CN109304653B

CN109304653B - Glass edging device

Info

Publication number: CN109304653B
Application number: CN201811318626.1A
Authority: CN
Inventors: 宋宇; 杨清华; 熊建; 江维; 江亮; 刘泽利
Original assignee: Xianning CSG Energy Saving Glass Co Ltd
Current assignee: Xianning CSG Energy Saving Glass Co Ltd
Priority date: 2018-11-07
Filing date: 2018-11-07
Publication date: 2023-12-22
Anticipated expiration: 2038-11-07
Also published as: CN109304653A

Abstract

The invention provides a glass edging device, and belongs to the technical field of glass production equipment. The edge grinding device comprises a supporting roller and a pressing roller positioned above the supporting roller, wherein the supporting roller is rotationally connected between two longitudinal beams through a supporting shaft, the pressing roller is rotationally connected between the two longitudinal beams through a pressing shaft, and the end part of the pressing shaft positioned on the same side and the end part of the supporting shaft synchronously and reversely rotate through a transmission structure; the fourth bevel gear is connected with the fifth bevel gear through a short shaft, an edging wheel is fixedly arranged on the short shaft, and an edging groove is formed in the peripheral surface of the edging wheel. The invention has the advantages of improving the edging quality and the like.

Description

Glass edging device

Technical Field

The invention belongs to the technical field of glass production equipment, and relates to a glass edging device.

Background

With the increasing development of the glass decoration industry, glass ornaments are various in variety, processed shapes are various, and glass processing equipment is various. Wherein, glass edging is an indispensable procedure of cutting glass.

In the actual production process, the existing glass edging equipment has the following defects:

1. the requirements on the running stability of the glass in the edging process are high, so that irregular edging and even glass breakage are easily caused;

2. the grinding wheel causes larger stress on the glass, so that the glass is deviated or tilted, and the like, especially the glass with smaller thickness;

3. glass powder and slag formed in the edging process are easy to adhere to the surface of glass, and under the extrusion action of the supporting roller and the glass, the glass powder and slag are easy to cause scraping and abrasion of the surface of the glass, so that defective products are caused;

4. the single-size edging wheel is adopted for one-time edging forming, and the removed edge allowance is larger, so that the edge is easy to be partially burst, partially burr and the like in the edging process.

Disclosure of Invention

The invention aims to solve the problems of the prior art and provides a glass edging device, which aims to solve the technical problems of improving the running stability of glass and improving the edging quality.

The aim of the invention can be achieved by the following technical scheme: the glass edging device comprises two longitudinal beams which are distributed in parallel, and is characterized by comprising a supporting roller and a compression roller positioned above the supporting roller, wherein the supporting roller is rotationally connected between the two longitudinal beams through a supporting shaft, the compression roller is rotationally connected between the two longitudinal beams through a compression shaft, and the end part of the compression shaft positioned on the same side and the end part of the supporting shaft synchronously and reversely rotate through a transmission structure;

the transmission structure comprises a first bevel gear, a second bevel gear, a third bevel gear, a fourth bevel gear, a fifth bevel gear, a sixth bevel gear, a seventh bevel gear and an eighth bevel gear, wherein the first bevel gear is fixedly connected with one end of a supporting shaft, the eighth bevel gear is fixedly connected with one end of a compacting shaft, a first installation cavity is formed in a longitudinal beam, the first bevel gear, the second bevel gear, the third bevel gear and the fourth bevel gear are all rotationally connected in the first installation cavity, the first bevel gear simultaneously meshes with the second bevel gear and the fourth bevel gear, the third bevel gear simultaneously meshes with the second bevel gear and the fourth bevel gear, the rotation axis of the first bevel gear and the rotation axis of the third bevel gear are positioned on the same straight line, and the rotation axis of the second bevel gear and the rotation axis of the fourth bevel gear are positioned on the same straight line;

