CN215473910U - Face tablet manufacture equipment - Google Patents

Abstract

The application discloses face tablet manufacture equipment, this face tablet manufacture equipment includes that the device of proving, turning device, printer and transfer device. The evidence providing device comprises a conveying mechanism, a double-sheet detection mechanism, a double-sheet separation mechanism and a transfer bearing mechanism. The conveying mechanism is used for conveying the certificate, the re-opening detection mechanism and the re-opening separation mechanism are located on a movement path of the certificate, the re-opening detection mechanism is used for detecting whether the certificate is re-opened or not, and the re-opening separation mechanism is used for separating the re-opened certificate and driving the single certificate to move to the transfer bearing mechanism. The turnover device is used for turning over the certificate, the printer is used for printing information on the certificate, and the transfer device is used for transferring the certificate among the transfer bearing mechanism, the turnover device and the printer. Because the double-sheet detection mechanism and the double-sheet separation mechanism are added, whether the certificate is double-sheet or not is detected by the double-sheet detection mechanism, and the double-sheet certificate is separated by the double-sheet separation mechanism, so that the problem of double-sheet certificate is solved.

Description

Face tablet manufacture equipment

Technical Field

The application relates to the technical field of card manufacture, in particular to card manufacture equipment.

Background

As the number of automobiles continues to increase, many car authorities or government agencies opt to use self-service temporary license plates in the form of certificates to provide drivers with temporary license plates in order to better serve the drivers. However, the existing card-registering manufacturing equipment often has the problem of certificate re-registration, for example, when a first certificate is conveyed, a second certificate below the first certificate is adhered to the lower surface of the first certificate, so that various information mismatch problems occur. Because the temporary license plate is printed in each region and only can be suitable for a certain region, and the density and the style of the used paper are different, the parameters (such as the suction force of the sucker for sucking the certificate) for conveying the certificate by the temporary license plate manufacturing equipment cannot be suitable for all regions of the country, and the probability of the problem of overlapping is increased due to the improper equipment parameters, so that improvement is needed.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims to provide a card temporary manufacturing device capable of solving the problem of certificate re-opening.

In a first aspect, an embodiment provides a card face manufacturing apparatus comprising:

the certificate providing device comprises a conveying mechanism, a double-sheet detection mechanism, a double-sheet separation mechanism and a transfer bearing mechanism; the conveying mechanism is used for conveying the certificate; the double-sheet detection mechanism and the double-sheet separation mechanism are positioned on the movement path of the certificate, the double-sheet detection mechanism is used for detecting whether the certificate is double-sheet or not, the double-sheet separation mechanism is used for separating the double-sheet certificate and driving the single certificate to move to the transfer bearing mechanism;

the overturning device is used for overturning the certificate;

a printer for printing information on a certificate;

and the transfer device is used for transferring the certificate among the transfer bearing mechanism, the turnover device and the printer.

In one embodiment, the said heavy sheet separation mechanism includes the first separation assembly and second separation assembly, the said certificate has first side and second side that is relatively disposed in its lamination direction, the said first separation assembly is used for exerting the first driving force to the certificate from the first side of the said certificate, the said second separation assembly is used for exerting the second driving force to the said certificate from the second side of the said certificate; when the certificate is re-tensioned, the first driving force and the second driving force are opposite in direction so as to drive the re-tensioned certificate to be separated from each other.

In one embodiment, the first separating assembly includes a first abutting member and a first driving member, the first driving member is located at a first side of the certificate, the first abutting member is located at a second side of the certificate, the first abutting member is used for abutting the certificate to the first driving member, and a friction force between the first driving member and the certificate is the first driving force;

the second separation assembly comprises a second abutting piece and a second driving piece, the second driving piece is located on the second side of the certificate, the second abutting piece is located on the first side of the certificate, the second abutting piece is used for abutting the certificate to the second driving piece, and the friction force between the second driving piece and the certificate is the second driving force.

In one embodiment, the conveying mechanism includes a conveying driving assembly and a conveying driving wheel, the conveying driving wheel is used for contacting with the certificate, and the conveying driving assembly is used for driving the conveying driving wheel to rotate so as to drive the certificate to move.

In one embodiment, the transport drive wheel is a cam structure for intermittently engaging the credential as it is driven in motion.

In one embodiment, the transfer device comprises a first transfer component, a second transfer component and an extraction component, wherein the extraction component is used for extracting and releasing the certificate, the first transfer component is connected with the extraction component, and the first transfer component is used for driving the extraction component to move along a first axis; the second transfer assembly is connected with the first transfer assembly, the second transfer assembly is used for driving the first transfer assembly and the extraction assembly to move along a second axis, and the first axis is perpendicular to the second axis.

