CN210260443U - Synchronous feeding mechanism for clamping film and clamping core - Google Patents

Abstract

The utility model belongs to the technical field of certificate manufacture, in particular to a synchronous feeding mechanism for a card film and a card core, which comprises a material taking part and a driving part, wherein the material taking part comprises a card core material taking position and a card film material taking position; the driving part is used for synchronously driving the clamping core to take the material level and the clamping film to take the material level so that the clamping core takes the material level and the clamping film takes the material level to switch between the material taking position and the material loading position. The utility model discloses a card membrane and the synchronous feed mechanism of card core can realize the synchronous material loading of card core and card membrane, is favorable to improving the system card efficiency of system card machine.

Description

Synchronous feeding mechanism for clamping film and clamping core

Technical Field

The utility model belongs to the technical field of the certificate preparation, concretely relates to card membrane and synchronous feed mechanism of card core.

Background

The existing temporary identity card is manufactured mainly by traditional handwork, materials are printed, and then the materials are cut and covered manually, so that time and labor are wasted, mistakes are easily made, and certain economic loss is caused. In order to actively respond to the 'Internet + government affairs service' call of a state institute, enable data to run more and people to run less, a temporary identity card making process is integrated by relying on an interconnected and intercommunicated information system and an automatic control system, and a temporary identity card making machine takes charge. For example: the patent document with the publication number of CN108062582A discloses a temporary identity card making machine, which relates to a card making device and comprises a machine body, wherein the machine body is composed of a bottom shell and a turnover cover, a clamping groove is arranged at the front side of the bottom shell, a card outlet is arranged at the side edge of the bottom shell, a bottom plate is arranged in the bottom shell, and a card film placing mechanism, an X-axis moving mechanism, a Y-axis moving mechanism, a printer component, a plastic passing mechanism, a control component and an ultraviolet illumination component are arranged on the bottom plate; compared with the traditional manual making, the certificate making speed is greatly improved, and the certificate making time is finished within three minutes at one time; however, the printing film, the clamping core and the matching film can not be synchronously taken by the X-axis moving mechanism, so that the certificate making efficiency is affected.

SUMMERY OF THE UTILITY MODEL

Based on the above-mentioned not enough that exists among the prior art, the utility model provides a card membrane and synchronous feed mechanism of card core.

In order to achieve the purpose of the utility model, the utility model adopts the following technical scheme:

a synchronous feeding mechanism for a clamping film and a clamping core comprises a material taking part and a driving part, wherein the material taking part comprises a clamping core material taking position and a clamping film material taking position; the driving part is used for synchronously driving the clamping core to take the material level and the clamping film to take the material level so that the clamping core takes the material level and the clamping film takes the material level to switch between the material taking position and the material loading position.

Preferably, the material taking part further comprises a core clamping seat located below the core clamping and taking position, a film clamping seat located below the film clamping and taking position, and a first lifting mechanism and a second lifting mechanism which are respectively used for driving the core clamping seat and the film clamping seat to move up and down, wherein the core clamping seat and the film clamping seat are respectively used for placing the laminated core clamping and the laminated film clamping.

As a preferred scheme, the material taking part further comprises a limiting frame, and the limiting frame is provided with a clamping core limiting groove and a clamping film limiting groove; the clamping core seat and the clamping film seat are respectively matched with the clamping core limiting groove and the clamping film limiting groove in a lifting mode.

As a preferred scheme, a friction piece is arranged on one side of the film clamping seat, and the friction piece is positioned between the film clamping seat and the film clamping taking position; when the film clamping seat moves up and down, the friction piece can be in friction contact with the film clamping on the film clamping seat.

Preferably, the friction member is a brush or a sheet.

Preferably, the core clamping and material taking position comprises a first base and a plurality of first suction nozzles arranged below the first base, and the first suction nozzles are used for being connected with a vacuum pump; the film clamping and material taking position comprises a second base and a plurality of second suction nozzles arranged below the second base, and the second suction nozzles are used for being connected with a vacuum pump.

