CN121892900A - Suction-compression positioning receiving mechanism and roll-to-roll direct imaging equipment - Google Patents

Abstract

This invention provides a suction-pressure positioning and receiving mechanism and a roll-to-roll direct imaging device, belonging to the field of laser processing. The suction-pressure positioning and receiving mechanism includes an adsorption cavity, an adsorption top plate, multiple receiving lifting drive assemblies, two receiving pressure members, and a debris groove. Two adsorption top plates with suction holes are installed side-by-side at intervals on the top of the adsorption cavity. The debris groove is installed in the middle of the top surface of the adsorption cavity and located below the gap between the two adsorption top plates. The receiving lifting drive assemblies are installed at the four corners of the adsorption cavity, and the two receiving pressure members are installed on the corresponding receiving lifting drive assemblies. The receiving pressure members are driven by the receiving lifting drive assemblies to rise and fall relative to the adsorption top plates for pressing and positioning the material. The suction-pressure positioning and receiving mechanism of this application has a simple structure and is easy to implement. The adsorption top plate has an adsorption area and a non-adsorption cutting area. While adsorbing and positioning, the material strip is fixed by the receiving pressure members, thereby achieving efficient and clean auxiliary receiving, which is convenient for promotion and application in the fields of material strip receiving and laser processing.

Description

Suction-compression positioning receiving mechanism and roll-to-roll direct imaging equipment

Technical Field

The invention belongs to the field of laser processing, and particularly relates to a suction-compression positioning receiving mechanism and roll-to-roll direct imaging equipment.

Background

Flexible printed circuit boards (FPCs) play an increasing role in the leading fields of consumer electronics, artificial Intelligence (AI) and the like at present, and the development trend of the full-flow RTR process innovation of a multi-series product supply chain is advanced in the current industry. The roll-to-roll direct imaging device (hereinafter referred to as "RTR device") is the core device.

The current RTR equipment is in the feed or receive the material in-process, can't stabilize the feed, and when receiving the material, can't stabilize two material area that wait to connect, also can't stabilize two material area when cutting, and the piece of cutting can't collect, influences the cleanliness in material area. Therefore, it is necessary to design an auxiliary mechanism for receiving materials.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention aims to provide a suction-pressing positioning receiving mechanism and a roll-to-roll direct imaging device, which can solve the problems.

The suction-pressing positioning material receiving mechanism comprises an adsorption cavity, an adsorption top plate, a plurality of material receiving lifting driving components, two material receiving pressing pieces and a chip groove, wherein the two adsorption top plates provided with suction holes are arranged at the top of the adsorption cavity in parallel at intervals, the chip groove is arranged at the middle part of the top surface of the adsorption cavity and is positioned below the adjacent gaps of the two adsorption top plates, the material receiving lifting driving components are arranged at four corners of the adsorption cavity, the two material receiving pressing pieces are arranged on the material receiving lifting driving components at corresponding sides, and the material receiving pressing pieces are lifted by the relative adsorption top plates driven by the material receiving lifting driving components and are used for pressing and positioning materials.

Further, the top surface of the adsorption cavity is provided with an air groove, a main air hole, a groove connecting installation concave part, a cavity installation hole and an end installation hole, the groove connecting installation concave part is arranged in the middle of the top surface of the adsorption cavity, a plurality of air grooves, the main air hole and the cavity installation hole are arranged on two sides of the groove connecting installation concave part, and the end installation holes are arranged on two ends of the top surface of the adsorption cavity.

Further, the chip groove comprises a groove body, a handle and a guide supporting part, wherein the handle and the guide supporting part are respectively arranged at two ends of the groove body.

The invention also provides roll-to-roll direct imaging equipment, which comprises a reeling station, an exposure station and a reeling station, wherein the reeling station and the reeling station adopt the suction-pressure positioning receiving mechanism to carry out auxiliary receiving, the exposure station adopts multi-coordinate fusion calibration, and adopts vector diagram position compensation to correct exposure positioning precision, so that the exposure precision is improved.

