GB2307988A - Surface form measurement - Google Patents

Abstract

A nominally cylindrical surface 10a of a workpiece 10 is sensed by a stylus 9 displaceable radially of an axis A of rotation of the surface relative to a support column 5 defining a reference datum B so that the stylus 9 follows the cylindrical surface at a given height along the surface. Relative rotation of the workpiece 10 and the stylus 9 about the axis A of rotation of the surface a is effected and the displacement of the stylus 9 used to determine information relating to the radial form of the surface at that height. These measurements are repeated at different heights along the surface so as to determine its cylindrical form. The displacement of the stylus 9 from a given position on the surface at each height before and after rotation A of the stylus and workpiece through 180{ are measured and the resulting measurements used to compensate for any error or deviation in the reference datum.

Description

SURFACE FORM MEASUREMENT This invention relates to a method of surface form measurement and is particularly applicable to the measurement of the radial or cylindrical form of an object such as a workpiece. Radial form is related to the roundness of an object and gives an indication of its deviation from circularity. Cylindrical form provides a measure of how close in shape the surface is to a right cylinder.

In known apparatus for measuring cylindrical form such as the Applicants' Talyrond TR 200 (trade mark) measurement apparatus, a generally cylindrical workpiece to be measured is mounted on a rotatable support or turntable. The rotatable support is centred and levelled, for example in the manner described in the Applicants' EP-A-0240150 the contents of which are incorporated herein by reference, so that the cylindrical axis of the workpiece is coincident with the spindle of the turntable which defines a rotational axis datum. An axial straight datum is defined by a support column located offset from but parallel to the rotational axis datum. The support column carries a probe arm which is moveable along and transversely of the support column to allow a stylus carried by the probe arm to contact the surface of the workpiece.

The radial or cylindrical form of the workpiece is measured by rotating the turntable and measuring the displacement of the stylus relative to the axial straight datum. As the axis of the cylinder is aligned with the rotational axis datum, the displacement of the stylus relative to the axial straight datum provides a measurement of the radius at each angular measurement position during rotation of the rotatable support. The radial form or deviation of the cross-section of the workpiece from a circular cross-section can thus be determined. In addition, the cylindrical form of the workpiece may be determined by making measurements at different heights along the workpiece by moving the probe arm along the axial straight datum.Movement of the probe arm transversely and longitudinally of the axial straight datum is measured by appropriate gauges, for example optical or linear variable differential transducer (LVDT) gauges.

The accuracy of measurements made using such apparatus depends on the accuracy of the rotational axis datum and, especially for cylindrical form, the axial straight datum. It is possible to define the spindle or rotational axis datum to, typically, within +25nm (nanometres) so, generally, the mechanical performance of the axial straight datum is the limiting source of error for radial and cylindrical form. Mechanically related errors in the axial straight datum may arise from, for example, long term mechanical instability, for example changes with temperature or other environmental factors, inaccuracies in the actual straightness of the axial straight datum or its parallelism to the rotational axis datum and variability of the interface between the support column defining the axial straight datum and the carriage carrying the probe arm on the support column.

As described in the manual for the Talyrond TR 200 at section 16.8, the straightness of the traverse, that is effectively the straightness of the axial straight datum, may be checked by mounting a cylinder slightly offset from the rotational axis datum of the turntable normally of the axial straight datum. The stylus is then caused to move axially along the surface of the workpiece by moving the probe arm longitudinally of the support column and the variation in the displacement of the stylus from the axial straight datum with height is plotted to form a first straightness graph. The abovementioned procedure is then repeated after the turntable has been rotated through 1800 to form a second straightness graph.The line bisecting the first and second straightness graphs should be a straight line and any departure from straightness of the bisector represents an error in the straightness of the column support or axial straight datum. The slope of the bisector is a function of any residual relative tilt of the column support and the cylindrical workpiece and is not related to the straightness of the column support.

The above-described straightness check is intended to be carried out from time to time before making a measurement on a workpiece so as to ensure that the straightness of the axial straight datum lies within acceptable limits and to enable calibration of the apparatus.

