Chamfering device and production line
By designing the base frame, conveying section, first chamfering assembly, and second chamfering assembly of the chamfering device, multi-directional chamfering of glass holes is achieved, solving the problem of low chamfering efficiency in the prior art, improving processing efficiency, and saving costs and space.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGXI NANBO NEW ENERGY MATERIAL TECH CO LTD
- Filing Date
- 2025-06-12
- Publication Date
- 2026-07-03
AI Technical Summary
In existing technologies, the chamfering efficiency of glass holes is low, and only one-way chamfering can be performed at a time, resulting in insufficient processing efficiency.
Design a chamfering device, comprising a base frame, a conveying unit, a first chamfering component, and a second chamfering component. The first and second chamfering components are arranged in different directions, and can simultaneously chamfer multiple holes on the glass. The conveying unit moves the glass along a first direction to change its placement position, thereby achieving both horizontal and vertical chamfering.
It improves the multi-directional processing capability of the chamfering device, saves the cost of installing multiple chamfering devices, reduces the space occupied, and improves chamfering efficiency.
Smart Images

Figure CN224445487U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of glass processing technology, and in particular to a chamfering device and production line. Background Technology
[0002] Glass, with its advantages of high light transmittance, low reflectivity, and high compressive strength, is widely used in the photovoltaic materials field. Double-glass modules use perforated glass as their backsheet glass. The holes in the perforated glass can be used to lead to junction boxes, ground the photovoltaic glass, or for installation and fixation. To avoid weakening the mechanical strength of the glass due to the holes, the holes need to be chamfered. In existing technology, chamfering devices are used to chamfer the glass holes, but these devices can only chamfer in one direction at a time, resulting in low chamfering efficiency. Utility Model Content
[0003] The main purpose of this invention is to propose a chamfering device and production line, which aims to solve the technical problem of low chamfering efficiency of glass holes.
[0004] To achieve the above objectives, a first aspect of this utility model provides a chamfering device for chamfering multiple holes in glass, the chamfering device comprising:
[0005] A base frame is used to support the glass;
[0006] A conveying unit connected to the base frame, the conveying unit being adapted to move the glass relative to the base frame along a first direction;
[0007] A first chamfering assembly is movably connected to the base frame. The first chamfering assembly includes a first chamfering portion and a second chamfering portion arranged at intervals along the first direction. The first chamfering portion and the second chamfering portion are adapted to chamfer each of the holes respectively.
[0008] The second chamfering assembly is movably connected to the base frame. The second chamfering assembly includes a third chamfering portion and a fourth chamfering portion arranged at intervals along a second direction. The third chamfering portion and the fourth chamfering portion are adapted to chamfer each of the holes respectively. The second direction is arranged intersecting the first direction.
[0009] In some embodiments, the first chamfering assembly includes a fifth chamfering portion arranged at a distance from the first chamfering portion and the second chamfering portion. Along the first direction, the fifth chamfering portion is located on the side of the second chamfering portion opposite to the first chamfering portion, and the fifth chamfering portion is adapted to chamfer the hole in the glass.
[0010] In some embodiments, the second chamfering assembly includes a sixth chamfering portion spaced apart from the third and fourth chamfering portions. Along the second direction, the sixth chamfering portion is located on the side of the fourth chamfering portion opposite to the third chamfering portion, and the sixth chamfering portion is adapted to chamfer the hole in the glass.
[0011] In some embodiments, the chamfering device includes a first sliding portion, which includes a first slider and a first slide rail that cooperate with each other. The first slide rail is connected to the base frame, and the first slider is connected to the first chamfering portion to drive the first chamfering portion to slide along the first direction.
[0012] In some embodiments, the chamfering device includes a second sliding portion, which includes a second slider and a second slide rail that cooperate with each other. The second slide rail is connected to the base frame, and the second slider is connected to the first chamfering portion to drive the first chamfering portion to slide along the second direction.
[0013] In some embodiments, the chamfering device includes a third sliding portion, which includes a third slider and a third slide rail that cooperate with each other. The third slide rail is connected to the base frame, and the third slider is connected to the first chamfering portion to drive the first chamfering portion to slide vertically, the vertical direction being perpendicular to the first direction and the second direction.
