RU2120368C1 - Method of combined quasiintermittent finishing - Google Patents

Abstract

FIELD: machining; effective finishing of blanks from various metals predisposed to defects. SUBSTANCE: blank and combined tool head with grinding wheel and disk with honing sticks located on it are set in rotary motion and in motion for feed along surface being treated. Finishing is effected with the aid of wheel and disk provided with honing sticks expandable in radial direction. Working layers of tools are made with axial shift in way of longitudinal feed for performing longitudinal reciprocating oscillatory motion. Honing sticks are mounted on disk for circumferential rolling over surface being treated. EFFECT: enhanced resistance of cutting tools; increased productivity and improved quality of finishing. 2 dwg, 1 App

Description

 The invention relates to mechanical engineering, namely to the processing of materials by cutting, and can be used at engineering enterprises for the effective finishing of workpieces from various metals predisposed to defect formation.

 A known method of finishing with abrasive bars, which are installed in the head opposite to the workpiece, is pressed to it and the rotation of the head and parts around their axes intersecting in the symmetry plane of the part profile / 1 / is reported.

 The disadvantage of this method is the low quality of the workpiece and the processing time, because when processing the inner surface of the part, regardless of the required shape of its profile, the latter acquires a convex circular shape, which reduces the durability of the workpiece. In addition, the implementation of this method of finishing requires the complexity of the kinematics of known machines.

 As a prototype, the method of combined processing by grinding and surface plastic deformation, carried out by a tool consisting of a grinding wheel with a conical intake part and a cylindrical body with deforming elements, to which the rotational movement and feed movement along the surface to be treated / 2 / was chosen, was selected. During processing, an additional rotation is communicated to the cylindrical body with deforming elements, leading to a decrease in the amplitude of oscillations of the technological system and to improve the quality of processing.

 The disadvantages of this method are: the use of the reverse stroke of the tool leads to excessive deformation and peeling of the surface layer; the proposed design of the body with deforming elements does not allow to restore the cutting properties of the grinding wheel during the dressing process.

 The proposed invention solves the problem of increasing tool life, productivity and processing quality.

 This is achieved by the fact that with the method of combined quasi-continuous finishing of holes, in which the workpiece and the combined tool head with the grinding wheel and the disk with working elements located therein communicate rotational movements and the feed movement along the surface to be machined, the processing being carried out by a circle and an abrasive expandable disk in the radial direction with bars, and the working surfaces of the tools are set with axial displacement relative to the longitudinal feed for IMPLEMENT longitudinal reciprocating oscillatory motion, wherein the abrasive bars move in the circumferential direction together with the workpiece.

 The invention is illustrated by drawings. In FIG. 1 shows a diagram of the proposed method of combined quasi-continuous processing; in FIG. 2 - scan trace of the combined tool on the work surface.

According to the proposed method, during processing for half a turn of the spindle 1 (Fig. 1) of the tool head, the cutting zone "b-c", located on the periphery of the grinding wheel 2, will move to the position "b ₁ -c ₁ ", and for the second half turnover it will return to its original position. Therefore, for a full revolution of the spindle 1 with the grinding wheel 2, all its peripheral points of the cutting zone will move along the axis of rotation equal to the amplitude A. Due to this axial displacement of the working cutting layer of the grinding wheel 2 in the section A in the cross section, intermittent grinding is observed, which is accompanied by low cutting temperature in comparison with traditional grinding, burns and microcracks are not observed on the treated surface.

This quasi-continuous grinding is a continuous cutting process, which provides oscillation of the thermal field due to the increase in the contact length K of the circle 2 and the part, equal to
K = A + B _W ,
Where
B _W - the height of the grinding wheel 2 in the direction of its longitudinal feed,
B _W = B • cosα,
Where
B - the height of the standard grinding wheel 2;
α is the angle of inclination of the grinding wheel 2.

