RU172335U1 - DEVICE FOR INSTALLING THE PROCESSED PARTS ON THE METAL-CUTTING MACHINE - Google Patents

Abstract

The device relates to removable devices for fastening, supporting or installing the workpiece or cutting tools in the working position and can be used to install flat round parts with non-parallel planes on metal cutting machines. The essence of the claimed technical solution lies in the fact that in the known device for mounting parts on metal-cutting machines, which includes a base and a vertical rotary element, made in the form of wedge disks having a common axis of rotation, while the beveled surfaces of the wedge disks are mutually mated, a node is introduced locking of the wedge disks, including a shaft located coaxially with the chuck of the metal cutting machine, and a self-aligning washer, which can provide mutual locking of the wedge claims when screwing the shaft into the threaded hole of the base, and directly on the vertical wedge disk, the fastening device of the workpieces is rigidly fixed. 3 ill.

Description

The device relates to removable devices for installation in the working position of the processed products or cutting tools and can be used for processing flat round parts with non-parallel planes on metal cutting machines.

A device for installing parts is known (AS 1143568 USSR, MKI B23Q 3/00. Device for installing parts [Text] / AM Afanasov, LN Bondarenko (USSR). - No. 3532095 / 25-08; decl. 07.01 .1983; publ. 07.03.1985, Bull. No. 9) containing a base made with an end beveled surface and with the possibility of installation in a machine chuck, a rotary wedge disk, a locking unit for said disk relative to the base, and a device for fixing the workpiece, rigidly fixed on the aforementioned disk, which with its sloping surface is mounted on constant surface of the base, wherein the rotation axis of said disc coincides with the axis of the base.

This design is closest to the claimed technical solution, therefore, adopted as a prototype.

The disadvantage of the prototype is the presence of complex nodes for mutual locking of the wedge disks and faceplates and fastening the workpieces.

The essence of the claimed technical solution lies in the fact that in the known device for mounting parts on metal-cutting machines containing a base made with an end beveled surface and with the possibility of installation in a machine chuck, a rotary wedge disk, a locking unit for said disk relative to the base, and a device for fixing the machined parts rigidly mounted on said disk, which is mounted with its beveled surface on the beveled surface of the base, the axis of rotation being mentioned of the disk coincides with the axis of the base, said base and the disk are made respectively with axial threaded and axial holes, wherein said locking unit is made in the form of a shaft installed in the axial hole of said disk with a threaded part located in the axial threaded hole of the base with the possibility of screwing the shaft into it, and a self-aligning washer placed on the shaft with the possibility of interacting with the rotary wedge disk and locking it when screwing the shaft.

Thus, the claimed technical solution differs from the prototype in that the said base and the disk are respectively made with axial threaded and with axial holes, while said locking unit is made in the form of a shaft installed in the axial hole of the disk coaxially with the threaded part located in axial threaded hole of the base with the possibility of screwing the shaft into it, and a self-aligning washer placed on the shaft with the possibility of interaction with the rotary wedge disk and its locking When turning the shaft.

A comparative analysis of the claimed utility model with other technical solutions showed that the use of locking units, including a shaft with a threaded part, is widely known in the art. However, only the claimed technical solution allows to simplify the orientation of the round billet relative to the cutting plane on metal cutting machines. The implementation of the base and the rotary wedge disk, respectively, with axial threaded and axial holes and the location in the axial threaded hole of the base of the shaft allows you to rotate the rotary wedge disk relative to the base. The presence of a threaded part on the shaft allows it to be screwed into and out of the threaded hole. Placing a self-aligning washer on the shaft with the possibility of interacting with the rotary wedge disk and locking it when screwing the shaft allows, by turning the said shaft, reliably lock the rotary wedge disk relative to the base in the desired position.

In FIG. 1 shows a device for installing the workpiece on a metal cutting machine, a longitudinal section.

In FIG. 2 shows the location of the claimed device on a lathe.

In FIG. 3 shows a layout of geometric points and lines on a round part with non-parallel planes.

