CN220115759U

CN220115759U - Feeding positioning device

Info

Publication number: CN220115759U
Application number: CN202321596547.3U
Authority: CN
Inventors: 刘家宏; 周家进; 高子原; 潘俊鹏; 张慈航; 申振江
Original assignee: Henan Shengchang Automation Equipment Co ltd
Current assignee: Henan Shengchang Automation Equipment Co ltd
Priority date: 2023-06-21
Filing date: 2023-06-21
Publication date: 2023-12-01
Anticipated expiration: 2033-06-21

Abstract

The utility model belongs to the technical field of printing equipment, and particularly relates to a feeding positioning device for silk screen printing. Feeding positioner includes the backup pad, still includes: the positioning platform is provided with two groups of Y-direction adjusting mechanisms, an X-direction adjusting mechanism arranged on a moving part of the Y-direction adjusting mechanism, an air suction mechanism arranged on the moving part of the X-direction adjusting mechanism and a positioning mechanism arranged on the air suction mechanism; the positioning mechanism comprises a positioning plate provided with an air suction hole, a positioning block arranged on the positioning plate, a positioning cylinder and a push plate; the air suction mechanism adsorbs the sheet-shaped paper on the positioning plate through the air suction hole and positions the sheet-shaped paper by the positioning block and the pushing plate; the reciprocating driving mechanism is arranged on the supporting plate, and a moving part of the reciprocating driving mechanism is fixedly connected to the positioning platforms and drives the two positioning platforms to reciprocate. The utility model has double positioning platforms and can adjust the position of the sheet paper.

Description

Feeding positioning device

Technical Field

The utility model belongs to the technical field of printing equipment, and particularly relates to a feeding positioning device for silk screen printing.

Background

When silk screen printing is performed on sheet-shaped paper materials such as mobile phone packaging boxes, in order to improve the silk screen printing efficiency, a disc silk screen printing machine is often adopted, namely, sheet-shaped paper materials are fed onto discs of the paper silk screen printing machine in batches, and along with rotation of the discs, the silk screen printing mechanism performs silk screen printing on the sheet-shaped paper materials on the discs. The Chinese patent application No. 2022210662840 discloses a disk screen printing machine. When feeding the disc screen printer of the type, sheet paper in a storage bin is generally required to be fed onto a positioning platform to position the sheet paper, and then the mechanical arm provided with a sucking disc is matched with a feeding device of a sliding rail and sliding block mechanism to feed the sheet paper on the positioning platform onto the disc screen printer. The existing feeding device is provided with one more, namely, after the sheet-shaped paper on one positioning platform is grabbed and conveyed to the disc screen printing machine, the other sheet-shaped paper is required to be conveyed to the positioning platform and positioned, and in the process, the feeding device and the disc screen printing machine have waiting time, so that the feeding and screen printing efficiency is low.

In addition, the existing positioning platform is used for positioning the sheet-shaped paper by using the air cylinder and the push plate arranged on the air cylinder, the positioning precision is low, and when the size of the sheet-shaped paper changes or the position needing silk screen printing changes, the existing positioning platform cannot adjust the positioning position of the sheet-shaped paper.

Therefore, it is needed to design a feeding positioning device with double positioning platforms, so that the sheet-shaped paper on one positioning platform is grabbed by the feeding device, and the other positioning platform is used for positioning the sheet-shaped paper, thereby realizing quick feeding, improving the feeding efficiency and adjusting the position of the sheet-shaped paper with high precision according to the silk-screen position.