Compared with the prior art, the suction-compression positioning material receiving mechanism has the beneficial effects that the suction-compression positioning material receiving mechanism is simple in structure and easy to realize, the suction top plate is provided with the suction area and the non-suction cutting area, and the material belt is fixed through the material receiving pressing piece while the suction positioning is performed, so that the efficient and clean auxiliary material receiving is realized, and the suction-compression positioning material receiving mechanism is convenient to popularize and apply in the fields of material belt material receiving and laser processing.

Drawings

Fig. 1 and 2 are schematic diagrams of different view angles of the suction-compression positioning receiving mechanism;

FIG. 3 is a schematic diagram of an adsorption chamber;

FIG. 4 is a schematic view of an adsorption top plate;

FIG. 5 is a schematic view of a debris chute;

Fig. 6 is a schematic diagram of a roll-to-roll direct imaging device.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-5, the suction-pressing positioning material receiving mechanism comprises an adsorption cavity 10, an adsorption top plate 20, a plurality of material receiving lifting drive assemblies 30, two material receiving pressing pieces 40 and a debris groove 50.

Specifically, two adsorption top plates 20 with suction holes are arranged at the top of the adsorption cavity 10 in parallel at intervals, a chip groove 50 is arranged in the middle of the top surface of the adsorption cavity 10 and is positioned below adjacent gaps of the two adsorption top plates 20, a material receiving lifting driving assembly 30 is arranged at four corners of the adsorption cavity 10, two material receiving pressing pieces 40 are arranged on the material receiving lifting driving assemblies 30 at corresponding sides, and the material receiving pressing pieces 40 are driven by the material receiving lifting driving assemblies 30 to lift relative to the adsorption top plates 20 for pressing and positioning of materials. Both ends of the suction top plate 20 are fixed to the suction chamber 10 by top plate pressing members 60.

Referring to fig. 3, the top surface of the adsorption cavity 10 is provided with an air groove 11, a main air hole 12, a groove mounting concave portion 13, a cavity mounting hole 14 and an end mounting hole 15, the groove mounting concave portion 13 is formed in the middle of the top surface of the adsorption cavity 10, a plurality of air grooves 11, main air holes 12 and cavity mounting holes 14 are formed on two sides of the groove mounting concave portion 13, and the end mounting holes 15 are formed on two ends of the top surface of the adsorption cavity 10.

In this case, referring to fig. 4, the suction top plates 20 are provided with top plate suction holes 21, and the two suction top plates 20 are not provided with suction holes at the edges of the adjacent sides, thereby forming an outer suction region and a cutting region at the adjacent positions.

Wherein, the material receiving lifting driving assembly 30 is driven by a cylinder or a linear motor, and the fixing parts of the material receiving lifting driving assembly 30 are arranged at the bottoms or the side parts of the four corners of the adsorption cavity 10. In the illustrated example, the take-up lift drive assembly 30 employs a cylinder drive assembly.

Wherein, the material receiving pressing piece 40 adopts a pressing plate or a pressing roller, and two material receiving pressing pieces 40 are arranged at the movable ends of the material receiving lifting driving components 30 at the corresponding sides. In the illustrated example, the receiving press 40 employs a platen.

Wherein, referring to fig. 5, the chip groove 50 includes a groove body 51, a handle 52 and a guide support 53, and the handle 52 and the guide support 53 are respectively provided at both ends of the groove body 51.

Further, a tank suction hole 54 is formed at the bottom of the tank 51.

Further, the suction-pressure positioning receiving mechanism further comprises a receiving chassis 70, the bottom of the adsorption cavity 10 is mounted on the receiving chassis 70, and an adsorption tube group is arranged on the receiving chassis 70.

Referring to fig. 6, the device comprises a winding station 1000, an exposure station 2000 and a winding station 3000, wherein the winding station 1000 and the winding station 3000 adopt the pressure-absorbing positioning material receiving mechanism to carry out auxiliary material receiving, the exposure station 2000 adopts multi-coordinate fusion calibration, and adopts vector diagram position compensation to correct exposure positioning precision, so that exposure precision is improved.