[0014] In some embodiments, the chamfering device includes a fourth sliding portion, which includes a fourth slider and a fourth slide rail that cooperate with each other. The fourth slide rail is connected to the base frame, and the fourth slider is connected to the third chamfering portion to drive the third chamfering portion to slide along the first direction; and / or,
[0015] The chamfering device includes a fifth sliding part, which includes a fifth slider and a fifth slide rail that cooperate with each other. The fifth slide rail is connected to the base frame, and the fifth slider is connected to the third chamfering part, so as to drive the third chamfering part to slide along the second direction; and / or,
[0016] The chamfering device includes a sixth sliding part, which includes a sixth slider and a sixth slide rail that cooperate with each other. The sixth slide rail is connected to the base frame, and the sixth slider is connected to the third chamfering part to drive the third chamfering part to slide vertically. The vertical direction is perpendicular to the first direction and the second direction.
[0017] In some embodiments, the first chamfering portion includes a base, a positioning portion, and a chamfering grinding head. The positioning portion is connected to the base and is used to identify the hole. The chamfering grinding head is rotatably connected to the base and is used to abut against the hole to chamfer the hole.
[0018] In some embodiments, the conveying unit includes a plurality of rollers spaced apart along the first direction, each roller being used to carry the glass; the conveying unit further includes a driving unit for driving the rollers to rotate, so that the rollers drive the glass to move relative to the base frame along the first direction.
[0019] A second aspect of this utility model provides a production line for processing glass, the production line including a chamfering device as described in the above embodiments.
[0020] Compared with the prior art, the beneficial effects of this utility model include:
[0021] In this invention, a chamfering device is used to chamfer multiple holes on glass. The chamfering device includes a base frame, a conveying unit, a first chamfering assembly, and a second chamfering assembly. The base frame supports the glass. The conveying unit is connected to the base frame, and both the first and second chamfering assemblies are movably connected to the base frame. Existing chamfering devices can only chamfer holes in one direction at a time, resulting in low efficiency. The first chamfering assembly of this invention includes a first chamfering section and a second chamfering section spaced apart along a first direction. The first and second chamfering sections are adapted to chamfer holes respectively, meaning the first chamfering assembly can simultaneously chamfer multiple holes arranged along the first direction on the glass. The second chamfering assembly includes a third chamfering section and a fourth chamfering section spaced apart along a second direction. The third and fourth chamfering sections are adapted to chamfer holes respectively, meaning the second chamfering assembly can simultaneously chamfer multiple holes arranged along the second direction on the glass. The second direction is arranged intersecting with the first direction, and the conveying unit enables the glass to move relative to the base frame along the first direction. Therefore, this solution can change the placement position of the glass through the conveying unit, and achieve transverse and longitudinal chamfering of the glass hole without changing the glass arrangement direction. This effectively improves the multi-directional processing capability of the chamfering device, saves the cost of installing multiple chamfering devices, reduces the space occupied, and improves the processing efficiency of the chamfering device. Attached Figure Description
[0022] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.
[0023] Figure 1 This is a schematic diagram of the chamfering device according to an embodiment of the present invention; wherein, a first sliding part, a second sliding part, a third sliding part, a fourth sliding part, a fifth sliding part, and a sixth sliding part are shown;
[0024] Figure 2 This is a top view of a chamfering device according to an embodiment of the present invention; wherein, a first chamfering component and a second chamfering component are shown;
[0025] Figure 3 This is a side view of an embodiment of the present invention; wherein, the first chamfered portion, the second chamfered portion, and the sixth chamfered portion are shown;
[0026] Figure 4 This is a schematic diagram of the structure of the first chamfered portion in one embodiment of the present invention; wherein, the base, the positioning portion, and the chamfering grinding head are shown.
[0027] Figure 5 This is a schematic diagram of glass in one embodiment of the present invention; wherein, a plurality of holes are arranged at intervals along a first direction;
[0028] Figure 6 This is a schematic diagram of the glass in one embodiment of the present invention; wherein, a plurality of holes are arranged at intervals along a second direction.
