UA134840U - METHOD OF ADHESIVE-ACTIVE EDITING OF DIAMOND GRINDING WHEELS - Google Patents

Abstract

The method of adhesive-active straightening of diamond grinding wheels, consisting of diamond grains and bonds, and is performed by a roller assembled from wear-resistant and adhesive-active metal plates, which alternate, and wear-resistant metal plates are located on the edge of the roller, and as an adhesive-active the metal of the roller used titanium as a wear-resistant metal - tungsten.

Description

The utility model belongs to the field of material processing by cutting, namely, straightening of diamond grinding wheels. It is known that diamond is the hardest material in nature. Diamond is a brittle material and, like all brittle materials, has a low tensile strength, so the diamond should be broken at a weak point - to overcome the tensile strength of the diamond. In practice, this is associated with great technical difficulties, since diamond grains are small (40-1000 μm) in size, and the number of grains on the working surface of the tool is calculated in thousands.

The cutting properties and geometry of grinding abrasive wheels are maintained in the process of work by periodic grinding with diamond tools, during which 40 to 95% of the working volume of the grinding wheel is removed (Superhard material. Obtaining and using: V 6 vol. /Under general editor. N. V. Novikov, National Academy of Sciences of Ukraine." Institute of Superhard Materials named after V.N.

Bakula - Vol. 6: Diamond-abrasive tool in machining technologies / Ed. A.A.

Shepeleva - K., 2007. - 340 p.). Disadvantages: The new tools cannot rule diamond wheels, because the hardness of the diamond of the ruling tool and the diamond of the wheel are the same.

Abrasive wheels rule single-crystal turning (cutters, needles, diamonds in frames, plates), multi-crystal (pencils, rollers, combs, bars), grinding with diamond rollers, abrasive wheels; by rolling with diamond, hard alloy discs (V.F. Romanov, V.V. Avakyan. Technology of diamond straightening of grinding wheels. - M.:

Mashinostroenie, 1980. - 119 p.) and others.

Disadvantages: Diamond tools cannot rule diamond wheels, because the hardness of the diamond of the ruling tool and the diamond of the wheel are equal.

Diamond pencils and diamond rollers have found the most widespread use in mechanical engineering.

At the Institute of Superhard Materials named after V.N. Bakulya of the National Academy of Sciences of Ukraine proposed composites: slavutich (natural diamonds and a charge of VKb hard alloy), Tvesal (synthetic diamonds and a charge of VKb hard alloy) New pencils have been widely tested. The average value of the stability coefficient is 1.4 times higher in comparison with serial diamond pencils of type C and C (Synthetic superhard material: V Z t. T. 2. Kompozisionnye instrumentalnye superhard material / Ed.: N.V. Novikov (open editor .) and others - K.: Nauk. dumka, 1986. - 264 p.). Diamond tools cannot rule diamond wheels, because the hardness of the diamond is the ruler

From the tool and the diamond, the circles are equal.

The proposed composites improve the quality of pencils, but it was not possible to use the properties of natural diamonds inherent in their nature. The new tools cannot rule diamond wheels, because the hardness of the diamond of the ruling tool and the diamond of the wheel are equal. Up to 95% of the working volume of the grinding wheel is spent on straightening wheels made of traditional abrasive materials. When using wheels made of superhard materials (diamond, dense modifications of boron nitride), such a wasteful consumption of superhard abrasive for straightening is not economically justified, and there are also no materials that could destroy diamond, dense modifications of boron nitride by cutting.

It is known that the processing of natural diamond crystals depends significantly on the type of the processed plane and its orientation relative to the direction of the cutting force. The polishing of the diamond plane is in the ratio 105110u8.55100u3.95111). (M.F. Semko, A.I. Grabchenko,

Khodorevsky MG, Diamond grinding of synthetic superhard materials. - Kharkiv:

Higher school, 1980. - 192 p.). On the working surface of the grinding wheel, there are simultaneously diamond grains of different orientation, which have different machinability. The most difficult to process when grinding a natural diamond crystal is the plane of the octahedron 5111).

Close to the proposed useful model is the method of grinding diamond wheels. During the grinding process, when a thermal field is applied to the diamond grain, tensile residual stress occurs in the thin surface layers, which weakens the diamond grain. Editing of diamond grinding wheels is carried out by grinding with wheels made of silicon carbide (KZ) or electrocorundum (EB). The connection between the diamond grains is polished, new diamond grains protrude on the working surface of the wheel, dulled diamond grains fall out of the connection. (Synthetic sverhtverd'se material!: V Z vol. T. 3. Application of synthetic sverhtverd'e materials / Ed.: N.V. Novikov (retd. ed.) et al. - K.: Nauk, dumka, 1986. - 280 p. ) The basis of the work of the new ruling tool proposed by the author is the interaction of adhesively active and wear-resistant metals with the surface of the diamond grain. Titanium (Ti) is selected as an adhesively active metal, and tungsten (M) is selected as a wear-resistant metal.

