Method of dressing grinding wheels in grinding machines

Abstract

A grinding wheel with a working surface having a complex profile is subjected to a path-controlled dressing operation by an apparatus which moves in the direction of the Z-axis of the machine while the grinding wheel moves in the direction of the X-axis. When necessary in view of configuration of the momentarily dressed portion of the working surface, the grinding wheel is turned about the B-axis of the machine, and such axis is remote from the point of contact between the dressing tool and the working surface and is normal to the Z- and X-axes. The controls of the grinding machine cause the dressing tool and the grinding wheel to perform additional movements in the direction of the Z- and X-axes so as to compensate for those deviations from the preselected movement which are due to turning of the grinding wheel about the B-axis.

Description

BACKGROUND OF THE INVENTION

The invention relates to improvements in path-controlled dressing of grinding wheels in grinding machines. More particularly, the invention relates to improvements in methods of dressing grinding wheels in grinding machines wherein the dressing of working surface of a grinding wheel involves a movement of the dressing tool in a first direction and a movement of the grinding wheel in a different second direction. Still more particularly, the invention relates to improvements in methods of dressing grinding wheels wherein the dressing operation further involves a pivotal or angular movement resulting in a change of orientation of the dressing tool and grinding wheel relative to each other.

Dressing operations involving the treatment of working surfaces of grinding wheels wherein the working surface has a relatively simple profile are carried out by moving the dressing tool in a first direction and by moving the grinding wheel in a second direction which, at least in many instances, is normal to the first direction. The point of contact between the dressing tool and the grinding wheel follows the desired contour or profile of the working surface of the grinding wheel. If the working surface of the grinding wheel has a rather complex profile, the dressing tool is caused to turn about a predetermined axis in order to ensure that the plane of the dressing tool will be maintained at an optimum angle to the adjacent portion of the working surface. Reference may be had to U.S. Pat. No. 4,603,677 granted Aug. 5, 1986 to Gile et al. for "Orthogonal dressing of grinding wheels." The disclosure of this patent is incorporated herein by reference. Thus, it is necessary to install the dressing tool in such a way that it can perform a linear movement as well as an angular movement while it treats a complex working surface. Such dressing apparatus contribute to complexity, space requirements and overall cost of the grinding machine.

OBJECTS OF THE INVENTION

An object of the invention is to provide a novel and improved method of dressing simple and/or complex working surfaces on rotary grinding wheels in such a way that the orientation of the dressing apparatus need not be changed while the dressing tool contacts and treats the working surface.

Another object of the invention is to provide a method which renders it possible to move all parts which cooperate in the course of a dressing operation in the directions of and/or about standard axes of a grinding machine.

A further object of the invention is to provide a method which is ideally suited for the dressing of complex or extremely complex working surfaces, for example of working surfaces with rather pronounced transitions between neighboring portions of the profile.

SUMMARY OF THE INVENTION

The invention resides in the provision of a method of path-controlled dressing of the working surface of a rotating grinding tool with a dressing tool in a grinding machine. The method comprises the steps of contacting the working surface of the grinding tool by the dressing tool, moving the dressing tool and the grinding tool relative to each other (in the direction of at least two axes which are inclined with respect to one another) to an extent which is dependent upon the profile or contour of the working surface while the dressing tool continues to contact the working surface, and changing the inclination of the grinding tool and dressing tool relative to each other as a function of the profile of the working surface. In accordance with a feature of the method, the inclination changing step includes changing the orientation of the grinding tool relative to the dressing tool.

In accordance with a presently preferred embodiment, the orientation changing step includes moving the grinding tool in a direction to maintain the profile of the working surface at least close to a position at right angles to the plane of the dressing tool. Such orientation changing step preferably includes turning the grinding tool about a further axis which is remote from the point of contact between the working surface and the dressing tool in the course of the dressing operation. The further axis is normal to the two axes.

The method preferably further comprises the step of additionally moving at least one of the tools linearly in the direction of one of the two axes to an extent which is a function of the orientation changing step.

The moving and orientation changing steps preferably take place by moving the respective tools in the direction of at least two of the B-, X- and Z-axes of the grinding machine.

The method further comprises the step of compensating for deviations of movements of the tools in the direction of the two axes during dressing of the working surface as a result of changes of orientation of the spindle.