[0029] Explanation of icon numbers:
[0030] Chamfering device 10;
[0031] Base frame 100; feed photoelectric sensor 110; discharge photoelectric sensor 120;
[0032] Conveyor section 200; Roller body 210;
[0033] First chamfering assembly 300; first chamfering portion 310; base 311; positioning portion 312; chamfering grinding head 313; second chamfering portion 320; fifth chamfering portion 330;
[0034] Second chamfering component 400; Third chamfering portion 410; Fourth chamfering portion 420; Sixth chamfering portion 430;
[0035] First sliding part 500; first slider 510; first slide rail 520;
[0036] Second sliding part 600; second slider 610; second slide rail 620;
[0037] Third sliding part 700; Third slider 710; Third slide rail 720;
[0038] Fourth sliding part 810; Fourth slider 811; Fourth slide rail 812;
[0039] Fifth sliding part 820; Fifth slider 821; Fifth slide rail 822;
[0040] Sixth sliding part 830; sixth slider 831; sixth slide rail 832;
[0041] Displacement component 900; Moving block 910; Track 920;
[0042] Glass 20; Hole 201;
[0043] First direction X; second direction Y; vertical Z.
[0044] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0045] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0046] The first aspect of this utility model provides a chamfering device 10, which is used to chamfer multiple holes 201 on a glass 20, effectively improving the chamfering efficiency of the glass holes. See below for reference. Figures 1 to 6 The chamfering device 10 according to an embodiment of this application will be introduced. Specifically, the chamfering device 10 includes a base frame 100, a conveying part 200, a first chamfering component 300 and a second chamfering component 400.
[0047] Reference Figure 1 and Figure 2 The base frame 100 is used to support the glass 20 and the various chamfering components. Specifically, in some embodiments, the base frame 100 may be composed of multiple horizontal beams and multiple vertical beams welded together. In other embodiments, the base frame 100 may also be composed of multiple horizontal beams and multiple vertical beams bolted or screwed together. The specific structure and arrangement of the base frame 100 may vary depending on the actual situation.
[0048] Reference Figure 1 and Figure 2 The conveying unit 200 is used to convey the glass 20. Specifically, the conveying unit 200 can be connected to the base frame 100. To facilitate description and understanding of the specific conveying direction of the glass 20, a first direction X is defined. The conveying unit 200 enables the glass 20 to move relative to the base frame 100 along the first direction X. (Refer to...) Figure 2 Orientation, the first direction X can point to the left or right.
[0049] Reference Figures 1 to 4The first chamfering assembly 300 is used to chamfer the hole 201. The first chamfering assembly 300 is movably connected to the base frame 100. Further, the first chamfering assembly 300 can be slidably connected to the base frame 100. The first chamfering assembly 300 includes a first chamfering portion 310 and a second chamfering portion 320, which are arranged at intervals along a first direction X. It can be understood that the first chamfering portion 310 and the second chamfering portion 320 can chamfer each hole 201 respectively. In some embodiments, the structure of the second chamfering portion 320 can be the same as that of the first chamfering portion 310. In other embodiments, the structure of the second chamfering portion 320 can also be different from that of the first chamfering portion 310. This application embodiment is described with the example of the first chamfering portion 310 and the second chamfering portion 320 having the same structure.
[0050] Reference Figures 1 to 4 The second chamfering assembly 400 is used to chamfer the hole 201. The second chamfering assembly 400 is movably connected to the base frame 100. Further, the second chamfering assembly 400 can be slidably connected to the base frame 100. The second chamfering assembly 400 includes a third chamfering portion 410 and a fourth chamfering portion 420. To facilitate description and understanding of the relative arrangement of the third chamfering portion 410 and the fourth chamfering portion 420, a second direction Y is defined, and the third chamfering portion 410 and the fourth chamfering portion 420 are arranged at intervals along the second direction Y. It can be understood that the third chamfering portion 410 and the fourth chamfering portion 420 can chamfer each hole 201 respectively. In some embodiments, the structure of the third chamfering portion 410 can be the same as that of the fourth chamfering portion 420. In other embodiments, the structure of the third chamfering portion 410 can also be different from that of the fourth chamfering portion 420. This application embodiment is described using the example of the third chamfering portion 410 and the fourth chamfering portion 420 having the same structure.