In one embodiment, the extraction assembly comprises an extraction connection plate and a suction cup member for absorbing and releasing the certificate, the suction cup member being connected to the extraction connection plate;

the first transfer assembly comprises a first movable piece, a transfer screw rod, a first transfer motor and a transfer connecting plate; the transfer screw rod is parallel to the first axis and is arranged in a rotating mode, the first movable piece is in threaded connection with the transfer screw rod, and the extraction connecting plate is connected with the first movable piece; the first transfer motor is arranged on the transfer connecting plate, and an output shaft of the first transfer motor is connected with the transfer screw rod;

the second transfer component comprises a second movable piece, a guide rod, a second transfer motor, a transfer driving belt wheel, a transfer driven belt wheel and a transfer transmission belt; the guide rod is parallel to the second axis, the second movable piece is movably sleeved with the guide rod, and the transfer connecting plate is connected with the second movable piece; the transfer driving belt wheel and the transfer driven belt wheel are respectively positioned at two ends of the guide rod, an output shaft of the second transfer motor is connected with the transfer driving belt wheel, the transfer driving belt wheel is connected with the transfer driven belt wheel, and the transfer connecting plate is connected with the transfer driving belt.

In one embodiment, the overturning device comprises an overturning seat, an overturning rotating shaft, a clamping structure, an overturning motor, an overturning driving belt wheel, an overturning driven belt wheel and an overturning transmission belt; the overturning rotating shaft is rotatably connected with the overturning seat, the overturning rotating shaft is connected with the clamping structure, and the clamping structure is used for clamping the certificate; the output shaft of the turnover motor is connected with the turnover driving belt wheel, the turnover driven belt wheel is connected with the turnover rotating shaft, and the turnover driving belt wheel is connected with the turnover driven belt wheel through the turnover driving belt.

In one embodiment, the device further comprises a supporting device, wherein the supporting device comprises a fixed seat, a supporting piece and a supporting motor, the supporting piece is rotatably connected with the fixed seat, the supporting piece is located between the printer and the clamping structure, and the supporting piece is used for supporting the certificate; the output shaft of the bearing motor is connected with the bearing piece, and the bearing motor is used for driving the bearing piece to rotate relative to the fixed seat.

In one embodiment, the certificate transfer system further comprises a code scanning device, wherein a code scanning ray sent by the code scanning device passes through a movement path of the certificate when the certificate moves between the transfer bearing mechanism and the printer, and the code scanning device is used for scanning an information code on the certificate.

According to the card temporary manufacturing equipment of the embodiment, the card temporary manufacturing equipment comprises a certificate device, a turnover device, a printer and a transfer device. The evidence providing device comprises a conveying mechanism, a double-sheet detection mechanism, a double-sheet separation mechanism and a transfer bearing mechanism. The conveying mechanism is used for conveying the certificate, the re-opening detection mechanism and the re-opening separation mechanism are located on a movement path of the certificate, the re-opening detection mechanism is used for detecting whether the certificate is re-opened or not, and the re-opening separation mechanism is used for separating the re-opened certificate and driving the single certificate to move to the transfer bearing mechanism. The turnover device is used for turning over the certificate, the printer is used for printing information on the certificate, and the transfer device is used for transferring the certificate among the transfer bearing mechanism, the turnover device and the printer. Because the double-sheet detection mechanism and the double-sheet separation mechanism are added, whether the certificate is double-sheet or not is detected by the double-sheet detection mechanism, and the double-sheet certificate is separated by the double-sheet separation mechanism, so that the problem of double-sheet certificate is solved.

Drawings

FIG. 1 is a schematic diagram of a card face manufacturing apparatus according to an embodiment of the present application;

FIG. 2 is a schematic diagram of an internal structure of a perspective downstream card manufacturing apparatus according to an embodiment of the present application;

FIG. 3 is a schematic diagram of an internal structure of a downstream card manufacturing apparatus from another perspective in accordance with an embodiment of the present application;

FIG. 4 is a schematic diagram of a perspective lower evidence obtaining apparatus according to an embodiment of the present application;

FIG. 5 is a schematic view of another perspective lower evidence obtaining apparatus according to an embodiment of the present application;

FIG. 6 is a schematic diagram of the internal structure of a certification device in one embodiment of the present application;

FIG. 7 is a schematic diagram of a third perspective lower evidence obtaining apparatus according to an embodiment of the present application;

FIG. 8 is a schematic diagram of a fourth perspective lower evidence obtaining apparatus according to an embodiment of the present application;

reference numerals: 1000. a certification device;

1100. a conveying mechanism;

1110. a transport drive assembly; 1111. a conveying motor; 1112. a conveying driving belt wheel; 1113. a conveying driven pulley; 1114. a conveying belt; 1115. a conveying rotating shaft; 1120. a conveying driving wheel;

1200. a double-sheet detection mechanism;

1300. a overlapped sheet separating mechanism;

1310. a first separation assembly; 1311. a first smooth wheel; 1312. a first drive wheel; 1320. a second separation assembly; 1321. a second smooth wheel; 1322. a second drive wheel; 1330. a first split drive assembly; 1331. a first separation motor; 1332. a first split driving pulley; 1333. a first disconnect driven pulley; 1334. a first separation belt; 1335. a first separating spindle; 1340. a second separation drive assembly; 1341. a second separation motor; 1342. a second split driving pulley; 1343. a second disconnect driven pulley; 1344. a second separation belt; 1345. a second separating shaft; 1350. separating the bearing plate;

1400. a transfer bearing mechanism;

1500. a storage device;