An embodiment of the present invention provides a method of measuring the form of a surface which is nominally symmetric about an axis, for example a surface having a cylindrical form, which method enables the effects of any deviations in the measurement direction in a reference datum to be eliminated or at least reduced during the measurement process.

In an embodiment, sensing means are used to obtain at least two sets of data for measurement points Pj(hy) on a surface with the points Pi(hy) being at different angular positions (with respect to an axis about which relative rotation of the surface and the sensing means is effected) for each measurement and the at least two sets of data are combined to compensate for any deviations in, for example, straightness or parallelism in a datum to which the measurements made by the sensing means are referenced. For example, the two sets of data may be combined by taking the mean of two values measured for the same location on the surface measured with two different orientations of the sensing means to the reference datum to give an indication of the radius (that is the distance from the said axis to the location) at that location.The difference of the same two measurements may be taken to give an indication of the value of any deviation or error in the reference datum.

This enables measurements of the form at a given height along a surface to be made which are not dependent on errors in the reference datum in the measurement direction. By making such measurements at different heights along the surface of the object, the form of the object can be determined without being affected by any deviation or error in the reference datum in the measurement direction.

In an embodiment, two sensing means are used to obtain data for two diametrically opposed points Pi(hy) and Pi+v(hy) on a surface so allowing two sets of data to be obtained at the same time. In this example a diameter determined by the separation of the two sensing means may be compared with a diameter obtained by combining the polar data which is obtained individually from the two sensing means and which is referenced to a reference datum. This enables any deviation in the measurement direction in the reference datum to be determined. These measurements may be repeated for other points at the same height and for corresponding points at different heights to determine the overall form of the surface compensated for any deviation in the measurement direction of the reference datum.

Relative rotation of the surface and the sensing means may be effected by mounting the surface on a rotatable support. As another possibility, relative rotation of the surface and the sensing means may be effected by rotatably mounting the sensing means to a support and rotating the sensing means about the surface.

Embodiments of the present invention will now be described, by way of example, with reference to the accompanying drawings in which: Figure 1 is a simplified schematic perspective view one example of metrological apparatus suitable for use in a method in accordance with the invention; Figures 2a and 2b are diagrammatic side and plan views, respectively, of part of the apparatus shown in Figure 1 for illustrating a first step in a first embodiment of a method in accordance with the invention; Figures 2c and 2d are views similar to Figures 2a and 2b for illustrating a second step in a first embodiment of a method in accordance with the present invention; Figures 3a to 3d are diagrams for explaining a method embodying the invention;; Figure 4a is a schematic perspective view of one example of apparatus suitable for use in a second embodiment of a method in accordance with the present invention; Figure 4b is a diagrammatic side view of the apparatus shown in Figure 4a; Figures 5a and Sb are diagrams for explaining in more detail a method embodying the invention using apparatus such as that shown in Figures 4a and 4b; Figure 6a is a diagrammatic side view of a second example of apparatus suitable for use in a second embodiment of a method in accordance with the present invention; Figure 6b is a top plan view of part of the apparatus shown in Figure 6a; Figure 7 is a simplified diagrammatic perspective view for illustrating the principles of another embodiment of apparatus suitable for use in a method in accordance with the invention;; Figure 8 is a simplified diagrammatic side elevational view of a further embodiment of apparatus suitable for use in a method embodying the invention; Figure 9 shows a diagrammatic side view of a modified coordinate measuring machine suitable for use in a method in accordance with the present invention; and Figure 10 is a simplified block diagram of a control system for the apparatus shown in the preceding figures.

Referring now to Figure 1, a first example of a metrological apparatus 1 suitable for use in a method in accordance with the invention comprises a work bench 2 (only part of which is shown) which carries a rotatable support or turntable 4 for receiving a workpiece (not shown) to be measured. The turntable 4 has a rotational axis shown by the dashed line A in Fig. 1. A support column 5 extends perpendicularly of the work bench 2 and has a longitudinal axis shown by the dashed line B. The rotational axis A of the turntable 4 defines a rotational axis datum while the support column 5 defines an axial straight datum in the form of a plane passing through the axis B parallel to the rotational axis datum A.

