CN217775947U - Processing jig and laser processing equipment - Google Patents

Abstract

The utility model relates to a laser beam machining technical field particularly, relates to a processing tool. The processing jig comprises a base, a first adsorption component and a second adsorption component; the first adsorption component is connected with the base and is used for adsorbing products or materials; the second adsorption component is connected with the base, and the second adsorption component is used for adsorbing the part to be cut off of the material, the material with the product is attached to each other, and the second adsorption component is suitable for driving the material to move along the first direction. The utility model discloses a first adsorption component is fixed the product or the material of waiting to cut, adsorbs the part that the material need amputate through second adsorption component to in-process cutting the material, second adsorption component stimulates this part gradually and removes along the first direction, makes during the cutting, and the cutting way on material surface outwards expands gradually, keeps too much dust particle in avoiding the cutting way, ensures machining efficiency.

Description

Processing jig and laser processing equipment

Technical Field

The utility model relates to a laser beam machining technical field particularly, relates to a processing tool and laser beam machining equipment.

Background

The polaroid is an important component of a liquid crystal module, and is widely applied to the fields of mobile phones, tablet computers, medical cosmetology, 3D glasses, vehicle-mounted display and the like. For example, in the cutting application of the 3D glasses industry, the polarizer is attached to the 3D glasses, and in fact, the polarizer film has a larger area than the 3D glasses, so that the film exceeding the 3D glasses needs to be cut away by laser, but because the polarizer film is thicker, the polarizer film deforms after being cut by laser, and with the increase of the laser cutting depth, cutting dust is accumulated in the cutting channel, which affects the laser cutting efficiency, and even the situation is continuous.

SUMMERY OF THE UTILITY MODEL

The utility model provides a problem be that the cutting dust can pile up the laser cutting efficiency who leads to in the cutting way and hang down excessively.

On one hand, in order to solve the problems, the utility model provides a processing jig, which comprises a base, a first adsorption component and a second adsorption component; the first adsorption component is connected with the base and is used for adsorbing products or materials; the second adsorption component is connected with the base, and the second adsorption component is used for adsorbing the part to be cut off of the material, the material with the product is attached to each other, and the second adsorption component is suitable for driving the material to move along the first direction.

Optionally, the first adsorption assembly comprises a first support rod and a first suction cup, one end of the first support rod is mounted on the base, the first suction cup is mounted at the other end of the first support rod, and the first suction cup is used for adsorbing the product or the material.

Optionally, the first suction assembly further comprises a support seat, the support seat is connected with the first support rod, the first suction disc is located in the support seat, and the top surface of the first suction disc is flush with the top surface of the support seat.

Optionally, the processing jig further comprises a driving mechanism, the driving mechanism is mounted on the base and is in driving connection with the second adsorption assembly, and the driving mechanism is suitable for driving the second adsorption assembly to move along the first direction.

Optionally, the processing jig further includes a connecting member, the driving mechanism is in driving connection with the connecting member, the driving mechanism is adapted to drive the connecting member to move along the first direction, the second adsorption component is movably mounted on the connecting member, and a distance between the second adsorption component and the first adsorption component is adjustable.

Optionally, the processing jig further comprises an adjusting device, the driving mechanism is in driving connection with the adjusting device, the adjusting device is connected with the connecting piece, and the adjusting device is used for adjusting the top surface of the second adsorption component to be attached to the surface of the material.

Optionally, the second adsorption component further comprises a second support rod and a second sucker, the second support rod is movably mounted on the connecting piece, a through hole is formed in the second support rod, the second sucker is connected with one end of the through hole, the other end of the through hole is suitable for being connected with an external vacuum generator, and the second sucker is used for adsorbing the material.

Optionally, the processing jig further comprises a fastener, a waist-shaped hole is formed in the connecting piece, and the fastener is suitable for penetrating through the waist-shaped hole and is connected with the second supporting rod.

Optionally, the number of the second adsorption assemblies is four, and four second adsorption assemblies are arranged along the circumferential array of the first adsorption assemblies.

On the other hand, the utility model also provides a laser beam machining equipment, include as above processing tool.

Compared with the prior art, the embodiment of the utility model provides a processing tool has beneficial effect is:

fix the product or the material of waiting to cut through first adsorption component, live the part that the material needs the excision through the adsorption of second adsorption component to in-process to the material cutting, the second adsorption component stimulates this part gradually and removes along first direction, makes during the cutting, and the cutting way on material surface outwards expands gradually, avoids preserving too much dust particle in the cutting way, ensures machining efficiency.