the upper part of the longitudinal beam is fixedly provided with an installation box, a second installation cavity is formed in the installation box, the fifth bevel gear, the sixth bevel gear, the seventh bevel gear and the eighth bevel gear are all rotationally connected in the second installation cavity, the eighth bevel gear is simultaneously meshed with the fifth bevel gear and the seventh bevel gear, the sixth bevel gear is simultaneously meshed with the fifth bevel gear and the seventh bevel gear, the rotation axis of the sixth bevel gear and the rotation axis of the eighth bevel gear are positioned on the same straight line, and the rotation axis of the fifth bevel gear and the rotation axis of the seventh bevel gear are positioned on the same straight line;

the fourth bevel gear is connected with the fifth bevel gear through a short shaft, an edging wheel is fixedly arranged on the short shaft, and an edging groove is formed in the peripheral surface of the edging wheel.

The first bevel gear, the second bevel gear, the third bevel gear and the fourth bevel gear are used for positioning the support shaft longitudinally and transversely, so that the support shaft rotates stably, and the fifth bevel gear, the sixth bevel gear, the seventh bevel gear and the eighth bevel gear are used for enabling the pressing shaft to rotate stably.

In the rotation process of the driving motor, the rotation directions of the pinch roller and the supporting roller are opposite, so that glass to be edged can stably run between longitudinal beams, and the rotation linear speed of the grinding wheel and the rotation linear speed of the supporting roller are different due to the fact that the diameter of the grinding groove of the grinding wheel is smaller than or larger than that of the supporting roller, so that the rotation speed of the grinding wheel is inconsistent with the running speed of the glass due to the fact that the rotation linear speed of the grinding wheel and the rotation linear speed of the supporting roller are different, and the edge of the glass is ground. The benefits of this arrangement are: the abrasion speed of the grinding wheel to the glass can be reduced, so that the abrasion is homogenized, thinned and gradually made, the edge grinding of the glass is gradually finished, and the cracking and the burr formation are avoided.

The edging production line adopts the pinch roller and the supporting roller to simultaneously position the upper surface and the lower surface of the glass, improves the running stability of the glass, and avoids the deviation, the shaking and the blocking of the stress formed in the polishing process to the running of the glass.

Through the reasonable setting of transmission structure, make the operation of pinch roller and backing roll synchronous, and the running direction is opposite, makes there is little relative motion between pinch roller and backing roll and the glass, prevents pinch roller and backing roll to the wearing and tearing that the glass surface caused, even at edging in-process partial glass piece and glass powder remain on glass's upper surface, also can not cause serious wearing and tearing to glass.

In the glass edging device, a strip-shaped buffer cavity is formed in the compaction shaft, the compaction roller comprises a plurality of compression rods, the compression rods are circumferentially and uniformly distributed on the outer side of the compaction shaft, the compression rods are connected with the compaction shaft through a plurality of connecting components, the connecting components comprise a pull rod, a sleeve and a connecting spring, the outer end of the pull rod is connected with the compression rods, the inner ends of the pull rod are inserted into the sleeve, the inner ends of the sleeve are fixedly connected with the outer wall of the compaction shaft, the two ends of the connecting spring are respectively connected with the inner ends of the pull rod and the inner wall of the sleeve, the sleeve is communicated with the buffer cavity, the buffer cavity is communicated with the air outlet end of an air pump, and the connecting components further comprise an overflow hole, the overflow hole penetrates through the outer wall surfaces of the pull rod and the compression rods, and the overflow hole is communicated with the inner cavity of the sleeve.

In order to remove glass powder and glass slag possibly existing on the upper surface of the glass, overflow holes are arranged, and under the action of an air pump, strong air flow impacts the surface of the glass, so that the glass slag and the glass powder possibly existing are far away from the part of the glass which is being acted by the compaction roller, and the surface of the glass is protected.

In order to improve the pressing force on the glass, the glass is enabled not to slip or relax under the action of the pressing roller and the supporting roller, the pressing roller adopts a structure of a plurality of pressing rods which can stretch and retract, and the pressing rods have outward tension under the action of air pressure, so that the pressing rods press the surface of the glass.

