CN112428331A - Chip cuts changes pastes all-in-one - Google Patents

Abstract

The invention is suitable for the technical field of wireless radio frequency label packaging equipment, and provides a chip cutting and transferring integrated machine which comprises a rack, and a vacuum drum assembly, a cutting knife assembly and a transmission piece which are arranged in the rack. The cutting knife assembly and the vacuum drum assembly synchronously run through a transmission part, and the cutting knife assembly can be matched with the vacuum drum assembly to cut the chip material adsorbed on the vacuum drum assembly into chips for rotary pasting; the vacuum drum component can adsorb chip materials conveyed by an external traction mechanism and can turn the cut chips to base paper. According to the invention, through the matching of the vacuum drum component and the cutting knife component, the cut chip transfer sticker can be directly positioned on the vacuum drum without other intermediate transition links, the cutting of the chip material and the transfer of the cut chip transfer sticker to the base paper belong to an uninterrupted work flow, the flow action structure of the matching mode is simple, and the production of small-jump-distance Inlay products can be met.

Description

Chip cuts changes pastes all-in-one

Technical Field

The invention belongs to the technical field of wireless radio frequency label packaging equipment, and particularly relates to a chip cutting and transferring integrated machine.

Background

Radio Frequency Identification (RFID) is a non-contact automatic identification technology that is in practical use in the middle of the 20 th century. The radio frequency identification system comprises a radio frequency label and a reader-writer. The radio frequency label is a carrier for carrying identification information, and the reader-writer is a device for acquiring information. The radio frequency identification tag and the reader-writer perform bidirectional communication by utilizing induction, radio waves or microwaves, so that the identification and data exchange of the stored information of the tag are realized.

Inlay is a special term for the smart card industry, and refers to a pre-laminated product formed by laminating a plurality of layers of PVC sheets containing chips and coils, and different types of RFID electronic tags can be manufactured through different forms of packaging. Generally consisting of two or three layers without any printed pattern on the surface. The Inlay product is suitable for the mass production of a plurality of kinds of cards in the early stage. The Inlay is covered with materials with different printed patterns on the upper side and the lower side, and then the materials are laminated again to form the colorful non-contact card.

The cutting mechanism and the transfer mechanism of the existing domestic and foreign electronic chip packaging machine industry adopt an independent split-body matched working mode, the chip after cutting of a chip material cannot be directly transferred to a vacuum drum, other mechanisms are needed for matching when the chip material is cut and the chip is transferred to base paper after cutting, the method belongs to a discontinuous working process, the flow action structure of the matching mode is complex, the structural mode of the cutting mechanism determines that the cutting width is limited (generally less than 150mm of version width), but only dry Inlay with large jump distance can be transferred to the vacuum drum to be combined with the base paper.

Disclosure of Invention

The embodiment of the invention aims to provide a chip cutting and transferring all-in-one machine, which aims to solve the problems in the background technology.

The embodiment of the invention is realized in such a way that a chip cutting and transferring integrated machine comprises: the cutting device comprises a rack, and a vacuum drum assembly, a cutting knife assembly and a transmission piece which are arranged in the rack;

the cutting knife assembly and the vacuum drum assembly synchronously run through a transmission part, and the cutting knife assembly can be matched with the vacuum drum assembly to cut the chip material adsorbed on the vacuum drum assembly into chips for rotary pasting;

the vacuum drum component can adsorb chip materials conveyed by an external traction mechanism and can turn the cut chips to base paper.

Preferably, the cutting blade assembly includes:

the cutting knife is provided with a sliding block which is arranged in the rack in a sliding manner;

the cutting knife is used for cutting the chip material adsorbed on the vacuum drum assembly into chips for rotary pasting in cooperation with the vacuum drum assembly; the cutting knife is rotatably arranged in the cutting knife mounting sliding block.

Preferably, the cutting blade includes:

cutting the cutter arbor body; a cutter groove is formed in the cutting cutter shaft body;

the blade is arranged in the cutter groove;

and the knife pressing strip is arranged in the knife groove and used for fixing the blade.

