RU2436666C2 - Method to install and adjust stocks of parts, such as shafts - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to the technology of machine building and may be used in processing of parts, such as shafts, in machines, for instance, lathes, cylindrical grinding machines. Prior to finishing treatment operation, the processed stock is checked, and value and position of radial striking is detected in horizontal and vertical planes. Then the stock is installed on the back ball rotary centre. The centre comprises a hollow tail with the external surface in the form of a Morse cone and a spindle. The spindle is equipped with a working cone and is arranged in the tail cavity on rolling bearings. At the end of the spindle there is a flange with a dead hole, in which there is a working cone installed with the help of a collet eccentric disc, having an eccentrically displaced step. The step is fixed in the flange by means of screws that are radially arranged and screwed into threaded holes provided on the flange. Prior to the finishing treatment the axis of the working cone displacement by the detected value of radial striking with the help of the back centre.

EFFECT: invention provides for reduced error and simplified process of stock installation.

10 dwg

Description

The invention relates to mechanical engineering technology, to the processing of parts such as shafts on turning, circular grinding and some other machines.

There is a method of installation and alignment of workpieces such as shafts on rotating centers, manufactured according to GOST 8742-75, and non-standard [1]. Rotating centers are used to install shaft blanks with center holes or conical chamfers. Shank dimensions - Morse cones 2-6 for the normal series; 4-6 for the reinforced series. Rotating centers are used as rear centers when machining with high cutting speeds and a workpiece mass of up to 20 tons. The installation accuracy at such centers is lower than on solid non-rotating ones. The radial runout of the surface of the working cone relative to the shank cone is from 0.007 to 0.015 mm. Processing of cones by the tailstock displacement method is carried out with installation on ball centers. The centers are made with the angles of the working cone 60 and 75 ° [2].

A known method of installation and alignment of workpieces of parts such as shafts for finishing, including monitoring and identifying the magnitude and position of the radial runout of the workpieces in horizontal and vertical planes, installing the workpiece on the rear ball rotating center, consisting of a hollow shank, the outer surface of which is made in the form of a Morse cone moreover, in the inner cavity on the rolling bearings with the possibility of rotation is a spindle with a working cone [3].

A disadvantage of the known methods and design of the centers by which the methods are implemented is the impossibility of adjustment and alignment in order to reduce installation and processing errors arising from intermediate operations (for example, rough turning, chemical-thermal: cementation, hardening, etc. when processing non-rigid shafts ) the technological process, and the need to introduce a straightening operation, which increases the cost of manufacturing the workpiece and complicates the process.

The objective of the invention is to expand the technological capabilities of the method and the equipment that implements it, which allows for the adjustment and alignment when processing workpieces of parts such as shafts in order to reduce the installation error, and simplify the process.

The problem is solved by the method of installation and alignment of workpieces of parts such as shafts on the machine during finishing, which includes monitoring the workpiece before the finishing operation and identifying the magnitude and position of the radial runout of the workpiece in horizontal and vertical planes, then installing the workpiece on the rear ball rotating center, consisting from a hollow shaft with an outer surface in the form of a Morse cone and located in its internal cavity on rolling bearings with the possibility of rotation spindle with a working cone, while before finishing, the axis of the working cone of the rear ball rotating center is shifted by the detected radial runout, and the rear ball rotating center is used, on the spindle end of which there is a flange with a blind hole, in which with the help of a collet eccentric disk a working cone is installed having an eccentrically offset step, by means of which it is fixed in the spindle flange with screws radially located and screwed into the threaded holes Stia provided on the flange.

Figure 1 shows a blank of a non-rigid shaft having an error e _З obtained in the first operations (for example, on rough turning, during cementation, hardening) of the technological process and detected when the test bench is installed on coaxial centers [3]; figure 2 - the same, the workpiece is installed in the centers, while the rear centering hole is offset relative to the total longitudinal axis of the workpiece by the value of the error of radial runout e ₃ , figure 3 is a diagram of the installation of the shaft workpiece in ball centers using a clamp and a leash, thin lines show the diametrically opposite position of the rear working cone during its planetary rotation; figure 4 - center design, side view, longitudinal section, the center is set to zero eccentric displacement of the working cone relative to the longitudinal axis of the shank, i.e. radial runout e = 0; figure 5 - ball working cone with an eccentrically offset step, side view; in Fig.6 is a view according to B in Fig.5, a view from the side of the eccentrically offset stage; Fig.7 - collet eccentric disk, side view, a longitudinal section; in Fig.8 is a view along A in Fig.7, an end view from the side of the collet step; figure 9 is a diagram of the planetary movement of the rear cone, a cross-section along BB in figure 3, increased; figure 10 is a General side view, the working center is shown in a diametrically opposite position relative to the position in figure 4, the center is configured for maximum eccentric displacement of the working cone relative to the longitudinal axis of the shank, i.e. radial runout e = max.