1510. a storage box; 1520. a lifting assembly; 1521. a lifting plate; 1522. lifting the screw rod; 1523. a hoisting motor; 1524. lifting the driving belt pulley; 1525. lifting the driven pulley; 1526. lifting the transmission belt;

1600. a certificate mounting rack;

1700. a height sensor;

2000. a turning device;

2100. a turning seat; 2200. turning over the rotating shaft; 2300. a clamping structure; 2400. turning over a motor; 2500. turning over the driving belt wheel; 2600. turning over the driven belt wheel; 2700. turning over the transmission belt;

3000. a printer;

4000. a transfer device;

4100. a first relay assembly; 4110. a first movable member; 4120. a first transfer motor; 4130. a transfer connecting plate; 4200. a second relay assembly; 4210. a second movable member; 4220. a guide bar; 4230. a second transfer motor; 4240. a transfer driving belt wheel; 4250. transferring the driven belt wheel; 4260. transferring a transmission belt; 4300. an extraction component; 4310. extracting a connecting plate; 4320. a chuck member;

5000. a supporting device;

5100. a fixed seat; 5200. a support member; 5300. supporting the motor;

6000. a code scanning device;

7000. an output device;

7100. outputting the bearing plate; 7200. an output drive assembly;

8000. a housing.

Detailed Description

The present invention will be described in further detail with reference to the following detailed description and accompanying drawings. Wherein like elements in different embodiments are numbered with like associated elements. In the following description, numerous details are set forth in order to provide a better understanding of the present application. However, those skilled in the art will readily recognize that some of the features may be omitted or replaced with other elements, materials, methods in different instances. In some instances, certain operations related to the present application have not been shown or described in detail in order to avoid obscuring the core of the present application from excessive description, and it is not necessary for those skilled in the art to describe these operations in detail, so that they may be fully understood from the description in the specification and the general knowledge in the art.

Furthermore, the features, operations, or characteristics described in the specification may be combined in any suitable manner to form various embodiments. Also, the various steps or actions in the method descriptions may be transposed or transposed in order, as will be apparent to one of ordinary skill in the art. Thus, the various sequences in the specification and drawings are for the purpose of describing certain embodiments only and are not intended to imply a required sequence unless otherwise indicated where such sequence must be followed.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning. The term "connected" and "coupled" when used in this application, unless otherwise indicated, includes both direct and indirect connections (couplings).

The embodiment provides a card face manufacturing device.

Referring to fig. 1-8, the card manufacturing apparatus includes a verification device 1000, a flipping device 2000, a printer 3000, and a transfer device 4000.

The certification device 1000 includes a conveying mechanism 1100, a double-sheet detection mechanism 1200, a double-sheet separation mechanism 1300, and a transfer loading mechanism 1400. The conveying mechanism 1100 is used for conveying certificates, the double-sheet detection mechanism 1200 and the double-sheet separation mechanism 1300 are located on a movement path of the certificates, the double-sheet detection mechanism 1200 is used for detecting whether the certificates are double-sheet or not, and the double-sheet separation mechanism 1300 is used for separating the double-sheet certificates and driving the single certificates to move to the transfer bearing mechanism 1400. The turning device 2000 is used for turning over the certificate, the printer 3000 is used for printing information on the certificate, and the transfer device 4000 is used for transferring the certificate among the transfer bearer 1400, the turning device 2000 and the printer 3000.

Because the double-sheet detection mechanism 1200 and the double-sheet separation mechanism 1300 are added, whether the certificate is double-sheet or not is detected by the double-sheet detection mechanism 1200, and the double-sheet certificate is separated by the double-sheet separation mechanism 1300, so that the problem of double-sheet certificate is solved. Specifically, the double-sheet detection mechanism 1200 may be the double-sheet detection mechanism 1200 based on the infrared principle or the double-sheet detection mechanism 1200 based on the ultrasonic principle.

Referring to fig. 4-8, in one embodiment, a sheetpile separation mechanism 1300 includes a first separation assembly 1310 and a second separation assembly 1320, the certificate having first and second oppositely disposed sides in a stacking direction, the first separation assembly 1310 for applying a first driving force to the certificate from the first side of the certificate, and the second separation assembly 1320 for applying a second driving force to the certificate from the second side of the certificate. When the certificate is re-tensioned, the first driving force and the second driving force are opposite in direction so as to drive the re-tensioned certificate to be separated from each other.

When the double-sheet detection mechanism 1200 detects the double-sheet of the certificate, a first driving force in a first direction is applied to the certificate from a first side of the certificate by the first separation assembly 1310, and a second driving force in a second direction is applied to the certificate from a second side of the certificate by the second separation assembly 1320, wherein the first direction is opposite to the second direction, so that the double-sheet certificates stacked together are separated. Specifically, in this embodiment, when the certificate is placed in a horizontal state, the stacking direction of the certificates is a vertical direction, a first side of the certificate refers to a lower side of the certificate, and a second side of the certificate refers to an upper side of the certificate. Of course, in other embodiments, the certificate may be transported at other suitable angles to the horizontal plane, for example, 60 ° or 45 °, and the stacking direction of the certificate may be changed to a direction perpendicular to the angle.