Preferably, the first suction nozzle comprises a first suction nozzle base fixed below the first base and a first suction nozzle telescopically matched with the first suction nozzle base; the second suction nozzle comprises a second suction nozzle seat fixed below the second base and a second suction head in telescopic fit with the second suction nozzle seat.

Preferably, the first suction nozzle base has a first hollow structure, a first elastic piece is arranged in the first hollow structure, and the first elastic piece is fixedly connected with the first suction head so that the first suction head is in telescopic fit with the first hollow structure; the second suction nozzle base is provided with a second hollow structure, a second elastic piece is arranged in the second hollow structure, and the second elastic piece is fixedly connected with the second suction nozzle so that the second suction nozzle is matched with the second hollow structure in a telescopic mode.

Preferably, the driving part comprises a driving motor, a guide rail and a linkage frame, and the linkage frame is fixedly connected with the first base and the second base; the linkage frame is connected with the guide rail in a sliding manner; the driving motor is used for driving the linkage frame to slide along the guide rail.

As a preferred scheme, limit switches are respectively arranged corresponding to the material taking position and the material loading position; correspondingly, a trigger switch matched with the limit switch is arranged on the linkage frame to control the operation of the driving motor.

Compared with the prior art, the utility model, beneficial effect is:

the utility model discloses a card membrane and the synchronous feed mechanism of card core can realize the synchronous material loading of card core and card membrane, is favorable to improving the system card efficiency of system card machine.

Drawings

Fig. 1 is a schematic structural view of a synchronous feeding mechanism for a card film and a card core according to a first embodiment of the present invention;

fig. 2 is a schematic structural diagram of another view angle of the synchronous feeding mechanism for the card film and the card core according to the first embodiment of the present invention;

fig. 3 is a schematic structural diagram of another view angle of the synchronous feeding mechanism for the card film and the card core according to the first embodiment of the present invention (excluding the structure of the laminated card core, the laminated card film, and the limiting frame);

fig. 4 is a schematic structural view of a limiting frame of a synchronous feeding mechanism for a card film and a card core according to a first embodiment of the present invention;

fig. 5 is a schematic structural diagram of another view angle of the feeding assembly of the synchronous feeding mechanism of the card film and the card core according to the first embodiment of the present invention.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention, the following description will explain embodiments of the present invention with reference to the accompanying drawings. It is obvious that the drawings in the following description are only examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be obtained from these drawings without inventive effort. In addition, directional terms referred to in the following examples, for example: up, down, left, right, front or rear, etc., are simply directions with reference to the drawings. Accordingly, the directional terminology is used for purposes of illustration and is in no way limiting.

The first embodiment is as follows:

the synchronous feeding mechanism for the card film and the card core is used for synchronously feeding the card core and the card film to a target feeding position;

specifically, as shown in fig. 1 to 3, the synchronous feeding mechanism includes a material taking part 20, a driving part 21, a limiting frame 23 and a mounting frame 24, and the material taking part 20 includes a core clamping and material taking position 201, a film clamping and material taking position 202, a core clamping seat 203, a film clamping seat 204, a first lifting mechanism 205 and a second lifting mechanism 206.

The core clamping and material taking position 201 comprises a first base 201a and four first suction nozzles 201b (the number of the first suction nozzles is not limited to four, and can be one, two, three or the like) arranged below the first base, wherein the four first suction nozzles 201b are uniformly distributed along the circumferential direction of the bottom surface of the first base; the first suction nozzle 201b is used for connecting with a vacuum pump so that the first suction nozzle 201b sucks the card core. The first suction nozzle 201b comprises a first nozzle seat 2011 fixed below the first base and a first suction head 2012 telescopically matched with the first nozzle seat; the specific manner of telescopic matching can be as follows: the first suction nozzle base is of a hollow columnar structure, an elastic piece (such as a spring, elastic rubber and the like) is fixed at the top of the hollow structure of the first suction nozzle base, and the first suction head is inserted into the hollow structure of the first suction nozzle base and is fixedly connected with the elastic piece, so that the first suction head can be in telescopic matching with the first suction nozzle base.