Drawings

Fig. 1 is a schematic structural view of an embodiment of the processing jig of the present invention;

fig. 2 is a schematic structural view of another embodiment of the processing jig of the present invention;

fig. 3 is a schematic structural view of another embodiment of the processing jig of the present invention;

fig. 4 is a schematic structural view of an embodiment of the second adsorption assembly of the present invention;

fig. 5 is a schematic structural view of another embodiment of the second adsorption assembly of the present invention.

Description of the reference numerals:

1-a base; 2-a first adsorption module; 21-a first support bar; 22-a first suction cup; 23-a support seat; 3-a second adsorption component; 31-a second support bar; 311-a via hole; 32-a second suction cup; 4-a drive mechanism; 5-a connecting piece; 51-kidney shaped hole; 6-a regulating device; 7-products; 8-material.

Detailed Description

The terms "mounted," "connected," and "coupled" are to be construed broadly and may include, for example, a fixed connection, a removable connection, or a rotatable connection; may be a mechanical connection; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

The embodiment of the present invention provides coordinate system XYZ in the drawings, wherein the forward direction of the X axis represents the right direction, the reverse direction of the X axis represents the left direction, the forward direction of the Z axis represents the top direction, the reverse direction of the Z axis represents the bottom direction, the forward direction of the Y axis represents the front direction, the reverse direction of the Y axis represents the back direction, and the directions or position relationships indicated by the terms "up", "down", "front", "back", "left" and "right" and the like are based on the directions or position relationships shown in the drawings, which is only for convenience of description and simplification of the description, rather than indicating or suggesting that the device indicated must have a specific direction, be constructed and operated in a specific direction, and therefore cannot be understood as a limitation to the present invention.

The terms "first", "second", and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or to implicitly indicate the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature.

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.

As shown in fig. 1 to 3, an embodiment of the present invention provides a processing jig. The processing jig comprises a base 1, a first adsorption component 2 and a second adsorption component 3; the first adsorption component 2 is connected with the base 1, and the first adsorption component 2 is used for adsorbing a product 7 or a material 8; the second adsorption component 3 with the base 1 is connected, the second adsorption component 3 is used for adsorbing the part of the material 8 to be cut off, the material 8 with the product 7 is attached to each other, and the second adsorption component 3 is suitable for driving the material 8 to move along the first direction.

The first direction may be the direction of the Z-axis in the figure, the product 7 may be a 3D spectacle lens and the material 8 may be a polarizer. Because the size specifications of the 3D glasses lens are different, the area of the general polaroid is larger than that of the 3D glasses lens, and after the polaroid is attached to the 3D glasses lens, the redundant polaroids need to be cut off according to the shape of the 3D glasses lens. When the polaroid is cut, laser can be used for cutting, and when the polaroid is cut, the second adsorption component 3 can drive the part of the polaroid needing to be cut to move towards the direction far away from the laser.

In one embodiment, the 3D glasses lens may be located between the first adsorption component 2 and the polarizer, and the first adsorption component 2 may be adsorbed at the center of the 3D glasses lens, and the second adsorption component 3 may be adsorbed at one end of the polarizer far from the 3D glasses lens. When the outline along the 3D lens carries out laser cutting to the polaroid, second adsorption component 3 can adsorb the polaroid and keep away from the one end of 3D lens and remove along Z axle negative direction gradually, and along with the increase of laser cutting number of turns, the cutting way on the polaroid outwards expands gradually, avoids piling up too much dust granule in the cutting way to promote cutting efficiency.

In another embodiment, the polarizer may be located between the first adsorption component 2 and the 3D glasses lens, and the first adsorption component 2 may be adsorbed at the center of the polarizer, and the second adsorption component 3 may be adsorbed at one end of the polarizer away from the 3D glasses lens. When carrying out laser cutting along the outline of 3D lens to the polaroid, second adsorption component 3 can adsorb the polaroid and keep away from the one end of 3D lens and remove along Z axle negative direction gradually, and along with the increase of laser cutting number of turns, the cutting on the polaroid says outwards expansion gradually, avoids piling up too much dust granule in the cutting to promote cutting efficiency.

Fix product 7 or the material 8 of treating the cutting through first adsorption component 2, adsorb the part that the material 8 needs to amputate through second adsorption component 3 to in-process cutting material 8, second adsorption component 3 stimulates this part gradually and moves along first direction, makes during the cutting, and the cutting way on 8 surfaces of material outwards expands gradually, avoids preserving too much dust granule in the cutting way, ensures machining efficiency.

As shown in fig. 1, the first adsorption module 2 includes a first support bar 21 and a first adsorption plate 22, one end of the first support bar 21 is mounted on the base 1, the first adsorption plate 22 is mounted on the other end of the first support bar 21, and the first adsorption plate 22 is used for adsorbing the product 7 or the material 8.