Referring to fig. 4-8, in an embodiment, when the certificate is a single certificate, the first driving force and the second driving force are in the same direction to drive the certificate to move to the relay bearing mechanism 1400.

When the double-sheet detection mechanism 1200 detects that the certificate is a single certificate, the first separation assembly 1310 and the second assembly drive the certificate to the same direction, so that the certificate moves to the transfer bearing mechanism 1400. Since the certificate on the transfer bearing mechanism 1400 is always a single certificate, the suction parameter of the suction cup 4320 of the transfer device 4000 can be maximized to ensure that the certificate can be sucked. The problem that in the conventional scheme, when the suction force of the suction disc piece 4320 is large, a single certificate is sucked through, so that a plurality of certificates are sucked simultaneously is solved.

Referring to fig. 4-8, in an embodiment, the first separating assembly 1310 includes a first urging member and a first driving member, the first driving member is located on a first side of the certificate, the first urging member is located on a second side of the certificate, the first urging member is configured to urge the certificate against the first driving member, and a friction between the first driving member and the certificate is a first driving force. The second separating assembly 1320 includes a second abutting member and a second driving member, the second driving member is located at the second side of the certificate, the second abutting member is located at the first side of the certificate, the second abutting member is used for abutting the certificate to the second driving member, and a friction force between the second driving member and the certificate is a second driving force.

The certificate is abutted to the first driving piece through the first abutting piece, the certificate is abutted to the second driving piece through the second abutting piece, and the certificate is driven to move and separate through friction force between the first driving piece and the certificate and between the second driving piece and the certificate.

Referring to fig. 4-8, in one embodiment, the first fastening member is configured as a first idler 1311, the first driving member is configured as a first driving wheel 1312, the second fastening member is configured as a second idler 1321, and the second driving member is configured as a second driving wheel 1322.

Referring to fig. 6, when the re-opened certificate is required to be separated, the first driving wheel 1312 is driven to rotate counterclockwise in fig. 6, so as to drive the lowermost certificate of the stacked certificates to move to the side of the storage box 1510 and drop into the storage box 1510. When a plurality of certificates are stacked, the operation is repeated until the double-tension detection mechanism 1200 detects that a certificate is a single certificate, the first driving wheel 1312 is driven to rotate clockwise in fig. 6, and the second driving wheel 1322 is driven to move counterclockwise in fig. 6, so that the single certificate is driven to move to the transfer bearing mechanism 1400.

In other embodiments, the first abutting member and the second abutting member may be other abutting structures, for example, block structures with smooth surfaces, and the first driving member and the second driving member may also be other driving structures using friction force, for example, a belt structure.

Referring to fig. 4-8, in one embodiment, the multifold separation mechanism 1300 further includes a first separation driving assembly 1330, a second separation driving assembly 1340, and a separation carrier 1350. The split carrier plate 1350 is used to hold the certificate, the first split drive assembly 1330 is used to rotate the first drive wheel 1312, and the second split drive assembly 1340 is used to rotate the second drive wheel 1322.

Referring to fig. 4-8, in one embodiment, first separation drive assembly 1330 includes a first separation motor 1331, a first separation drive pulley 1332, a first separation driven pulley 1333, a first separation drive belt 1334, and a first separation shaft 1335. The first separating rotating shaft 1335 is rotatably connected with the proof mounting frame 1600, and the first driving wheel 1312 is connected with the first separating rotating shaft 1335. The first separation driven pulley 1333 is connected to the first separation rotating shaft 1335, the first separation driving pulley 1332 is connected to an output shaft of the first separation motor 1331, and the first separation driving pulley 1334 connects the first separation driving pulley 1332 to the first separation driven pulley 1333.

When the first driving wheel 1312 needs to be driven to rotate, the first separation driving pulley 1332 is driven to rotate by the first separation motor 1331, so as to drive the first separation driven pulley 1333 to rotate, the first separation rotating shaft 1335 is driven to rotate by the first separation driven pulley 1333, and the first separation rotating shaft 1335 drives the first driving wheel 1312 to rotate.

Referring to fig. 4-8, the second separation drive assembly 1340 includes a second separation motor 1341, a second separation drive pulley 1342, a second separation driven pulley 1343, a second separation drive belt 1344, and a second separation rotation shaft 1345. The second separation rotating shaft 1345 is rotatably connected to the certificate mounting bracket 1600, and the second driving wheel 1322 is connected to the second separation rotating shaft 1345. The second separation driven pulley 1343 is connected to a second separation rotating shaft 1345, the second separation driving pulley 1342 is connected to an output shaft of a second separation motor 1341, and the second separation driving pulley 1342 is connected to the second separation driven pulley by a second separation belt 1344.

When the second driving wheel 1322 needs to be driven to rotate, the second separation driving pulley 1342 is driven to rotate by the second separation motor 1341, so as to drive the second separation driven pulley 1343 to rotate, the second separation rotating shaft 1345 is driven to rotate by the second separation driven pulley 1343, and the second separation rotating shaft 1345 drives the second driving wheel 1322 to rotate.