Preferably, the vacuum drum assembly comprises:

the vacuum drum mounting sliding block is arranged in the rack in a sliding manner;

the vacuum drum is used for adsorbing the chip materials conveyed by the external traction mechanism and turning the cut chips to base paper; the vacuum drum is rotatably arranged in the vacuum drum mounting slider.

Preferably, the vacuum drum comprises:

a vacuum drum shaft body; the shaft body of the vacuum drum is provided with a groove;

the arc block is arranged in the groove;

and the air suction pipe is arranged in the vacuum drum shaft body and communicated with the vacuum drum shaft body.

Preferably, the chip cutting, transferring and pasting all-in-one machine further comprises a driving assembly for driving the vacuum drum assembly to operate.

Preferably, the chip cutting and transferring all-in-one machine further comprises a chip pressing component for pressing the chip material so as to enable the chip material to be attached to the vacuum drum component, and the chip pressing component comprises:

the adjusting rubber shaft is used for pressing the chip;

the adjusting shaft is connected with the rubber shaft;

and the material pressing adjusting hand wheel is used for adjusting the distance between the rubber shaft and the vacuum drum assembly through the adjusting shaft.

Preferably, the chip cutting and transferring all-in-one machine further comprises a pressurizing shaft assembly for applying load to the cutting knife assembly, and the pressurizing shaft assembly comprises:

the pressurizing slide block is arranged in the rack in a sliding manner;

and the pressurizing shaft is connected with the pressurizing sliding block and is positioned on one side of the cutting knife assembly.

Preferably, the chip cutting and transferring all-in-one machine further comprises a pressurizing and adjusting assembly for adjusting the load applied to the cutting knife assembly by the pressurizing shaft assembly, and the pressurizing and adjusting assembly comprises:

locking the nut;

the adjusting screw is rotatably arranged in the locking nut; one end of the adjusting screw rod is connected with the pressurizing slide block;

and the pressurizing adjusting hand wheel is connected with one end of the adjusting screw rod, which is far away from the pressurizing sliding block.

Preferably, the chip cutting, transferring and pasting all-in-one machine further comprises an adjusting assembly used for adjusting the coating angle between the base paper and the vacuum drum assembly.

The embodiment of the invention provides a chip cutting, transferring and pasting all-in-one machine which comprises a rack, and a vacuum drum assembly, a cutting knife assembly and a transmission piece which are arranged in the rack. The cutting knife assembly and the vacuum drum assembly synchronously run through a transmission part, and the cutting knife assembly can be matched with the vacuum drum assembly to cut the chip material adsorbed on the vacuum drum assembly into chips for rotary pasting; the vacuum drum component can adsorb chip materials conveyed by an external traction mechanism and can turn the cut chips to base paper. According to the invention, through the matching of the vacuum drum component and the cutting knife component, the cut chip transfer sticker can be directly positioned on the vacuum drum without other intermediate transition links, the cutting of the chip material and the transfer of the cut chip transfer sticker to the base paper belong to an uninterrupted work flow, the flow action structure of the matching mode is simple, and the production of small-jump-distance Inlay products can be met.

Drawings

Fig. 1 is a front view of a chip cutting, transferring and pasting all-in-one machine provided by an embodiment of the invention;

FIG. 2 is a right side view of a chip cutting and transferring integrated machine according to an embodiment of the present invention;

fig. 3 is a left side view of a chip cutting, transferring and pasting integrated machine according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a station frame according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a cutting blade assembly according to an embodiment of the present invention;

fig. 6 is a schematic structural view of a cutting point of the cutting blade according to an embodiment of the present invention;

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

FIG. 8 is a schematic structural diagram of a driving assembly according to an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a chip pressing assembly according to an embodiment of the present disclosure;

FIG. 10 is a schematic illustration of a pressurized shaft assembly provided by an embodiment of the present invention;

FIG. 11 is a schematic structural diagram of a pressurization adjustment assembly according to an embodiment of the present invention;

FIG. 12 is a side view of an adjustment assembly provided by an embodiment of the present invention.