The novel features which are considered as characteristic of the invention are set forth in particular in the appended claims. The improved method itself, however, together with additional features and advantages thereof, will be best understood upon perusal of the following detailed description of certain specific embodiments of machines for the practice of the method with reference to the accompanying drawing.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1, is a schematic plan view of a grinding machine, and

FIG. 2 is an enlarged view of a detail in the grinding machine of FIG. 1, the dressing tool and the grinding tool being shown in two different positions including broken-line positions which they assume as a result of a change of orientation of the grinding tool and linear movements of the dressing tool and grinding tool which are necessitated by such change of orientation.

DESCRIPTION OF PREFERRED EMBODIMENTS

FIG. 1 shows a plain (circular or cylindrical) grinding machine which comprises a base or bed 1 having parallel guides 4, 4a for a reciprocable table or carriage 3. The base 1 further supports a wheelhead 2 adjacent one side of the carriage 3. The guides 4, 4a extend in the direction of the Z-axis of the grinding machine, and the drive means for moving the carriage 3 along a straight (linear) path which is defined by these guides includes a reversible electric or other suitable motor 6 which is operatively connected with the carriage 3 by a transmission including a rotary spindle 6a.

The carriage 3 supports a headstock 7 having a driven center 8 and a torque-transmitting element 8a, and a tailstock 9 with a center 11 mounted on a tailstock sleeve 12. The latter supports a toroidal dressing tool 16 (e.g., a doughnut-shaped diamond roll) forming part of an apparatus for dressing the working surface 38 of a rotary grinding tool 28 (hereinafter called grinding wheel). The dressing apparatus further comprises a motor 13 which is affixed to the tailstock 9 and can drive the dressing tool 16 through the medium of a belt transmission 14. The reference character 17 denotes a workpiece which is held between the centers 8, 11 and has a circumferentially extending groove 18 bounded by a concave surface. The grinding wheel 28 serves to remove material from the surface around the groove 18.

The wheelhead 2 includes a support 21 which is mounted on a turntable 19 and is provided with parallel guides 22, 22a for a slide 26 mounting a rotary spindle 27 for the grinding wheel 28. The drive means for moving the slide 26 along the guides 22, 22a includes a motor 23 which is mounted on the guides 22, 22a and/or on the support 21 and is operatively connected with the slide 26 by a rotary spindle 24 so that the slide 26, the tool spindle 27 and the grinding wheel 28 can be moved in directions of the X-axis of the machine, namely at an angle to the Z-axis. The support 21 can be caused to turn relative to the turntable 19 about a vertical axis B (which is normal to the X- and Z-axes) by a further motor 29 which can turn the support through the medium of a worm gearing 31. The directions in which the support 21 can turn with the slide 26, spindle 27 and grinding wheel 28 about the axis B are indicated by a double-headed arrow 19a.

The profile or contour of the working surface 38 of the grinding wheel 28 is dependent upon the desired final configuration of the surface surrounding the groove 18 of the workpiece 17. The illustrated working surface 38 has two undercut lateral flanks 32 in order to reduce the likelihood of excessive rubbing contact between the working surface 38 and the workpiece 17 when the grinding wheel 28 is in the process of removing material from the workpiece. The flanks 32 extend radially inwardly from a substantially cylindrical peripheral surface 39 with a rather abrupt but smooth transition between such peripheral surface and both flanks.

The grinding machine further comprises controlling means 33 including a control unit 34 of conventional design (this control unit serves to control the movements of the carriage 3 and wheelhead 2 relative to each other when the grinding machine is in actual use, i.e., when the grinding wheel 28 removes material from the workpiece 17), a 3-axis interpolator 36 which receives signals from the control unit 34, and three regulators 37Z, 37B and 37X. These regulators receive modified signals from the interpolator 36 and transmit signals to the motors 6, 29 and 23, respectively (note the non-referenced conductor means between the regulators and the associated motors).