Through the steady voltage air feed of air pump, then discharge through the overflow aperture, can be quick dispel the heat to glass surface, especially glass limit portion avoids thermal expansion to cause glass size to take place slightly to change, makes edging precision reduce.

In the glass edging device, the supporting roller and the compression bar are made of hard rubber plastic materials.

In the glass edging device, in the whole production line, each first bevel gear, each second bevel gear, each third bevel gear, each fourth bevel gear, each fifth bevel gear, each sixth bevel gear, each seventh bevel gear and each eighth bevel gear are gears with the same specification.

The bevel gears are distributed in the same specification and in a regular manner, so that the transmission among all parts is stable, the operation is stable, the reliability is higher, and the synchronization and the same speed of the compaction roller and the supporting roller are ensured.

Drawings

FIG. 1 is a schematic view of a glass edging line.

Fig. 2 is a cross-sectional view of a glass edging device.

Fig. 3 is a schematic structural view of a pneumatic pinch roller in a glass edging device.

Fig. 4 is an enlarged view of a portion a in fig. 2.

In the figure, 1, a longitudinal beam; 11. a first mounting cavity; 12. a mounting box; 13. a second mounting cavity; 2. a column; 3. a support roller; 31. a support shaft; 4. a pinch roller; 41. a compression shaft; 42. a buffer chamber; 43. a compression bar; 44. a pull rod; 45. a sleeve; 46. a connecting spring; 47. an air pump; 48. an overflow aperture; 51. a first bevel gear; 52. a second bevel gear; 53. a third bevel gear; 54. a fourth bevel gear; 55. a fifth bevel gear; 56. a sixth bevel gear; 57. a seventh bevel gear; 58. an eighth bevel gear; 59. a short shaft; 6. edging wheel; 61. edging grooves; 7. and driving the motor.

Detailed Description

The following are specific embodiments of the present invention and the technical solutions of the present invention will be further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1 and 2, the edging production line comprises two parallel longitudinal beams 1, wherein the longitudinal beams 1 are fixedly connected with the ground through a plurality of upright posts 2, and a plurality of edging devices capable of guiding and edging glass are arranged between the two longitudinal beams 1 at equal intervals;

the edging device comprises a supporting roller 3 and a pressing roller 4 positioned above the supporting roller 3, wherein the supporting roller 3 is rotationally connected between two longitudinal beams 1 through a supporting shaft 31, the pressing roller 4 is rotationally connected between the two longitudinal beams 1 through a pressing shaft 41, and the end part of the pressing shaft 41 positioned on the same side and the end part of the supporting shaft 31 synchronously and reversely rotate through a transmission structure;

the transmission structure comprises a first bevel gear 51, a second bevel gear 52, a third bevel gear 53, a fourth bevel gear 54, a fifth bevel gear 55, a sixth bevel gear 56, a seventh bevel gear 57 and an eighth bevel gear 58, wherein the first bevel gear 51 is fixedly connected with one end of the supporting shaft 31, the eighth bevel gear 58 is fixedly connected with one end of the compacting shaft 41, a first installation cavity 11 is formed in the longitudinal beam 1, the first bevel gear 51, the second bevel gear 52, the third bevel gear 53 and the fourth bevel gear 54 are all rotationally connected in the first installation cavity 11, the first bevel gear 51 simultaneously meshes with the second bevel gear 52 and the fourth bevel gear 54, the third bevel gear 53 simultaneously meshes with the second bevel gear 52 and the fourth bevel gear 54, the rotation axis of the first bevel gear 51 and the rotation axis of the third bevel gear 53 are positioned on the same straight line, and the rotation axis of the second bevel gear 52 and the rotation axis of the fourth bevel gear 54 are positioned on the same straight line;