Referring to fig. 1-3, in an embodiment, the card face manufacturing apparatus further includes an output device 7000, where the output device 7000 includes an output carrier plate 7100 and an output driver 7200, the output carrier plate 7100 is used for carrying the certificate, and the output driver 7200 is used for driving the certificate on the output carrier plate 7100 to outside the card face manufacturing apparatus.

Referring to fig. 1-3, in one embodiment, the face card manufacturing apparatus further includes a housing 8000, and the certification device 1000, the turning device 2000, the printer 3000, the transfer device 4000, and the output device 7000 are all disposed within the housing 8000, and one side of the housing 8000 has an opening, and the certification device 1000 and the output device 7000 are disposed adjacent to the opening of the housing 8000.

Referring to fig. 1-3, in one embodiment, the transport mechanism 1100 includes a transport drive assembly 1110 and a transport drive wheel 1120, the transport drive wheel 1120 is configured to contact the credential, and the transport drive assembly 1110 is configured to drive the transport drive wheel 1120 to rotate to move the credential. The driving of the certificate is achieved by the friction between the transport drive wheel 1120 and the certificate.

Referring to fig. 4-8, in one embodiment, the transport drive wheel 1120 is a cam structure for intermittently engaging the certificate as it is driven in motion.

Because the transport drive wheel 1120 is a cam, the transport drive wheel 1120 intermittently contacts the certificate when rotating, achieving an effect similar to "knocking" the certificate, thereby driving the certificate to vibrate. The vibrations through the certificates may separate the certificates of the double note from each other, thereby reducing the number of double notes that need to be separated by the double note separation mechanism 1300.

Referring to fig. 4-8, in one embodiment, the conveying driving assembly 1110 includes a conveying motor 1111, a conveying driving pulley 1112, a conveying driven pulley 1113, a conveying belt 1114 and a conveying shaft 1115. The certificate of the staff device 1000 further comprises a certificate of the staff mounting rack 1600, the conveying rotating shaft 1115 is rotatably connected with the certificate of the staff mounting rack 1600, and the conveying driving wheel 1120 is connected with the conveying rotating shaft 1115. An output shaft of the conveyance motor 1111 is connected to a conveyance driving pulley 1112, a conveyance driven pulley 1113 is connected to a conveyance rotation shaft 1115, and a conveyance transmission belt 1114 connects the conveyance driving pulley 1112 and the conveyance driven pulley 1113.

When the certificate needs to be conveyed, the conveying motor 1111 drives the conveying driving pulley 1112 to rotate, so as to drive the conveying driven pulley 1113 to rotate, the conveying driven pulley 1113 drives the conveying rotating shaft 1115 to rotate, the conveying rotating shaft 1115 drives the conveying driving wheel 1120 to rotate, and finally the certificate is driven to move by the conveying driving wheel 1120.

Referring to fig. 4-8, in one embodiment, the certification device 1000 further includes a storage device 1500, the storage device 1500 includes a storage cassette 1510 and a lifting assembly 1520, the storage cassette 1510 is configured to store the certificates, the lifting assembly 1520 is configured to move the certificates in the storage cassette 1510 closer to the transport mechanism 1100 to bring the certificates in the storage cassette 1510 into contact with the transport mechanism 1100, and to move the certificates in the storage cassette 1510 away from the transport mechanism 1100 to bring the certificates in the storage cassette 1510 out of contact with the transport mechanism 1100.

Batch storage of the certificates is realized through the storage box 1510, so that the time interval for replenishing the certificates for workers is longer, and the labor intensity of the workers is reduced. The continuous supply of credentials to the transport mechanism 1100 is accomplished by the lift assembly 1520 providing credentials within the storage cartridge 1510 to the transport mechanism 1100.

Referring to fig. 4-8, in one embodiment, the storage case 1510 is a drawer structure, and the licensing device 1000 further comprises a licensing mounting frame 1600, wherein the storage case 1510 is movably connected to the licensing mounting frame 1600. The storage case 1510 is capable of moving closer to the mounting block 1600 to embed the mounting block 1600 and away from the mounting block 1600 to detach the mounting block 1600.

When the certificate in the storage box 1510 needs to be supplemented, a worker can pull the storage box 1510 in the direction away from the certificate installation frame 1600, so that the certificate is conveniently supplemented in the storage box 1510, and after the certificate is supplemented, the storage box 1510 is pushed in the direction close to the certificate installation frame 1600 so as to be embedded into the certificate installation frame 1600.

Referring to fig. 4-8, in one embodiment, the lifting assembly 1520 includes a lifting plate 1521, a lifting screw 1522, a lifting motor 1523, a lifting drive pulley 1524, a lifting driven pulley 1525 and a lifting belt 1526, wherein at least a portion of the lifting plate 1521 is disposed within the storage box 1510 for supporting the credential within the storage box 1510. The lift screw 1522 is perpendicular to the lift plate 1521, the lift screw 1522 is rotatably disposed, and one side of the lift plate 1521 is in threaded connection with the lift screw 1522. The lifting driving pulley 1524 is connected with an output shaft of a lifting motor 1523, the lifting driven pulley 1525 is connected with the lifting screw rod 1522, and the lifting transmission belt 1526 connects the lifting driving pulley 1524 with the lifting driven pulley 1525.

