CN103381568A - Method for polishing glass edge - Google Patents
Method for polishing glass edge Download PDFInfo
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- CN103381568A CN103381568A CN2012101577816A CN201210157781A CN103381568A CN 103381568 A CN103381568 A CN 103381568A CN 2012101577816 A CN2012101577816 A CN 2012101577816A CN 201210157781 A CN201210157781 A CN 201210157781A CN 103381568 A CN103381568 A CN 103381568A
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- Grinding And Polishing Of Tertiary Curved Surfaces And Surfaces With Complex Shapes (AREA)
Abstract
The invention mainly discloses a method for polishing a glass edge. The glass edge polishing method mainly comprises the following steps: providing a plurality of glass sheets; providing a plurality of spacing pieces which are arranged among the glass pieces, are used as intervals among the glass pieces and fix the relative positions of the glass pieces; providing a first clamping force, and enabling a first clamping main shaft to be connected to the outermost spacing piece of the spacing pieces; providing a second clamping force to enable a second clamping main shaft to be connected with the other outermost spacing piece of the spacing pieces; and providing a tool rotating wheel for polishing the glass sheets. By means of the method, a plurality of glass sheets can be polished at one time, and the effects of reducing manufacturing cost, improving product quality, prolonging service life of equipment and improving labor environment are achieved.
Description
Technical field
The present invention is relevant for a kind of finishing method, particularly relevant for a kind of method of glass edge polishing, can once carry out polishing to the multi-disc sheet glass by the method, to reach the effect that reduces manufacturing cost, improves product quality, extension device service life and improve work situation.
Background technology
Press, existing general glazier crop for circular or irregular moulding, for preventing that its clear-cut margin after cutting from can cause incised wound people phenomenon, usually after cutting is completed, need relend the milling tool that the assistant moves and give the grinding dressing periphery, make to be rounder and more smooth smooth shape, so use time side without the anxiety of hurting sb.'s feelings, and relatively also can obtain apparent the Beauty person.But tradition has the periphery with the operation attrition process glass plate of manual mode now, but the accuracy of its size just is difficult to grasp, add manual attrition process operating speed slow, it is convenient not to operate, virtually more will improve the cost of its making, therefore how providing a glass polishing device throw the glass quality and reduce total production cost to promote, will be the key factor that glass is expanded its commercial value.
With reference to No. the 410189th, TaiWan, China patent announcement, it discloses a kind of glass polishing method, utilize the glass plate setting that its loading plate grips and stress on a polishing machine, this machine has two pressing plates in the upper and lower position, clamp surface is stained with multi-disc pill type grinding stone, and supplies the diamond abrasive stone that comprises the water-soluble slurries of cerium oxide fine particle and comprise the diamond fine particle.Plant whereby the polishing method and can reach very high polishing speed, and keep accurate surface roughness.Yet grinding milk and grinding stone that this patent is used are expensive, are not inconsistent cost benefit.
Announce No. 87101316 with reference to Chinese patent, it discloses a kind of glass polishing method and utilizes titanium dioxide as polishing powder, according to traditional approach, glass is carried out polishing, therefore can reach grinding stone technology effect simple and easy and with low cost.Yet this patent is used the source titanium dioxide that is prepared from sulfuric acid process or chloridising of shortage gradually, therefore is not inconsistent the environmental protection subject under discussion of advocating now.
Announce No. 20820109191.5 with reference to Chinese patent, it discloses a kind of quartz glass polisher, utilizes the main shaft on feed support, and the front end of main shaft is equipped with polishing wheel, by the mutual motion between main shaft and polishing wheel, glass is carried out polishing, to reach the effect of automation polished glass.Now please refer to Fig. 1, a kind of quartz glass polisher schematic diagram that it discloses for No. 20820109191.5 for prior art Chinese patent bulletin.This polishing machine 10 mainly comprises: a glass 11; One polishing wheel 12; One main shaft 13; An and feed support 14, its device is mainly this main shaft 13 that utilizes on this feed support 14, the front end of this main shaft 13 is equipped with this polishing wheel 12, by the mutual motion of 12 of this main shaft 13 and this polishing wheels, this glass 11 is carried out polishing, to reach the effect of automation polished glass.Yet the quartz glass polisher of this patent successively can only polishing one sheet glass, is not inconsistent the mass-produced demand of business circles.