a mounting box 12 is fixedly arranged above the longitudinal beam 1, a second mounting cavity 13 is formed in the mounting box 12, a fifth bevel gear 55, a sixth bevel gear 56, a seventh bevel gear 57 and an eighth bevel gear 58 are all rotationally connected in the second mounting cavity 13, the eighth bevel gear 58 is simultaneously meshed with the fifth bevel gear 55 and the seventh bevel gear 57, the sixth bevel gear 56 is simultaneously meshed with the fifth bevel gear 55 and the seventh bevel gear 57, the rotation axis of the sixth bevel gear 56 and the rotation axis of the eighth bevel gear 58 are positioned on the same straight line, and the rotation axis of the fifth bevel gear 55 and the rotation axis of the seventh bevel gear 57 are positioned on the same straight line;

the fourth bevel gear 54 and the fifth bevel gear 55 are connected through a short shaft 59, an edging wheel 6 is fixedly arranged on the short shaft 59, and an edging groove 61 is formed in the peripheral surface of the edging wheel 6;

one bevel gear II in each edging device is connected with a driving motor 7, each driving motor 7 is connected with a frequency converter, and each frequency converter is connected with a controller after being connected in parallel;

the diameter of the pinch roller 4 is the same as the diameter of the backup roller 3, and the diameter of the edging groove 61 is greater than or less than the diameter of the backup roller 3.

The support shaft 31 is positioned longitudinally and laterally by the first bevel gear 51, the second bevel gear 52, the third bevel gear 53 and the fourth bevel gear 54, so that the support shaft 31 rotates smoothly, and the pressing shaft 41 rotates smoothly by the fifth bevel gear 55, the sixth bevel gear 56, the seventh bevel gear 57 and the eighth bevel gear 58.

In the rotation process of the driving motor 7, the rotation directions of the pinch roller 4 and the supporting roller 3 are opposite, so that glass to be edged can stably run between the longitudinal beams 1, and the rotation linear speed of the grinding wheel and the rotation linear speed of the supporting roller 3 are different due to the fact that the diameter of the grinding groove of the grinding wheel is smaller than or larger than that of the supporting roller 3, and the rotation speed of the grinding wheel is inconsistent with the running speed of the glass due to the fact that the differential speed exists, so that edges of the glass are ground. The benefits of this arrangement are: the abrasion speed of the grinding wheel to the glass can be reduced, so that the abrasion is homogenized, thinned and gradually made, the edge grinding of the glass is gradually finished, and the cracking and the burr formation are avoided.

The edging production line adopts the pinch roller 4 and the support roller 3 to simultaneously position the upper surface and the lower surface of the glass, improves the running stability of the glass, and avoids the deviation, the shaking and the blocking of the stress formed in the polishing process to the running of the glass.

Through the reasonable setting of transmission structure, make the operation of pinch roller 4 and backing roll 3 synchronous, and the running direction is opposite, make pinch roller 4 and backing roll 3 have little relative motion with glass between, prevent pinch roller 4 and backing roll 3 to the wearing and tearing that the glass surface caused, even at edging in-process partial glass piece and glass powder remain on the upper surface of glass, also can not cause serious wearing and tearing to glass.

As shown in fig. 2, 3 and 4, a strip-shaped buffer cavity 42 is formed in the compression shaft 41, the compression roller 4 comprises a plurality of compression rods 43, the compression rods 43 are circumferentially and uniformly distributed on the outer side of the compression shaft 41, the compression rods 43 are connected with the compression shaft 41 through a plurality of connecting components, each connecting component comprises a pull rod 44, a sleeve 45 and a connecting spring 46, the outer end of the pull rod 44 is connected with the compression rod 43, the inner end of the pull rod 44 is inserted into the sleeve 45, the inner end of the sleeve 45 is fixedly connected with the outer wall of the compression shaft 41, two ends of the connecting spring 46 are respectively connected with the inner end of the pull rod 44 and the inner wall of the sleeve 45, the sleeve 45 is communicated with the buffer cavity 42, the buffer cavity 42 is communicated with the air outlet end of an air pump 47, and the connecting components further comprise an overflow hole 48, the overflow hole 48 penetrates through the outer wall surfaces of the pull rod 44 and the compression rod 43, and the overflow hole 48 is communicated with the inner cavity of the sleeve 45.