The closest analogue of the proposed useful model is the method of straightening diamond wheels with abrasives, in which during the straightening process, the bond between the grains is polished and new diamond grains appear on the working surface of the wheel, and dulled grains fall out of the wheel.

(Synteticheskie sverhtverdse material!: V Z vol. T. 3. Applications of synthetic super-solid materials / Ed.: N.V. Novikov (retd. ed.) et al. - K.: Nauk, dumka, 1986. - 280 p. ).

Disadvantages of the method: diamond grains do not rule, they remain in an unprocessed form.

The basis of the useful model is the task of adjusting the diamond grain of the grinding wheel by the adhesive-active method. The problem is solved as follows: adhesive-active straightening of diamond wheels is performed by a roller made of wear-resistant and adhesive-active metal plates, which alternate, and the wear-resistant metal plates are located on the edge of the roller.

The essence of the claimed useful model is to create a tool for straightening diamond wheels by an adhesive-active method, namely, it differs in that it is performed by a roller made of wear-resistant and adhesive-active metal plates, which alternate, and the wear-resistant metal plates are located on the edge of the roller .

At the same time, titanium is used as an adhesive-active metal of the roller, and tungsten is used as a wear-resistant metal.

Example.

The tool for straightening diamond circles is made in the form of a roller made of alternating plates: M/-Ti-M/-Ti-MU (Fig. 1). Titanium from the surface of the guide roller during running-in is applied to the surface of the diamond grain in the form of a film. As a result of repeated contact of the titanium roller with the adhered film on the diamond grains, the diamond grains are subjected to tensile stress. The destruction of the surface layer of the diamond grain occurs from the tensile stress in those places where the tensile stress reaches the limit of the strength of the diamond. The wear-resistant metal (M/) of the guide roller when in contact with the working surface of the diamond wheel removes the residue of the Ti film from the surface of the diamond grain. Diamond wheels were ruled by the rollers described above (Fig. 1), which were installed at an angle of 5" relative to the axis of the diamond wheel. The adhesive-active metal (Ti) of the guide roller, item 2 (Fig. 1), upon contact, is applied to the surface of the diamond grain in the form of a film During running-in, as a result of multiple contact of the metal of the roller with the adhered film, the diamond grains are exposed to tensile stress directed perpendicular to the normal of the working surface of the wheel. The destruction of the surface layer of the diamond grain occurs due to tensile stress in those places where the tensile stress reaches the values of diamond strength.

Due to the presence on the surface of the diamond wheel, there are flat grains with different machinability

From the surface of the diamond, it is destroyed selectively, that is, the destruction takes place along a weak plane, on which the limit of tensile strength is reached. The surface of the diamond grain is covered with craters (Fig. 2) with sharp edges. Diamond wheels after correction in the grinding process cut the ridges of the roughness of the processed material with the sharp edges of the diamond grain crater. Such a diamond grain ensures a low roughness of the polished surface, because there are no sharp points of the diamond grains protruding, and no deep lines are formed. Wear-resistant metal of the guide roller pos. 1 (Fig. 1) when in contact with the working surface of the diamond wheel, removes the excess film of the adhesive-active metal. The removal of particles of the tool material-diamond is caused by the adhesion phenomena of the metal-diamond pair. Conducted experiments and analysis of literary sources show that crystals of instrumental materials with covalent bonds in contact with adhesively active metals are subject to adhesive wear. Standard diamond wheels without straightening and after straightening with adhesive-active rollers were tested on grinding operations of samples of technical molybdenum, tungsten - the material of laser metal-optics mirrors. The videos and editing technology have been tested on the mod machine. ZE-7218F for grinding operations of Mo, MU samples according to the mode: Mk-35 m/s, Zpr. - 6 m/min, Zpop. - 0.3 mm/dv. stroke, 1-0.005 mm,

SOT - aqual-11. The test results are given in the table.

Table

Characteristics of circles and roughness of the polished surface of materials

As follows from the given data, straightening of diamond wheels with the proposed rollers ensures a lower roughness of the polished surface of tungsten and molybdenum samples compared to standard diamond wheels straightened by the standard method - without adhesively active straightening with the proposed rollers. The roughness of the surfaces of tungsten metal samples is 1.5 times less; molybdenum is 2 times less with the same modes of grinding with diamond wheels after adhesive-active straightening with the proposed rollers in comparison with standard diamond wheels.

Tungsten and molybdenum metals are used in metallo-optics designs.

Claims (2)

USEFUL MODEL FORMULA 1. A method of adhesive-active straightening of diamond grinding wheels, which consist of diamond grains and bonds, which is distinguished by the fact that it is performed by a roller composed of alternating wear-resistant and adhesive-active metal plates, and the wear-resistant metal plates are located on the edge of the roller . 2. The method according to claim 1, which differs in that titanium is used as the adhesive-active metal of the roller, and tungsten is used as the wear-resistant metal. Shshsh- k shi SHE Fig. 1 V I o Z ps 0 Fig. 2