FIG. 1 shows the apparatus including the dressing tool 16, the motor 13 and the transmission 14 in the process of dressing the working surface 38 of the grinding wheel 28. The dressing operation is particularly satisfactory if the dressing tool 16 extends substantially at right angles to the tangent at that point of the working surface 38 which is contacted by the dressing tool. In accordance with a feature of the invention, such mutual positioning of the grinding wheel 28 and dressing tool 16 is achieved by changing the orientation of the grinding wheel 28 relative to the dressing tool 16 in the course of the dressing operation, i.e., while the dressing tool contacts the working surface 38. To this end, the regulator 37B causes the motor 29 and the worm gearing 31 to turn the support 21 (and hence the grinding wheel 28) about the axis B, i.e., about an axis which is remote from the point of contact between the dressing tool 16 and the working surface 38 while the tool 16 is in the process of dressing the grinding wheel 28. The extent of angular or turning movement of the rotating grinding wheel 28 relative to the rotating dressing tool 16 is such that the flank 32 which is adjacent the dressing tool and the plane of the dressing tool make an optimum clearance or relief angle alpha. If the construction of the grinding machine and the geometries of the dressing tool 16 and of the working surface 38 permit it, the clearance angle alpha will approach a right angle, i.e., the plane of the dressing tool will extend substantially at right angles to the adjacent portion of the working surface 38. The regulation (by 37B) which is necessary to ensure such orientation of the working surface 38 and dressing tool 16 relative to each other is initiated by the control unit 34 of the grinding machine. This control unit stores information pertaining to the desired profile of the working surface 38 and to the magnitude of the corresponding angle beta (FIG. 2) indicating the extent of change of orientation of the grinding wheel 28 as a result of turning the support 21 and grinding wheel 28 about the axis B. The control unit 34 transmits (by way of the interpolator 36) to the regulators 37Z and 37X for the motors 6 and 23 data denoting the positions of the carriage 3 and support 21 in the directions of the Z- and X-axes in dependency on the desired profile or contour of the working surface 38 of the grinding wheel 28. For example, the substantially cylindrical peripheral surface 39 of the grinding wheel 28 can be dressed in response to signals denoting the position of the slide 26 in the direction of the X-axis and a sequence of positions of the dressing tool 16 in the direction of the Z-axis. This is indicated in FIG. 2 by solid lines. When the dressing tool 16 has completed the treatment of the peripheral surface 39 and is to dress the transition zone between the surface 39 and one of the flankes 32, the motor 29 is caused to turn the support 21 and the grinding wheel 28 about the axis B so as to move the momentarily treated portion of the working surface 38 close to a position at right angles to the plane of the dressing tool. FIG. 2 indicates by broken lines that position (28a) of the grinding wheel 28 when the motor 29 has completed a turning of the support 21 through the angle beta. The flank 32 which is about to be treated then assumes the broken-line position 32a. This ensures that the angle alpha between the flank 32 (in the position 32a) and the plane of the dressing tool 16 assumes an optimum value.

It is not always possible to ensure that the plane of the dressing tool 16 will assume a position exactly at right angles to the adjacent portion of the working surface 38. This is due to the particular design of a grinding machine and/or to other parameters, such as the profile or contour of the working surface 38. However, it is desirable to ensure that the angle alpha be relatively large and that it at least approximate the optimum value. This contributes to quality of the dressing operation.

Since the axis B does not extend through the point of contact between the dressing tool 16 and the working surface 38 of the grinding wheel 28, it is necessary to move the carriage 3 in the direction of the axis Z and/or to move the slide 26 in the direction of the axis X whenever the motor 29 is started to turn the support 21. FIG. 2 shows (at X.sub.1) the extent of movement of the slide 26 in the direction of axis X, and (at Z.sub.1) the extent of movement of the carriage 3 and dressing tool 16 in the direction of the axis Z when the grinding wheel 28 is caused to change its orientation through the angle beta. This results in a movement of the slide 26 to the broken-line position 26a and in a movement of the dressing tool 16 to the broken-line position 16a.

Signals which initiate movements of the slide 26 to the position 26a and of the dressing tool 16 to the position 16a are transmitted by the interpolator 36 which is connected with the control unit 34 as well as with the regulators 37Z and 37X for the motors 6 and 23, respectively. The interpolator 36 is designed to assign, on the basis of programmed information which is stored in a memory of the control unit 34 and denotes data pertaining to the positions of the slide 26 and carriage 3 in the directions of the X- and Z-axes, correction data corresponding to the angle beta, and such correction data are superimposed upon data furnished by the memory of the control unit 34. Thus, the interpolator 36 modifies the information from the control unit 34 as a function of the extent of change of orientation of the grinding wheel 28 relative to the dressing tool 16, i.e., as a function of the magnitude of angle beta which denotes the extent to which the support 21 is turned by the motor 29 in response to signals from the regulator 37B.