It should be noted that the above-mentioned embodiments are merely for illustrating the technical solution of the present invention, and not for limiting the same, and although the present invention has been described in detail with reference to the above-mentioned embodiments, it should be understood by those skilled in the art that the technical solution described in the above-mentioned embodiments may be modified or some technical features may be equivalently replaced, and these modifications or substitutions do not make the essence of the corresponding technical solution deviate from the spirit and scope of the technical solution of the embodiments of the present invention.

Claims (10)

1. The suction-pressing positioning receiving mechanism is characterized by comprising an adsorption cavity (10), an adsorption top plate (20), a plurality of receiving lifting driving components (30), two receiving pressing pieces (40) and a chip groove (50);

Two adsorption top plates (20) with suction holes are arranged at intervals on the tops of the adsorption cavities (10) side by side, a chip groove (50) is arranged in the middle of the top surface of the adsorption cavities (10) and is positioned below adjacent gaps of the two adsorption top plates (20), a material receiving lifting driving assembly (30) is arranged at four corners of the adsorption cavities (10), two material receiving pressing pieces (40) are arranged on the material receiving lifting driving assemblies (30) on corresponding sides, and the material receiving pressing pieces (40) are lifted by the material receiving lifting driving assemblies (30) to drive the opposite adsorption top plates (20) to be used for pressing and positioning materials.

2. The suction positioning receiving mechanism according to claim 1, wherein the top surface of the suction cavity (10) is provided with an air groove (11), a main air hole (12), a receiving groove mounting concave part (13), a cavity mounting hole (14) and an end mounting hole (15), the receiving groove mounting concave part (13) is arranged in the middle of the top surface of the suction cavity (10), the plurality of air grooves (11), the main air hole (12) and the cavity mounting hole (14) are arranged on two sides of the receiving groove mounting concave part (13), and the end mounting holes (15) are arranged on two ends of the top surface of the suction cavity (10).

3. The suction, pressing, positioning and receiving mechanism as set forth in claim 1, wherein the suction top plates (20) are provided with top plate suction holes (21), and the two suction top plates (20) are not provided with suction holes at the edges of the adjacent sides, thereby forming an outer suction area and a cutting area at the adjacent positions.

4. The suction, pressure and positioning material receiving mechanism as set forth in claim 1, wherein the material receiving lifting driving assembly (30) is driven by a cylinder or a linear motor, and the fixing part of the material receiving lifting driving assembly (30) is mounted to the bottom or the side part of four corners of the adsorption cavity (10).

5. The suction and compression positioning receiving mechanism according to claim 1, wherein the receiving pressing pieces (40) are pressing plates or pressing rollers, and the two receiving pressing pieces (40) are mounted to movable ends of the receiving lifting driving components (30) on corresponding sides.

6. The suction, pressure, positioning and receiving mechanism as set forth in claim 1, wherein the chip tank (50) comprises a tank body (51), a handle (52) and a guide supporting portion (53), and the handle (52) and the guide supporting portion (53) are respectively arranged at two ends of the tank body (51).

7. The suction positioning receiving mechanism as set forth in claim 5, wherein a tank suction hole (54) is formed at the bottom of the tank (51).

8. The suction, pressing, positioning and receiving mechanism as set forth in claim 1, wherein both ends of the suction top plate (20) are fixed to the suction cavity (10) by top plate pressing members (60).

9. The suction pressure positioning and receiving mechanism as set forth in claim 1, further comprising a receiving chassis (70), wherein the bottom of the suction cavity (10) is mounted to the receiving chassis (70), and wherein the suction tube group is disposed on the receiving chassis (70).

10. A roll-to-roll direct imaging device comprises a roll-up station (1000), an exposure station (2000) and a rolling station (3000), and is characterized in that the roll-up station (1000) and the rolling station (3000) adopt the suction-pressure positioning material receiving mechanism as set forth in any one of claims 1-8 to carry out auxiliary material receiving, the exposure station (2000) adopts multi-coordinate fusion calibration, and adopts vector diagram position compensation to correct exposure positioning precision, so that the exposure precision is improved.