SU1729702A1 - Boring head - Google Patents

Abstract

Usage: boring stepped holes through a hole of a smaller diameter, in particular the boring of stepped holes-samples in one part of the blind holes. SUMMARY OF THE INVENTION: The head comprises a housing 1 in which a mandrel 3, a tool holder 6 with a cutter 9, an average adjusting sleeve 5 and an extreme adjusting sleeve 4 are mounted with an eccentricity relative to its axis. On the mandrel, different thread sections are made for interactions with the tool holder and extreme adjusting sleeve, in which, respectively, threaded holes with different pitches are made with an eccentricity. The middle adjustment sleeve is made with a threaded hole of the same pitch as the tool holder sleeve, and is mounted on the mandrel with the possibility of rotation and engagement with the tool holder sleeve and the extreme adjustment sleeve. 3 hp f-ly, 6 ill.

Description

Fy

The invention relates to metal cutting and can be used for boring in body parts of stepped holes through a hole of smaller diameter on horizontal boring and vertically boring machines, in particular for boring stepped holes in the bottom of blind holes,

A known boring bar with an eccentric mounted cutter for machining stepped holes through a hole of smaller diameter, in which the housing is provided with an eccentric bearing guide, whose axis is offset relative to the housing axis by an amount defined as the difference between the radius of the hole being machined and the distance from the tool tip to axis of rotation borschangi.

A known boring head comprising a housing with a cylindrical mandrel, a tool-cutting bushing with a cutting tool, an average adjusting sleeve and an extreme adjusting sleeve, the working sections for interacting with the tool-fixing sleeve and an extreme adjusting sleeve, and an average adjusting sleeve installed on the mandrel. the mandrel can be rotated and interacts with the tool holder and the extreme adjusting sleeve.

A disadvantage of the known boring head is the limited technological capabilities that do not allow processing for several working strokes of stepped holes located in the depth of the hole to be machined, as well as steps of different diameters when a larger diameter bore is located at the bottom of the blind hole.

The purpose of the invention is to expand technological capabilities by continuously adjusting the radial size of the cutter, as well as enabling the boring of larger diameter holes located in the bottom part of blind holes for several working strokes.

The goal is achieved by the fact that in a boring head comprising a body with a cylindrical mandrel, a tool holder bushing with a tool bite, an average adjusting sleeve and an extreme adjusting sleeve, and the mandrel has working sections designed to interact with the tool bushing and an extreme adjusting sleeve, and The middle adjustment sleeve is mounted on the mandrel so that it can be rotated and interacts with the tool holder and the extreme adjustment sleeve; on the housing

with an eccentricity about its axis, and the working areas on it are threaded with different steps, while in the hub of the tool holder and the extreme adjusting hub, respectively,

with an eccentricity, threaded holes with different pitch, and the middle adjusting sleeve are made with a threaded hole of the same step as the tool holder, and on the end surfaces of the tool holder and the middle adjustment sleeve, protrusions and depressions are used to match them, and on the outer surfaces cylindrical surface of the extreme adjustment sleeve on the side

end, designed to interact with the middle adjusting sleeve, applied calibration scale of the radial displacement of the cutter with the cost of division

. (eW)

180 ° -P2

where Pi is the thread pitch of the extreme adjustment bush, mm; 2 - thread pitch of the tool holder, mm; a ° jPil-central angle of one dividing scale on the extreme adjusting bush, deg .; e is the displacement of the axis of the mandrel relative to the axis of the housing, mm; e is the offset of the axis of the sleeve-toolholder relative to the axis of the mandrel, mm.

The boring head is additionally equipped with an elastic element installed between the middle and extreme adjusting bushings, balls mounted in the separator between the ends of the middle and extreme adjusting bushings, and an eccentric sleeve designed to secure the mandrel in the housing.

 The proposed boring head provides for expanding technological capabilities when boring stepped holes in body parts on boring machines for several working strokes with stepless adjustment of the size of the tool extension, ensuring the supply and removal of the tool from the surface to be processed by expanding the bore diameter of the tool holder. , boring stepped holes-samples in the bottom of the blind holes for several working strokes.