Summary of the invention
In order to solve the problems of the technologies described above, the present invention proposes a kind of method of glass edge polishing, it improves the disappearance that tradition only can single polishing monolithic glass, to reach the effect that reduces manufacturing cost, improves product quality, extension device service life and improve work situation.
The method of a kind of glass edge polishing provided by the invention, step comprises:
(a) provide the multi-disc sheet glass;
(b) provide the multi-disc distance piece, be arranged between those sheet glass, as the interval between those sheet glass, and fix the relative position of those sheet glass;
(c) provide one first chucking power, make one first gripper spindle be connected in an outermost distance piece of those distance pieces;
(d) provide one second chucking power, make one second gripper spindle be connected in another outermost distance piece of those distance pieces; And
(e) provide a cutter runner, the surface of this cutter runner and the edge of those sheet glass keep in touch, in order to those sheet glass are carried out polishing;
Wherein, the processing capacity minimum of this cutter runner is 0.01 nanometer, is 10 centimetres to the maximum.
Better, the method for aforesaid glass edge polishing, the shape of this multi-disc sheet glass of step (a) are selected from triangle, quadrangle, pentagon, hexagon and one of irregularly shaped.
Better, the method for aforesaid glass edge polishing, those distance pieces of step (b) are selected from triangle, quadrangle, pentagon, hexagon and one of irregularly shaped.
Better, the method for aforesaid glass edge polishing, those distance pieces of step (b) have stickiness, and the external form profile of those distance pieces is all less than the external form profile of those sheet glass.
Better, the method for aforesaid glass edge polishing, step (c) is clockwise or clockwise direction with this first gripper spindle of step (d) and the rotation mode of this second gripper spindle, and its rotating speed is constant speed or speed change.
Better, the method for aforesaid glass edge polishing, the emery wheel that this cutter runner of step (e) is a High Rotation Speed, and its material is aluminium oxide, carborundum, diamond or cubic boron nitride.
Better, the method for aforesaid glass edge polishing, this cutter runner of step (e) is cylinder, and the rotating speed of this cutter runner is between 100 to 3500 rpm.
Better, the method for aforesaid glass edge polishing, the rotating shaft of this cutter runner of step (e) is for fixing, cam mechanism or digit driver drives, and rotates simultaneously and swings, and contacts with the processing edges maintain of those glass guaranteeing.
Better, the method for aforesaid glass edge polishing, the rotation mode of this cutter runner of step (e) is counter clockwise direction or clockwise direction, and its rotating speed is constant speed or speed change.
Better, the method for aforesaid glass edge polishing, the rotation of this cutter runner of step (e) and the speed adjustment of swing are to the edge of those sheet glass carrying out the while polishing.
Better, the method for aforesaid glass edge polishing, this cutter runner of step (e) uses one deeply to advance to delay to the dry-type processing of polishing and carry out the while polishing with the edge to those sheet glass.
Better, the method for aforesaid glass edge polishing, this cutter runner of step (e) is soft or flexible processing wheel, and uses one to contain the wet type processing that polishing fluid splashes into and carry out the while polishing with the edge to those sheet glass.
The method of a kind of glass edge polishing of the present invention has following effect:
By the method for glass edge polishing of the present invention, can once carry out a large amount of glass polishing processing, reach the effect of improving work situation and improving product quality;
The method of glass edge polishing of the present invention has low cost, and also can reach the extension device effect in service life by the method;
The method of glass edge polishing of the present invention, but processed and applied shows its high convenience in the sheet glass of any shape.
Description of drawings
Fig. 1 is shown as the schematic diagram of prior art of the present invention;
Fig. 2 is shown as the structural representation of a kind of glass edge burnishing device of the present invention;
Fig. 3 is shown as the flow chart of the method for a kind of glass edge polishing of the present invention; And
Fig. 4 is shown as the motion mode schematic diagram of the method for a kind of glass edge polishing of the present invention.
