METHOD FOR CALIBRATING A DRESSING SPINDLE OF A MACHINE TOOL

Abstract

A method for calibrating a dressing spindle of a machine tool having a main spindle arranged in a machine head and the dressing spindle arranged in the machining area, wherein a grinding tool can be mounted on the main spindle and a dressing tool can be mounted on the dressing spindle and the grinding tool and the dressing tool can be moved relatively to each other for dressing the grinding tool by the dressing tool.

Claims

1. A method for calibrating a dressing spindle of a machine tool having a main spindle arranged in a machine head and the dressing spindle arranged in the machining area, wherein a grinding tool can be mounted on the main spindle and a dressing tool can be mounted on the dressing spindle and the grinding tool and the dressing tool can be moved relatively to each other for dressing the grinding tool by the dressing tool, the method comprising: a. providing a test mandrel with an elongated body and a seat; b. mounting the test mandrel on the dressing spindle by connecting the seat with the dressing spindle such that the axial axis of the body is in parallel with the rotation axis of the dressing spindle; c. measuring a plurality of positions on the body by contacting a measuring device with the body of the test mandrel at the plurality of positions; d. determining the tilt angle of the rotation axis of the dressing spindle based on the measured plurality of positions on the test mandrel by a processing unit, wherein the tilt angle is the angulation of the rotation axis of the dressing spindle with respect to the vertical direction; e. mounting a calibration sphere having a connecting portion and a jig on the top of the connecting portion on the dressing spindle, wherein the calibration sphere is concentrically arranged on the dressing spindle; f. mounting a touch probe on the main spindle; g. measuring a plurality of positions on the jig by contacting the touch probe with the jig at the plurality of positions; h. determining the center position (P) of the calibration sphere in accordance with the measured plurality of calibration sphere positions by the processing unit; and i. determining by the processing unit the position of a referencing point (R) of the dressing spindle based on the determined center position of the calibration sphere, the tilt angle of the rotation axis of the dressing spindle and the dimension of the calibration sphere, wherein the referencing point is located at the center position on a referencing surface (FR) of the dressing spindle.

2. The method according to claim 1, wherein the measuring device is a touch probe or a dial indicator.

3. The method according to claim 1, wherein three-dimensional coordinates are measured at all measuring positions.

4. The method according to claim 1, wherein the determined position of the referencing point is added into a kinematic compensation model, in particular the determined referencing position is automatically fed into the kinematic compensation model.

5. The method according to claim 1, wherein the touch probe is controlled by a control unit of the machine tool to conduct the measurement.

6. The method according to claim 1, wherein the touch probe is calibrated before conducting the measurement.

7. The method according to claim 1, wherein the calibration sphere is first applied for determining a primary center position before mounting the test mandrel on the dressing spindle to determine the tilt angulation of the dressing spindle.

8. The method according to claim 1, wherein the height of the calibration sphere is considered for determining the referencing point of the dressing spindle.

9. A method for grinding a workpiece by a machine tool having a main spindle arranged in a machine head and a dressing spindle arranged in the machining area, wherein a grinding tool can be mounted on the main spindle for grinding the workpiece mounted on the machine table, wherein a dressing tool can be mounted on the dressing spindle and the grinding tool and the dressing tool can be moved relatively to each other for dressing the grinding tool by the dressing tool, wherein the rotation axis of the dressing spindle has an inclination T to the vertical direction comprising: a. calibrating the dressing spindle according to claim 1; b. dressing the grinding tool by the dressing tool; and c. grinding the workpiece by the dressed grinding tool.

10. A machine tool for grinding a workpiece comprising a main spindle arranged in a machine head and a dressing spindle arranged in the machining area, wherein a grinding tool can be mounted on the main spindle for grinding the workpiece mounted on the machine table, wherein a dressing tool can be mounted on the dressing spindle and the grinding tool and the dressing tool can be moved relatively to each other for dressing the grinding tool by the dressing tool, wherein the rotation axis of the dressing spindle has an inclination T to the vertical direction.

11. The machine tool according to claim 10, wherein a control unit is provided in the machine tool.

12. The machine tool according to claim 10, wherein the machine tool includes a calibration sphere and a test mandrel which can be mounted on the dressing spindle for calibrating a dressing spindle, wherein the calibration sphere comprises a connecting portion and a jig on the top of the connecting portion, wherein the test mandrel comprises a seat and an elongated body formed on the top of the seat.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0026] In the following, a more particular description of the present invention is further described. The embodiments are described and explained with details with reference to accompanying drawings in which:

[0027] FIG. 1 illustrates a side view of a machine tool having main spindle and dressing spindle;

[0028] FIG. 2 illustrates a side view of the machining area in which the dressing spindle is mounted;

[0029] FIG. 3a illustrates schematically dressing the side surface of a grinding tool;

[0030] FIG. 3b illustrates schematically dressing the bottom surface of the grinding tool;

[0031] FIG. 4 illustrates a schematic view of the dressing spindle;

[0032] FIG. 5 illustrates schematically test mandrel having an elongated body and a seat mounted on the dressing spindle;

[0033] FIG. 6 illustrates the trigonometry for calculation of tilt angulation;

[0034] FIG. 7 illustrates schematically a calibration sphere having a jig and a supporting element mounted on the dressing spindle; and

[0035] FIG. 8 illustrates steps of the method of the present invention.