[0051] It should be noted that the second direction Y intersects with the first direction X. In some embodiments, the second direction Y may be perpendicular to the first direction X. In other embodiments, the second direction Y may also be at other angles that are not perpendicular to the first direction X. This application embodiment is illustrated using the example of the second direction Y being perpendicular to the first direction X, referring to... Figure 3 Orientation: The first direction, X, can point to the left or right, and the second direction, Y, can point to the front or back.
[0052] In the technical solution of this utility model, the chamfering device 10 is used to chamfer multiple holes 201 on the glass 20. The chamfering device 10 includes a base frame 100, a conveying part 200, a first chamfering assembly 300, and a second chamfering assembly 400. The base frame 100 is used to support the glass 20. The conveying part 200 is connected to the base frame 100, and both the first chamfering assembly 300 and the second chamfering assembly 400 are movably connected to the base frame 100. The existing chamfering devices can only chamfer holes in one direction at a time, resulting in low chamfering efficiency for the holes in the glass. In this solution, the first chamfering assembly 300 includes a first chamfering part 310 and a second chamfering part 320 arranged at intervals along the first direction X. The first chamfering part 310 and the second chamfering part 320 are adapted to chamfer the holes 201 respectively, that is, the first chamfering assembly 300 can simultaneously chamfer multiple holes 201 arranged along the first direction X on the glass 20. The second chamfering assembly 400 includes a third chamfering portion 410 and a fourth chamfering portion 420 arranged at intervals along the second direction Y. The third chamfering portion 410 and the fourth chamfering portion 420 are adapted to chamfer the holes 201 respectively. That is, the second chamfering assembly 400 can simultaneously chamfer multiple holes 201 arranged along the second direction Y on the glass 20. The second direction Y intersects with the first direction X, and the conveying unit 200 can move the glass 20 relative to the base frame 100 along the first direction X. Therefore, this solution can change the placement position of the glass 20 by the conveying unit 200, and achieve lateral and longitudinal chamfering of the glass holes 201 without changing the arrangement direction of the glass 20. This effectively improves the multi-directional processing capability of the chamfering device 10, saves the cost of installing multiple chamfering devices, reduces the space occupied, and improves the processing efficiency of the chamfering device 10.
[0053] Reference Figure 1 and Figure 2 In some embodiments, the first chamfering assembly 300 includes a fifth chamfered portion 330, the structure of which may be the same as that of the first chamfered portion 310. The fifth chamfered portion 330 is spaced apart from both the first chamfered portion 310 and the second chamfered portion 320. Along the first direction X, referring to... Figure 2 In terms of orientation, specifically along the left-right direction, the fifth chamfered portion 330 is located on the side of the second chamfered portion 320 opposite to the first chamfered portion 310. The fifth chamfered portion 330 is used to chamfer the holes 201 on the glass 20. In other embodiments, the first chamfering assembly 300 may be provided with a seventh chamfered portion and an eighth chamfered portion, etc., and the number of chamfered portions provided in the first chamfering assembly 300 can be determined according to the actual situation. By providing the fifth chamfered portion 330, this solution can chamfer more holes 201 arranged along the first direction X on the glass 20, further improving the chamfering efficiency of the glass holes and enhancing the multi-directional processing capability of the chamfering device 10.
[0054] Reference Figure 1 and Figure 2In some embodiments, the second chamfering assembly 400 includes a sixth chamfer portion 430, the structure of which may be the same as that of the third chamfer portion 410. The sixth chamfer portion 430 is spaced apart from the third chamfer portion 410 and the fourth chamfer portion 420. Along the second direction Y, referring to... Figure 1 In terms of orientation, specifically along the front-to-back direction, the sixth chamfered portion 430 is located on the side of the fourth chamfered portion 420 opposite to the third chamfered portion 410. The sixth chamfered portion 430 is used to chamfer the holes 201 on the glass 20. In other embodiments, the second chamfering assembly 400 may be provided with a seventh chamfered portion and an eighth chamfered portion, etc., and the number of chamfered portions provided in the second chamfering assembly 400 can be determined according to the actual situation. By providing the sixth chamfered portion 430, this solution can chamfer more holes 201 arranged along the second direction Y on the glass 20, further improving the chamfering efficiency of the glass holes and enhancing the multi-directional processing capability of the chamfering device 10.
