EP1177067A1

EP1177067A1 - Method for grinding convex running surfaces and outside diameters on undulated workpieces in a clamping, and a grinding machine for carrying out the method

Info

Publication number: EP1177067A1
Application number: EP00922668A
Authority: EP
Inventors: Erwin Junker
Original assignee: Erwin Junker Maschinenfabrik GmbH
Current assignee: Erwin Junker Maschinenfabrik GmbH
Priority date: 1999-05-11
Filing date: 2000-04-27
Publication date: 2002-02-06
Anticipated expiration: 2020-04-27
Also published as: CZ20013992A3; JP2002543991A; ES2185589T3; AU4298400A; RU2247641C2; DE19921785B4; US6685536B1; EP1177067B1; DE19921785A1; CZ294212B6; BR0010489A; DE50000975D1; CA2372659A1; WO2000067947A1; JP4473457B2; CA2372659C

Abstract

The invention relates to a method for grinding convex running surfaces and exact outside diameters on undulated workpieces (10). In a clamping, a first convex running surface (36) is ground on a discoid partial section of an undulated workpiece (10) during a first grinding operation while using a first grinding wheel (33) that comprises at least one concave lateral surface (35). A second grinding wheel (34) is used to grind a desired outside diameter on the discoid partial section as well as on other partial sections of the undulated workpiece (10) during a second grinding operation.

Description

Process for grinding convex treads and outer diameters on shaft-shaped workpieces in one clamping and grinding machine for carrying out the process

The invention relates to a method for grinding convex treads and outer diameters on shaft-shaped workpieces in one setting and a grinding machine for performing the method.

According to the prior art, convex treads and outer diameters are grinded on shaft-shaped workpieces by means of oblique plunge-cut grinding machines, the corresponding shaft parts having to be machined in several setups. This procedure is based on several work steps because the shaft parts to be machined have to be repeatedly ground on different grinding machines. Repeated clamping is associated with further manufacturing disadvantages, because even the slightest dimensional and shape inaccuracies are additively transferred from one clamping to the other on the finished part.

The invention is based on the object to provide a method for grinding convex treads and outer diameters on shaft-shaped workpieces in one setting. In particular, tapered, semi-ellipsoidal or paraboloidal treads should be ground. For this purpose, a special grinding machine is to be used, with which the Disadvantages inherent in the prior art are eliminated. The shaft parts to be machined are to be ground in one clamping with two CBN grinding wheels to the finished product. The method according to the invention is also intended to enable individual grinding operations on comparable workpieces with the aid of the special grinding machine.

This object is achieved by a method having the features according to claim 1 and by a grinding machine according to claim 6. The subclaims referring to this design the process technologically and the grinding machine constructively.

The method for grinding shaft parts with convex, in particular tapered, semi-ellipsoidal or paraboloidal treads and the desired, exact outer diameters on shaft-shaped workpieces is carried out in one setting on a swiveling grinding headstock. The grinding headstock comprises two arms which form an angle α, which is in particular 60 °, and grinding spindles are provided at their free ends. On one grinding spindle a grinding wheel with at least one concave side surface for producing a contour-conforming convex running surface is clamped on the shaft part to be machined and on the other grinding spindle a grinding wheel for producing exact outer diameters is clamped on the shaft parts to be machined. The grinding of a wave-shaped workpiece is carried out in such a way that the workpiece, which has a plane-side section with a large diameter, is clamped between the tips of a workpiece headstock and a tailstock and is supported at the bearing points of the workpiece with steadies.

To produce a tread on the plane-side section that is convex in cross section, in particular conical, semi-ellipsoidal or paraboloidal of the wave-shaped workpiece with a large diameter, a relatively large grinding wheel is used, which has at least one concave, in particular conical, semi-ellipsoidal or paraboloid-shaped cross-section, contour-conforming side surface for creating the running surface of the wave-shaped workpiece section

According to one embodiment, the opposite side surface of the grinding wheel is also designed accordingly if convex treads with a large diameter are to be produced on both sides of the wave-shaped workpiece section

After the production of the convex tread or convex tread, the grinding wheel, which is concave in cross section, is brought out of the area of engagement with the wave-shaped workpiece section by pivoting the grinding headstock.At the same time, the second grinding wheel is moved against the outer circumference of the wave-shaped workpiece section by moving the grinding headstock in the X-axis hired to grind an exact diameter