[main element symbol description]
10, the schematic diagram of prior art;
11, glass;
12, polishing wheel;
13, main shaft;
14, feed support;
20, the structural representation of glass edge burnishing device;
21, multi-disc sheet glass;
22, multi-disc sheet distance piece;
23, the first gripper spindle;
24, the second gripper spindle;
25, cutter runner;
26, the rotating shaft of cutter runner;
30, the preparation flow figure of the method for glass edge polishing.
The specific embodiment
The invention will be further described below in conjunction with the drawings and specific embodiments, can be implemented so that those skilled in the art can better understand the present invention also, but illustrated embodiment is not as a limitation of the invention.
Although the present invention can show as multi-form embodiment, but the accompanying drawing those shown and below the expositor be the present invention can preferred embodiment, and please understand person disclosed herein and consider to be one example of the present invention, and be not that intention is in order to be limited to the present invention in diagram and/or described specific embodiment.
Now please refer to Fig. 2, it is shown as the embodiment schematic diagram of a kind of glass edge burnishing device 20 of the present invention, and it mainly comprises: multi-disc sheet glass 21; Multi-disc distance piece 22; One first gripper spindle 23; One second gripper spindle 24 and a cutter runner 25.Wherein, those sheet glass 21 are not the member of this glass edge burnishing device 20, play the part of in this technique the role of polished processing, therefore must select according to different demands the glass of unlike material.Preferably, due to plate glass easily process, with low cost the advantage such as very easily to obtain, therefore, use in the present invention plate glass.In addition, the shape of those sheet glass 21 can be arbitrary shape, and for example triangle, quadrangle, pentagon, hexagon and one of irregularly shaped, in a preferred embodiment, be selected from toroidal as this multi-disc sheet glass 21 of the present invention.
This multi-disc distance piece 22 as the interval between 21 every a slices of multi-disc sheet glass and sheet, and is fixed the relative position of those sheet glass 21.This first gripper spindle 23 is connected in an outermost distance piece of those distance pieces 22 with one first chucking power.This second gripper spindle 24 is arranged at the offside of this first gripper spindle 23 with one second chucking power, and is connected in another outermost distance piece of those distance pieces 22.This cutter runner 25, the surface of this cutter runner and the edge of those sheet glass keep in touch, in order to those sheet glass 21 are carried out polishing.
Now please continue with reference to figure 2, and coordinate with reference to Fig. 3.Fig. 3 is shown as method 30 schematic diagrames of a kind of glass edge polishing of the present invention, and it comprises following step:
Step 31: multi-disc sheet glass 21 is provided;
Step 32: multi-disc distance piece 22 is provided, is arranged between those sheet glass 21, as the interval between those sheet glass 21, and fix the relative position of those sheet glass 21;
Step 33: one first chucking power is provided, makes one first gripper spindle 23 be connected in an outermost distance piece of those distance pieces 22;
Step 34: one second chucking power is provided, makes one second gripper spindle 24 be connected in another outermost distance piece of those distance pieces 22; And
Step 35: a cutter runner 25 is provided, and the surface of this cutter runner and the edge of those sheet glass keep in touch, in order to those sheet glass 21 are carried out polishing.
