RU88600U1 - INTERRUPTED GRINDING CIRCLE - Google Patents

Abstract

Intermittent grinding wheel containing an abrasive disk, characterized in that on the peripheral surface of the abrasive disk are depressions with an angle of inclination to the axis of rotation of the wheel equal to from 10 to 80 °, and an angular step equal to from 10 to 80 °.

Description

The utility model relates to mechanical engineering, to machining with an abrasive tool, in particular to grinding wheels for performing operations of flat grinding of parts from materials that are prone to defect formation in the form of burns and microcracks.

Known intermittent grinding wheel containing a prefabricated cylindrical wheel of thin abrasive discs mounted on a common shaft without axial clearance. While the discs are rotated by an angle α to a plane perpendicular to the axis of the common shaft with the formation of an inclined broken circle with an oval peripheral surface having protrusions and depressions (RF Patent No. 2137592, IPC V24V 53/00, B24D 5/00, publ. 1999).

A disadvantage of the known circle is the increased heat stress in the cutting zone due to poor air circulation during processing and the lack of self-sharpening.

Closest to the proposed utility model in terms of technical nature and the achieved result (prototype) is a prefabricated longitudinally discontinuous grinding wheel containing abrasive discs mounted on a common housing with an axial clearance relative to each other. In this case, the abrasive disks are made in the form of truncated cylinders, one of the ends of which is inclined at an acute angle to a plane perpendicular to the axis of rotation. Abrasive discs are installed in pairs by unbalanced parts in antiphase, diametrically opposite and beveled ends to each other so that the latter are parallel and inside the circle, and with the possibility of adjusting the gap between them using spacers (RF Patent No. 2192344, IPC V24V 1/00, publ. 2002).

The disadvantages of the described circle are the presence of high heat stress in the cutting zone due to poor air circulation during processing and the lack of self-sharpening due to the fact that the angle of inclination of the ends of the abrasive disks to a plane perpendicular to the axis of rotation of the disk is less than 10 °.

The proposed utility model solves the problem of reducing heat stress in the cutting zone and providing the possibility of self-sharpening the circle.

To achieve this technical result, an intermittent grinding wheel contains an abrasive disk, on the peripheral surface of which there are hollows with an angle of inclination to the axis of rotation of the wheel equal to from 10 ° to 80 °, and an angular step equal to from 10 ° to 80 °.

The reduction of heat stress in the cutting zone due to the creation of conditions for intensive air circulation is ensured by the fact that depressions are made on the peripheral surface of the abrasive disk with an angle of inclination to the axis of rotation of the circle equal to 10 ° to 80 ° and an angular step equal to 10 ° to 80 °.

The possibility of self-sharpening the circle is achieved by the fact that depressions are made on the peripheral surface of the abrasive disk with an angle of inclination to the axis of rotation of the circle equal to from 10 ° to 80 °.

The angle of inclination of the depressions to the axis of rotation of the wheel, equal to from 10 ° to 80 °, is optimal, as it provides intensive air circulation in the cutting zone and the possibility of self-grinding of an intermittent grinding wheel. Performing depressions at an angle of inclination less than 10 ° is impractical, since the operation of an intermittent grinding wheel may be accompanied by increased vibrations due to the shock nature of the work, and performing depressions at an angle of inclination greater than 80 ° is also impractical, since it does not provide intensive air circulation due to the fact that the cavities are not able to pump air to the cutting zone, and does not provide the possibility of self-grinding of an intermittent grinding wheel, since the cutting edges of an intermittent grinding wheel not subject to shock loads, as a result of which their destruction does not occur.

An angular step of 10 ° to 80 °, the location of the troughs is optimal, as it provides intensive air circulation and high cutting ability of the intermittent grinding wheel. The implementation of cavities with an angular step of less than 10 ° leads to a decrease in the cutting ability of the intermittent grinding wheel due to the fact that the surface area of the intermittent grinding wheel tends to zero, and an increase in the angular step, more than 80 °, reduces the air circulation in the cutting zone, which in turn leads to an increase in the heat stress of the grinding process and a decrease in air circulation in the cutting zone.

The proposed utility model is illustrated in the drawing, where Fig. 1 shows an intermittent grinding wheel, an end view; figure 2 too, side view.

In addition, figure 1, 2 shows:

φ is the angular pitch of the troughs, deg .;

α is the angle of inclination of the troughs to the axis of rotation of the circle, deg.

The proposed intermittent grinding wheel contains an abrasive disk 1 with a bore hole 2 located in the center and intended for installation on a spindle (not shown in the drawing). On the peripheral surface 3 of the abrasive disk 1 (FIG. 2), depressions 4 are made with an inclination angle α to the axis of rotation 5 of the circle equal to 10 ° to 80 ° (FIG. 2) and an angular pitch ϕ equal to 10 ° to 80 ° , (figure 1). The abrasive disk 1 may be made of abrasive material and ligaments, for example, electrocorundum on a metal ligament.

The proposed intermittent grinding wheel works as follows.

An intermittent grinding wheel is mounted on the machine spindle (not shown) with a bore 2. During operation, an intermittent grinding wheel is rotated around the axis 5 of rotation of the wheel, as well as a longitudinal and transverse feed. In contact with the workpiece surface being treated, the abrasive disk 1 by cutting grains located on the peripheral surface 3, metal is removed from the workpiece surface being processed. Due to the presence of depressions 4 made on the peripheral surface 3 of the abrasive disk 1, the cutting process is periodically interrupted in the cutting zone. Due to the interruption of the cutting process, the heat stress in the cutting zone is reduced (Yakimov A.V. Optimization of grinding processes / A.V. Yakimov - M .: Mechanical Engineering, 1975, p.45). The implementation of the depressions 4 at an angle of inclination α to the axis of rotation of the circle, equal to from 10 ° to 80 °, and an angular pitch equal to 10 ° to 80 °, allows you to create an air stream directed to the cutting zone, which also reduces the heat stress in the cutting zone. Therefore, the proposed intermittent grinding wheel allows to reduce the heat stress in the cutting zone, as well as to provide the possibility of self-grinding, which allows to increase the processing performance. The implementation of the depressions 4 at an angle of inclination α to the axis of rotation of the wheel, equal from 10 ° to 80 °, allows you to create conditions for the occurrence of shock loads on the cutting edges of an intermittent grinding wheel, which leads to their constant destruction and updating, which in turn provides the possibility of self-sharpening . The proposed intermittent grinding wheel can be used in any metalworking enterprises engaged in grinding hard-to-work materials and can increase the productivity of metal processing by reducing heat stress. The ability of the proposed wheel to self-sharpen allows you to reduce the number of edits of the intermittent grinding wheel, which reduces the time for its maintenance.

Thus, the use of the proposed utility model allows to reduce the heat stress in the cutting zone and to provide the possibility of self-grinding of an intermittent grinding wheel.

Claims (1)

Intermittent grinding wheel containing an abrasive disk, characterized in that on the peripheral surface of the abrasive disk are depressions with an angle of inclination to the axis of rotation of the wheel equal to from 10 to 80 °, and an angular step equal to from 10 to 80 °.