RU175492U1 - ABRASIVE TOOL - Google Patents

Abstract

The invention relates to the production of an abrasive tool, in particular a highly porous ceramic-corundum electrocorundum tool. The technical result is achieved in an abrasive tool containing electrocorundum abrasive grains, a ceramic bond and boron carbide particles of the same shape as a pore-forming refractory filler, while boron carbide particles are isometric in shape with a rolled surface and a size of 0.35 ÷ 0.45 of the size of the abrasive grains. The technical result is to increase the durability and performance of the tool.

Description

The invention relates to the production of an abrasive tool, in particular a highly porous ceramic-corundum electrocorundum tool.

A high-structure grinding tool made of abrasive mass is known, containing an abrasive from a mixture of abrasive grains with different grain sizes, the sizes of which are 60-160 microns and 160-420 microns, a ceramic bond, a filler in the form of a mixture of hollow spherical particles of aluminosilicate with sizes ranging from 85 to 560 microns and other additives (patent RU No. 2493956, IPC B24D 3/18, B24D 3/34, 09/27/2013). Thus, in an abrasive tool, the ratio of the particle size of the blowing agent and the size of the abrasive grain is 0.2-9.3.

The disadvantage of this tool is the increased fragility of the hollow spherical particles of aluminosilicate, which leads to a decrease in the strength of the tool as a whole, as well as to a decrease in porosity by reducing additional pores on the working surface. As well as salting of the working surface, increasing the heat stress of the grinding process and cutting forces, which significantly reduces the durability and productivity of the tool.

Known grinding wheel containing abrasive grains, a ceramic bond and thin-walled electrocorundum spherical particles, the value of which is 0.45-0.65 of the size of the abrasive grains, and the amount is 0.5-0.54 of the number of abrasive grains with a content of the last 30-37% (copyright certificate SU No. 1073082, IPC B24D 3/14, 02.15.1984).

A high-structure abrasive tool of abrasive mass is known, including an abrasive from a mixture of abrasive grains of two different grain sizes with sizes ranging from 60-160 microns and 160-500 microns, a ceramic bond, a filler in the form of a mixture of hollow spherical particles of fusible glass and hollow spherical particles of aluminosilicate size in the range from 85 to 560 microns and the corresponding additives (patent RU No. 2536576, IPC B24D 3/18, B24D 3/34, 12/27/2014). Thus, in an abrasive tool, the ratio of the particle size of the blowing agent and the size of the abrasive grain is 0.17-9.3.

The disadvantage of these tools is the impossibility of obtaining a satisfactory quality in terms of uniformity and uniformity of the structure of the tools due to the sharp difference in the specific gravity of the filler particles and abrasive grains. Such a difference will lead to stratification of the abrasive mass during its mixing and the formation of tool blanks. This will lead to the appearance of local foci of increased density, and, consequently, the heterogeneous distribution of the hardness of the crock of tools, which will increase their imbalance and reduce the quality of processing and productivity of the grinding process. In addition, the increased fragility of hollow spherical particles gives a high probability of their destruction even at the stage of formation of the structure of tools, especially when molding moldings. This will lead to a decrease in the strength of the tool as a whole, as well as to a decrease in their porosity by reducing additional pores on the working surface. The latter circumstance leads to salting of the working surface, increasing the heat stress of the grinding process and cutting forces, which significantly reduces the tool life and productivity.

A known abrasive tool made of abrasive mass containing abrasive grains of aluminum oxide or silicon carbide, a ceramic bond, a blowing agent and other components (copyright certificate SU No. 1689355, IPC С04В 35/18, С04В 35/63, B24D 3/18, С09K 3/14 , 11/7/1991). Moreover, the ratio of the particle size of the blowing agent and the size of the abrasive grain is 0.8-8.0, 1.3-6.7 and 2.5-14.5, respectively, for grains having sizes of 160-500 microns, 60-120 microns and 7-40 microns.

The disadvantage of this tool is the heterogeneity of the structure of the tool due to the sharp difference in particle size of the filler and abrasive grains, resulting in the formation of local foci of increased density, contributing to the heterogeneous distribution of hardness of the crock of tools.

The closest is an abrasive tool containing electrocorundum abrasive grains, a ceramic binder and boron carbide particles as an abrasive refractory filler, in which the particles of the abrasive refractory pore-forming filler are of equal size and shape with abrasive grains, while the ratio of the volume of the filler particles to the volume of abrasive grains is in the range 0.10-0.15 (patent RU No. 2215643, IPC B24D 3/18, 11/10/2003).