If this wavy workpiece section with the large diameter is to be convexly grinded on both sides, in particular in the shape of a cone, semi-ellipsoid or paraboloid, a grinding wheel with two concave, in particular cone, semi-ellipsoidal or paraboloid-shaped side surfaces is to be used from the outset, which conforms to the contour of the running surfaces to be created wave-shaped workpiece section with the large diameter are used. In this case, after the production of the first convex tread of the wave-shaped workpiece section with the large diameter, the grinding wheel is first on the X-axis from the area of the wave-shaped workpiece section with the large diameter moved out and pivoted against the previous swivel direction of the grinding headstock. Then the workpiece is moved by a feed movement on the Z axis in the direction of the workpiece center axis to feed the grinding wheel to create the second convex, in particular cone, semi-ellipsoidal or paraboloidal tread of the to enable wavy workpiece section with respect to the X-axis. The second concave, in particular conical, semi-ellipsoidal or paraboloidal side surface of the first grinding wheel is brought into engagement with the other side surface of the wave-shaped workpiece section with the large diameter in order to create the second convex tread with the second concave side surface of the grinding wheel .

After grinding the one convex, in particular conical, semi-ellipsoidal or paraboloidal tread and / or grinding the second opposite convex, in particular conical, semi-ellipsoidal or paraboloidal tread of the wavy workpiece section with the large diameter, the grinding headstock becomes on the X-axis from the

Area of the wavy workpiece section driven with the large diameter. A second grinding wheel on the other's grinding spindle

Arm of the workpiece headstock is clamped and forms an angle α, which is preferably 60 °, with respect to the arm with the spindle for the first grinding wheel, is fed perpendicular to the longitudinal axis of the wavy workpiece to the desired outer diameter on the corresponding sections of the wavy workpiece to create.

A special grinding machine is suitable for carrying out the method, on the machine bed of which a workpiece headstock and a tailstock aligned in the longitudinal axis are arranged, which realize the feed movement according to the Z axis. Also in this area are the Machine bed adjustable bezels provided against the bearing points of the workpiece. A two-armed grinding headstock is provided behind the arrangement of the workpiece headstock and tailstock, with each arm being equipped at the end with a grinding spindle for receiving grinding wheels. The verticals on the longitudinal axes of the two grinding spindles intersect in one plane at an angle α of preferably 60 ° in the pivot axis of the two-armed common grinding headstock with the two grinding spindles arranged at the end and carrying the grinding wheel. The grinding headstock can be pivoted in one plane, for example horizontally, and can be advanced vertically along the X axis to the Z axis.

This grinding machine allows the setting of optimal use positions for the grinding wheels in relation to the workpiece to be machined. The arrangement of the two-armed grinding headstock with the grinding spindles for the first and second grinding wheels attached at the ends has the advantage that the two grinding spindles are arranged on a common guide for carrying out the infeed movement in accordance with the X axis. This arrangement ensures very high rigidity values, including the grinding slide guide. The high rigidity of the grinding headstock and the guide system on the guide carriage result in high precision values for the end product produced by grinding in one clamping. On the other hand, the dimensional inaccuracies creeping in with multiple clamping operations add up until the end product is produced. The high stiffness values of the guide system therefore decisively improve the process reliability of the method and also reduce wear on the grinding wheels.

The method and the grinding machine are explained in more detail in the drawings according to FIGS. 1 to 5. Fig. 1 shows the structural design of the grinding machine used to carry out the method, which is arranged on a machine bed and which, in alignment, has a workpiece headstock and a tailstock with a corrugated workpiece clamped in between, which has a section with the larger diameter, and a two-armed grinding headstock arranged behind it each with a grinding spindle mounted at the ends in the arms.

Fig. 2 shows the clamping of a pre-ground, wavy workpiece between the tips of the workpiece headstock and the

Tailstock with the Z-axis characterizing the feed movement, the workpiece having a disk-shaped section with a large diameter.

3 shows the first method step for grinding a first convex, in particular conical, semi-ellipsoidal or paraboloidal tread on the disk-shaped partial section of the wave-shaped workpiece with the larger diameter by means of a concave, in particular conical, semi-ellipsoidal or paraboloidal contour-conforming side surface of a first grinding wheel .