Those distance pieces 22 are arranged between those sheet glass 21, as the interval between those sheet glass 21, and fix the relative position of those sheet glass 21.Wherein, the shape of those distance pieces 22 can be arbitrary shape, for example triangle, quadrangle, pentagon, hexagon and one of irregularly shaped, but the external form profile that should be noted those distance pieces 22 is all less than the external form profile of those sheet glass 21.Those distance pieces 22 are selected from one of rubber suction cups, aluminium alloy sucker and silicon rubber suction cup, and preferably, it has anti-corrosion, high temperature resistant and the advantage such as intensity is good because of the aluminium alloy sucker, so the present invention utilizes this material as preferred embodiment.Wherein, aluminium alloy is a kind of alloy made from copper, zinc, manganese, silicon, magnesium etc., generally be divided into: alumal, alusil alloy, almag, aluminium magnesium copper alloy, aldray, magnalium kirsite etc.,, corrosion resistance lighter than the ordinary carbon steel quality, the easy characteristic such as processing, therefore generally also common industrial goods, building doors and windows and the electronic equipment structure of being applied to fill part etc.It should be noted that between those distance pieces to be between 0.2 centimeter to 5 centimeters apart from scope.In another embodiment, those distance pieces 22 have stickiness, and the external form profile of those distance pieces 22 is all less than the external form profile of those sheet glass, so those distance pieces 22 adopt the soft suckers with vacuum chuck ability.
This first gripper spindle 23 is connected in an outermost distance piece of those distance pieces 22; This second gripper spindle 24 is arranged at the offside of this first gripper spindle 23, and is connected in another outermost distance piece of those distance pieces 22; The chucking power of this first gripper spindle 23 and this second gripper spindle 24 is mainly adjusted according to the quantity of those sheet glass 21 of clamping, the machining state that is unlikely to break to keep glass, and this chucking power is about 20 to 500 newton.Therefore this first gripper spindle 23 and this second gripper spindle 24 are necessary for the material of the good and abrasion performance of intensity.Preferably, because stainless steel has the advantages such as intensity is high and corrosion-resistant, so the present invention utilizes this material as preferred embodiment.Usually being applied to engineering is divided into the stainless steel of carrier or fixture: 304 stainless steels, 310 stainless steels, 316 stainless steels and 317 stainless steels etc., and in a preferred embodiment of the present invention, it has the advantages such as better high-temperature oxidation, resistance to acid attack and high strength because of 304 stainless steels, therefore select 304 stainless steels as the material of the first gripper spindle 23 of the present invention with this second gripper spindle 24.
In the present invention, this cutter runner 25 play the part of to wear and tear instrument of glass is in order to carry out polishing to those sheet glass.Therefore need a material hard than glass, generally speaking, the polishing tool material is generally selected wolfram steel cutter, diamond cutter and acryl cutter etc., preferably, the advantages such as, abrasion performance good because of its hardness of wolfram steel cutter and resistance to high temperature corrosion are therefore select the wolfram steel cutter as this cutter runner 25 of the present invention.In addition, in another embodiment, this cutter runner 25 be selected from the fixing number number emery wheel polishing of High Rotation Speed or adsorbable abrasive material reuse the polishing material, it is shaped as cylinder.
In another embodiment, this cutter runner 25 is selected from one of the emery wheel of a High Rotation Speed and polishing material of an adsorbable abrasive material.Preferably, this cutter runner 25 is selected from the emery wheel of the High Rotation Speed of fixing number number.Wherein, emery wheel be by the small abrasive grain of many multiangulars with after bond mixes, form via compacting, shaping and sintering, utilize its fine crisp hard abrasive grain to be the cutting element of cutting blade.The emery wheel commonly used with industrial quarters can be divided into two large classes: traditional, as aluminium oxide or carborundum; And non-traditional type, as diamond or cubic boron nitride.The former is applicable to common metal material or cutter material; The latter is exclusively used in hard-cutting material, as ceramet, cutter or glass etc.It is one of instrument of sharpening by cutter due to emery wheel, each abrasive particle on its wheel face is all little ore particle extremely hard, that reach crisp and heatproof, every sharp hard little ore particle during grinding, can be with the speed per hour surface of cutting speed by working substance of 10 kilometers nearly, can produce abrasive dust in the middle of processing, its abrasive dust comprises the small bits sheet of workpiece and the abrasive material that comes off because of passivation.Should be noted, the diameter of emery wheel is take 6 ", 8 ", 10 ", 12 " with 14 " for generally, and the selection of emery wheel size need coordinate the size of those sheet glass 21.In addition, the rotating speed of this cutter runner 25 is about 100 to 3500 rpm, and processing capacity (that is processing degree of depth) via the adjustment of this cutter runner 25, minimum is 0.01 nanometer, maximum can transfer to 10 cm range.