The specification of FIG. 3:

A, B, C, D - the thickness of the part is round in shape with non-parallel planes at the points at which the gaps between the mating planes are measured, mm;

C is the geometric center of a round shape with non-parallel planes;

m, n are points at which the thickness of the part has either a maximum or a minimum value;

pq is the line along which the part thickness t _const has a constant value;

D _ext. - internal diameter of the part, mm;

D _nar. - outer diameter of the part, mm.

A device for mounting a workpiece on a metal cutting machine includes a base 1 made with an end beveled surface and with the possibility of installation in a machine chuck, a rotary wedge disk 2, with its beveled surface mounted on a beveled surface of the base, a mounting device for workpieces 3, in which a turning chuck is used, a locking unit for a rotary wedge disk, including a shaft 4 located coaxially with a rotary wedge disk, a self-aligning washer 5, o a boundary washer 6, having a fixed position on the shaft 4, fastening parts - a washer 7 and a nut 8, as well as a clamping ring 9. The fastening device of the workpieces 3 is fixed to the rotary wedge disk 2 with screws 10. There is zero risk on the side surface of the base 1 and vernier scale, a circular scale with degrees in degrees is plotted along the perimeter of the lateral surface of the rotary wedge disk 2.

The device operates as follows.

Install the device in the chuck of a metal cutting machine and fasten it with cams to the base 1. Rotate the rotary disk 2 to the design angle to set the desired machining plane of the part using the rotary disk circular scale, as well as zero risk and vernier scale applied to the side surface of the base 1. Insert the clamp a key into the central hole of the fastening device of the workpieces 3 before docking with the shaft 4 of the locking unit and rotating the shaft to failure, lock the rotary wedge disk 2 relative tionary base 1. Fix the workpiece in jaws of fastening device 3. workpiece to obtain the desired sizes. At the end of processing, using the clamping key, turning the shaft of the locking assembly 4 against the stop in the restrictive washer 6, the rotary wedge disk 2 is disengaged from the base 1, while the self-aligning washer 5 remains pressed against the spherical surface of the shaft 1 due to the elastic forces of the pressure ring 9. If there is a central hole in the part, sufficient for the passage of the clamping key, the workpiece can be installed in the mounting device 3 to set the desired plane of its processing.

In the absence of a calculation program, the desired processing plane of the part can be set by rotating the rotary wedge disk 2 with simultaneous measurement of deviations in the vertical plane of the point h _min , in which the thickness of the part will have a minimum value after processing from the point h _max , in which the thickness of the part will have a maximum value . In this case, the calculation of the maximum and minimum thickness of the wedge lining is performed according to the formulas

where c is the thickness of the lining along the line p-q, mm;

f is the increment of the thickness of the lining at points m and h relative to point C, mm

The calculation of the thickness of the wedge lining along the p-q line is performed according to the formulas

The calculation of the increment of the thickness of the lining at points m and h relative to point C is performed according to the formulas

The calculation of the deviation in the vertical plane of the point h _min from the point h _max is performed according to the formula

The claimed technical solution greatly simplifies the orientation of the workpiece relative to the cutting plane on metal cutting machines, because for this, it is only necessary to combine the calculated value of the angle on the dial of the rotary disk with zero risk applied to the side surface of the base 1, using the vernier scale for accurate angle setting. In the absence of a calculation program, the orientation of the workpiece relative to the cutting plane on metal cutting machines is performed without the use of squeezing devices, and the deviation of the surface of the workpiece from the vertical plane is measured only at two points characterizing the smallest and largest thickness of the workpiece with non-parallel planes.

Claims (1)

A device for mounting a workpiece on a metal cutting machine, comprising a base made with an end beveled surface and with the possibility of installation in a machine chuck, a rotary wedge disk, a locking unit for said disk relative to the base, and a device for fixing the workpiece rigidly fixed to the said disk, which the beveled surface is mounted on the beveled surface of the base, and the axis of rotation of the said disk coincides with the axis of the base, characterized in that said the base and the disk are respectively made with axial threaded and axial holes, wherein said locking unit is made in the form of a shaft mounted in the axial hole of said disk coaxially with the threaded portion located in the axial threaded hole of the base with the possibility of screwing the shaft into it, and a self-aligning washer placed on the shaft with the possibility of interaction with the rotary wedge disk and its locking when screwing the shaft.

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