Disclosure of Invention

In order to solve the technical problems in the prior art, the utility model provides a feeding positioning device which is provided with double positioning platforms and can be used for adjusting the position of sheet paper.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

feeding positioner includes the backup pad, still includes:

the positioning platform is provided with two groups of Y-direction adjusting mechanisms which are connected with the upper end face of the supporting plate in a sliding way, X-direction adjusting mechanisms which are arranged on moving parts of the Y-direction adjusting mechanisms, air suction mechanisms which are arranged on the moving parts of the X-direction adjusting mechanisms and positioning mechanisms which are arranged on the upper end faces of the air suction mechanisms,

the positioning mechanism comprises a positioning plate provided with an air suction hole, a positioning block arranged on the positioning plate, a positioning cylinder arranged on the positioning plate and a push plate arranged on a guide rod of the positioning cylinder;

the air suction mechanism adsorbs the sheet-shaped paper on the positioning plate through the air suction hole and positions the sheet-shaped paper by the positioning block and the pushing plate;

the reciprocating driving mechanism is arranged on the supporting plate, and a moving part of the reciprocating driving mechanism is fixedly connected to the positioning platforms and drives the two positioning platforms to reciprocate.

Preferably, the Y-direction adjusting mechanism comprises a Y-direction adjusting plate which is connected to the upper end face of the supporting plate in a sliding way through a first sliding rail sliding block assembly, a second sliding rail sliding block assembly and a first screw rod assembly, wherein the second sliding rail sliding block assembly and the first screw rod assembly are arranged on the upper end face of the Y-direction adjusting plate along the Y direction, and the X-direction adjusting mechanism is fixedly connected to the sliding piece of the first screw rod assembly and the sliding block of the second sliding rail sliding block assembly.

Preferably, the X-direction adjusting mechanism comprises an X-direction adjusting plate fixedly connected to the sliding piece of the first screw rod assembly, a third sliding rail sliding block assembly and a second screw rod assembly, wherein the third sliding rail sliding block assembly and the second screw rod assembly are arranged on the upper end face of the X-direction adjusting plate along the X direction, and the air suction mechanism is fixedly connected to the sliding piece of the second screw rod assembly and the sliding block of the third sliding rail sliding block assembly.

Preferably, the air suction mechanism comprises an air suction connecting plate fixedly connected to the sliding piece of the second screw rod assembly, an air suction cylinder body vertically arranged on the air suction connecting plate and an air suction plate arranged on the upper end face of the air suction cylinder body, an air suction groove is formed in the air suction plate, a sealing ring is embedded in the upper end face of the air suction plate outside the air suction groove, and the air suction hole, the air suction groove and the air suction cylinder body are sequentially communicated to the vacuum generator.

Preferably, the reciprocating driving mechanism comprises a servo motor, a third screw rod assembly and two connecting blocks, wherein the servo motor and the third screw rod assembly are fixedly connected to the lower end surface of the supporting plate, the two connecting blocks are meshed with the screw rods of the third screw rod assembly, and the two connecting blocks are respectively and fixedly connected to Y-direction adjusting plates of the two Y-direction adjusting mechanisms.

Preferably, a trigger plate is arranged on one connecting block, and at least two groove-type photoelectric switches matched with the trigger plate are arranged on the lower end surface of the supporting plate along the length direction of the supporting plate.

Preferably, kidney-shaped connecting holes are respectively arranged on the positioning plate along the X direction and the Y direction, and the positioning block is fixedly connected in the connecting holes.

Preferably, the positioning plate is respectively provided with a chute along the X direction and the Y direction, the push plate is provided with a slide bar, and the slide bar can be slidably arranged in the chute in a penetrating way.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, by arranging the two positioning platforms and driving the positioning platforms to reciprocate along the length direction of the supporting plate by the reciprocating driving mechanism, the cyclic reciprocation of the two positioning platforms is realized, and the feeding and positioning procedures are realized, so that the feeding speed of the sheet-shaped paper is improved; in addition, by arranging the Y-direction adjusting mechanism and the X-direction adjusting mechanism, the positioning mechanism can be adjusted in the X-direction and the Y-direction, so that the adjustment of the sheet-shaped paper materials with different sizes and different silk-screen positions can be realized.

Drawings

Fig. 1 is a schematic overall structure of a first view angle of the present utility model.

Fig. 2 is a schematic overall structure of a second view angle of the present utility model.

Fig. 3 is an enlarged schematic view of the structure at a in fig. 2.

FIG. 4 is a schematic diagram of the connection structure of the positioning platform, the X-direction adjusting mechanism and the Y-direction adjusting mechanism of the present utility model.