This cutter runner 25 is soft or flexible processing wheels, and uses one to contain the wet type processing that polishing fluid splashes into and carry out the while polishing with the edge to those sheet glass.This cutter runner 25 can also advance to delay to the dry-type processing of polishing or the wet type processing that comprises electrobrightening, chemically mechanical polishing and surge and press the polishing method deeply.Wherein
Deeply advance to delay to polishing:
Deeply advance to delay to grinding, different with general flat surface grinding, grinding depth (Depth of cut) increases several times to tens times, and feed rate (Feed Rate) slows down with identical multiple, can increase the grinding technique of removal rates and enhancement working surface rugosity.
Electrobrightening:
Electrobrightening is namely that workpiece is placed anode, switches in electrolyte, under the proper handling parameter, make workpiece generation cell reaction (also claim anti-electroplate), surface of the work and because the electric field concentration effect produces dissolution, thereby can reach the smooth process technology with gloss of surface of the work.
Chemically mechanical polishing:
Chemically mechanical polishing is that workpiece is pressed on the elastic insert (grinding pad) of rotation, utilizes the polishing technology of relative motion processing.To have corrosive working fluid supplies on workpiece, when workpiece carries out corrosion processing (chemistry), supply with simultaneously ultra micro abrasive particle (diameter 10 nanometers are following) polishing (mechanicalness) material, protuberance to workpiece carries out optionally polishing operation, therefore (tool) chemical polishing of title machine or chemically mechanical polishing.
In a preferred embodiment, this cutter runner 25 adopts the dry-type processing method.It can only not remove damaged surface layer and the residual stress that the polishing program produces, and can also prevent rupture strength, the raising yield of crystal grain fragment and warpage, reduction crystal grain warpage, increase crystal grain, simultaneously, can reduce the pollution to environment.
In addition, what this cutter runner 25 also can be selected adsorbable abrasive material reuses the polishing material, for example: rubber.If when adopting rubber to be used as cutter roller 25, it can be arranged in pairs or groups to surge and press the polishing method to carry out polishing.This processing method has the characteristics such as trace processing, measurable working modulus and height reappearance.The processing mode of pressing the polishing method that surges is that wishs polishing material is placed in defibrination, the stable load of control one between the hemispherical rubber cutter of High Rotation Speed and surface of the work.When cutter adds man-hour near workpiece, between the two because wedge effect (wedge effect) produces the hydrldynamic pressure lubrication effect, make and form the defibrination film between cutter and workpiece.Because when defibrination is driven when entering the processing district by the cutter High Rotation Speed, abrasive particle can be stable flows through surface of the work, so this film is laminar flow (laminar flow) structure.In this processing district, the shear stress effect that abrasive particle is subject to defibrination produces slip and rolls, and surface of the work is produced the processing behavior.Because the driving force of dominating abrasive particle motion kenel is flow field shear stress, so only the effect of GPRS flow field shear stress just can be controlled the working ability of abrasive particle.Therefore when pressure polishing rate was surged in discussion, the working ability that should be noted abrasive particle was to become positive relationship with flow field shear stress, and this shear stress is relevant with the processing district lubricating condition.And when cutter was not directly being pressed abrasive machining, in order effectively to remove the surface of the work material, abrasive particle must bear enough large stress.And surge and press the polishing method to play the hydrodynamic lubrication theory as the basis, set up a cover processing Theory and explain and the prediction working ability.By this processing Theory, controlling surges presses the machined parameters of polishing method, grasps the abrasive grain density of unit are and the working modulus of abrasive particle, estimates accurately the amount of removing of material, reaches the purpose of high reappearance processing.Rotating speed that it should be noted that this cutter runner 25 of selecting rubber is about 100 to 3500 rpm, and processing capacity (that is processing degree of depth) via the adjustment of this cutter runner 25, minimum is 0.01 nanometer, maximum can transfer to 10 cm range.
