TH14908B - Methods and machines for sharpening fragile materials - Google Patents

Abstract

Provides a tool and a mechanized method for brittle materials. For the realization of sharpening in the modal area by using ordinary sharpening machines, sharpening or polishing of working surfaces of workpieces containing brittle materials is obtained. An action by relative movement between the workpiece and the grinding wheel containing abrasive grains. Rubbing the amount provided on the support base, while also bringing the said sharpening wheel into contact. Pressure to the working surface at the preset pressure Will perform a secret or interruption of the set. Pressure that is conditionally placed in such a way that Cutting depth d into the working surface of the abrasive grain. Among such a large number of abrasive grains which are involved in sharpening or polishing are It has been made to less than the critical depth of the de-cut, the least league of cuts that, at this depth, creates a brittle fracture in the specimen.

Claims (6)

1.Mechanical methods for brittle materials for sharpening or polishing of surfaces. Use of workpieces with brittle materials It consists of the steps of: Making relative motion between the workpiece and the sharpening tool. The large amount of abrasive grains provided on the supports; And the introduction of this grinding tool into pressure contact with the working surface at the total load P during this relative motion to perform a sharpening or polishing operation. Where the secret operation will be performed Or abrasive while satisfying P < N MAX.Pe, where NMAX represents the maximum number of active abrasive grains present in the area of contact. Between the sharpening tool and the workpiece When this sharpening tool has cut into the working surface In such a way that Cutting depth d into the working surface of active abrasive grains among the number The abundance of abrasive grains that are involved in this grinding or abrasive achieve critical depth of de-cut, the smallest depth of cut at depths that cause brittle cracking in the workpiece. This, and Pe represent the critical load per one abrasive grain when one abrasive grain gets Cut into the working surface at critical depth of this de cut 2. Method according to claim 1, where this workpiece has a fracture value and Ktc toughness of less than 10 MW / ( M) 3/2 The working surface is then subjected to grinding or polishing when moving the sharpening tool and the workpiece in relation to each other. 3. Method of claim 1, where this sharpening tool is one of which Will make The height of the grain tip, the large amount of abrasive provided on this support is uniform. With a high degree of accuracy below the critical depth of this de cut 4. Method according to claim 1, where this sharpening tool is one of which The average diameter of the particles of this abrasive grain is greater than 20 μm, and the hardness of The bonding material is greater than the Vickers hardness of 300. 5. Method of claim 1 where this workpiece is to be formed from any type of glass material. Crystal material And materials, types of ceramics 6. Method of claim No. 5, where the workpiece will be anything. An optical lens Optical mirror And optical prism 7. Method according to claim 5, where the working surface of this workpiece will be a flat surface or A spherical surface with a conditional curvature. 8. Mechanical methods for brittle materials for sharpening or polishing surfaces. Operate workpieces with brittle materials by relative motion between the workpiece and tool for The grinding agent contains a large amount of abrasive grains provided on the support, while the sharpening tool is brought into contact with pressure with the working surface at the total load P, the method will Includes steps of: measuring the critical depth of cut de, the smallest depth of cut at the brittle fracture depth in this workpiece; N MAX count of the grains of active abrasive grains present in the area of contact. Between the sharpening tool and the workpiece When this work surface has been cut to the critical depth of this de cut; Critical load measurement pe per one abrasive grain when one abrasive grain was cut. Into the working surface at critical depth of this de cut; P < N MAX.Pe 9. Method of Clause 8 where the Confidentiality Apparatus is one of the means to ensure the The height of the grain tip, the large amount of abrasive provided on this support is uniform. With a high degree of accuracy below the critical depth of this de cut 1 0. The method according to claim 8, where this sharpening tool is one which The average diameter of the particles of this abrasive grain is greater than 20 μm, and the hardness of The bonding material is greater than the Vickers hardness of 300 1 1. Method of claim 8, where this workpiece is to be formed from any type of glass material. Crystal material And ceramic materials 1 2. Method of Clause 11 where the workpiece will be any An optical lens Optical mirror And optical prism 1 3. Method according to claim 11, where the working surface of this workpiece is a flat surface. Or spherical surfaces with conditional curvature 1 4. Mechanical methods for brittle materials for sharpening or polishing surfaces. Use of workpieces with brittle materials By relative movement between the workpiece and the tool for The grinding agent is composed of a large amount of abrasive grains provided on the support, while the grinding tool is in contact with pressure with the working surface at the total load P, which is performed in order to : The critical depth of de-cut is measured, the smallest depth of cut at the brittle fracture depth in this workpiece; Count N MAX maximum number of active abrasive grains present in the area of contact. Between the sharpening tool and the workpiece When this work surface has been cut to the critical depth of this de cut; Measure the critical pe load per one abrasive seed when one abrasive seed was cut into the Working surface at critical depth of this de cut; And grinding operations while satisfying P < N MAX.Pe conditions. The method consists of the steps of: Fixing one abrasive grain into the storage compartment. , The gradual cut into this workpiece up to the critical depth of this de-cut, and the measurement of the critical load pe per one active abrasive grain at that time. Operated by the first machine; The abrasion formation in the workpiece is rotated through a pre-determined angle to form. The image of the scratch after the sharpening tool consisting of a large amount of abrasive grain has been made. Up to cut into this dummy to the critical depth of this de-cut and to obtain the maximum N MAX number of active abrasive grains contained in the contact area between the sharpening machine and the slice. This work by Counting the number of scratches Where steps like this have been performed by the second machine; P < N MAX.Pe 1 5. Method of Clause 14, where this confidentiality tool is one of the means to make The height of the grain tip, the large amount of abrasive provided on this support is uniform. With a high degree of accuracy at a lower than the critical depth of this de cut 1 6. Method according to claim 14, where this sharpening tool is one of the tools in which the cut The average center of this abrasive grain particle is more than 20 μm, and the hardness of the material to The fastening is greater than the Vickers hardness of 300 1. 