In order to dislodge glass dust and glass cullet that may be present on the upper surface of the glass, overflow holes 48 are provided, and under the action of air pump 47, a strong air flow impinges on the glass surface, causing the glass dust and glass cullet that may be present to be away from the glass being acted on by pinch roller 4, thereby protecting the glass surface.

In order to improve the pressing force on the glass, the glass is not slipped or loosened under the action of the pressing roller 4 and the supporting roller 3, the pressing roller 4 adopts a structure of a plurality of telescopic pressing rods 43, and the pressing rods 43 have outward tension under the action of air pressure, so that the pressing rods 43 press the surface of the glass.

Through the steady voltage air feed of air pump 47, then discharge through overflow hole 48, can be quick dispel the heat to glass surface, especially glass limit portion, avoid thermal expansion to cause glass size to take place slightly, make edging precision reduce.

The diameter of the edging groove 61 on the edging wheel 6 in each edging device increases gradually in the direction of travel of the glass on the stringers 1. In general, from the entrance of the production line, the diameter of the edging groove 61 is minimum, and as small as the minimum distance between two edging grooves 61 adjacent in the transverse direction is larger than the width of the glass, and the diameter of the edging groove 61 gradually increases to the exit, the edge of the glass is abraded layer by layer, and the edge of the glass is polished by adopting a small amount of multiple stripping mode, so that the precision is higher, the reliability is higher, the possibility of cracking is smaller, and the possibility of forming burrs is smaller.

The support roller 3 and the pressing bar 43 are made of hard rubber plastic materials.

In the whole production line, the first bevel gears 51, the second bevel gears 52, the third bevel gears 53, the fourth bevel gears 54, the fifth bevel gears 55, the sixth bevel gears 56, the seventh bevel gears 57 and the eighth bevel gears 58 are all gears of the same specification. The bevel gears are distributed in the same specification and in a regular manner, so that the transmission among all parts is stable, the operation is stable, the reliability is higher, and the synchronization and the same speed of the compaction roller 4 and the support roller 3 are ensured.

It should be noted that: the frequency converters are conventional components for controlling the rotation speed of the driving motor 7, and the controller is provided with a program or an element without a control program for uniformly controlling each frequency converter, and the two elements are conventional elements in the prior art, so that the invention aims at and the effect of the invention can be achieved even if the two elements are not present, and the two elements are not described herein.

In order to improve edging quality and edging yield, in combination with the edging production line, the glass edging method comprises the following steps:

A. the controller controls the driving motors 7 to synchronously run, and the glass to be edged is slowly fed in from the inlet of the longitudinal beam 1; setting of the diameter of the edging groove 61 of the edging wheel 6 at the inlet: the minimum distance of the edging grooves 61 of the two edging wheels 6 on the same transverse straight line is greater than the width of the glass to be edging; setting of the edging groove 61 diameter of the edging wheel 6 at the outlet: the minimum distance of the edging grooves 61 of the two edging wheels 6 on the same transverse straight line is the same as the set width of the edging glass;

B. when the operator holds the glass and the glass runs under the pinch roller 4, the driving motor 7 is stopped, the air pump 47 is started at the same time, after the air pump 47 runs for 3-20S, the driving motor 7 is started until the edging of the glass is finished, and the edging glass is taken away from the outlet of the production line.

The method can greatly improve the edging yield and precision of the glass, and enable the glass to be smooth and flat after edging.