A disadvantage of the known tool is that in the grinding process, accelerated wear of the tool is observed due to the increased efforts of the filler particles to be pulled out of the bundle due to their large size, and as a result, the ceramic bond around the abrasive grains is further destroyed, which leads to a weakening of their fixing and premature removal from the working surface of the tool. All this leads to a significant decrease in tool life and productivity.

The proposed utility model solves the problem of increasing the strength and durability of an abrasive tool.

The technical result is to increase the durability and performance of the tool.

The technical result is achieved in an abrasive tool containing electrocorundum abrasive grains, a ceramic bond and boron carbide particles of the same shape as a pore-forming refractory filler, while boron carbide particles are isometric in shape with a rolled surface and a size of 0.35 ÷ 0.45 of the size of the abrasive grains.

The use of boron carbide particles with a size of 0.35 ÷ 0.45 of the size of electrocorundum abrasive grains, which is on average 2.5 times smaller in size compared with abrasive particles, can significantly reduce the efforts of tearing these particles out of the binder during the formation of a surface pore during grinding and reduce the zone of destruction of the ligament around the abrasive grains. In addition, this combination of particle sizes of the abrasive and pore-forming refractory filler provides a denser packing of abrasive grains and filler particles in the shard of the tool, providing an increase in the strength of the tool as a whole. The identical isometric shape of boron carbide particles with a rolled surface, unlike ordinary particles with sharp edges and peaks, helps to eliminate local foci of increased stress around these particles during the manufacturing process of the tool, leading to cracking in the bond and weakening of the abrasive grains and, as a consequence , to their premature removal from the working surface of the tool, creating additional pores on it during grinding without destroying the ligament around the abrasive grains.

Thus, in the proposed abrasive tool provides strength characteristics, durability and higher productivity.

For testing, the following abrasive grinding wheels were made: a wheel according to the prototype (example 4) and the inventive tool. The characteristics of the inventive abrasive tool are presented in the table.

A sample of a highly porous abrasive tool with an isometric-shaped boron carbide particle filler with a rolled surface and a size of 0.35 ÷ 0.45 of the size of the abrasive grains was made using the volume percent of the components in accordance with the prototype formulation (see Table). From the molding mass, consisting of electrocorundum abrasive grain, ceramic binder and boron carbide, “eight” samples were prepared for comparative tests on the mechanical strength of the proposed tool. The tensile strength of the calcined samples was determined on a testing machine UMM-5. Comparative tests of abrasive wheels on performance indicators: durability and performance. The tests were carried out on a surface grinding machine model 3E711. Samples from ШХ15 steel were processed. Grinding modes: V _cr = 35 m / s, V _st = 20 m / min, t = 0.01 mm / dv.

The table shows that the strength of the samples of the proposed tool is 1.14 times greater than that of the prototype tool samples. Analysis of the results on the performance and durability of the circles presented in the table shows that the proposed abrasive tool has the best values of these indicators compared to the prototype.

An increase in tool productivity occurs due to the implementation of boron carbide particles with an isometric shape with a rolled surface and a size of 0.35 ÷ 0.45 of the size of abrasive grains, which can significantly reduce the efforts of tearing these particles out of the binder during the formation of the surface pore during grinding and reduce the zones of destruction of the binder around abrasive grains. In addition, a denser packing of abrasive grains and filler particles in the shard of the tool is provided, increasing the strength of the tool as a whole. The use of isometric-shaped filler particles with a rolled surface in comparison with ordinary particles with sharp edges and vertices helps to eliminate local foci of increased stress around these particles during the manufacture of the tool, leading to cracking in the bond and weakening of the abrasive grains and, as a result, to their premature removal from the working surface of the tool, reducing its durability and performance. In this case, particles of an isometric-shaped filler with a rolled surface will more easily and quickly be removed from the working surface of the tool, creating additional pores on it during grinding without destroying the bond around the abrasive grains.

Thus, an abrasive tool containing electrocorundum abrasive grains, a ceramic bond and particles of boron carbide of an isometric shape with a rolled surface and a size of 0.35 ÷ 0.45 of the size of the abrasive grains, has an increased resistance and performance.

Claims (1)

An abrasive tool containing electrocorundum abrasive grains, a ceramic bond and boron carbide particles of the same shape as a pore-forming refractory filler, characterized in that the boron carbide particles are isometric in shape with a rolled surface and with a size of 0.35 ÷ 0.45 of the size of the abrasive grains .