FIG. 5 is a schematic view of the structure of a single positioning stage of the present utility model.

Fig. 6 is a schematic structural view of the air suction mechanism of the present utility model.

Fig. 7 is a schematic view of a first view structure of the positioning mechanism of the present utility model.

Fig. 8 is a schematic view of a second view structure of the positioning mechanism of the present utility model.

In the figure: 1. the support plate, 11, the support plate through groove, 2, the positioning platform, 21, Y-direction adjusting mechanism, 211, a first sliding rail sliding block assembly, 212, a Y-direction adjusting plate, 213, a second sliding rail sliding block assembly, 214, a first screw rod assembly, 215, a positioning platform connecting plate, 22, an X-direction adjusting mechanism, 221, an X-direction adjusting plate, 222, a third sliding rail sliding block assembly, 223, a second screw rod assembly, 23, an air suction mechanism, 231, an air suction connecting plate, 232, an air suction cylinder, 233, an air suction plate, 234, an air suction groove, 235, a sealing ring, 236, an air suction channel, 24, a positioning mechanism, 241, a positioning plate, 242, a positioning block, 243, a positioning cylinder, 244, a push plate, 245, an air suction hole, 246, a connecting hole, 247, a sliding groove, 248, a sliding bar, 25, a hand wheel, 3, a reciprocating driving mechanism, 31, a servo motor, 32, a third screw rod assembly, 33, a connecting block, 34, a trigger plate, 35 and a photoelectric switch.

Description of the embodiments

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments, and that all other embodiments obtained by persons of ordinary skill in the art without making creative efforts based on the embodiments in the present utility model are within the protection scope of the present utility model.

In the description of the present utility model, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present utility model and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Examples

Referring to fig. 1, 2, 4 and 5, a feeding positioning device comprises a support plate 1, two positioning platforms 2 which can slide along the length direction of the support plate 1 at the upper end of the support plate 1, and a reciprocating driving mechanism 3 which is arranged at the lower end of the support plate 1 and drives the two positioning platforms 2 to reciprocate.

The positioning platform 2 is provided with two groups along the length direction of the supporting plate 1 and comprises a Y-direction adjusting mechanism 21 which is connected with the upper end surface of the supporting plate 1 in a sliding way, an X-direction adjusting mechanism 22 which is arranged on a moving part of the Y-direction adjusting mechanism 21, an air suction mechanism 23 which is arranged on a moving part of the X-direction adjusting mechanism 22, and a positioning mechanism 24 which is arranged on the upper end surface of the air suction mechanism 23. In the present embodiment, the X-direction is the longitudinal direction of the support plate 1, and the Y-direction is the direction perpendicular to the X-direction.

The Y-direction adjusting mechanism 21 includes a first slide rail slider assembly 211, a Y-direction adjusting plate 212, a second slide rail slider assembly 213, and a first screw assembly 214. The two Y-direction adjustment plates 212 of the two positioning platforms 2 are connected together by a positioning platform connecting plate 215.

Specifically, the sliding rail of the first sliding rail sliding block assembly 211 is fixedly connected to the upper end surface of the supporting plate 1 along the X direction through a bolt, the sliding block of the first sliding rail sliding block assembly 211 is slidably arranged on the sliding rail of the first sliding rail sliding block assembly 211, and the Y-direction adjusting plate 212 is horizontally and fixedly connected to the sliding block of the first sliding rail sliding block assembly 211 through a bolt. The second sliding rail sliding block assembly 213 and the first screw rod assembly 214 are fixed on the upper end surface of the Y-direction adjusting plate 212 along the Y direction, the X-direction adjusting mechanism 22 is fixedly connected on the sliding piece of the first screw rod assembly 214 and the sliding block of the second sliding rail sliding block assembly 211, and the X-direction adjusting mechanism 22 can be driven to reciprocate along the Y direction by rotating the screw rod of the first screw rod assembly 214.

The X-direction adjusting mechanism 22 includes an X-direction adjusting plate 221, a third slide rail slider assembly 222, and a second screw assembly 223.