7. Method of claim 14, where this workpiece is to be formed from any material. A kind of glass Crystal material And ceramic materials 1 8. Method of claim 17, where the workpiece will be any An optical lens Optical mirror And optical prism 1 9. Method according to claim 17 where the working surface of this workpiece will be a flat surface. Or a spherical surface with a conditional curvature 2 0. Mechanized method for brittle materials consists of the procedure of: Preparing a layout sharpening tool which includes Numerous abrasive grains provided on the support on the shaft of the grinding tool. Has been placed in a rocking mechanism. Where the far end of the seed a large amount of abrasive substance determines An envelop with a spherical shape whose radius of curvature has been obtained by value replication. Target of the radius of curvature along the workpiece surface; Supporting the workpiece on the provided support on the pressure inducing mechanism on the workpiece; And sharpening or polishing operations by rotating workpieces and tools for sharpening relative to This, while satisfying the P < N MAX.Pe condition, where: N MAX represents the maximum number of active abrasive grains present in the area of A touch between the sharpening tool and the workpiece When this sharpening tool cuts into the working surface To the critical depth of de-cut, which is the smallest depth of cut at the Fragile fractures in this specimen, and Pe represent the critical load per abrasive grain. Has been cut into the working surface at critical depth of this de cut 2 1. Method according to claim 20, where the shape of this workpiece will be what the lens is. A sphere with diameter D and radius of curvature R, as well as the surface area M, is defined by M = 2 Pi R [R- {R2- (D / 2) 2) 1/2. ] Where the maximum NMAX amount of active abrasive grains has been treated to less than 3000 per M surface area, and the grinding is performed at a depth less than the critical de-cutting depth of this workpiece. By rotating the workpiece and tools to sharpen each other and rock this 2 2. The mechanical action method for brittle materials incorporates the steps of: mechanical action on the work surface of the combined blankets. The brittle material that will act as the workpiece that will be taken to the final finished shape. Where is the shape Estimated target by one or two covert operations; Sharpening or polishing operations while satisfying P < N MAX.Pe conditions in order to sharpen or polish the working surface. By relative movement between the workpiece and the sharpening tool at It is assembled with a large amount of abrasive grains prepared on the support, while this grinding tool is brought into pressure contact with the working surface of the workpiece at the total load, P which: N MAX is shown. Represents the maximum number of active abrasive grains contained in the area of contact. Between the sharpening tool and the workpiece When this sharpening tool cuts into the working surface In such a way that Cutting depth d into the working surface of active abrasive grains among the number The abundance of abrasive grains that participate in this grinding or abrasive achieve a critical depth of de-cut, the smallest depth of cut at the depth that creates brittle cracking in the workpiece. This, and Pe represent the critical load per one abrasive grain when one abrasive grain gets Cut into the working surface at critical depth of this de cut; And final polishing operation by 2 abrasion-free grains 3. Method according to claim 22, where this workpiece will be optical part 2. 4.Machine action for brittle materials, for sharpening or polishing surfaces. The workpiece with brittle materials includes: a sharpening tool containing a large amount of abrasive grains provided on the support; The path for the introduction of such a sharpening apparatus into contact with the working surface at the preset pressure and the resulting relative motion between Such sharpening tools and this working surface. Where the interruption or sharpening will be performed Pressure that is conditionally placed in such a way that Cutting depth d into the working surface of the abrasive grain. Among such vast amounts of abrasive grains which are involved in sharpening or polishing have been made. To less than de-critical depth, which is the least league of the cut, which will cause a crack Brittle in this work 2 5.Machine action for brittle materials for sharpening or surface polishing. The workpiece with brittle materials includes: a sharpening tool containing a large amount of abrasive grains provided on a support; The method for the introduction of such a sharpening apparatus into contact with pressure on the working surface at the total load P and relative motion is the result between Such sharpening tools and this working surface. Where to perform a sharpening or polishing while satisfying the P < N MAX.Pe condition where: N MAX represents the maximum number of active abrasive grains present in the area of contact. Between the secret tool and this work When the sharpening tools cut into This working surface In such a way that Cutting depth d into the working surface of the abrasive grains. Among such vast amounts of abrasive grains that are involved in this polishing or polishing are achieved. The critical depth of de-cut, which is the smallest depth of cut at the resulting depth Fragile fractures in this specimen, and Pe represent the critical load per abrasive grain when one abrasive grain gets. Cut into the working surface at critical depth of this de cut 2. 6. Machine tool for brittle materials, which includes: Layout sharpening tool containing large amounts of abrasive grains. It is provided on the support, which on the shaft of the sharpening tool is placed in the rocking mechanism where the very end of the grain of such a large amount of abrasive determines the available Envilope. A spherical shape whose radius of curvature has been obtained by the target-value replication of Radius of curvature along the working surface of the workpiece; Mechanism for creating pressure on the workpiece with a support for supporting this workpiece; And the method for sharpening or polishing by rotating this workpiece and the sharpening tool As such, relate to each other and this rocking while satisfying the condition P < N MAX.Pe where: N MAX represents the maximum number of active abrasive grains present in the area of contact. Between the secret tool and this work When the sharpening tools cut into This working surface reaches the depth of cut de, the smallest depth of cut at the brittle fracture depth in this workpiece, and the Pe represents the critical load per abrasive grain. Seed when one abrasive grain It is cut into the working surface at critical depth of such de-cut.