The first suction cup 22 may be fixed on the first support bar 21, and the first support bar 21 may elevate the first suction cup 22 for processing the 3D glasses lens. The first suction cup 22 can be connected with an external vacuum generator through an air pipe, and the first suction cup 22 can be adsorbed on the surface of a 3D spectacle lens or a polaroid, so that the 3D spectacle lens or the polaroid can be fixed, and the 3D spectacle lens is prevented from being shifted in position during cutting and machining. And the adsorption and release of the first adsorption plate 22 to the 3D eyeglass or the polarizer can be achieved by controlling the vacuum generator.

As shown in fig. 1, the first suction assembly 2 further includes a supporting base 23, the supporting base 23 is connected to the first supporting rod 21, the first suction cup 22 is located in the supporting base 23, and a top surface of the first suction cup 22 is flush with a top surface of the supporting base 23.

The supporting seat 23 may be attached to the surface of the 3D glasses lens or the polarizer, and when the second adsorption assembly 3 pulls the polarizer along the negative Z-axis direction, the supporting seat 23 and the second adsorption assembly 3 may provide opposite acting forces to the polarizer. When the laser cuts the polaroid, the cutting channel gradually expands outwards, and the joint part of the polaroid and the 3D glasses lens and the position of the 3D glasses lens relative to the supporting seat 23 are not changed.

As shown in fig. 1, 4 and 5, the processing jig further includes a driving mechanism 4, the driving mechanism 4 is mounted on the base 1, the driving mechanism 4 is in driving connection with the second adsorption component 3, and the driving mechanism 4 is adapted to drive the second adsorption component 3 to move along the first direction.

The number of the driving mechanisms 4 can be one, two, three, four, etc., and the driving mechanisms 4 can be air cylinders which are installed on the base 1 and can comprise cylinder bodies and piston rods which can extend or retract relative to the cylinder bodies. Before the polaroid is subjected to laser cutting, the piston rod can extend out of the cylinder body, and the second adsorption component 3 connected with the piston rod is attached to the lower surface of the polaroid. When the polaroid is subjected to laser cutting, the piston rod can gradually retract into the cylinder body along with the increase of the laser cutting depth and the number of cutting turns. Meanwhile, the second adsorption component 3 connected with the second adsorption component drives the outer ring polaroid to gradually move downwards until the laser cuts off the polaroid completely, so that the part, which is not needed by the polaroid, is separated from the 3D spectacle lens.

As shown in fig. 1, 4 and 5, the processing jig further includes a connecting member 5, the driving mechanism 4 is in driving connection with the connecting member 5, the driving mechanism 4 is adapted to drive the connecting member 5 to move along the first direction, the second suction assembly 3 is movably mounted on the connecting member 5, and a distance between the second suction assembly 3 and the first suction assembly 2 is adjustable.

The number of links 5 may be two and the number of links 5 may match the number of drive mechanisms 4. For 3D spectacle lenses of different sizes, the distance of the second suction module 3 relative to the first suction module 2 needs to be adjusted, so that adaptation to 3D spectacle lenses of different sizes can be achieved.

For example, for a large-sized 3D spectacle lens, the size of the polarizer material 8 required correspondingly is also large, so that the second adsorption assembly 3 needs to be moved away from the first adsorption assembly 2, so that the second adsorption assembly 3 can adsorb the portion of the polarizer to be cut; for the two pairs of 3D glasses with smaller size, the size of the polarizer material 8 required by the glasses is also smaller, so that the second absorption member 3 needs to be moved toward the first absorption member 2, so that the second absorption member 3 can absorb the portion of the polarizer to be cut.

As shown in fig. 1, 4 and 5, the processing jig further includes an adjusting device 6, the driving mechanism 4 is in driving connection with the adjusting device 6, the adjusting device 6 is connected with the connecting member 5, and the adjusting device 6 is used for adjusting the top surface of the second adsorption component 3 to be attached to the surface of the material 8.

Adjusting device 6 can be the micrometer, and its precision is 0.01mm, to the 3D lens of different thickness, need through the micrometer accurately with second adsorption component 3 upper surface adjust to with the 3D lens upper surface or the 8 lower surfaces of material position that flush mutually. From this, can realize the adaptation to the 3D lens of different thickness for second adsorption component 3 carries out good absorption, the going on of the later stage manufacturing procedure of being convenient for to material 8.

As shown in fig. 1, 4 and 5, the second adsorption component 3 further includes a second support rod 31 and a second suction cup 32, the second support rod 31 is movably mounted on the connecting member 5, a through hole 311 is formed in the second support rod 31, the second suction cup 32 is connected with one end of the through hole 311, the other end of the through hole 311 is suitable for being connected with an external vacuum generator, and the second suction cup 32 is used for adsorbing the material 8.