[0055] Reference Figure 1 and Figure 2 In some embodiments, the chamfering device 10 includes a first sliding portion 500, which drives the first chamfering portion 310 to slide. Specifically, the first sliding portion 500 includes a first slider 510 and a first slide rail 520 that cooperate with each other. The first slide rail 520 can be connected to the base frame 100, and the first slider 510 can be connected to the first chamfering portion 310, that is, the first slider 510 can drive the first chamfering portion 310 to slide along the first direction X on the first slide rail 520. In other embodiments, the second chamfering portion 320 can also slide relative to the base frame 100, and the specific sliding configuration of the second chamfering portion 320 can be the same as that of the first chamfering portion 310. It should be noted that in some embodiments, the first slider 510 can be directly driven to slide relative to the first slide rail 520. In other embodiments, the first slide rail 520 is a lead screw, and the first slider 510 can be moved by driving the lead screw to rotate. The first chamfered part 310 of this solution can be adjusted in position by the first sliding part 500 to adapt to the actual working conditions of the glass 20 and meet the processing requirements of glass 20 of various sizes.
[0056] Reference Figure 1 and Figure 2In some embodiments, the chamfering device 10 includes a second sliding portion 600, which drives the first chamfering portion 310 to slide. Specifically, the second sliding portion 600 includes a second slider 610 and a second slide rail 620 that cooperate with each other. The second slide rail 620 can be connected to the base frame 100, and the second slider 610 can be connected to the first chamfering portion 310, that is, the second slider 610 can drive the first chamfering portion 310 to slide along the second direction Y on the second slide rail 620. In other embodiments, the second chamfering portion 320 can also slide relative to the base frame 100, and the specific sliding configuration of the second chamfering portion 320 can be the same as that of the first chamfering portion 310. It should be noted that in some embodiments, the second slider 610 can be directly driven to slide relative to the second slide rail 620. In other embodiments, the second slide rail 620 is a lead screw, and the second slider 610 can be moved by driving the lead screw to rotate. The first chamfered part 310 of this solution can be adjusted in position by the fifth sliding part 820 to adapt to the actual working conditions of the glass 20 and meet the processing requirements of glass 20 of various sizes.
[0057] Reference Figure 1 and Figure 2 In some embodiments, the chamfering device 10 includes a third sliding portion 700, which drives the first chamfering portion 310 to slide. Specifically, the third sliding portion 700 includes a third slider 710 and a third slide rail 720 that cooperate with each other. The third slide rail 720 can be connected to the base frame 100, and the third slider 710 can be connected to the first chamfering portion 310, that is, the third slider 710 can drive the first chamfering portion 310 to slide along the vertical direction Z on the third slide rail 720. The vertical direction Z is perpendicular to the first direction X and the second direction Y. In other embodiments, the second chamfering portion 320 can also slide relative to the base frame 100, and the specific sliding configuration of the second chamfering portion 320 can be the same as that of the first chamfering portion 310. It should be noted that in some embodiments, the third slider 710 can be directly driven to slide relative to the third slide rail 720. In other embodiments, the third slide rail 720 is a lead screw, and the third slider 710 can be moved by driving the lead screw to rotate. The first chamfered part 310 of this solution can be adjusted in position by the third sliding part 700 to adapt to the actual working conditions of the glass 20 and meet the processing requirements of glass 20 of various sizes.