As shown in fig. 2-3, the film sticking and fetching position 202 includes a second base 202a and four second suction nozzles 202b (the number of the second suction nozzles is not limited to four, and may also be one, two, three, etc.) installed below the second base, and the four second suction nozzles 202b are evenly distributed along the circumferential direction of the bottom surface of the second base; the second suction nozzle 202b is used for connecting with a vacuum pump so that the second suction nozzle 202b sucks the card film. Wherein, the second suction nozzle 202b comprises a second suction nozzle seat 2021 fixed under the second base and a second suction head 2022 telescopically matched with the second suction nozzle seat; the specific manner of telescopic matching can be as follows: the second suction nozzle base is of a hollow columnar structure, an elastic piece (such as a spring, elastic rubber and the like) is fixed at the top of the hollow structure of the second suction nozzle base, and the second suction nozzle is inserted into the hollow structure of the second suction nozzle base and is fixedly connected with the elastic piece, so that the second suction nozzle can be in telescopic fit with the second suction nozzle base; i.e. the second suction nozzle has the same construction as the first suction nozzle.

The core print 203 is located below the core print position 201, and the top of the core print 203 is a horizontal plane for placing the stacked core prints. The film clamping seat 204 is positioned below the film clamping material taking position 202, and the top of the film clamping seat 204 is a horizontal plane and used for placing laminated film clamping. In addition, the mounting frame 24 is fixedly mounted at the bottom of the box body 10, the limiting frame 23 is fixedly mounted above the mounting frame 24, as shown in fig. 4, the limiting frame 23 is provided with a core limiting groove 230 and a film limiting groove 231 which are respectively matched with the core base 203 and the film base 204, the core base 203 and the film base 204 are matched with the core limiting groove 230 and the film limiting groove 231 in a lifting and descending manner, and the core limiting groove 230 and the film limiting groove 231 can limit the laminated cores on the core base 203 and the laminated films on the film base 204; moreover, due to the adhesion between the card cores or the card films, when the excess card cores or the card films sucked by the first suction nozzle or the second suction nozzle fall, the falling card cores or the falling card films can be automatically aligned to the laminated card cores or the laminated card films through the action of the card core limiting groove 230 and the card film limiting groove 231.

As shown in fig. 3, the lifting movement of the card core holder 203 is driven by a first lifting mechanism 205, and the first lifting mechanism 205 is fixedly mounted on the mounting frame 24. Specifically, the first lifting mechanism 205 is a screw motor, and accordingly, the bottom of the chuck base 203 has a threaded hole matched with a rotating shaft of the screw motor, so that the chuck base 203 can move up and down by the operation of the screw motor. In addition, the first lifting mechanism can also be a driving piece such as a telescopic cylinder. The first lifting mechanism 205 drives the chuck base 203 to ascend to a first suction head 2012 of the first suction nozzle, the first suction head 2012 sucks a chuck on the surface of the laminated chuck, and the first lifting mechanism 205 continues to drive the chuck base 203 to ascend, so that the first suction head 2012 retracts into a first suction nozzle base 2011; when the first limit switch 241 mounted on the mounting bracket 24 is triggered by the trigger switch 2031 mounted at the bottom of the cartridge housing 203, the first elevating mechanism 205 drives the cartridge housing 203 to descend. Wherein, the telescopic structure design of first suction nozzle is favorable to improving the adsorption affinity of first suction nozzle to the card core.

As shown in fig. 3, the raising and lowering movement of the film clamp holder 204 is driven by a second raising and lowering mechanism 206, and the second raising and lowering mechanism 206 is fixedly mounted on the mounting frame 24. Specifically, the second lifting mechanism 206 is a screw motor, and accordingly, the bottom of the film clamping seat 204 has a threaded hole matched with the rotating shaft of the screw motor, so that the film clamping seat 204 can be lifted by the operation of the screw motor. In addition, the second lifting mechanism can also be a driving piece such as a telescopic cylinder. The second lifting mechanism 206 drives the film clamping seat 204 to ascend to a second suction head 2022 of a second suction nozzle, the second suction head 2022 sucks one film clamping film on the surface of the laminated film clamping seat, and the second lifting mechanism 206 continues to drive the film clamping seat 204 to ascend, so that the second suction head 2022 retracts into the second suction nozzle seat 2021; when the second limit switch 242 mounted on the mounting bracket 24 is triggered by a trigger switch (not shown) mounted at the bottom of the chuck base 204, the second elevating mechanism 206 drives the chuck base 204 to descend. Wherein, the telescopic structure design of second suction nozzle is favorable to improving the adsorption affinity of second suction nozzle to the card membrane.