In the drawings: 1. a base; 2. a station frame; 3. an adjustment assembly; 4. a drive assembly; 5. a vacuum drum assembly; 501. a vacuum drum shaft body; 502. an arc block; 503. a second gear; 504. a vacuum drum is provided with a slide block; 505. an air suction pipe; 6. a chip material pressing component; 7. a cutting blade assembly; 701. cutting the cutter arbor body; 702. a blade; 703. pressing a cutter strip; 704. a first gear; 705. a sliding block is arranged on the cutting knife; 8. a pressurized shaft assembly; 9. a pressurization adjustment assembly.

Detailed Description

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

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

As shown in fig. 1 to 3, an embodiment of the invention provides a chip cutting, transferring and pasting all-in-one machine, which includes: the cutting device comprises a rack, and a vacuum drum component 5, a cutting knife component 7 and a transmission component which are arranged in the rack;

the cutting knife component 7 and the vacuum drum component 5 synchronously run through a transmission part, and the cutting knife component 7 can be matched with the vacuum drum component 5 to cut the chip material adsorbed on the vacuum drum component 5 into chips for transfer pasting;

the vacuum drum component 5 can adsorb chip materials conveyed by an external traction mechanism and can turn the cut chips to base paper.

Specifically, the chip cutting and transferring integrated machine is mainly used for the production of Inlay products, but is not limited to the production of Inlay products. Inlay is understood to be a semi-finished product of the RFID tag that is not encapsulated, divided into dry Inlay and wet Inlay. The dry Inlay does not contain back glue, and the structure is antenna + chip packaging; the wet Inlay contains a back adhesive and can be directly attached to an article, and the structure of the wet Inlay is antenna + chip packaging + surface paper + bottom paper.

The frame of the embodiment of the invention consists of an upper part and a lower part, wherein the upper part is a station frame 2, and the lower part is a base 1. Fig. 4 is a schematic structural diagram of the station frame 2. All or most other parts in the chip cutting and transferring integrated machine are arranged in the station frame 2. The chip cutting and transferring integrated machine is provided with a servo transmission system or is controlled by an external servo transmission system to operate.

The transmission part of the embodiment adopts a gear pair, a first gear 704 in the gear pair is arranged on the cutting knife component 7, a second gear 503 in the gear pair is arranged on the vacuum drum component 5, and the first gear 704 is meshed with the second gear 503. Besides, the transmission part can also adopt other transmission mechanisms such as a conveyor belt, a conveyor chain and the like.

When the chip cutting and transferring integrated machine works, the chip material conveyed by the external traction mechanism is firstly adsorbed by the vacuum drum component 5, the feeding speed of the chip material is not controlled by the vacuum drum component 5 when the chip material is not cut, after the chip material is cut off under the combined action of the cutting knife component 7 and the vacuum drum component 5, the obtained chip is transferred and adsorbed on the vacuum drum component 5 and is driven by the vacuum drum component 5 to rotate in the anticlockwise direction, and the chip cutting jump distance is controlled by the traction mechanism and the servo transmission system.

Meanwhile, the base paper with glue or self-adhesive passes through the lower part of the vacuum drum assembly 5, and when the chip transfer paste rotates to be in contact with the base paper, the chip transfer paste and the base paper are adhered together through the adhesive effect of the base paper gluing. The speed of the base paper is controlled by a traction mechanism for feeding the base paper, and the joint action of the traction mechanism for feeding the base paper and a servo transmission system of the chip cutting and transferring integrated machine achieves the transferring jump distance between the chip and the base paper.

According to the invention, through the matching of the vacuum drum component 5 and the cutting knife component 7, the cut chip transfer sticker can be directly positioned on the vacuum drum without other intermediate transition links, the cutting of the chip material and the transfer of the cut chip transfer sticker onto the base paper belong to an uninterrupted work flow, the flow action structure of the matching mode is simple, and the production of small-jump-distance Inlay products can be met.

As shown in fig. 5, as a preferred embodiment of the present invention, the cutting blade assembly 7 includes:

a cutting knife mounting slider 705 arranged in the frame in a sliding manner;

the cutting knife is used for cutting the chip material adsorbed on the vacuum drum component 5 into chips for rotary pasting in cooperation with the vacuum drum component 5; the cutting blade is rotatably disposed in the cutting blade mounting block 705.