[0058] Reference Figure 1 and Figure 2In some embodiments, the chamfering device 10 includes a fourth sliding portion 810, which drives the third chamfering portion 410 to slide. Specifically, the fourth sliding portion 810 includes a fourth slider 811 and a fourth slide rail 812 that cooperate with each other. The fourth slide rail 812 can be connected to the base frame 100, and the fourth slider 811 can be connected to the third chamfering portion 410, that is, the fourth slider 811 can drive the third chamfering portion 410 to slide along the first direction X on the fourth slide rail 812. In other embodiments, the fourth chamfering portion 420 can also slide relative to the base frame 100, and the specific sliding configuration of the fourth chamfering portion 420 can be the same as that of the third chamfering portion 410. It should be noted that in some embodiments, the fourth slider 811 can be directly driven to slide relative to the fourth slide rail 812. In other embodiments, the fourth slide rail 812 is a lead screw, which can be driven to rotate to drive the fourth slider 811 to move. The third chamfered part 410 of this solution can be adjusted in position by the fourth sliding part 810 to adapt to the actual working conditions of the glass 20 and meet the processing requirements of glass 20 of various sizes.
[0059] Reference Figure 1 and Figure 2 In some embodiments, the chamfering device 10 includes a fifth sliding portion 820, which drives the third chamfering portion 410 to slide. Specifically, the fifth sliding portion 820 includes a fifth slider 821 and a fifth slide rail 822 that cooperate with each other. The fifth slide rail 822 can be connected to the base frame 100, and the fifth slider 821 can be connected to the third chamfering portion 410, that is, the fifth slider 821 can drive the third chamfering portion 410 to slide along the second direction Y on the fifth slide rail 822. In other embodiments, the fourth chamfering portion 420 can also slide relative to the base frame 100, and the specific sliding configuration of the fourth chamfering portion 420 can be the same as that of the third chamfering portion 410. It should be noted that in some embodiments, the fifth slider 821 can be directly driven to slide relative to the fifth slide rail 822. In other embodiments, the fifth slide rail 822 is a lead screw, which can be driven to rotate to drive the fifth slider 821 to move. The third chamfered part 410 of this solution can be adjusted in position by the fifth sliding part 820 to adapt to the actual working conditions of the glass 20 and meet the processing requirements of glass 20 of various sizes.
[0060] Reference Figure 1 and Figure 2In some embodiments, the chamfering device 10 includes a sixth sliding portion 830, which drives the third chamfering portion 410 to slide. Specifically, the sixth sliding portion 830 includes a sixth slider 831 and a sixth slide rail 832 that cooperate with each other. The sixth slide rail 832 can be connected to the base frame 100, and the sixth slider 831 can be connected to the third chamfering portion 410, that is, the sixth slider 831 can drive the third chamfering portion 410 to slide along the vertical direction Z on the sixth slide rail 832. The vertical direction Z is perpendicular to the first direction X and the second direction Y. In other embodiments, the fourth chamfering portion 420 can also slide relative to the base frame 100, and the specific sliding configuration of the fourth chamfering portion 420 can be the same as that of the third chamfering portion 410. It should be noted that in some embodiments, the sixth slider 831 can be directly driven to slide relative to the sixth slide rail 832. In other embodiments, the sixth slide rail 832 is a lead screw, and the sixth slider 831 can be moved by driving the lead screw to rotate. The third chamfered part 410 of this solution can be adjusted in position by the sixth sliding part 830 to adapt to the actual working conditions of the glass 20 and meet the processing requirements of glass 20 of various sizes.
[0061] Reference Figure 4 The specific configuration of the first chamfering part 310 is described below. In some embodiments, the first chamfering part 310 includes a base 311, a positioning part 312, and a chamfering grinding head 313. The positioning part 312 is connected to the base 311 and is used to identify the hole 201 to determine the processing position, thus ensuring chamfering accuracy. The chamfering grinding head 313 is rotatably connected to the base 311 and is used to abut against the hole 201 to chamfer the hole 201. It can be understood that the chamfering grinding head 313 can be provided with multiple layers of groove cutting edges with specific inclination angles. The chamfering grinding head 313 can be connected to the chamfering spindle rotor, and grinds the edge of the glass hole by high-speed rotation. The hole chamfering operation is achieved by moving relative to the base frame 100 along the first direction X, the second direction Y, and the vertical direction Z. It should be noted that the first chamfering part 310 can be equipped with a high-speed water-cooled motor, which can drive the chamfering grinding head 313 to rotate at high speed to achieve the chamfering operation.