The method of glass edge polishing proposed by the invention adopts with a chucking power and is put on those sheet glass 21 and those distance pieces 22 by gripper spindle, and then with rotation mode at a slow speed, drive those sheet glass 21 and carry out Surface Contact and and then polishing with this cutter runner 25.
Now please refer to Fig. 4, it shows the motion mode of a kind of slope of the present invention glass edge polishing device.The motion mode of the first gripper spindle 23 and the second gripper spindle 24 (diagram represents take the first gripper spindle) is as rotating at a slow speed around a central point, and rotation can counterclockwise or clockwise, rotating speed can be adopted constant speed or speed change simultaneously.Should be noted, if when sheet glass is non-circular, the first gripper spindle 23 and the second gripper spindle 24 can cam mechanisms or other digit drivers drive and rotate and keep in touch a little and the rotatablely moving of this cutter runner 25 Surface Contacts.In a preferred embodiment, gripper spindle adopts a cam mechanism (not drawing).Wherein, this cam mechanism is by two plate cams and the conjugate cam mechanism that the uniform clutch plate of roller layering consists of.Its technical characteristics is to have adopted cam to connect the mill technology, and namely two cams are made an integral body, with a formula continuously grinding, have avoided the secondary position error during cam computer controlled grinding, have improved the positioning accuracy of cam.
In addition, adjust for the ease of assembling and gap, adopted the inclined to one side separation structure of casing and camshaft eccentrically braces structure.The conjugate cam indexing accuracy reaches as high as 15 ", the highest input speed 1000 rpm, approximately 3500 hours service life, 30 ℃ of fuel factors and operation torque 1500 Nm.Wherein, the mode of the rotation of the first gripper spindle 23 described in the present invention and the second gripper spindle 24 is optional from counter clockwise direction or clockwise direction, and rotating speed also can be adopted constant speed or speed change simultaneously.
Again, that the rotating shaft 26 of this cutter runner can be is fixing, cam mechanism or other digit drivers drive, and rotates simultaneously and swings, and contacts with the glass processing edges maintain guaranteeing.Wherein, the mode of rotation is optional from counter clockwise direction or clockwise direction, and its rotating speed also can be adopted constant speed or speed change.In addition, all rotate with the movement rate of the mechanism that swings and all can adjust, and are finished to simultaneously purpose with the edge of reaching multi-disc sheet glass 21.
Above-mentioned a kind of glass edge burnishing device all need coordinate cutter runner 25.Yet, in another embodiment, ignore this cutter runner 25, adopt an abrasive jet machining method.the principle of the method is to make abrasive material produce kinetic energy with the strength of gases at high pressure in the abrasive material of hard and tool acute angle, utilize air-pressure tube to carry, abrasive grain is subject to crunch and accelerates to surface of the work to clash into, surface of the work suffers high pressure stress, form a plastic strain district around the rum point, the material of plastic zone is because being subject to pushing of abrasive grain, and in formation tensile region, the periphery of plastic zone, the fragile material of this tensile region be can't stand expanding from the plastic zone and is pushed, and then generation crack, this crack can be divided into transverse crack (lateral crack) and two types of radial fissures (radial/median crack), transversal crack under the plastic zone can extend to surface of the work, until fragment comes off.Radial cracking continues down to extend to inside workpiece, makes the workpiece material strength reduction.Because abrasive jet machining method processing mode does not directly contact with workpiece, so nothing vibration and the problem that shakes in processing procedure, and gases at high pressure are except producing kinetic energy fine abrasive, it can change fineness and the stress state of surface of the work also to have cooling effect, and can be applicable to the processing of multi-disc workpiece.