FIG. 1 shows a boring head, a general view; in fig. 2 — node I in FIG. one; in fig. 3 is a view A of FIG. one; in fig. 4 - scheme

boring a stepped hole in several working strokes; in fig. 5 is a diagram for adjusting the position of the boring bit when boring; in fig. 6 — node II in FIG. 1 (option).

The boring head includes a housing 1, in a threaded hole of which a sleeve 2 is placed with a threaded hole eccentrically located relative to the axis of the housing (machine spindle axis) with eccentricity e, into which a mandrel 3 is screwed, on which threaded sections I are made, 2 threaded according to step Pi , Pr, threaded section I with a threaded pitch PI, adjacent to the body of the boring head, mates with an eccentrically made eccentricity e with a threaded hole of the extreme adjusting bush 4, and threaded section 2 with a threaded aga Pa is coupled with an eccentric eccentricity e with a threaded hole of the middle adjusting sleeve 5 and the tool holder 6, and the middle adjusting sleeve 5 is in contact with one end, on which an annular groove of radius r is made through balls 7 of radius r installed in the separator 8, with reciprocal ring groove extreme adjusting sleeve 4, and the other end, which is made protrusions and depressions, for example, trapezoidal profile (figure 2), is in contact with the counter protrusions and depressions on the front The surface of the tool holder sleeve 6, on the front end of the tool holder sleeve 6 at an angle p ° to the axis is fixed a cylindrical cutter 9, the extension of which is adjusted by a screw 10, and the cutter itself is fixed in the tool holder sleeve 6 with screws 11 and 12. Circular position of the extreme adjusting sleeve 4 and the middle adjustment sleeve 5 is fixed by screws 13 and 14. The sleeve 2 is locked with a screw 15. On the cylindrical surface of the extreme adjustment sleeve 4 in the area adjacent to the middle adjustment sleeve 5, a reference scale is applied scheny cutter 9 (fig.Z). The protrusions and depressions on the end surfaces of the middle adjustment sleeve 5 and the toolholder sleeve 6 serve to set the initial position of the boring tool (when they are reciprocally shifted) to the diameter do, which on the graduation scale of the extreme adjustment sleeve corresponds to reading O.

In order to ensure the smoothness of the penetration of the boring tool to the depth of the allowance at the working passages, the boring head is provided with an elastic element 16 installed between the middle and extreme adjusting bushings.

The scale of the radial movements of the boring cutter is made with the price of 5 divisions.

Pi -otflPii

AR

(e + e)

180 ° P2 where PI is the thread pitch of the extreme adjustment sleeve, mm; P2 is the thread pitch of the tool holder sleeve, mm; 2n IPil - the central angle of a single division of the scale of the extreme adjusting bush, degrees; e is the displacement of the axis of the mandrel relative to the axis of the housing, mm; e 5 offset of the axis of the sleeve-toolholder relative to the axis of the mandrel, mm.

The boring head works as follows.

The body 1 of the boring head is installed in the machine spindle and secured. Using the adjusting screw 10 and the graduation scale on the extreme adjusting sleeve 4, the boring cutter outreach corresponds to the diameter of the bore hole do (О on the scale of the extreme adjusting sleeve 4 and the middle sleeve 5 (Fig. 5, position Е). Axial movement of the spindle of the machine boring the head is inserted into the bore

0 the hole to the desired depth corresponding to the position of the beginning of the stepped hole, then rotating the extreme adjusting sleeve 4 to the left (counterclockwise) on the graduated scale sets the incision size of the tool to the first working stroke (radial displacement of the tool by the amount of allowance ti of the first work), then the position of the extreme adjusting bush 4 is fixed by screw 0. Then, by turning the tool holder 6 to the left (counterclockwise), the cutter is brought to touch with the surface to be treated, After that the machine spindle rotation with minimal reporting