A carriage 6 is moveable along the support column 5 parallel to the axial straight datum B by means, for example, of a motor (not shown) or manually. The manner in which the carriage 6 is moved along the support column 5 is conventional and will not be described further.

Measurement of the actual location of the carriage 6 along the support column 5 is effected by a suitable conventional linear transducer, for example an optical transducer arrangement such as that described in EP-A0240151, the contents of which are incorporated herein by reference.

A probe arm 7 is mounted to the carriage 6 so as to be moveable transversely of the axial straight datum B and radially of the rotational axis datum A. Again, any suitable form of conventional mechanism such as a lead screw may be used for moving the probe arm 7 relative to the carriage 6. A stylus 9 is mounted to the probe arm 7 by means of a pivotable arm 8. Measurement of the position of the probe arm 7 (and thus the stylus 9) is made using a suitable conventional transducer (not shown).

In use of the apparatus, as shown diagrammatically in Figure 2a, a workpiece 10 of a generally cylindrical external form l0a is mounted to the turntable 4 so that its axis of rotation is coincident with the rotational axis datum A. This may be achieved by, for example, using the centring and levelling arrangement disclosed in EP-A-0240150 or Application No. 9421013.5 (filed 18 October 1994), or any other suitable known centring and levelling technique.

The carriage 6 is adjusted to a desired measurement starting height, for example a height h above the base of generally cylindrical workpiece 10. The moveable probe arm 7 is then driven transversely of the carriage 6 until the stylus 9 contacts the surface lOa of the workpiece. Contact between the stylus 9 and the surface 10a of the workpiece may be determined by any suitable mechanism, for example that described in EP-A-0240151 so that the probe arm 7 is driven so as to maintain the deflection of the stylus 9 within the range of operation of an associated transducer. The pivot arm 8 is maintained at a fixed orientation.The distance between the rotational axis datum A and the axial straight datum B minus the displacement of the stylus 9 relative to the axial straight datum B provides a measure R of the radius of the workpiece 10 at the measurement point P at the height h on the workpiece.

As the workpiece 10 is rotated about the rotational datums axis A, a set of radius values Pi (hl) is obtained for each angular orientation, i, of the workpiece at a height h.

Measurements at a different height h2 along the workpiece can be made by driving the carriage 6 along the column 5 and then proceeding to measure a further set of radius values Pi (h2).

After sufficient sets of data at different desired heights hy have been obtained, the probe can be driven using the extending arm 7 and the pivotal arm 8 so as to address a second measurement position P' diametrically opposed to the original position P.

If necessary the carriage 6 may be lifted in order to avoid interference between the workpiece and the stylus 9.

The stylus 9 can then be driven to the height h1 once more and another set of radius values obtained Pl(i+v(hl). The carriage 6 can then be driven to all the previous heights hy to obtain corresponding sets of radius data Pi+ (hy) for each height.

The obtained radial or polar data thus gives two measurements of the radius at each point Pi(hy) on the surface 10a of the workpiece 10, with the workpiece having been rotated through 1800 between the two measurements. By taking the mean of the two measurements at each point Pi(hy) errors in the axial straight datum B can be compensated for. As indicated above, these errors may arise from mechanical inaccuracies in the straightness of the support column 5 defining the axial straight datum, changes with time in the support column 5 and, for example, variations in the interface between the carriage 6 and the support column 5. Typically, such deviations may be of the same order as deviations from roundness or circularity of the cross-section of a nominally circular cross-section workpiece.

Figure 3a shows a cross-section lOa' of the workpiece 10 at a measurement height h. The dashed line circle C represents the circle having the radius r which is the closest fit to the cross-sectional shape or form of the workpiece 10. 6r represents the "out of roundness" or deviation from circularity of the crosssection of the workpiece 10 at the measurement point P at the height h.

As indicated above, the axial straight datum B may deviate from straightness for various reasons. The deviation of the axial straight datum B from the ideal B1 is shown as 8c in Figure 3a.