The second suction cup 32 may be fixed on the second support rod 31, and the second suction cup 32 may adsorb the polarizer, so that when the laser cutting machining is performed, in the process that the second support rod 31 and the second suction cup 32 move along the Z-axis negative direction, the second suction cup 32 pulls the polarizer adsorbed by the second suction cup downward. And the absorption and release of the polarizer by the second suction cup 32 can be realized by controlling the vacuum generator.

As shown in fig. 1, 4 and 5, the processing jig further includes a fastener, a waist-shaped hole 51 is formed on the connecting member 5, and the fastener is adapted to penetrate through the waist-shaped hole 51 and is connected to the second support rod 31.

The fastener can be a bolt, the waist-shaped holes 51 can be arranged at an included angle with the X-axis direction or the Y-axis direction in the figure, two waist-shaped holes 51 can be formed in one connecting piece 5, the two waist-shaped holes 51 are arranged in an axisymmetric manner, and the second support rod 31 can be fixed on the connecting piece 5 through the bolt. One end of the second support rod 31, which is far away from the 3D glasses lens, may be provided with a threaded hole, and a bolt may be inserted into the waist-shaped hole 51 from the lower side of the waist-shaped hole 51 of the connecting member 5 and screwed into the threaded hole of the second support rod 31.

As shown in fig. 1 and 2, the number of the second adsorption assemblies 3 is four, and four second adsorption assemblies 3 are arranged in a circumferential array along the first adsorption assembly 2.

The shape of polaroid can be the square, and every second adsorption component 3 can adsorb an angle of polaroid, when carrying out laser cutting to this polaroid, four angles of this polaroid lapse of pulling are respectively with four second adsorption component 3 to this outwards expands the cutting way on the polaroid gradually, avoids cutting the interior dust of way to pile up, ensures laser cutting efficiency.

Another embodiment of the utility model provides a laser beam machining equipment, include as above processing tool. The laser processing equipment has the same beneficial effects as the processing jig, and the description is omitted.

Although the present application has been disclosed above, the scope of protection of the present application is not limited thereto. Those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present application, and such changes and modifications will fall within the scope of the present invention.

Claims (10)

1. A processing jig is characterized by comprising:

a base;

a first adsorbent assembly connected to the base, the first adsorbent assembly being for adsorbing a product or material;

the second adsorption component is connected with the base and used for adsorbing the part of the material to be cut off, the material is attached to the product, and the second adsorption component is suitable for driving the material to move along the first direction.

2. The processing jig of claim 1, wherein the first adsorption component comprises a first support rod and a first suction cup, one end of the first support rod is mounted on the base, the first suction cup is mounted at the other end of the first support rod, and the first suction cup is used for adsorbing the product or the material.

3. The processing fixture of claim 2, wherein the first suction assembly further comprises a support base connected to the first support rod, the first suction cup is located in the support base, and a top surface of the first suction cup is flush with a top surface of the support base.

4. The processing jig of claim 1, further comprising a driving mechanism, wherein the driving mechanism is mounted on the base, the driving mechanism is in driving connection with the second adsorption assembly, and the driving mechanism is adapted to drive the second adsorption assembly to move along the first direction.

5. The processing jig of claim 4, further comprising a connecting member, wherein the driving mechanism is in driving connection with the connecting member, the driving mechanism is suitable for driving the connecting member to move along the first direction, the second adsorption assembly is movably mounted on the connecting member, and the distance between the second adsorption assembly and the first adsorption assembly is adjustable.

6. The processing jig according to claim 5, further comprising an adjusting device, wherein the driving mechanism is in driving connection with the adjusting device, the adjusting device is connected with the connecting piece, and the adjusting device is used for adjusting the top surface of the second adsorption component to be attached to the surface of the material.

7. The processing jig of claim 5, wherein the second adsorption component further comprises a second support rod and a second suction cup, the second support rod is movably mounted on the connecting member, a through hole is formed in the second support rod, the second suction cup is connected with one end of the through hole, the other end of the through hole is suitable for being connected with an external vacuum generator, and the second suction cup is used for adsorbing the material.

8. The processing jig of claim 7, further comprising a fastener, wherein the connecting member is provided with a waist-shaped hole, and the fastener is suitable for being inserted into the waist-shaped hole and connected with the second support rod.

9. The processing jig according to claim 1, wherein the number of the second suction assemblies is four, and four second suction assemblies are arranged in a circumferential array along the first suction assembly.

10. A laser processing apparatus comprising the processing jig according to any one of claims 1 to 9.

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