The proposed method is intended for installation and alignment of workpieces of parts such as shafts. According to this method, the workpieces being processed before finishing operations are monitored and radial runout and deviation of the position of the workpiece in horizontal and vertical planes are detected, and then the workpiece is mounted on the rear ball rotating center. Workpieces such as shafts, when machining them on turning, circular grinding and some other machines, are installed with center holes or conical chamfers on ball rotating centers.

The ball rotating center that implements the proposed method consists of a hollow shank 1 with an outer surface made in the form of a Morse cone (see figure 4). Shank dimensions can be made according to GOST 8742-75. Shank dimensions - Morse cones 2-6 for the normal series; 4-6 for the reinforced series. In the inner cavity of the shank on the rolling bearings 2 and 3, a spindle 4 with a working cone 5 is rotatably located. The working cone is made of two stages (see Figs. 5-6), while the axis of the smaller diameter that it is attached to the spindle is eccentrically displaced by the value of the radial runout e relative to the axis of the cone of the larger step. The end face of the spindle from the side of the working cone is made in the form of a flange 6. The working cone is installed in the blind hole of the flange using a collet eccentric disk 7. The disk has two stages (see Figs. 7-8), of which the smaller stage 8 is a collet. The outer surface of the larger step of the disk is concentric with the inner surface of the hole. The axis of the outer surface of the collet step is shifted by the amount of eccentricity e relative to the axis of the hole of the disk.

The disk is eccentrically offset by a collet step mounted in the flange with screws 9, radially located and twisted into the threaded holes of the flange.

The center is assembled in the following sequence. Spindle 4 is assembled into the longitudinal hole of the shank 1 with bearings 2 and 3. From the side of the smaller diameter of the shank, the cap 10 is screwed into the threaded hole. The working cone 5 is fixed in the flange 6 of the spindle 4 with screws 9 through the disk 7. Screws 9 having a hexagonal a turnkey hole, screwed into radial threaded holes located in the flange, transfers the clamping forces to the collet petals, which, in turn, moving radially to the center, fix and fix the working cone in this position 5. Adjustment to the the eccentricity e of the displacement of the axis of the working cone relative to the longitudinal axis of the spindle is carried out by mutual rotation of the disk and the working cone, the value of which is controlled by a scale 11 applied on the periphery of the large step of the disk and zero risk 12 applied on the working cone (see Fig. 10) . The working cone is rotated relative to the collet disk with the screws released using the handles 13 and 14 mounted respectively on the working cone and the disk, while the handles are removable and installed for the time of adjustment and regulation (see Fig. 4).

The eccentric displacement of the axis of the working cone relative to the axis of the shank by an amount e allows the planetary movement of the axis and allows adjustment and alignment in order to reduce the installation error (see Fig. 9).

Work using the proposed center is as follows.

After performing rough, semi-finished and chemical-thermal operations, critical parameters are checked using a special stand [3], where the workpiece of the processed shaft is installed in the centers and the deviation of the radial runout e, its size and location are detected (see Fig. 1). Left finishing allowance for finishing (cylindrical surface of a small step) may not be enough, and after finishing, rough draft sections will remain, which will lead to marriage. The end surface of the step with a maximum diameter may not be perpendicular to the longitudinal axis of the workpiece and will require the removal of a large allowance not provided for by the process.

Next, set the measured radial runout parameter e on the back center of the proposed by turning the working cone relative to the disk using the handles 13 and 14, using the scale 11 and 12, applied to the disk and the working cone (see figure 10). The final finishing operations are performed with preloading by the proposed rear center with a planetary, eccentrically displaced cone (see Figs. 3, 4).

The use of the proposed method and center is recommended in the manufacture of non-rigid shafts, drums, cylinders, as well as various blanks mounted on mandrels.

The center is used as a back when installing the workpiece in the cartridge in case of large diameter and length in the absence of a center hole from the front headstock.

The proposed method and center make it possible to adjust and reconcile in order to reduce installation errors that occur during intermediate operations of the technological process, for example, rough turning, chemical-thermal: cementation, hardening, etc. when processing non-rigid shafts.

The proposed method and the center expands the technological capabilities of the process, allows for the adjustment and alignment when processing workpieces of parts such as shafts in order to reduce the installation error, simplifies the process, namely, allows to abandon the "straightening" operation, increases productivity, improves processing quality and reduces the cost of processed products.

Claims (1)

The method of installation and alignment of workpieces of parts such as shafts on the machine during finishing, including monitoring the workpiece before the finishing operation and identifying the size and position of the radial runout of the workpiece in horizontal and vertical planes, then installing the workpiece on the rear ball rotating center, consisting of a hollow shank with the outer surface in the form of a Morse cone and located in its inner cavity on rolling bearings with the possibility of rotation of the spindle with a working cone, distinguishes In that, before finishing, the axis of the working cone of the rear ball rotating center is shifted by the detected radial runout, while the rear ball rotating center is used, on the spindle end of which there is a flange with a blind hole in which the working cone is mounted using a collet eccentric disk having an eccentrically offset step, by means of which it is fixed in the spindle flange with screws radially spaced and screwed into the threaded holes provided and the flange.

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