SU1787695A1 - Boring head - Google Patents

Description

The invention relates to the processing of metals by cutting and can be used for boring in case details of stepped holes. Through a hole of a smaller diameter on boring machines, in particular 5 for boring stepped holes in the bottom of blind holes.

There is a ра 'Т Т Т ю овка head containing a body equipped with an eccentric sleeve designed to secure 10 mandrels in a body with an eccentricity relative to its axis, the working sections of which are threaded with different steps, the tool holder and an adjusting sleeve are installed on the threaded sections. with a reference scale for radial displacements of the cutter, while in the sleeve of the holder and the adjusting sleeve threaded holes with different steps are made with eccentricity, the adjusting sleeve 20 has means iksatsii relative threaded mandrel _head: the separator is provided with the balls and the elastic member.

A disadvantage of the known boring head is the limited range of regulation of the radial movements of the boring tool.

The aim of the invention is the expansion of technological capabilities by expanding the range of diameters of the boring stages by expanding the limits of regulation of the diameter of the radial movements of the cutting element.

This goal is achieved by the fact that 35 in a boring head containing a body equipped with an eccentric sleeve designed to fix the mandrel in the body with an eccentricity relative to its axis, the working sections on which are performed at 40 yen with different thread steps, a tool holder is installed on the threaded sections and an adjusting sleeve with a scale for counting the radial movements of the cutter, while in the cutter sleeve 45 holder and the adjusting sleeve, threaded holes with different steps are made with eccentricity, adjustable Naya sleeve has retaining means with respect to the threaded mandrel head 50 is provided with a cage with balls and elastic member according to the invention, the eccentricity of the housing opening relative to its axis is made a value determined from the condition of 55 es = ei - er.

where ei is the eccentricity of the sleeve hole of the holder: ei is the eccentricity of the hole of the sleeve, the sleeve is fixed in the housing with a tangential clamp, holes are made on the end surface of the sleeve for rotation, and the fixing means of the adjustment sleeve are made in the form of a lock nut. An additional reference scale of radial displacements of the cutting element is applied to the end surface of the sleeve, the division value of which is equal to the value determined from the condition

C = (ex + e3) cos a, where a is the central angle around the circumference of the position of the center of the mandrel in the range of 0360 °, and the scale of reference for the radial movements of the cutting element, made on the adjusting sleeve, has a division value of a value determined from the condition d p _ ^ 1 '(PQ

180 ° · P ₂ (ei + C), where Pi is the thread pitch of the adjusting sleeve, mm; Rg - thread pitch sleeve-tool holder, mm; ei is the eccentricity of the hole of the tool holder sleeve relative to its axis, mm; eg is the eccentricity of the bore of the sleeve relative to its axis, mm; ez is the eccentricity of the housing opening relative to its axis, mm, a _r i (Pi) is the central angle of one scale division of the adjustment sleeve, deg.

The proposed boring head provides the expansion of technological capabilities for boring stepped openings in case parts on boring machines in several working strokes by expanding the range of regulation of the extension of the cutting element and providing a greater difference between the diameter of the boring steps, the initial diameter of the hole and the diameter of the tool holder.

In FIG. 1 shows a General view of the boring head; in FIG. 2 is a view along arrow A in FIG. V in FIG. 3 is a section BB in FIG. 1; in FIG. 4a, section BB of FIG. 1. when the sleeve is in the upper position; in FIG. 46 - section BB in the rotation of the sleeve 180 °; in FIG. 5 is a diagram for calculating a graded reference frame for a change in the total eccentricity (e + ez) when the sleeve is rotated for three values of the rotation angle; it is in FIG. 6 is a diagram of the installation of a boring head in the boring hole in the initial position do = d _p : in FIG. 7 is a diagram of the regulation of the radial size of the cut-in R _Bp when boring the stage D _p , I initial position. II - final position.