Because the card membranes of the laminated card membranes are adhered to each other, the second suction head 2022 is easy to suck a plurality of card membranes at a time; as shown in fig. 2, a friction member (not shown in the figure) is arranged on the right side of the film clamping seat 204, and the friction member is fixedly mounted on the limiting frame 23 through a mounting bracket c, so that the friction member is positioned between the film clamping seat 204 and the film clamping and taking position 202 in the vertical direction, namely between the laminated film clamping seat and the second suction head; when the film clamping base 204 moves up and down, the friction piece can be in friction contact with the film clamping on the film clamping base, so that the adhered film clamping is separated, and the second suction head is ensured to only suck one film clamping at a time. Wherein, the friction piece is made of materials such as brushes, sheets and the like.

The driving part 21 of this embodiment is configured to synchronously drive the core clamping material taking position 201 and the film clamping material taking position 202, so that the core clamping material taking position 201 and the film clamping material taking position 202 are switched between the material taking position and the material loading position; the material taking position is that a core clamping material taking position 201 and a film clamping material taking position 202 are respectively positioned above a core clamping seat 203 and a film clamping seat 204. Specifically, as shown in fig. 5, the driving portion 21 includes a driving motor 210, a guide rail 211, and a linkage bracket 212, and the linkage bracket 212 is fixedly connected to the first base 201a and the second base 202 a; the linkage frame 212 is slidably connected on the guide rail 211; the driving motor 210 is used for driving the linkage frame 212 to slide along the guide rail so as to synchronously drive the core clamping material taking position 201 and the film clamping material taking position 202, so that the core clamping material taking position 201 and the film clamping material taking position 202 are switched between a material taking position and a material loading position. Specifically, the driving motor drives and links through the structures of the driving wheel, the driving belt and the driven wheel, the linkage frame is fixedly connected with the driving belt, and the connection structure among the driving wheel, the driving belt and the driven wheel can refer to the prior art and is not described herein in detail. In addition, two limit switches are respectively arranged corresponding to the material taking position and the material loading position, and correspondingly, a trigger switch matched with the limit switches is arranged to control the operation of the driving motor (refer to the existing control mode), so that the movable position of the linkage frame is limited. When the core clamping material taking position 201 and the film clamping material taking position 202 are located at the feeding positions, the communication between the vacuum pump and the first suction nozzle and the communication between the vacuum pump and the second suction nozzle are cut off (the specific cutting off mode can be controlled by an electromagnetic valve), and the core clamping and the film clamping respectively fall onto target positions.

The utility model discloses card membrane and card core's synchronous feed mechanism's work flow as follows:

respectively placing the laminated card core and the laminated card film on the card core seat and the card film seat;

starting the first lifting mechanism and the second lifting mechanism, lifting the card core seat and the card film seat, and respectively sucking the card core and the card film by the first suction nozzle and the second suction nozzle;

and starting the driving motor until the material taking position of the clamping core and the material taking position of the clamping film are at the feeding position, cutting off the communication between the vacuum pump and the first suction nozzle and the communication between the vacuum pump and the second suction nozzle, and respectively dropping the clamping core and the clamping film to the target position to realize synchronous feeding.

The card membrane of this embodiment and the synchronous feed mechanism of card core are favorable to improving the system card efficiency of system card machine, realize waiting immediately and advisable.

Example two:

the synchronous feeding mechanism of the card film and the card core of the embodiment is different from the first embodiment in that:

at least one of the first suction nozzle and the second suction nozzle of the embodiment does not have the telescopic function described in the first embodiment, is a conventional suction nozzle, can also realize the material taking of the clamping core and the clamping film, and is suitable for application occasions with low requirements on adsorption force.

Other structures can refer to the first embodiment.