Once the dressing tool 16 has reached the flank 32 (in the position 32a, as seen in FIG. 2), the motor 29 need no longer change the orientation of the grinding wheel 28. The dressing operation is then controlled as a result of programmed movements of the dressing tool 16 in the direction of the axis Z and of the grinding wheel 28 in the direction of the axis X. Such dressing operation proceeds until the point of contact between the dressing tool 16 and the grinding wheel 28 again reaches a portion of the working surface 38 which cannot be properly treated without changing the orientation of the grinding wheel, i.e., without turning the slide 26 about the axis B.

It will be seen that the dressing operation involves movements of dressing tool 16 in the direction of the Z-axis as well as movements of the grinding wheel 28 about the axis B and/or in the direction of the axis X. Thus, all of these movements take place in the direction of or about the three standard axes of a grinding machine. This not only simplifies the controls of the machine but also ensures a highly satisfactory dressing operation. There is no need to provide means for turning the dressing apparatus about a discrete axis. Such turning means would contribute to complexity and higher cost of the dressing apparatus and of the entire grinding machine.

The control unit 34 is or can be a standard control unit of the type used in numerically controlled grinding machines. This control unit cooperates with the interpolator 36 to ensure the transmission of appropriate signals to the regulators 37B, 37X, 37Z and hence to the motors 29, 6 and 23 which initiate movements of the dressing tool 16 and grinding wheel 28 in the course of a dressing operation.

It goes without saying that the profile or contour of the working surface 38 which is shown in FIGS. 1 and 2 is but one of numerous profiles which can be dressed in accordance with the method of the present invention.

Prior methods of dressing grinding wheels are disclosed in numerous pending United States and foreign patent applications and in numerous United States and foreign patents of the assignee of the present application. Reference may be had, for example, to U.S. Pat. No. 4,557,078 granted Dec. 10, 1985 to Jurgen Brill for "Method of dressing and finishing grinding wheels", to U.S. Pat. No. 4,571,892 granted Feb. 25, 1986 to Jurgen Brill for "Method of dressing grinding wheels in grinding machines", and to U.S. Pat. No. 4,696,130 granted Sept. 29, 1987 to Heinz Belthle for "Method of profiling and dressing grinding wheels".

A further method of dressing grinding wheels is disclosed in U.S. patent application Ser. No. 227,238 filed Aug. 2, 1988 by Heinrich Mushardt et al. for "Method of and apparatus for dressing grinding wheels".

Without further analysis, the foregoing will so fully reveal the gist of the present invention that others can, by applying current knowledge, readily adapt it for various applications without omitting features that, from the standpoint of prior art, fairly constitute essential characteristics of the generic and specific aspects of my contribution to the art and, therefore, such adaptations should and are intended to be comprehended within the meaning and range of equivalence of the appended claims.

Claims

1. A method of path-controlled dressing of a profiled working surface of a rotating grinding tool, which is rotatable about a predetermined axis, with a dressing tool in a grinding machine, comprising the steps of positioning the dressing tool and the grinding tool at a predetermined inclination relative to each other and contacting the working surface by the dressing tool; moving the dressing tool and the grinding tool relative to each other, in a direction of at least two axes which are inclined relative to each other, to an extent which is dependent upon the profile of the working surface while the dressing tool continues to contact the working surface; changing the inclination of the grinding tool and dressing tool relative to each other as a function of the profile of the working surface, including changing the orientation of the grinding tool, said orientation changing step including turning the grinding tool about a further axis which is remote from the point of contact between the working surface and the dressing tool; moving at least one of the tools linearly in a direction of one of said at least two axes to an extent which is a function of said orientation changing step; and compensating for deviations of movement of the grinding and dressing tools in the directions of said at least two axes during dressing of the working surface as a result of changes of orientation of the grinding tool.

2. The method of claim 1, wherein said turning step includes moving the grinding tool in a direction to maintain the profile of the working surface at least close to a position at right angles to a plane which includes the dressing tool.

3. The method of claim 1, wherein said further axis is normal to said two axes.

4. The method of claim 1, wherein said moving and orientation changing steps take place in the direction of at least two of the B, X and Z axes of the grinding machine.