In the method, in the first three edging devices from the inlet to the outlet, the minimum distance between the edging grooves 61 of the two edging wheels 6 which are transversely aimed is larger than the width of the glass, so that the glass can smoothly enter until the minimum distance between the edging grooves 61 of the two edging wheels 6 which are transversely aimed in the last edging device is the same as the width of the glass after edging, so that the abrasion of the glass is gradually carried out, and the precision is improved.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the invention. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions thereof without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims

1. The glass edging device comprises two longitudinal beams (1) which are distributed in parallel, and is characterized by comprising a supporting roller (3) and a compression roller (4) which is positioned above the supporting roller (3), wherein the supporting roller (3) is rotationally connected between the two longitudinal beams (1) through a supporting shaft (31), the compression roller (4) is rotationally connected between the two longitudinal beams (1) through a compression shaft (41), and the end part of the compression shaft (41) positioned on the same side and the end part of the supporting shaft (31) synchronously and reversely rotate through a transmission structure;

the transmission structure comprises a first bevel gear (51), a second bevel gear (52), a third bevel gear (53), a fourth bevel gear (54), a fifth bevel gear (55), a sixth bevel gear (56), a seventh bevel gear (57) and an eighth bevel gear (58), wherein the first bevel gear (51) is fixedly connected with one end of a supporting shaft (31), the eighth bevel gear (58) is fixedly connected with one end of a pressing shaft (41), a first installation cavity (11) is formed in the longitudinal beam (1), the first bevel gear (51), the second bevel gear (52), the third bevel gear (53) and the fourth bevel gear (54) are all rotationally connected in the first installation cavity (11), the first bevel gear (51) simultaneously meshes with the second bevel gear (52) and the fourth bevel gear (54), the third bevel gear (53) simultaneously meshes with the second bevel gear (52) and the fourth bevel gear (54), the rotation axis of the first bevel gear (51) and the rotation axis of the third bevel gear (53) are located on the same straight line, and the rotation axis of the first bevel gear (52) and the fourth bevel gear (54) are located on the same rotation axis;

a mounting box (12) is fixedly arranged above the longitudinal beam (1), a second mounting cavity (13) is formed in the mounting box (12), a fifth bevel gear (55), a sixth bevel gear (56), a seventh bevel gear (57) and an eighth bevel gear (58) are all rotationally connected in the second mounting cavity (13), the eighth bevel gear (58) is simultaneously meshed with the fifth bevel gear (55) and the seventh bevel gear (57), the sixth bevel gear (56) is simultaneously meshed with the fifth bevel gear (55) and the seventh bevel gear (57), the rotation axis of the sixth bevel gear (56) and the rotation axis of the eighth bevel gear (58) are positioned on the same straight line, and the rotation axis of the fifth bevel gear (55) and the rotation axis of the seventh bevel gear (57) are positioned on the same straight line;

the fourth bevel gear (54) and the fifth bevel gear (55) are connected through a short shaft (59), an edging wheel (6) is fixedly arranged on the short shaft (59), and an edging groove (61) is formed in the peripheral surface of the edging wheel (6);

the compression roller (4) comprises a plurality of compression rods (43), the compression rods (43) are circumferentially and uniformly distributed on the outer side of the compression shaft (41), the compression rods (43) are connected with the compression shaft (41) through a plurality of connecting components, the connecting components comprise a pull rod (44), a sleeve (45) and a connecting spring (46), the outer ends of the pull rod (44) are connected with the compression rods (43), the inner ends of the pull rod (44) are inserted into the sleeve (45), the inner ends of the sleeve (45) are fixedly connected with the outer wall of the compression shaft (41), two ends of the connecting spring (46) are respectively connected with the inner ends of the pull rod (44) and the inner wall of the sleeve (45), the sleeve (45) is communicated with the buffer cavity (42), the buffer cavity (42) is communicated with the air outlet end of an air pump (47), the connecting components further comprise an overflow hole (48), and the overflow hole (48) penetrates through the outer wall surfaces of the pull rod (44) and the compression rod (43), and the inner wall of the sleeve (45) is communicated with the inner cavity (48).

In the whole production line, each first bevel gear (51), each second bevel gear (52), each third bevel gear (53), each fourth bevel gear (54), each fifth bevel gear (55), each sixth bevel gear (56), each seventh bevel gear (57) and each eighth bevel gear (58) are gears with the same specification.

2. Glass edging device according to claim 1, characterized in that the support roller (3) and the pressure bar (43) are both made of hard rubber-plastic material.