b

The boring head comprises a housing 1, in an eccentric eccentricity ez relative to the axis of the housing 1 of which a sleeve 2 is fixed with a threaded hole eccentrically located 5 with an eccentricity eg relative to the axis of the sleeve, into which a mandrel 3 is screwed, on which the threaded portions h are made, 1g with thread corresponding to pitch Pi, Р _г , threaded portion h with thread 10 of step Р1 adjacent to the body of the boring head, is coupled to the threaded hole of the lock nut 4 and the eccentricity eccentricity of the alignment sleeve 5, and the threaded portion 1d with a thread 15 of the pitch P _{2 is} coupled to the threaded hole of the tool holder sleeve 6 eccentric with eccentricity ei, with-. than the adjusting sleeve 5 is contacted by one end, on which an annular groove of radius r is made through balls 7 fixed in the separator 8 with a reciprocal annular groove of the elastic element 9, the other end of which contacts the end of the tool-holder sleeve 6, at the front end of which at an angle <p ° to the axis, a cutter of cylindrical shape 10 is fixed, the extension of which is regulated by screw 11, and the cutter itself is fixed by screws 12. The position of the mandrel 3 in the sleeve 2 is fixed with screw 50 volume 13, the position of the sleeve 2 is fixed with a tang With a special clamp containing the rod 14, the sleeve 15 and the nut 16, the rod is secured against rotation by the screw 17. On the outer surface of the sleeve 55 of the tool holder 6, the adjusting sleeve 5 and the lock nut 4, holes D are made, using which a special key is used to rotate bushings and locknuts when adjusting the size of the extension of the boring tool, holes E are made on the end surface of the sleeve 2, by means of which a special key is used to rotate the sleeve 2 when adjusting ^ 5 of the total eccentric iteta (er + es). On the cylindrical surface of the adjusting sleeve 5 in the areas adjacent to the lock nut 4 and the elastic element 9, the scales G of the reference frame of the radial displacements of the cutter 10 are inserted (Fig. 2).

The reference scale of the radial movements of the insertion of the boring tool on the working strokes is graduated according to dependence 55

180 ° · P ₂ (θ1 ⁺ C) _? where C = (e ₂ + ez) cos and ei is the eccentricity of the hole of the holder sleeve relative to its axis, mm; eg is the eccentricity of the bore of the sleeve relative to its axis, mm; ez is the eccentricity of the housing opening relative to its axis, mm: On (Pi) is the central angle of one division of the adjustment sleeve, deg; Pi is the thread pitch of the adjusting sleeve, mm; Rg - the thread pitch of the sleeve-tool holder, mm: a - the Central angle on the circumference of the position of the center of the mandrel in the range 0-360 °, deg.

On the outer surface of the sleeve-tool holder 6, the adjusting sleeve 5 and on the housing 1 are made flats And and the risks are 0 of the reference point of the movements of the cutting element according to the position at which the values of the eccentricities are summed. The graduation of an additional reference scale of radial movements of the cutting element on the end surface of the sleeve is carried out (Fig. 5) according to the condition

Cn = (er + ez) soe a _p , where η is the number of divisions of the additional graduated scale: (1 _L ~ central angle on the circumference of the position of the center of the mandrel in the range 0-360 °.

When the position of the sleeve 2 in the housing shown nafig. 1, the diameter of the boring stage is controlled by changing the circular position of the tool holder sleeve, while the regulation limits are determined from the expression •

Dpi = 2 2 (ei + eg + ez), 1 = o where η is the number of graduated scale divisions at 1/9 of the angle of rotation of the adjusting sleeve.

When the sleeve 2 is rotated 180 °, the axis of the mandrel, when equal to e = ez, is aligned with the axis of the housing 1, while e = 0 and the diameter ’of the boring is

D _p = dp + 2ei (1)

With intermediate positions of the sleeve 2 in the range from 0 to 180 °, the limits of regulation of the boring stage are determined from the expression

Dpi = 2 § (ei + Ci) (2)

I = o

Cl = (er + e3) cos щ, (3) where a i is the angle on the circumference of the position of the center of the mandrel, deg; η is the number of divisions of the graded additional scale. Given that the angle a can vary from 0 to 90 ° (Fig. 5), the largest boring diameter is provided at <7i = 0 ° and is determined by the expression