When the certificate is required to be provided for the conveying mechanism 1100, the lifting motor 1523 drives the lifting driving belt wheel 1524 to rotate, so that the lifting driven belt wheel 1525 is driven to rotate, the lifting driven belt wheel 1525 drives the lifting screw rod 1522 to rotate, the lifting plate 1521 is driven to move through the lifting screw rod 1522, and finally the certificate is driven to move along the extending direction of the lifting screw rod 1522 through the lifting plate 1521.

Referring to fig. 5, in one embodiment, the certification device 1000 further includes a height sensor 1700, wherein the height sensor 1700 is used for sensing the height of the certificate.

Referring to fig. 1-3, in an embodiment, the transit apparatus 4000 includes a first transit component 4100, a second transit component 4200, and an extracting component 4300, the extracting component 4300 is configured to extract and release the certificate, the first transit component 4100 is connected to the extracting component 4300, and the first transit component 4100 is configured to drive the extracting component 4300 to move along a first axis. The second relay assembly 4200 is connected to the first relay assembly 4100, and the second relay assembly 4200 is configured to drive the first relay assembly 4100 and the picking assembly 4300 to move along a second axis, where the first axis is perpendicular to the second axis. Specifically, in this embodiment, the extending direction of the first axis is a vertical direction, and the extending direction of the second axis is a horizontal direction. In other embodiments, the first axis and the second axis may extend in other directions perpendicular to each other in space, for example, the first axis extends at an angle of 15 ° to the horizontal plane, and the second axis is perpendicular to the first axis.

Referring to fig. 1-3, in one embodiment, the extraction assembly 4300 includes an extraction connection plate 4310 and a suction cup member 4320, the suction cup member 4320 is used to adsorb and release certificates, and the suction cup member 4320 is connected to the extraction connection plate 4310. The first relay assembly 4100 includes a first moving member 4110, a relay screw rod, a first relay motor 4120 and a relay connection plate 4130. The transfer lead screw is parallel to the first axis, the transfer lead screw is rotatably disposed, the first moving member 4110 is in threaded connection with the transfer lead screw, and the extraction connecting plate 4310 is connected with the first moving member 4110. The first relay motor 4120 is provided on the relay connection plate 4130, and an output shaft of the first relay motor 4120 is connected with the relay screw rod.

Referring to fig. 1 to 3, the second intermediate transfer assembly 4200 includes a second mover 4210, a guide rod 4220, a second intermediate motor 4230, an intermediate driving pulley 4240, an intermediate driven pulley 4250, and an intermediate transfer belt 4260. The guide rod 4220 is parallel to the second axis, the second movable piece 4210 is movably sleeved with the guide rod 4220, and the transfer connecting plate 4130 is connected with the second movable piece 4210. The relay driving pulley 4240 and the relay driven pulley 4250 are respectively located at both ends of the guide rod 4220, an output shaft of the second relay motor 4230 is connected with the relay driving pulley 4240, a relay transmission belt 4260 connects the relay driving pulley 4240 with the relay driven pulley 4250, and a relay connection plate 4130 is connected with the relay transmission belt 4260.

Referring to fig. 1-3, during transferring certificates, the first transfer motor 4120 drives the transfer screw to rotate, the transfer screw drives the first movable member 4110 to move, and the first movable member 4110 drives the pick-up assembly 4300 to move in a vertical direction. The second relay motor 4230 drives the relay driving pulley 4240 to rotate, so as to drive the relay transmission belt 4260 and the relay driven pulley 4250 to move, the relay transmission belt 4260 drives the relay connection plate 4130 and the second movable member 4210 to move along the extending direction of the guide rod 4220, and the relay connection plate 4130 drives the first relay assembly 4100 and the extraction assembly 4300 to move in the horizontal direction.

It should be noted that, in this embodiment, the transfer device 4000 realizes the transfer of the certificate among the transfer supporting mechanism 1400, the turning device 2000 and the printer 3000 through one conveying device. In other embodiments, this function may be achieved by multiple sets of conveying devices, for example, the transfer between the transfer carriage 1400 and the printer 3000 is achieved by one conveying device, and the transfer between the printer 3000 and the turnover device 2000 is achieved by another conveying device.

Referring to fig. 1-3, in one embodiment, the flipping unit 2000 includes a flipping base 2100, a flipping rotation shaft 2200, a clamping structure 2300, a flipping motor 2400, a flipping driving pulley 2500, a flipping driven pulley 2600, and a flipping driving belt 2700. The turning rotating shaft 2200 is rotatably connected with the turning base 2100, the turning rotating shaft 2200 is connected with the clamping structure 2300, and the clamping structure 2300 is used for clamping the certificate. The output shaft of upset motor 2400 is connected with upset driving pulley 2500, and upset driven pulley 2600 is connected with upset pivot 2200, and upset drive belt 2700 will overturn driving pulley 2500 and upset driven pulley 2600 is connected.

When the certificate is required to be turned over, the certificate is clamped through the clamping structure 2300, the overturning driving belt wheel 2500 is driven to rotate through the overturning motor 2400, the overturning driven belt wheel 2600 is driven to rotate, the overturning rotating shaft 2200 is driven to rotate through the overturning driven belt wheel 2600, the clamping structure 2300 is driven to rotate 180 degrees through the overturning rotating shaft 2200, and the turning over of the certificate in the clamping structure 2300 is achieved.