[0062] Reference Figure 1 and Figure 2 In some embodiments, the conveying unit 200 includes a plurality of rollers 210 arranged at intervals along a first direction X, each roller 210 being used to carry glass 20. It should be noted that the rollers 210 can be fixed to the base frame 100 by bearings. In other embodiments, the conveying unit 200 further includes a driving unit for driving the rollers 210 to rotate, so that the rollers 210 drive the glass 20 to move relative to the base frame 100 along the first direction X. Specifically, the driving unit can be driven by a motor. The conveying unit 200 of this solution can convey the glass 20 to a designated position, ensuring the stability and reliability of the chamfering of the glass holes.
[0063] Reference Figure 3 In some embodiments, the first crossbeam of the base frame 100 may be equipped with a feed photocell 110, which can be a photoelectric sensor. The feed photocell 110 can be mounted on the base frame 100 via a movable guide rail. The feed photocell 110 is used to sense the processed product (glass 20) and can provide a signal to the conveying unit 200. Further, a groove and a groove slider can be provided on one side of the movable guide rail of the feed photocell 110. The slider can be connected to the feed photocell 110, and the slider can move laterally to change the position of the photocell. In other embodiments, the last crossbeam of the base frame 100 may be equipped with a discharge photocell 120, which can be a photoelectric sensor. The discharge photocell 120 can sense the processed product (glass 20) and provide a signal to the conveying unit 200. It should be noted that a groove and a groove slider can be set on one side of the moving guide rail of the discharge photoelectric sensor 120. The slider is connected to the discharge photoelectric sensor 120 to change the position of the photoelectric sensor. The slider can also be connected to the first-stage deceleration photoelectric sensor, the second-stage deceleration photoelectric sensor and the stop photoelectric sensor, so that the processing position of the processed product can be precisely adjusted to adapt to different processing specifications.
[0064] Reference Figure 1 In some embodiments, the chamfering device 10 includes a displacement component 900, which drives the overall structure of the first chamfered portion 310 to move. The displacement component 900 includes a movable block 910 and a track 920. The track 920 can be disposed on the bottom side of the base frame 100, and the sliding block can be connected to the support platform of the first chamfered portion 310 to drive the overall structure of the first chamfered portion 310 to move along the first direction X. In other embodiments, multiple displacement components 900 can be provided, and the displacement components 900 can also drive the second chamfered portion 320 to move along the first direction X. The displacement component 900 of this solution can further expand the movement range of the first chamfered portion 310, so that the chamfering device 10 can adapt to various chamfering conditions and meet the processing needs of glass 20 of various sizes.
[0065] In a specific embodiment of this application, reference is made to Figure 5 The three holes 201 on the glass 20, spaced apart along the first direction X, can be chamfered by the first chamfered portion 310, the second chamfered portion 320, and the fifth chamfered portion 330. (Refer to...) Figure 6 The three holes 201 on the glass 20, which are spaced apart along the second direction Y, can be chamfered by the third chamfered portion 410, the fourth chamfered portion 420 and the sixth chamfered portion 430.
[0066] A second aspect of this utility model provides a production line including the chamfering device 10 described in the above embodiment. This solution can change the placement position of the glass 20 via the conveyor 200, achieving both lateral and longitudinal chamfering of the glass hole 201 without altering the orientation of the glass 20. This effectively enhances the multi-directional processing capability of the chamfering device 10, saves the cost of installing multiple chamfering devices, reduces space occupation, and improves the processing efficiency of the chamfering device 10.
[0067] It should be noted that if the embodiments of this utility model involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indicators will also change accordingly.
[0068] Furthermore, if the embodiments of this utility model involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the use of "and / or," "and / or," or "and / or" throughout the text implies three parallel solutions. For example, "A and / or B" includes solution A, solution B, or a solution where A and B are simultaneously satisfied. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed by this utility model.