<embodiment 1 〉
At first, first prepare the toroidal plate glass of 3 centimeters of 6 thickness and 50 centimeters of diameters.Afterwards, then prepare several pieces aluminium alloy distance pieces of 2 centimeters of thickness and 30 centimeters of diameters with impact style, the distance piece spacing is about 5 centimeters, then with toroidal plate glass with the aluminium alloy distance piece with interlace mode and take out with vacuum and engage; In addition, also preparing with said method the 304 stainless steel gripper spindles that two thickness are about 10 centimeters of 5 centimeters, diameter joins in the two ends of bonding plate glass and aluminium alloy viscosity distance piece; Then will be about the wolfram steel polishing tool that 400 centimeters, thickness are about 10 centimeters and be placed under the said equipment in addition.At last, the chucking power that imposes 260 newton is put on this multi-disc glass and distance piece by gripper spindle and then with pin rotation mode counterclockwise at a slow speed, drives multi-disc sheet glass and polishing tool Surface Contact, can make it reach the effect of polishing.Wherein, its reflectivity of the glass after polishing is about 8%, and penetration is about 85%, and than 6 monolithic toroidal plate glass improved efficiencies of polishing approximately 75%.<embodiment 2 〉
Embodiment 2 roughly as the step of embodiment 1, please refer to Fig. 3, and its Main Differences is: the multi-disc sheet glass changes 3 centimeters of thickness into, long 70 centimeters with the rectangular shape plate glass of wide 50 centimeters; The distance piece spacing changes 3 centimeters into; Polishing tool changes take diamond cutter as material.At last, the chucking power that imposes 250 newton is put on this multi-disc glass and distance piece by gripper spindle and then with pin rotation mode counterclockwise at a slow speed, drives multi-disc sheet glass and polishing tool Surface Contact, can make it reach the effect of polishing.Wherein, the glass polishing equipment completed of preparation once can be processed 10 plate glass, and its reflectivity of the glass after polishing is about 10%, and penetration is about 86%, and than 10 the rectangular shape plate glass of monolithic improved efficiencies of polishing approximately 80%.
In sum, the method for a kind of glass edge polishing of the present invention has following effect:
By the method for glass edge polishing of the present invention, can once carry out a large amount of glass polishing processing, reach the effect of improving work situation and improving product quality;
The method of glass edge polishing of the present invention has low cost, and also can reach the extension device effect in service life by the method;
The method of glass edge polishing of the present invention, but processed and applied shows its high convenience in the sheet glass of any shape.
The above embodiment is the preferred embodiment that proves absolutely that the present invention lifts, and protection scope of the present invention is not limited to this.Being equal to that those skilled in the art do on basis of the present invention substitutes or conversion, all in protection scope of the present invention.Protection scope of the present invention is as the criterion with claims.
Claims (12)
1. the method for a glass edge polishing, is characterized in that, step comprises:
(a) provide the multi-disc sheet glass;
(b) provide the multi-disc distance piece, be arranged between those sheet glass, as the interval between those sheet glass, and fix the relative position of those sheet glass;
(c) provide one first chucking power, make one first gripper spindle be connected in an outermost distance piece of those distance pieces;
(d) provide one second chucking power, make one second gripper spindle be connected in another outermost distance piece of those distance pieces; And
(e) provide a cutter runner, the surface of this cutter runner and the edge of those sheet glass keep in touch, in order to those sheet glass are carried out polishing;
Wherein, the processing capacity minimum of this cutter runner is 0.01 nanometer, is 10 centimetres to the maximum.
2. the method for glass edge polishing as claimed in claim 1, is characterized in that, the shape of this multi-disc sheet glass of step (a) is selected from triangle, quadrangle, pentagon, hexagon and one of irregularly shaped.
3. the method for glass edge polishing as claimed in claim 1, is characterized in that, those distance pieces of step (b) are selected from triangle, quadrangle, pentagon, hexagon and one of irregularly shaped.
4. the method for glass edge polishing as claimed in claim 1, is characterized in that, those distance pieces of step (b) have stickiness, and the external form profile of those distance pieces is all less than the external form profile of those sheet glass.
5. the method for glass edge polishing as claimed in claim 1, it is characterized in that, step (c) is clockwise or clockwise direction with this first gripper spindle of step (d) and the rotation mode of this second gripper spindle, and its rotating speed is constant speed or speed change.