Specifically, the first gear 704 in the transmission member is disposed at one end of the cutting blade, and drives the cutting blade to rotate, so that the chip material adsorbed on the vacuum drum assembly 5 is cut into chips and then is pasted.

In addition, two cutting knife mounting sliding blocks 705 are respectively arranged at two ends of each cutting knife, a sliding groove is formed in the station frame 2, and the cutting knives are slidably mounted in the station frame 2 through the two cutting knife mounting sliding blocks 705. During operation, the two cutting blade mounting blocks 705 can slide up and down in the station frame 2 to drive the cutting blades to be close to or far away from the vacuum drum assembly 5, so that the cutting blades have different cutting states.

As shown in fig. 5, as a preferred embodiment of the present invention, the cutting blade includes:

a cutter arbor body 701; a cutter groove is formed in the cutting cutter shaft body 701;

a blade 702 disposed in the pocket;

and a blade pressing strip 703 provided in the blade groove and used for fixing the blade 702.

Specifically, the cutting knife according to the embodiment of the present invention includes a cutting knife shaft body 701, a blade 702, and a blade pressing bar 703. The first gear 704 in the transmission member is disposed at one end of the cutting arbor 701, and drives the cutting arbor 701 to rotate. The cutting knife shaft body 701 is rotatably disposed in the cutting knife mounting slider 705, and a plurality of knife grooves are uniformly distributed thereon. The insert 702 is provided in a plurality of pieces, each of which is disposed within a respective one of the plurality of pockets. The blade holding strip 703 is also provided with a plurality of pieces, which are respectively provided in the plurality of blade grooves for holding the blade 702. It should be noted that other similar cutting blades capable of rotatably cutting the chip material are also within the scope of the present invention.

As shown in fig. 7, the vacuum drum assembly 5, as a preferred embodiment of the present invention, comprises:

a vacuum drum mounting slide 504 slidably disposed within the frame;

the vacuum drum is used for adsorbing the chip materials conveyed by the external traction mechanism and turning the cut chips to base paper; the vacuum drum is rotatably disposed within the vacuum drum mounting skid 504.

Specifically, a second gear 503 in the transmission is disposed at one end of the vacuum drum and is in meshing engagement with the first gear 704. Two ends of the vacuum drum are respectively provided with two vacuum drum installation sliding blocks 504, the station frame 2 is provided with a sliding groove, and the vacuum drum is slidably installed in the station frame 2 through the two vacuum drum installation sliding blocks 504.

As shown in fig. 7, as a preferred embodiment of the present invention, the vacuum drum includes:

a vacuum drum shaft body 501; grooves are formed in the vacuum drum shaft body 501;

an arc block 502 disposed in the groove;

and the air suction pipe 505 is arranged in the vacuum drum shaft body 501 and is communicated with the vacuum drum shaft body 501.

Specifically, the vacuum drum in the embodiment of the present invention includes a vacuum drum shaft body 501, an arc block 502 and a suction pipe 505. A plurality of grooves are uniformly distributed on the shaft body 501 of the vacuum drum, and a plurality of arc blocks 502 are arranged in the grooves respectively. As shown in fig. 6, there is a fall between the surface of the arc block 502 and the contact point (tangent point) between the cutting blade and the vacuum drum, and the surface of the arc block 502 is treated to prevent adhesion of the chip material to the cutting blade, so that the cutting blade does not damage the coating and can ensure the cutting precision. The air suction pipe 505 is installed inside the vacuum drum shaft body 501 and communicates with the vacuum drum shaft body 501. A second gear 503 in the transmission is provided at one end of the vacuum drum shaft 501, which meshes with the first gear 704. It should be noted that other vacuum drums capable of generating negative pressure to adsorb the chip material similar thereto are also within the scope of the present invention.

As shown in fig. 8, as a preferred embodiment of the present invention, the integrated chip cutting and transferring machine further includes a driving assembly 4 for driving the operation of the vacuum drum assembly 5.