[0069] The above are merely preferred embodiments of this utility model and do not limit the patent scope of this utility model. Any equivalent structural transformations made based on the inventive concept of this utility model and the contents of this utility model specification and drawings, or direct / indirect applications in other related technical fields, are included within the patent protection scope of this utility model.
Claims
1. A chamfering device for chamfering multiple holes in glass, characterized in that, The chamfering device includes: A base frame is used to support the glass; A conveying unit connected to the base frame, the conveying unit being adapted to move the glass relative to the base frame along a first direction; A first chamfering assembly is movably connected to the base frame. The first chamfering assembly includes a first chamfering portion and a second chamfering portion arranged at intervals along the first direction. The first chamfering portion and the second chamfering portion are adapted to chamfer each of the holes respectively. The second chamfering assembly is movably connected to the base frame. The second chamfering assembly includes a third chamfering portion and a fourth chamfering portion arranged at intervals along a second direction. The third chamfering portion and the fourth chamfering portion are adapted to chamfer each of the holes respectively. The second direction is arranged intersecting the first direction.
2. The chamfering device as described in claim 1, characterized in that, The first chamfering assembly includes a fifth chamfering portion spaced apart from the first chamfering portion and the second chamfering portion. Along the first direction, the fifth chamfering portion is located on the side of the second chamfering portion opposite to the first chamfering portion. The fifth chamfering portion is adapted to chamfer the hole in the glass.
3. The chamfering device as described in claim 1, characterized in that, The second chamfering assembly includes a sixth chamfering portion spaced apart from the third and fourth chamfering portions. Along the second direction, the sixth chamfering portion is located on the side of the fourth chamfering portion opposite to the third chamfering portion. The sixth chamfering portion is adapted to chamfer the hole in the glass.
4. The chamfering device as described in claim 1, characterized in that, The chamfering device includes a first sliding part, which includes a first slider and a first slide rail that cooperate with each other. The first slide rail is connected to the base frame, and the first slider is connected to the first chamfering part, so as to drive the first chamfering part to slide along the first direction.
5. The chamfering device as described in claim 1, characterized in that, The chamfering device includes a second sliding part, which includes a second slider and a second slide rail that cooperate with each other. The second slide rail is connected to the base frame, and the second slider is connected to the first chamfering part, so as to drive the first chamfering part to slide along the second direction.
6. The chamfering device as described in claim 1, characterized in that, The chamfering device includes a third sliding part, which includes a third slider and a third slide rail that cooperate with each other. The third slide rail is connected to the base frame, and the third slider is connected to the first chamfering part to drive the first chamfering part to slide vertically. The vertical direction is perpendicular to the first direction and the second direction.
7. The chamfering device as described in claim 1, characterized in that, The chamfering device includes a fourth sliding part, which includes a fourth slider and a fourth slide rail that cooperate with each other. The fourth slide rail is connected to the base frame, and the fourth slider is connected to the third chamfering part, so as to drive the third chamfering part to slide along the first direction. And / or, The chamfering device includes a fifth sliding part, which includes a fifth slider and a fifth slide rail that cooperate with each other. The fifth slide rail is connected to the base frame, and the fifth slider is connected to the third chamfering part, so as to drive the third chamfering part to slide along the second direction. And / or, The chamfering device includes a sixth sliding part, which includes a sixth slider and a sixth slide rail that cooperate with each other. The sixth slide rail is connected to the base frame, and the sixth slider is connected to the third chamfering part to drive the third chamfering part to slide vertically. The vertical direction is perpendicular to the first direction and the second direction.
8. The chamfering device as described in claim 1, characterized in that, The first chamfering part includes a base, a positioning part, and a chamfering grinding head. The positioning part is connected to the base and is used to identify the hole. The chamfering grinding head is rotatably connected to the base and is used to abut against the hole to chamfer the hole.
9. The chamfering device as described in claim 1, characterized in that, The conveying section includes a plurality of rollers arranged at intervals along the first direction, each roller being used to carry the glass; the conveying section also includes a driving section for driving the rollers to rotate, so that the rollers drive the glass to move relative to the base frame along the first direction.
10. A production line for processing glass, characterized in that, Includes the chamfering device as described in any one of claims 1-9.