6. the method for glass edge polishing as claimed in claim 1, is characterized in that, the emery wheel that this cutter runner of step (e) is a High Rotation Speed, and its material is aluminium oxide, carborundum, diamond or cubic boron nitride.
7. the method for glass edge polishing as claimed in claim 1, is characterized in that, this cutter runner of step (e) is cylinder, and the rotating speed of this cutter runner is between 100 to 3500 rpm.
8. the method for glass edge polishing as claimed in claim 1, it is characterized in that, the rotating shaft of this cutter runner of step (e) is for fixing, cam mechanism or digit driver drives, and rotates simultaneously and swings, and contacts with the processing edges maintain of those glass guaranteeing.
9. the method for glass edge polishing as claimed in claim 1, is characterized in that, the rotation mode of this cutter runner of step (e) is counter clockwise direction or clockwise direction, and its rotating speed is constant speed or speed change.
10. the method for glass edge polishing as claimed in claim 8, is characterized in that, the rotation of this cutter runner of step (e) and the speed adjustment of swing are to the edge of those sheet glass carrying out the while polishing.
11. the method for glass edge polishing as claimed in claim 1 is characterized in that, this cutter runner of step (e) uses one deeply to advance to delay to the dry-type processing of polishing and carry out the while polishing with the edge to those sheet glass.
12. the method for glass edge polishing as claimed in claim 1 is characterized in that, this cutter runner of step (e) is soft or flexible processing wheel, and uses one to contain the wet type processing that polishing fluid splashes into and carry out the while polishing with the edge to those sheet glass.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| TW101115750A TW201345659A (en) | 2012-05-03 | 2012-05-03 | A method of polishing the edges of glass |
| TW101115750 | 2012-05-03 |
Publications (1)
| Publication Number | Publication Date |
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| CN103381568A true CN103381568A (en) | 2013-11-06 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN2012101577816A Pending CN103381568A (en) | 2012-05-03 | 2012-05-21 | Method for polishing glass edge |
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| TW (1) | TW201345659A (en) |
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| CN104440413A (en) * | 2014-12-08 | 2015-03-25 | 蓝思科技股份有限公司 | Deformation polishing process and polishing clamp for 2.5D window screen |
| CN106392859A (en) * | 2016-12-08 | 2017-02-15 | 宇晶机器(长沙)有限公司 | Multi-surface polishing process |
| CN106392781A (en) * | 2016-10-25 | 2017-02-15 | 伯恩高新科技(惠州)有限公司 | Processing method for hard glass edge |
| CN111070005A (en) * | 2020-01-02 | 2020-04-28 | 崔如祥 | Refined edging treatment process for manufacturing and processing toughened glass |
| CN112476130A (en) * | 2020-11-27 | 2021-03-12 | 中建材衢州金格兰石英有限公司 | Chamfering device and method for quartz glass wafer |
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| JP2000015546A (en) * | 1998-06-26 | 2000-01-18 | Ngk Insulators Ltd | Manufacture of glass substrate |
| JP2004058256A (en) * | 2002-07-31 | 2004-02-26 | Kinseki Ltd | Method to chamfer and polish flat plates |
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| CN104440413A (en) * | 2014-12-08 | 2015-03-25 | 蓝思科技股份有限公司 | Deformation polishing process and polishing clamp for 2.5D window screen |
| CN104440413B (en) * | 2014-12-08 | 2017-04-12 | 蓝思科技股份有限公司 | Deformation polishing process and polishing clamp for 2.5D window screen |
| CN106392781A (en) * | 2016-10-25 | 2017-02-15 | 伯恩高新科技(惠州)有限公司 | Processing method for hard glass edge |
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| CN111070005A (en) * | 2020-01-02 | 2020-04-28 | 崔如祥 | Refined edging treatment process for manufacturing and processing toughened glass |
| CN112476130A (en) * | 2020-11-27 | 2021-03-12 | 中建材衢州金格兰石英有限公司 | Chamfering device and method for quartz glass wafer |
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| Publication number | Publication date |
|---|---|
| TW201345659A (en) | 2013-11-16 |
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