining direction, and a second conveying belt (10) is arranged at the low position of the inclined sliding table (9).