Fig. 4 shows the second method step for grinding a convex, in particular conical, semi-ellipsoidal or paraboloidal tread on both sides on the disk-shaped section of the wavy workpiece with the large diameter by means of a second concave, in particular conical, semi-ellipsoidal or paraboloidal, contour-conforming side surface of the first grinding wheel. 5 shows the third method step for producing different outer diameters on a wave-shaped workpiece.

1 shows the grinding machine A to be used according to the method according to the invention for grinding workpieces such as wave-shaped gear parts. A grinding table 2 is arranged schematically in the front area on the machine bed 1, on which the feed movement is carried out along the double arrow in accordance with the Z axis. The CNC-controlled drive required for this is not shown. On the grinding table 2, a motor-driven workpiece headstock 3 and a tailstock 4 are arranged in alignment on a common longitudinal axis 5. The wavy workpiece 10 to be finished, which has a section with a large diameter D, is clamped between the workpiece headstock 3 and the tailstock 4. For this purpose, the workpiece headstock 3 has a rotor-driven workpiece spindle 6, which has a workpiece holder 7 designed as a tip in the front region. The opposite tailstock 4, which is arranged in alignment on the grinding table 2, has a hydraulically axially displaceable tailstock quill 8. This tailstock quill 8 has a tailstock tip 9 at the workpiece-side end. The longitudinal axis of the workpiece spindle 6 of the workpiece headstock 3, the workpiece 10 and the tailstock quill 8 of the tailstock 4 thus form a common, aligned longitudinal axis 5.

A grinding headstock 20, which is mounted on a guide carriage 21, is arranged in the rear region of the machine bed 1. The guide carriage 21 is equipped with an infeed drive 22 which realizes the infeed movement in the X-axis relative to the workpiece 10. The guide carriage 21 is mounted hydrostatically on guides 23 and aligned at right angles to the workpiece center axis 5. The guide carriage 21 is consequently arranged to be displaceable in accordance with the CNC axis. The Grinding headstock 20 comprises two arms 24 and 25, each of which has grinding spindles 28 and 29 equipped with HF drives 26 and 27 at the ends. The verticals emanating from the longitudinal axes 31 and 32 of the grinding spindles 28 and 29 in one plane intersect to form an angle α, for example at an angle α of 60 °, in the pivot axis 30 of the two arms 24 and 25 of the grinding headstock 20. The grinding headstock 20 can be pivoted so far by the angle α corresponding to the CNC axis that, depending on the preselection, one or the other longitudinal axis 31 or 32 of the grinding spindle 28 or 29 assumes a position parallel to the longitudinal axis 5 of the workpiece 10. Each grinding spindle 28, 29 is equipped with a grinding wheel 33, 34.

2 shows the clamping of a wavy workpiece 10 which has been pre-ground with an oversize a and which has a section 40 with a large diameter. The measurement is, for example, between 0.1 and 0.2 mm. The workpiece 10 is clamped between the tip of the workpiece holder 7 of the workpiece spindle 6 of the workpiece headstock 3 and the tailstock tip 9 of the tailstock quill 8 of the tailstock 4. The positioning of the grinding wheels 33 and 34 and the grinding spindles 28 and 29, not shown in FIG. 2, can correspond to the position according to FIG. 1.

3 shows the positioning of the first grinding wheel 33 and the wave-shaped workpiece 10 in a first method step, in which the longitudinal axis 32 of the grinding spindle 29 is inclined by an angle α with respect to the horizontal. This angle α corresponds to the convex, in particular conical, semi-ellipsoidal or paraboloid-shaped tread 36 of the workpiece 10 that can be achieved with the first grinding wheel 33, which has a concave, in particular conical, semi-ellipsoidal or paraboloid-shaped side surface 35, which conforms to the contour of the concave trained side surface 35. The infeed of the first grinding wheel 22 follows the X axis while the feed movement over the Z axis is carried out with the aid of the guide slide 21.

4 is the grinding of both sides convex, in particular conical, semi-ellipsoidal or paraboloidal treads 36 and 37 on the

Section of the workpiece 10 shown with the large diameter D. For this purpose, the first grinding wheel 33, which has two concave, in particular conical, semi-ellipsoidal or paraboloid-shaped side surfaces

35 and 35 ', pivoted in opposite directions by the angle α', the grinding wheel 33 having the side surface 35 'for generating the second convex, in particular conical, semi-ellipsoidal, by corresponding infeed movement along the X axis and feed movement along the Z axis. or paraboloid

Tread 37 is used on the section with the large diameter D.