The X-direction adjusting plate 221 is fixedly connected to the slide block of the second slide rail slide block assembly 211 and the slide piece of the first screw rod assembly 214 through bolts, and the X-direction adjusting plate 231 can be driven to reciprocate along the Y-direction by rotating the screw rod of the first screw rod assembly 214. The third sliding rail and sliding block assembly 222 and the second screw rod assembly 223 are fixed on the upper end surface of the X-direction adjusting plate 221 along the X-direction, and the air suction mechanism 23 is fixedly connected to the sliding piece of the second screw rod assembly 223 and the sliding block of the third sliding rail and sliding block assembly 222.

In order to facilitate the adjustment of the screws of the first screw assembly 214 and the second screw assembly 223, a hand wheel 25 is fixedly connected to the screw ends of the first screw assembly 214 and the second screw assembly 223.

Referring to fig. 6, the air suction mechanism 23 includes an air suction connection plate 231, an air suction cylinder 232, and an air suction plate 233.

The air suction connection plate 231 is fixedly connected to the sliding piece of the second screw rod assembly 223 and the sliding block of the third sliding rail sliding block assembly 222 through bolts, and the air suction mechanism 23 can be driven to reciprocate along the X direction by rotating the screw rod of the second screw rod assembly 223.

The air suction cylinder 232 is vertically and fixedly connected to the upper end face of the air suction connecting plate 231 through bolts, the air suction plate 233 can be integrally formed on the upper end face of the air suction cylinder 232, the air suction groove 234 is formed in the air suction plate 233, and the sealing ring 235 is embedded in the upper end face of the air suction plate 233 outside the air suction groove 234. A ventilation channel 236 extending into the air suction cylinder 232 is formed at the bottom of the air suction groove 234, and the lower part of the ventilation channel 236 is communicated with a vacuum generator (not shown).

Referring to fig. 7 and 8, positioning mechanism 24 includes positioning plate 241, positioning block 242, positioning cylinder 243, and push plate 244.

The positioning plate 241 is bolted to the upper end surface of the air suction plate 233 and seals the air suction groove 234 in cooperation with the seal ring 235. A plurality of air suction holes 245 penetrating through the positioning plate 241 are formed in the upper end face of the positioning plate 241, and the air suction holes 245 are communicated with the air suction grooves 234.

The positioning block 242 is bolted to the positioning plate 241, and further, in order to facilitate adjustment of the relative position of the positioning block 242 on the positioning plate 241, waist-shaped connecting holes 246 are respectively arranged on the positioning plate 241 along the X direction and the Y direction, and the positioning block 242 is fixedly connected in the connecting holes 246 by bolts.

The positioning cylinder 243 is fixed on the positioning plate 241 by bolts, the push plate 244 is fixed on the guide rod of the positioning cylinder 243 by bolts, and a group of positioning blocks 242 and push plates 244 which are arranged oppositely are respectively arranged in the X direction and the Y direction, namely, the positioning cylinder 243 pushes the push plates 244 to position the sheet paper between the two groups of positioning blocks 242 and the push plates 244, thereby realizing the positioning of the sheet paper on the positioning plate 241. Further, in order to make the push plate 244 more smooth and accurate when sliding along the X-direction and the Y-direction respectively, the positioning plate 241 is provided with a sliding slot 247 along the X-direction and the Y-direction respectively, the push plate 244 is provided with a protruding sliding strip 248, and the sliding strip 248 is slidably inserted into the sliding slot 247.

Thus, when the sheet paper is placed on the positioning plate 241, the vacuum generator can suck air between the sheet paper and the upper end surface of the positioning plate 241 through the air suction holes 245, the air suction grooves 234 and the air passage 236, so that the sheet paper is adsorbed on the positioning plate 241 and positioned by the positioning block 242 and the push plate 244.

As can be seen in figures 2 and 3,

the reciprocating driving mechanism 3 is arranged on the supporting plate 1, and a moving part of the reciprocating driving mechanism 3 is fixedly connected to the positioning platforms 2 and drives the two positioning platforms 2 to reciprocate.