Example three:

the synchronous feeding mechanism of the card film and the card core of the embodiment is different from the first embodiment in that:

the drive division of this embodiment is replaced by two and drives actuating cylinder, and two drive actuating cylinder are used for driving first base and second base respectively, drive actuating cylinder synchronous drive first base and second base through two, also can realize the synchronous material loading of card core and card membrane, realize that synchronous feed mechanism's structure is diversified.

Other structures can refer to the first embodiment.

The foregoing has been a detailed description of the preferred embodiments and principles of the present invention, and it will be apparent to those skilled in the art that variations may be made in the specific embodiments based on the concepts of the present invention, and such variations are considered as within the scope of the present invention.

Claims (10)

1. The synchronous feeding mechanism for the clamping film and the clamping core is characterized by comprising a material taking part and a driving part, wherein the material taking part comprises a clamping core material taking position and a clamping film material taking position; the driving part is used for synchronously driving the clamping core to take the material level and the clamping film to take the material level so that the clamping core takes the material level and the clamping film takes the material level to switch between the material taking position and the material loading position.

2. The synchronous feeding mechanism of the card film and the card core as claimed in claim 1, wherein the material taking part further comprises a card core seat below the card core material taking position, a card film seat below the card film material taking position, and a first lifting mechanism and a second lifting mechanism for driving the card core seat and the card film seat to move up and down respectively, wherein the card core seat and the card film seat are used for placing the laminated card core and the laminated card film respectively.

3. The synchronous feeding mechanism for the clamping films and the clamping cores as claimed in claim 2, wherein the material taking part further comprises a limiting frame, and the limiting frame is provided with a clamping core limiting groove and a clamping film limiting groove; the clamping core seat and the clamping film seat are respectively matched with the clamping core limiting groove and the clamping film limiting groove in a lifting mode.

4. The synchronous feeding mechanism for the film clamping and the core clamping as claimed in claim 2, wherein a friction member is arranged on one side of the film clamping seat, and the friction member is positioned between the film clamping seat and the film clamping taking position; when the film clamping seat moves up and down, the friction piece can be in friction contact with the film clamping on the film clamping seat.

5. The synchronous feeding mechanism of claim 4, wherein the friction member is a brush or a sheet.

6. The synchronous feeding mechanism of the card film and the card core as claimed in any one of claims 1 to 5, wherein the card core material taking position comprises a first base and a plurality of first suction nozzles arranged below the first base, the first suction nozzles are used for being connected with a vacuum pump; the film clamping and material taking position comprises a second base and a plurality of second suction nozzles arranged below the second base, and the second suction nozzles are used for being connected with a vacuum pump.

7. The synchronous loading mechanism of claim 6, wherein the first suction nozzle comprises a first suction nozzle base fixed below the first base and a first suction nozzle telescopically engaged with the first suction nozzle base; the second suction nozzle comprises a second suction nozzle seat fixed below the second base and a second suction head in telescopic fit with the second suction nozzle seat.

8. The synchronous loading mechanism for the card membrane and the card core as claimed in claim 7, wherein the first suction nozzle base has a first hollow structure, a first elastic member is arranged in the first hollow structure, and the first elastic member is fixedly connected with the first suction head so that the first suction head is telescopically matched with the first hollow structure; the second suction nozzle base is provided with a second hollow structure, a second elastic piece is arranged in the second hollow structure, and the second elastic piece is fixedly connected with the second suction nozzle so that the second suction nozzle is matched with the second hollow structure in a telescopic mode.

9. The synchronous feeding mechanism for the card film and the card core as claimed in claim 6, wherein the driving part comprises a driving motor, a guide rail and a linkage frame, and the linkage frame is fixedly connected with the first base and the second base; the linkage frame is connected with the guide rail in a sliding manner; the driving motor is used for driving the linkage frame to slide along the guide rail.

10. The synchronous feeding mechanism of the card film and the card core as claimed in claim 9, wherein limit switches are respectively provided corresponding to the material taking position and the material feeding position; correspondingly, a trigger switch matched with the limit switch is arranged on the linkage frame to control the operation of the driving motor.

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