Referring to fig. 1-3, in an embodiment, the card face manufacturing apparatus further includes a supporting device 5000, the supporting device 5000 includes a fixing base 5100, a supporting member 5200 and a supporting motor 5300, the supporting member 5200 is rotatably connected to the fixing base 5100, the supporting member 5200 is located between the printer 3000 and the clamping structure 2300, and the supporting member 5200 is used for supporting the certificate. The output shaft of bearing motor 5300 is connected with bearing piece 5200, and bearing motor 5300 is used for driving bearing piece 5200 and rotates relatively fixing base 5100.

When the support 5200 is used to support a certificate, the support 5300 is driven by the support motor 5300 to rotate the support 5200 in a direction close to the flipping mechanism 2000, so that the support 5200 can support the certificate output from the printer 3000. When the turning device 2000 needs to turn over the certificate, the supporting member 5200 is driven by the supporting motor 5300 to rotate in a direction away from the turning device 2000, so that the supporting member 5200 prevents the holding structure 2300 of the turning device 2000 from moving.

Referring to fig. 1-3, in an embodiment, the card face manufacturing apparatus further includes a code scanning device 6000, the code scanning device 6000 is configured to scan the information code on the certificate, and the code scanning device 6000 is configured to scan the code scanning beam emitted by the code scanning device 6000 through a moving path of the certificate when the certificate moves between the transfer bearer 1400 and the printer 3000. The information code on the certificate is read by the code scanning device 6000 to judge the authenticity of the certificate.

In another aspect, referring to fig. 1-8, the present embodiment provides an overview of the operation of the card face manufacturing apparatus.

When facing the tablet preparation, at first promote driving pulley 1524 through the drive of promotion motor 1523 and rotate, and then drive and promote driven pulley 1525 and rotate, promote driven pulley 1525 and drive hoist lead screw 1522 and rotate, drive through hoist lead screw 1522 and promote the motion of board 1521, finally drive the certificate through promoting board 1521 and be close to conveying mechanism 1100.

When the certificate contacts with the conveying driving wheel 1120 of the conveying mechanism 1100, the conveying motor 1111 drives the conveying driving pulley 1112 to rotate, and further drives the conveying driven pulley 1113 to rotate, the conveying driven pulley 1113 drives the conveying rotating shaft 1115 to rotate, the conveying rotating shaft 1115 drives the conveying driving wheel 1120 to rotate, and finally the conveying driving wheel 1120 drives the certificate to move towards the re-tensioning detection mechanism 1200 and the re-tensioning separation mechanism 1300.

When the double-fed certificate is detected by the double-fed detection mechanism 1200, the first driving wheel 1312 is driven to rotate counterclockwise in fig. 6, so as to drive the lowermost certificate of the stacked certificates to move to the side of the storage device 1500, and drop into the storage device 1500. When a plurality of certificates are stacked, the operation is repeated until the double-tension detection mechanism 1200 detects that a certificate is a single certificate, the first driving wheel 1312 is driven to rotate clockwise in fig. 6, and the second driving wheel 1322 is driven to move counterclockwise in fig. 6, so that the single certificate is driven to move to the transfer bearing mechanism 1400.

The certificate on the relay support 1400 is attracted by the suction cup 4320, and the certificate is moved to the printer 3000 by the first relay unit 4100 and the second relay unit 4200. When passing over the code scanning device 6000, the certificate stays for a short time, so that the code scanning device 6000 reads the information code of the certificate. When the certificate information is correct, the certificate continues to move to the printer 3000 and the first side is printed. The certificate printed on the first surface is adsorbed by the sucker 4320, and the certificate is pushed by the transfer device 4000 to move along the support 5200 into the clamping structure 2300.

The support piece 5200 is driven to rotate in a direction away from the flipping unit 2000 by the support motor 5300, so as to prevent the support piece 5200 from obstructing the movement of the clamping structure 2300 of the flipping unit 2000. Then, the overturning driving belt wheel 2500 is driven to rotate through the overturning motor 2400, the overturning driven belt wheel 2600 is driven to rotate, then the overturning rotating shaft 2200 is driven to rotate through the overturning driven belt wheel 2600, the clamping structure 2300 is driven to rotate 180 degrees through the overturning rotating shaft 2200, and the overturning of the certificate in the clamping structure 2300 is achieved. The turned-over certificate is transferred to the second side of the printer 3000 for printing the certificate by the transfer device.

After printing the second side of the certificate, the transfer device 4000 is used to transmit the certificate to the output device 7000, and the above operations are repeated to print the second certificate associated with the first certificate, and transmit the second certificate to the output device 7000, and output the two certificates to the outside of the temporary card manufacturing equipment through the output device 7000.

The present invention has been described in terms of specific examples, which are provided to aid understanding of the utility model and are not intended to be limiting. For a person skilled in the art to which the utility model pertains, several simple deductions, modifications or substitutions may be made according to the idea of the utility model.