Вслед за шлифовальным кругом 2 обрабатываемая поверхность подвергается чистовой обработке рабочими элементами 3, шарнирно закрепленными на диске 4, который с помощью подшипника 5 установлен под углом α на шпинделе 1. Абразивные бруски 3, имеющие возможность радиального перемещения и прижимаемые к обрабатываемой поверхности с определенным усилием специальными пружинами, обкатываются по обрабатываемой поверхности, совершая возвратно-поступательные осевые движения S_Б. Амплитуда A этого колебательного движения зависит от диаметра D инструмента, угла наклона α и определяется по формуле:
A = D•tgα,
Частота колебательного движения абразивных брусков 3 будет равна частоте вращения шпинделя инструментальной головки. Благодаря продольному колебательному движению и радиальному разжиму брусков 3 на обрабатываемой поверхности абразивными зернами образуются царапины, направление которых перпендикулярно предыдущим, полученных шлифовальным кругом 2 (фиг. 2). Несмотря на постоянные радиальные силы разжима брусков, они работают в условиях непрерывно изменяющихся давлений.The angle of inclination of the circle 2 allows you to increase the number of abrasive grains involved in cutting. If in conventional conventional grinding the number of cutting grains involved in cutting (according to well-known literature) is from 5% to 15%, then with this quasi-continuous grinding, their number increases by n times, which can be determined by the formula:

Following the grinding wheel 2, the surface to be machined is subjected to finishing by working elements 3 pivotally mounted on the disk 4, which is mounted using the bearing 5 at an angle α on the spindle 1. Abrasive bars 3, which can be radially moved and pressed against the surface to be machined with a certain force springs, run on the work surface, making a reciprocating axial motion S _B. The amplitude A of this oscillatory movement depends on the diameter D of the tool, the angle of inclination α and is determined by the formula:
A = D • tgα,
The frequency of oscillatory motion of the abrasive bars 3 will be equal to the frequency of rotation of the spindle of the tool head. Due to the longitudinal vibrational movement and the radial expansion of the bars 3, scratches are formed on the treated surface with abrasive grains, the direction of which is perpendicular to the previous ones, obtained by grinding wheel 2 (Fig. 2). Despite the constant radial forces of expansion of the bars, they work in conditions of continuously changing pressures.

 Using the combined tool of the proposed design allows processing using the entire peripheral working part of the tool while maintaining the advantages of intermittent grinding and honing. The performance of this method of finishing combined processing can be increased by 2 ... 2.5 times, and surface roughness - by 1-2 classes. At the same time, the consumption of an abrasive tool is reduced by 30%.

Example. On the internal grinding machine mod. 3K228V polished a through hole with a diameter of D ₃ = 60 H7 ( ^+0.03 ) and a length l = 60 mm. The surface roughness parameter R _a = 0.63 μm. Side allowance h = 0.2 mm. The workpiece material is steel 45, hardened, hardness HRC _e 45. The machine is equipped with a device for active control of workpieces. Grinding wheel with abrasive layer recommended for this steel (full characteristics of the wheel 24A25PS25K8A). For internal grinding, it is recommended that D _k / D _z = 0.8 ... 0.9. Therefore, a circle with a diameter of D _k = 50 mm was made. Processing was carried out under the following cutting conditions. The rotational speed of the circle was taken n _k = 13000 min ^-1 ; the rotation speed of the workpiece was taken n _s = 200 min ^-1 . The longitudinal feed according to the recommendations was set S _m = 5390 mm / min. Cross feed for normal circles recommended S _tdv.kh = _0,004 mm / dv.hod. For this special circle took S _tdv.kh = 0,006 mm / dv.hod. Abrasive whetstones: grain material 63C, grain size M40, hardness CM1, bond - ceramic, number of whetstones - 6, length of whetstones - 30 mm, width of whetstones - 16 mm. Coolant - emulsion. Processing was carried out in 25 passes. The angle of inclination of the grinding wheel and the disk with abrasive bars α = 10 ^o . The amplitude in this case was A = 8 mm. The radial pressure of the bars was 0.05 ... 0.06 MPa.

To ensure the required quality and dimensional accuracy of the processing, the main time T _о = 0.6 min was required, which is 2 times faster than with conventional grinding. The application of this method of finishing combined quasi-continuous processing eliminates the operation of semi-grinding due to the improvement of surface roughness by 1-2 classes. At the same time, the consumption of an abrasive tool is reduced by 30%.

Claims (1)

 A method of combined quasi-continuous finishing of holes, in which the workpiece and the combined tool head with a grinding wheel and a disk with working elements communicate rotational movements and a feed movement along the surface to be machined, characterized in that the combined head is taken with axial displacement in the direction of longitudinal feeding of the working a layer of a grinding wheel and a disk having abrasive sliding blocks in the radial direction as working elements that run in a circular direction along the work surface.

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