EXEMPLARY EMBODIMENTS

[0036] FIG. 1 illustrates a machine tool which is applicable for grinding. In particular, the FIG. 1 shows a machine tool for milling and grinding. The machine tool 1 has three linear axes X, Y and Z and two rotational axes B and C. The machine tool comprises a machine table 2 which can be moved linearly along the axis X. The linear movements along the Y and Z axes are conducted by the machine head 4. A cradle 3 is mounted on the machine table and can be rotated around the rotation axis B. The cradle includes a workpiece table 6 for mounting a workpiece thereon and the workpiece table is rotatable around the second rotation axis C. A main spindle 5 is mounted in the machine head for clamping different machining tools, for example a grinding tool therein. A dressing spindle 10 is fixedly mounted on the machine table, so it is not movable along with the workpiece table.

[0037] The FIG. 2 shows the arrangement of the dressing spindle depicted in the FIG. 1. A fixture 11 is mounted on the side surface of the machine table. The dressing spindle is mounted on the top surface of the fixture. On the top of the dressing spindle, a dressing tool 12 can be mounted for conditioning the grinding tool. As depicted in FIG. 2, the rotation axis of the dressing spindle 14 is not in parallel to Z direction, but having a tilt angle To The reason of the tilting is shown in the FIGS. 3a and 3b.

[0038] In order to reshape the grinding tool, not only the side surface 7a of the grinding tool but also the front surface 7b of the grinding tool must be dressed. FIG. 3a shows schematically the state of dressing the side surface of the grinding tool. FIG. 3b shows schematically the state of dressing the front surface of the grinding tool. For dressing, the grinding tool is mounted on the main spindle and moved closely to the dressing tool to be contacted by the dressing tool. The dressing tool is fixed mounted on the dressing spindle but rotates during the dressing. It can be clearly seen that the dressing spindle must have a tilt angle such that the bottom surface can also be reached by the dressing tool.

[0039] FIG. 4 shows a schematic view of the dressing spindle 10 which comprises a dressing spindle body 13 and a tool interface 14. The tool interface serves as an interface to clamp the dressing tool thereon and is located on the top surface of the dressing spindle body. The connecting surface of the spindle body 13 and the tool interface is defined as a referencing surface FR. The center point of the referencing surface is defined as a referencing point R. The goal of the calibration is to precisely determine the coordinate of this position and the tilt angulation of the dressing spindle. The determined values can be stored in the control unit of the machine tool for calculating the movement of the main spindle for dressing. The standard touch probe is only able to probe in an X-Y workplane and in Z-axis. Due to the inclination of the dressing spindle it is not possible to determine the position of the referencing point by the standard touch probe.

[0040] To determine the tilt angulation To of the dressing spindle, the grinding tool mounted on the main spindle is replaced by a touch probe 40 and the dressing tool is replace by a test mandrel 30. As shown in FIG. 5, the test mandrel comprises a sit 32 for clamping it on the dressing spindle and an elongated body 31 on the seat. The seat has a cylindrical body and in its inner side a clamping interface is provided to be precisely mounted on the dressing spindle. The clamping interface is designed such that it can be coupled with the tool interface of the spindle in a simple manner. In particular, in the mounted state, the center axis of the test mandrel is in line with the rotation axis of the dressing spindle. The touch probe is controlled by the control unit of the machine tool to contact the different positions on the body and determine the tilt angle based on the measured positions.

[0041] As shown in FIG. 5, the touch probe is positioned close to the body and controlled by the control unit to contact for example the points Q1 and Q2 on the side surface of the body. The coordinates of the measured points Q1 and Q2, Q1(x.sub.Q1, y.sub.Q1 Z.sub.Q1) and Q2(x.sub.Q2, y.sub.Q2 Z.sub.Q2) are input into the control unit and the tilt angle of the mandrel T can be calculated.

[0042] As shown in FIG. 6, the trigonometry must be applied to calculate the tilt angulation T. The length a is the distance of the measured positions in Z direction, namely the difference of the two values of z.sub.Q1 and z.sub.Q2. The length b is the distance of measured positions in Y direction, namely the difference of the two values of y.sub.Q1 and y.sub.Q2.

[0043] In a further step, a calibration sphere is applied. The test mandrel is replaced by the calibration sphere which comprises a connecting portion 22 for clamping it on the dressing spindle and a jig 21 formed on the top of the connecting portion. The connecting portion has a cylindrical body and is provided with a clamping interface to be precisely mounted on the dressing spindle. In particular, the center axis of the calibration sphere is in line with the rotation axis of the dressing spindle. The touch probe is controlled by the control unit of the machine tool to contact the different positions on the jig and determine the center position of the jig based on the measured positions, namely the coordinates of the point P shown in the FIG. 7. The distance A is known from manufacturing the calibration sphere. The diameter of the jig B is also known from manufacturing data. Since the coordinates of the center point of jig P is determined, the coordinates of the referencing point R can be determined by applying trigonometry.

[0044] The FIG. 8 shows the sequences of the method of the present invention. In the step S1, a touch probe is mounted on the main spindle. In the step S2, the dressing spindle is replaced by a test mandrel. In the step S3, the tilt angle of the rotation axis of the dressing spindle is determined by contacting the touch probe with the mandrel at a plurality of positions on the mandrel. In the step S4, the test mandrel is replaced by a calibration sphere. In the step S5, a plurality of positions on the calibration sphere is measured by contacting the touch probe with the calibration sphere at a plurality of positions and the measured positions are recorded. In the step S6, the center position of the calibration sphere is determined based on the plurality of calibration sphere positions by a processing unit. In the step S7, the center position of the dressing spindle is determined based on the determined center position of the calibration sphere, the tilt angle of the rotation axis of the dressing spindle and the dimension of the touch probe.