Claims (10)

1. A card face manufacturing apparatus, comprising:

the certificate providing device comprises a conveying mechanism, a double-sheet detection mechanism, a double-sheet separation mechanism and a transfer bearing mechanism; the conveying mechanism is used for conveying the certificate; the double-sheet detection mechanism and the double-sheet separation mechanism are positioned on the movement path of the certificate, the double-sheet detection mechanism is used for detecting whether the certificate is double-sheet or not, the double-sheet separation mechanism is used for separating the double-sheet certificate and driving the single certificate to move to the transfer bearing mechanism;

the overturning device is used for overturning the certificate;

a printer for printing information on a certificate;

and the transfer device is used for transferring the certificate among the transfer bearing mechanism, the turnover device and the printer.

2. The card manufacturing apparatus of claim 1, wherein the restrike separation mechanism includes a first separation member and a second separation member, the certificate having a first side and a second side disposed opposite to each other in a stacking direction thereof, the first separation member being configured to apply a first driving force to the certificate from the first side of the certificate, the second separation member being configured to apply a second driving force to the certificate from the second side of the certificate; when the certificate is re-tensioned, the first driving force and the second driving force are opposite in direction so as to drive the re-tensioned certificate to be separated from each other.

3. The card manufacturing apparatus of claim 2, wherein the first separating assembly includes a first urging member and a first driving member, the first driving member being located on a first side of the certificate, the first urging member being located on a second side of the certificate, the first urging member being configured to urge the certificate against the first driving member, a friction between the first driving member and the certificate being the first driving force;

the second separation assembly comprises a second abutting piece and a second driving piece, the second driving piece is located on the second side of the certificate, the second abutting piece is located on the first side of the certificate, the second abutting piece is used for abutting the certificate to the second driving piece, and the friction force between the second driving piece and the certificate is the second driving force.

4. The card facing manufacturing apparatus of claim 1, wherein the transport mechanism includes a transport drive assembly and a transport drive wheel, the transport drive wheel for contacting the certificate, the transport drive assembly for driving the transport drive wheel in rotation to move the certificate.

5. The card manufacturing apparatus of claim 4, wherein said transport drive wheel is of a cam configuration for intermittently engaging said certificate while driving movement of said certificate.

6. The card face manufacturing apparatus according to claim 1, wherein the relay device includes a first relay member, a second relay member, and an extracting member, the extracting member being configured to extract and release the certificate, the first relay member being connected to the extracting member, the first relay member being configured to drive the extracting member to move along a first axis; the second transfer assembly is connected with the first transfer assembly, the second transfer assembly is used for driving the first transfer assembly and the extraction assembly to move along a second axis, and the first axis is perpendicular to the second axis.

7. The card manufacturing apparatus of claim 6, wherein the extraction assembly includes an extraction attachment plate and a suction cup member for absorbing and releasing the certificate, the suction cup member being connected to the extraction attachment plate;

the first transfer assembly comprises a first movable piece, a transfer screw rod, a first transfer motor and a transfer connecting plate; the transfer screw rod is parallel to the first axis and is arranged in a rotating mode, the first movable piece is in threaded connection with the transfer screw rod, and the extraction connecting plate is connected with the first movable piece; the first transfer motor is arranged on the transfer connecting plate, and an output shaft of the first transfer motor is connected with the transfer screw rod;

the second transfer component comprises a second movable piece, a guide rod, a second transfer motor, a transfer driving belt wheel, a transfer driven belt wheel and a transfer transmission belt; the guide rod is parallel to the second axis, the second movable piece is movably sleeved with the guide rod, and the transfer connecting plate is connected with the second movable piece; the transfer driving belt wheel and the transfer driven belt wheel are respectively positioned at two ends of the guide rod, an output shaft of the second transfer motor is connected with the transfer driving belt wheel, the transfer driving belt wheel is connected with the transfer driven belt wheel, and the transfer connecting plate is connected with the transfer driving belt.

8. The card facing manufacturing device of claim 1, wherein the flipping mechanism comprises a flipping base, a flipping rotating shaft, a clamping structure, a flipping motor, a flipping driving pulley, a flipping driven pulley, and a flipping driving belt; the overturning rotating shaft is rotatably connected with the overturning seat, the overturning rotating shaft is connected with the clamping structure, and the clamping structure is used for clamping the certificate; the output shaft of the turnover motor is connected with the turnover driving belt wheel, the turnover driven belt wheel is connected with the turnover rotating shaft, and the turnover driving belt wheel is connected with the turnover driven belt wheel through the turnover driving belt.

9. The card facing manufacturing apparatus of claim 8, further comprising a supporting device, wherein the supporting device comprises a fixed base, a supporting member and a supporting motor, the supporting member is rotatably connected with the fixed base, the supporting member is located between the printer and the clamping structure, and the supporting member is used for supporting the certificate; the output shaft of the bearing motor is connected with the bearing piece, and the bearing motor is used for driving the bearing piece to rotate relative to the fixed seat.

10. The card manufacturing apparatus of any of claims 1-9, further comprising a code scanner, wherein the code scanner emits a code scanning beam that traverses a path of the certificate as it moves between the relay carrier and the printer, and wherein the code scanner is configured to scan an information code on the certificate.

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