5 rotational speed. Under the influence of friction on the contact surface of the cutting edge of the tool with the surface to be machined and under the action of an unbalanced inertial mass, the tool hub 6 automatically rotates (counterclockwise), and the tool cuts into the cutting depth of the extreme adjustment sleeve 4 (figure 5, position G) ti. Wherein

5 due to the difference in the pitch of the thread sections with the pitch PI and Pa; the tool-cutting sleeve 6 together with the middle sleeve 5 with the thread pitch Pa, interacting with each other through the projections and depressions of the trapezoidal profile, comes into contact through

balls 7c extreme adjusting sleeve 4 (thread pitch Pi), and the axial component of the cutting force is perceived extreme adjusting sleeve 4, which has a threaded hole with a different thread pitch Pa than the middle sleeve 5 and tool holder sleeve 6 (thread pitch P2). After cutting the cutter into the cutting depth ti (Fig. 4), the spindle of the machine with the boring head reports the working speed and movement of the axial feed for a given length of the stepped hole, after which the spindle of the machine is returned to its original position and its rotation is turned off. By turning the extreme adjustment sleeve 4 to the left (counterclockwise) on the scale of movements, set the size of the allowance for the second working stroke (Fig. 5, position 3), and the cycles are repeated until the specified diameter of the bore is reached.

The axial movement of the boring tool on the working strokes, caused by the rotation of the tool holder sleeve, is taken into account by the corresponding initial axial displacement of the machine spindle.

After stopping the spindle of the machine after finishing boring the stage, rotating the extreme adjusting sleeve 4, the tool holder sleeve 6 together with the middle sleeve 5 to the right (clockwise) establish the initial position of the boring head and the spindle of the machine with the boring head is removed from the hole,

The proposed boring head for boring stepped holes in body parts can be used in various fields of engineering, in particular, in power engineering, heavy, transport, chemical and other parts of engineering.

Claims (4)

Claims 1. A boring head comprising a housing with a cylindrical mandrel, a cutter sleeve with a cutter, a middle adjusting sleeve and an extreme adjusting sleeve, wherein the mandrel is provided with working sections designed to interact with the cutter holder and an extreme adjusting sleeve, and The adjusting sleeve is mounted on the mandrel with the possibility of rotation and interaction with the tool holder and the extreme adjusting sleeve, which means that, in order to expand the process Due to the infinitely variable adjustment of the radial size of the cutter, as well as the possibility of boring the larger diameter holes located at the bottom of the blind holes for several working strokes, the mandrel is fixed in the housing with eccentricity about its axis, and the working sections on it are threaded with different steps , at the same time respectively in the sleeve of the tool holder and the extreme adjusting sleeve are made with an eccentricity, threaded holes with different pitch, and the middle adjusting sleeve are made with a threaded hole of the same step as the tool holder, and on the end surfaces of the tool holder and the middle adjustment sleeve, protrusions and depressions are used to match them, and on the outer surfaces cylindrical surface of the extreme adjustment sleeve on the side end, designed to interact with the middle adjusting sleeve, applied graduated scale of the radial displacement of the cutter with the cost of division PI / ty i PI I AR P1 n Pli - (e + e), 180 ° P2 V where Pi is the thread pitch of the extreme adjustment bush, mm; Ra thread pitch of the toolholder, mm; оЈ IPil - the central angle of a single division of the scale of the extreme adjusting bush, degrees; e is the displacement of the axis of the mandrel relative to the axis of the housing, mm; e is the offset of the axis of the sleeve-toolholder relative to the axis of the mandrel, mm, 2. The head according to claim 1, characterized in that it is additionally equipped with balls installed in the separator between the ends of the middle and extreme adjustment sleeves. 3.Head on PP. 1 and 2, that is, with the fact that it is additionally equipped with an elastic element placed between the middle and extreme adjusting sleeves. 4. The head according to claim 1, in that it is additionally provided with an eccentric sleeve designed to secure the mandrel in the housing. FIG. 2 MA 58 L / Fig.Z