Specifically, the reciprocating driving mechanism 3 includes a servo motor 31 fixedly connected to the lower end surface of the support plate 1 by bolts, a third screw assembly 32, and two connection blocks 33 engaged on screws of the third screw assembly 32, and the two connection blocks 33 are fixedly connected to Y-direction adjustment plates 212 of the two Y-direction adjustment mechanisms 21, respectively. The servo motor 31 can be connected with a screw rod of the third screw rod assembly 32 through belt transmission, a support plate through groove 11 is formed in the support plate 1 along the length direction of the support plate, and a connecting block 33 is slidably arranged in the support plate through groove 11 in a penetrating mode. In order to improve the automation level and the accuracy of the driving positioning platform 2 by the reciprocating driving mechanism 3, a trigger plate 34 is arranged on one connecting block 33, at least two groove-type photoelectric switches 35 matched with the trigger plate 34 are arranged on the lower end face of the supporting plate 1 along the length direction of the supporting plate 1, in the embodiment, two photoelectric switches 35 are arranged, and the photoelectric switches 35 can be selected from photoelectric switches of a precision photoelectric sensor FC-SPX303 PZ. Referring to fig. 2, two trigger plates 34 are arranged from left to right, when the trigger plates 34 move to the left photoelectric switch 35 and trigger the photoelectric switch 35, sheet paper in the stock bin is grabbed onto the left positioning platform 2 and positioned, and the positioned sheet paper on the right positioning platform 2 is grabbed onto the screen printing mechanism by the feeding mechanism; when the trigger plate 34 moves to the photoelectric switch 35 on the right side and triggers the photoelectric switch 35, the sheet paper in the stock bin is grabbed onto the positioning platform 2 on the right side and positioned, and the positioned sheet paper on the positioning platform 2 on the left side is grabbed onto the screen printing mechanism by the feeding mechanism.

The working process of the embodiment of the utility model is as follows:

1. the components are installed according to the structural description of the above embodiment, as shown in fig. 1 and 2; two storage bins filled with sheet-shaped paper are respectively arranged at two ends of one side of the supporting plate 1, and storage bin feeding mechanisms (not shown in the figure) which grab the sheet-shaped paper from the storage bins and transfer the sheet-shaped paper to the corresponding positioning platforms 2 are correspondingly arranged; a silk-screen feeding mechanism (not shown in the figure) is arranged in the middle of the other side of the supporting plate 1; according to the sheet paper size and the silk screen position, the relative position of the positioning mechanism 24 is adjusted by rotating the hand wheel 25, and the relative position of the positioning block 242 on the positioning plate 241 is adjusted;

2. as shown in fig. 1, when the servo motor 31 drives the third screw rod assembly 32 to move the left positioning platform 2 to the middle, the feeding mechanism of the right stock bin grabs the sheet paper from the right stock bin and transfers the sheet paper to the positioning plate 241 on the right positioning platform 2, the sheet paper is adsorbed on the positioning plate 241 by the vacuum generator, and the guide rod of the positioning cylinder 243 extends out to position the sheet paper between the positioning block 242 and the push plate 244;

3. when the servo motor 31 drives the third screw rod assembly 32 to enable the right positioning platform 2 to move to the middle, the positioned sheet paper on the right positioning platform 2 is absorbed by the silk-screen feeding mechanism and is transferred to the silk-screen mechanism; at this time, the left bin feeding mechanism grabs the sheet-shaped paper from the left bin and transfers the sheet-shaped paper to the positioning plate 241 on the left positioning platform 2, and adsorbs the sheet-shaped paper to the positioning plate 241 through the vacuum generator, and the guide rod of the positioning cylinder 243 extends out to position the sheet-shaped paper between the positioning block 242 and the push plate 244;

4. when the servo motor 31 drives the third screw rod assembly 32 to enable the left positioning platform 2 to move to the middle, the positioned sheet paper on the left positioning platform 2 is absorbed by the silk-screen feeding mechanism and is transferred to the silk-screen mechanism; the feeding mechanism of the right stock bin grabs the sheet-shaped paper from the right stock bin and transfers the sheet-shaped paper to the positioning plate 241 on the right positioning platform 2, the sheet-shaped paper is adsorbed on the positioning plate 241 through the vacuum generator, and the guide rod of the positioning cylinder 243 extends out, so that the sheet-shaped paper is positioned between the positioning block 242 and the push plate 244;

5. and (3) circulating the steps 3-4 to realize the rapid feeding of the sheet-shaped paper to the screen printing mechanism.