Specifically, the driving assembly 4 comprises a motor, a speed reducer, an output gear and the like, the driving assembly 4 is installed in an installation hole on the non-operation side of the station frame 2 and connected with the station frame 2, and the output gear is meshed with the second gear 503 on the vacuum drum assembly 5 for transmission.

In addition, the driving unit 4 may also employ a power mechanism formed by cooperating a speed reducer and an output gear, such as a hydraulic motor driven by hydraulic pressure, an air compressor driven by air, and the like.

As shown in fig. 9, as a preferred embodiment of the present invention, the integrated chip cutting, transferring and pasting machine further includes a chip pressing assembly 6 for pressing and pasting the chip material to the vacuum drum assembly 5, wherein the chip pressing assembly 6 includes:

the adjusting rubber shaft is used for pressing the chip;

the adjusting shaft is connected with the rubber shaft;

and the material pressing adjusting hand wheel is used for adjusting the distance between the rubber shaft and the vacuum drum component 5 through the adjusting shaft.

Specifically, the chip pressing component 6 is installed in an installation hole in the station frame 2 and matched with the vacuum drum to press and attach the chip material to the vacuum drum. The both ends of adjusting the gluey axle all are equipped with the regulating spindle, and one of them regulating spindle is connected with the lock sleeve, and the other end of lock sleeve is connected with presses material adjusting hand wheel. When the device is operated, the pressing material adjusting hand wheel is rotated to drive the adjusting shaft to rotate, the adjusting shaft further drives the adjusting rubber shaft to be close to or far away from the vacuum drum, and chip materials are pressed on the vacuum drum or are convenient to remove.

As shown in fig. 10, as a preferred embodiment of the present invention, the die cutting and transfer printing integrated machine further includes a pressure shaft assembly 8 for applying a load to the cutting blade assembly 7, and the pressure shaft assembly 8 includes:

the pressurizing slide block is arranged in the rack in a sliding manner;

and the pressurizing shaft is connected with the pressurizing slide block and is positioned on one side of the cutting knife component 7.

Specifically, the pressurizing slide block is provided with two pressurizing slide blocks which are respectively positioned at two ends of the pressurizing shaft, the station frame 2 is provided with a chute, and the pressurizing shaft is slidably arranged in the station frame 2 through the two pressurizing slide blocks. The pressurizing shaft is positioned above the cutting knife component 7 and mainly comprises a shaft core, a shaft roller arranged on the shaft core, a pressurizing bearing arranged on the shaft core and the like. When the chip cutting machine operates, the two pressurizing slide blocks slide in the station frame 2, so that the pressurizing shaft is close to the cutting knife assembly 7, and load is applied to the cutting knife assembly 7, so that the cutting knife assembly 7 cuts a chip material into chips which are rotationally attached.

As shown in fig. 11, as a preferred embodiment of the present invention, the die cutting and transfer printing integrated machine further includes a pressure regulating assembly 9 for regulating the load applied by the pressure shaft assembly 8 to the cutter assembly 7, wherein the pressure regulating assembly 9 includes:

locking the nut;

the adjusting screw is rotatably arranged in the locking nut; one end of the adjusting screw rod is connected with the pressurizing slide block;

and the pressurizing adjusting hand wheel is connected with one end of the adjusting screw rod, which is far away from the pressurizing sliding block.

Specifically, the locking nut, the adjusting screw and the pressurizing adjusting hand wheel are respectively provided with two pressurizing sliding blocks. The pressurization regulating assembly 9 further comprises two mounting blocks, and the pressurization regulating assembly 9 is arranged on the station frame 2 through the two mounting blocks. When the pressure-applying adjusting hand wheel is operated, the pressure-applying adjusting hand wheel is rotated to drive the adjusting screw rod to rotate in the locking nut, and then the pressure-applying sliding block is driven to slide in the station frame 2, so that the pressure-applying shaft is close to or far away from the cutting knife assembly 7, and the load is applied to the cutting knife assembly 7. The size of the applied load is adjusted by a pressurizing adjusting hand wheel.