Dp. Naib. = dp + 2 (et + e ₂ + ez)

The boring head is equipped with a set of adjusting sleeves with scales graduated for various values of C5 (4-5 sleeves), covering the entire range of changes in the total value of the eccentricities (e ₂ + ez) with the accepted interval, for example, through 1 mm,

Work using a boring head is as follows. By turning the sleeve 2, the required value of the total value of the eccentricities is set and the sleeve is fixed with a tangential clamp, the housing of the boring head is fixed in the spindle of the machine. Using the adjusting screw 11 and screw 12 set the desired overhang of the cutter, taking into account the diameter of the hole d ₀ . By axial movement of the machine spindle, the boring head is inserted into the bored hole to the required depth corresponding to the beginning of the stepped hole, and then by turning the adjusting sleeve 5 to the left on a graduated scale, set the size of the cutter for the first working stroke (by the allowance ti of the first working stroke), after which the position the bushings 5 are fixed with a lock nut 4. By turning the sleeve of the tool holder 6 to the left, the cutter is brought into contact with the surface to be machined, after which the machine spindle is informed of rotation with a minimum frequency. Under the action of friction forces on the contact surfaces of the cutting edge of the cutter with the surface to be machined, the tool holder bushing is turned back (clockwise), while the cutter cuts into the cutting depth c specified by the position of the sleeve 5 and the calibrated value of the elastic compression of the elastic element. Moreover, due to the difference in the steps of the threaded sections of the mandrel with the steps Pi and Р _{2 of the} tool holder sleeve, it comes into contact with the adjusting sleeve through the elastic element and balls, while the axial component of the cutting force is perceived by the adjusting sleeve 5. After cutting the cutter to the calculated depth ti, the machine spindle is informed the working speed and the movement of the axial feed to the desired length of the stepped hole, after which the machine spindle is returned to its original position and its rotation is turned off. The rotation of the adjusting sleeve 5 on the insert size dial sets the size of the allowance for the second and subsequent working strokes and cycles are repeated until the specified diameter of the boring step is reached. The axial displacement of the boring tool at the working strokes caused by the rotation of the toolholder takes into account the corresponding displacement of the machine spindle.

After turning off the machine spindle, upon completion of the boring step, lock nut 4 is released and the rotation of the bushings 6 and 5 (clockwise to the right) sets the initial position of the elements of the boring head and the spindle with the boring head is removed from the hole.

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

Claims (5)

Claim 1. A boring head comprising a housing with a cylindrical mandrel, a tool holder with a cutter, an adjusting sleeve, and on the mandrel there are working sections designed to interact with a tool holder and an adjusting sleeve) characterized in that, in order to expand technological capabilities, due to stepless regulation of the radial movement of the cutter and the expansion of the range of this regulation, the boring head is equipped with an eccentric sleeve designed to secure the mandrel in the housing e, a separator with balls and an elastic element located between the sleeve of the tool holder and the adjusting sleeve, means for fixing the adjusting sleeve relative to the cylindrical; the mandrel and the eccentric sleeve relative to the housing, while the working sections on the cylindrical mandrel are threaded with different steps, threaded holes with different steps are made with an eccentricity in the tool holder and the adjusting sleeve, and a hole with an eccentricity is made in the housing, the value of which is determined by the dependence = ei - e ₂ . where ei is the value of the eccentricity of the hole of the sleeve-tool holder, e ₂ is the value of the eccentricity of the hole of the eccentric sleeve, and the adjustment sleeve is made With the reference scale of the radial displacements of the cutter, and on the end surface of the eccentric sleeve, an additional reference scale of the radial displacements of the cutter is applied. 5 2. Boring head according to π. 1, with the fact that the means for fixing the eccentric sleeve in the housing is made in the form of a tangential clamp, 10 3. Boring head pop. 1, distinguished by the fact that holes are made on the end surface of the eccentric sleeve. designed to interact with the sleeve turning means. 4. The boring head of claim 1, wherein the means for fixing the adjusting sleeve relative to the cylindrical mandrel is in the form of a lock nut. 5-6 ^from camping rezZaboy οπραβχυ