5 finally shows the grinding of the exact outer diameter by grinding the allowance a on the individual cylindrical sections of the wave-shaped workpiece 10 with the aid of the second grinding wheel 23, the longitudinal axis 21 of the associated grinding spindle 28 by pivoting the grinding headstock 20 about the pivot axis 30 parallel to the longitudinal axis 5 of the workpiece 10 is positioned, and the feed and feed movement takes place in accordance with the X-axis and the Z-axis.

According to the method according to the invention, the repeated clamping of wave-shaped workpieces is eliminated with the special grinding machine, which is equipped with a pivotable grinding headstock 20, in order to produce exact convex, conical, semi-ellipsoidal or paraboloidal treads and exact outer diameters. At the same time, finished parts are produced using the method according to the invention and the special grinding machine A. Made with high dimensional and shape accuracy, because an addition of clamping-related inaccuracies is excluded.

With the progress in grinding and manufacturing technology, i.e. the production of two convex side surfaces on a disk-shaped shaft section with a large diameter and exact outer diameter on the shaft-shaped workpiece, for example a gear shaft, are associated with considerable economic advantages by saving changeover times and the like. At the same time, the finished workpieces are characterized by the highest measuring accuracy.

Claims

Patent claims

1. Method for grinding convex treads and precise

Outer diameters on wave-shaped workpieces, characterized in that in a clamping in a first grinding operation a first convex running surface on a disk-shaped section of a wave-shaped workpiece is ground with a first grinding wheel having at least one concave side surface and in a second grinding operation with a second grinding wheel a desired one

Outer diameter is ground on the disc-shaped section and other sections of the wave-shaped workpiece.

2. The method according to claim 1, characterized in that in the first grinding operation a grinding wheel is used, both of which

Side surfaces are concave, with the first

Process step the first convex and in a second

Process step a second convex tread on the one large one

Diameter disc-shaped section of the wave-shaped workpiece is ground, and then with a second grinding wheel the desired outer diameter of the

Partial section as well as other sections with different outside diameters are finished.

3. The method according to claim 1 or 2, characterized in that a grinding wheel with at least one concave side surface is used as the first grinding wheel and a grinding wheel with a sharp peripheral edge or with a flat lateral surface is used as the second grinding wheel.

4. The method according to any one of claims 1 to 3, characterized in that a grinding wheel arrangement is used in which the first

Grinding wheel and the second grinding wheel successively engage with those to be ground by pivoting through an angle

Sections of the wave-shaped workpiece are brought.

5. The method according to claim 4, characterized in that a grinding wheel arrangement is used in which the pivot angle α between the first and the second grinding wheel is 60 °.

6. Grinding machine for carrying out the method according to one of claims 1 to 5, characterized in that a grinding machine (A) is used, the machine bed (1) of which has a in the front area

Grinding table (2) on which a feed movement is carried out along a Z axis, on the grinding table (2) a rotationally driven workpiece headstock (3) and a tailstock (4) are arranged in alignment on a common longitudinal axis (5), steady rests for Support for the workpiece (10) is provided

The workpiece headstock (3) has a rotationally driven workpiece spindle (6), which is equipped in the front area with a workpiece holder (7) designed as a tip, the tailstock (4) has a hydraulically axially displaceable tailstock spindle (8), which is on the workpiece-side end with a tailstock center

(7) is equipped, in the rear area of the machine bed (1) a grinding headstock (20) is arranged, which is mounted on a guide carriage (21), the guide carriage (21) is equipped with a feed drive (22) which enables a feed movement in an which each have grinding spindles (28, 29) equipped at the ends with HF drives (26, 27), the verticals of which extend from their longitudinal axes (31, 32) in a plane at an angle α in the pivot axis (30) of the two arms ( 24, 25) of the grinding headstock (20), and each grinding spindle (28, 29) has a grinding wheel (33, 34).

Grinding machine according to claim 6, characterized in that the two arms (24, 25) of the grinding headstock (20) form an angle α of 60°.

8. Grinding machine according to claim 6 or 7, characterized in that rotationally driven grinding spindles (28, 29) having grinding wheels (33, 34) are arranged in the free ends of the arms (24, 25).

9. Grinding machine according to one of claims 7 to 9, characterized in that the grinding spindles (28, 29) have HF drives (26, 27).

0. Grinding machine according to one of claims 7 to 9, characterized in that the grinding headstock (20) can be pivoted continuously about its pivot axis (30).