As shown in fig. 12, as a preferred embodiment of the present invention, the integrated chip cutting, transferring and pasting machine further comprises an adjusting component 3 for adjusting the wrapping angle between the base paper and the vacuum drum component 5.

Specifically, the adjustment assembly 3 is located on one side of the vacuum drum assembly 5, also located within the station frame 2. The adjusting component 3 comprises an adjusting shaft, and the wrapping angle between the base paper and the vacuum drum component 5 can be adjusted through the adjusting shaft, so that the base paper and the chip are better combined in a transfer mode.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The utility model provides a chip cuts changes pastes all-in-one which characterized in that includes: the cutting device comprises a rack, and a vacuum drum assembly, a cutting knife assembly and a transmission piece which are arranged in the rack;

the cutting knife assembly and the vacuum drum assembly synchronously run through a transmission part, and the cutting knife assembly can be matched with the vacuum drum assembly to cut the chip material adsorbed on the vacuum drum assembly into chips for rotary pasting;

the vacuum drum component can adsorb chip materials conveyed by an external traction mechanism and can turn the cut chips to base paper.

2. The chip cutting, transferring and pasting all-in-one machine according to claim 1, wherein the cutting knife assembly comprises:

the cutting knife is provided with a sliding block which is arranged in the rack in a sliding manner;

the cutting knife is used for cutting the chip material adsorbed on the vacuum drum assembly into chips for rotary pasting in cooperation with the vacuum drum assembly; the cutting knife is rotatably arranged in the cutting knife mounting sliding block.

3. The integrated chip cutting, transferring and pasting machine according to claim 2, wherein the cutting knife comprises:

cutting the cutter arbor body; a cutter groove is formed in the cutting cutter shaft body;

the blade is arranged in the cutter groove;

and the knife pressing strip is arranged in the knife groove and used for fixing the blade.

4. The integrated chip cutting and transferring machine according to claim 1, wherein the vacuum drum assembly comprises:

the vacuum drum mounting sliding block is arranged in the rack in a sliding manner;

the vacuum drum is used for adsorbing the chip materials conveyed by the external traction mechanism and turning the cut chips to base paper; the vacuum drum is rotatably arranged in the vacuum drum mounting slider.

5. The integrated chip cutting and transferring machine according to claim 4, wherein the vacuum drum comprises:

a vacuum drum shaft body; the shaft body of the vacuum drum is provided with a groove;

the arc block is arranged in the groove;

and the air suction pipe is arranged in the vacuum drum shaft body and communicated with the vacuum drum shaft body.

6. The all-in-one machine for cutting, transferring and pasting chips as claimed in claim 1, further comprising a driving assembly for driving the vacuum drum assembly to operate.

7. The integrated chip cutting and transferring machine according to claim 1, further comprising a chip pressing assembly for pressing the chip material to be attached to the vacuum drum assembly, the chip pressing assembly comprising:

the adjusting rubber shaft is used for pressing the chip;

the adjusting shaft is connected with the rubber shaft;

and the material pressing adjusting hand wheel is used for adjusting the distance between the rubber shaft and the vacuum drum assembly through the adjusting shaft.

8. The integrated chip cutting and converting machine of claim 1, further comprising a pressure shaft assembly for applying a load to the cutter assembly, said pressure shaft assembly comprising:

the pressurizing slide block is arranged in the rack in a sliding manner;

and the pressurizing shaft is connected with the pressurizing sliding block and is positioned on one side of the cutting knife assembly.

9. The integrated chip cutting and transferring machine according to claim 8, further comprising a pressurization adjusting assembly for adjusting the load applied by the pressurization shaft assembly to the cutting blade assembly, wherein the pressurization adjusting assembly comprises:

locking the nut;

the adjusting screw is rotatably arranged in the locking nut; one end of the adjusting screw rod is connected with the pressurizing slide block;

and the pressurizing adjusting hand wheel is connected with one end of the adjusting screw rod, which is far away from the pressurizing sliding block.

10. The all-in-one machine for cutting, transferring and pasting chips as claimed in claim 1, further comprising an adjusting assembly for adjusting a wrapping angle between the base paper and the vacuum drum assembly.

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