The connection relation and control logic between the controller and each component are automatic operation to improve the production efficiency, and of course, the controller can also be controlled and operated manually, and the related connection relation and control logic are the prior art and are not described herein.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a material loading positioner, includes the backup pad, its characterized in that: further comprises:

the positioning platform is provided with two groups of Y-direction adjusting mechanisms which are connected to the upper end face of the supporting plate in a sliding way, an X-direction adjusting mechanism which is arranged on a moving part of the Y-direction adjusting mechanism, an air suction mechanism which is arranged on a moving part of the X-direction adjusting mechanism, and a positioning mechanism which is arranged on the upper end face of the air suction mechanism;

2. A loading positioning device according to claim 1, wherein: the Y-direction adjusting mechanism comprises a Y-direction adjusting plate, a second sliding rail sliding block assembly and a first screw rod assembly, wherein the Y-direction adjusting plate is connected to the upper end face of the supporting plate in a sliding mode through the first sliding rail sliding block assembly, the second sliding rail sliding block assembly and the first screw rod assembly are arranged on the upper end face of the Y-direction adjusting plate along the Y direction, and the X-direction adjusting mechanism is fixedly connected to the sliding piece of the first screw rod assembly and the sliding block of the second sliding rail sliding block assembly.

3. A loading positioning device according to claim 2, wherein: the X-direction adjusting mechanism comprises an X-direction adjusting plate fixedly connected to the sliding piece of the first screw rod assembly, a third sliding rail and sliding block assembly and a second screw rod assembly, wherein the third sliding rail and sliding block assembly and the second screw rod assembly are arranged on the upper end face of the X-direction adjusting plate along the X direction, and the air suction mechanism is fixedly connected to the sliding piece of the second screw rod assembly and the sliding block of the third sliding rail and sliding block assembly.

4. A loading positioner according to claim 3, wherein: the air suction mechanism comprises an air suction connecting plate fixedly connected to the sliding piece of the second screw rod assembly, an air suction cylinder body vertically arranged on the air suction connecting plate and an air suction plate arranged on the upper end face of the air suction cylinder body, an air suction groove is formed in the air suction plate, a sealing ring is embedded in the upper end face of the air suction plate outside the air suction groove, and the air suction hole, the air suction groove and the air suction cylinder body are sequentially communicated to the vacuum generator.

5. The feeding positioning device according to claim 4, wherein: the reciprocating driving mechanism comprises a servo motor, a third screw rod assembly and two connecting blocks, wherein the servo motor and the third screw rod assembly are fixedly connected to the lower end face of the supporting plate, the two connecting blocks are meshed with the screw rods of the third screw rod assembly, and the two connecting blocks are respectively and fixedly connected to Y-direction adjusting plates of the two Y-direction adjusting mechanisms.

6. The feeding positioning device according to claim 5, wherein: a trigger plate is arranged on one connecting block, and at least two groove-type photoelectric switches matched with the trigger plate are arranged on the lower end face of the supporting plate along the length direction of the supporting plate.

7. A loading positioning device according to claim 1, wherein: waist-shaped connecting holes are respectively arranged on the positioning plate along the X direction and the Y direction, and the positioning block is fixedly connected in the connecting holes.

8. A loading positioning device according to claim 1, wherein: the positioning plate is provided with sliding grooves along the X direction and the Y direction respectively, the push plate is provided with a sliding strip, and the sliding strip can be slidably arranged in the sliding grooves in a penetrating mode.