Consider the measurement of a radius at a particular point on the surface at orientation o of the full data set Pi(h). The radius at this point measured closest to the axial straight datum B (that is the position shown in Figures 2a and 2b) is given by: PO (h) = r-6r+Ec 1) The radius Pi(h) is thus dependent on any error Sc in the measurement direction in the straightness of the axial straight datum B.

The same radius measured at the same point on the surface (orientation 0) of the workpiece when the gauge is in the second position P' shown in Figures 2c and 2d is: P0'(h) = r-Er-Ec 2) Taking the mean of equations 1) and 2) gives: (Pe(h) + P0'(h)) = r-6r 3) which is the true radius of the component at orientation 9 independent of any error Sc in the direction of the measurement in the axial straight datum B.

Thus taking the mean of the two radius measurements P0(h) and P8'(h) for all values of e around the circumference of the workpiece at height h will give a complete picture of the cross section and shape (and thus of the radial form of workpiece 10) at the height h, independent of any error in the measurement direction of the axial straight datum B.

The method described above also prevents any lack of straightness in the axial straight datum affecting the measurement of cylindrical form. To explain this, reference will now be made to Figures 3b to 3d which are schematic diagrams showing the use of a method embodying the present invention to measure the cylindrical form of a perfect cylinder 100 when the axial straight datum B is bowed so as to be concave when viewed from the workpiece 100. It will, of course, be appreciated that the degree of lack of straightness of the axial straight datum B has been considerably exaggerated in Figures 3b and 3c.

As shown in Figure 3b, when measurements of the radius of points P around the circumference of the workpiece 100 are made at different heights h along the workpiece 100 with the stylus 9 in the position shown in Figures 2a and 2b, the resulting cylindrical form data set represents the workpiece 100 as being barrel-shaped because of the curvature of the axial straight datum B.

In contrast, when measurements of the cylindrical form are made with the stylus 9 displaced by 1800 from the position shown in Figure 3b then, as shown in Figure 3c, the cylindrical form data represents the workpiece 100 as having an inwardly-bowed surface.

By combining a measurement made of the radius at a point Pi(hy) using the arrangement shown in Figure 3b with a measurement of the same point Pi(hy) with the arrangement shown in Figure 3c, a set of cylindrical form data is obtained from which the influence of the lack of straightness of the axial straight datum B has been removed so that the workpiece 100 is correctly represented as a perfect cylinder as shown in Figure 3d.

Thus, the cylindrical form of a workpiece can be determined independently of any errors in the measurement direction in the axial straight datum, so avoiding or at least reducing the need to effect calibration to determine the straightness and/or parallelism of the axial straight datum B before carrying out a measurement.

Although Figures 2a to 3d show the measurement of the cylindrical form of an external surface of a workpiece, it will, of course, be appreciated that the above-described method can be applied to measurement of the cylindrical form of an accessible interior surface of a workpiece with, as will be appreciated by those skilled in the art, appropriate modification of the probe arm and stylus.

Figure 4a shows a schematic perspective view of apparatus la suitable for use in a second embodiment of a method in accordance with the invention. Figure 4b is a schematic side view of the apparatus la showing a workpiece 12 mounted on the turntable 4.

The apparatus shown in Figure 4a differs from that shown in Figure 1 mainly in that the carriage 6 carries two probe arms 7a and 7b each of which carries a respective stylus 9a and 9b to form a twin gauge 90.

The probe arms 7a and 7b are received in respective mounting members lla and llb which engage a guide rail 6a of the carriage 6 so as to be moveable along the guide rail 6a. Any suitable drive arrangement may be provided for driving the mounting members lla,llb along the guide rail 6a, for example, a rack and pinion type arrangement may be provided. The mounting members 11a and 11b may be arranged to be driven manually or by a motor (not shown) so that rotation of the motor in one direction causes the carriages lOa and lOb to move in opposite directions. Of course, the mounting members lla and 11b may be independently driven to provide greater flexibility.

As shown more clearly in the side view of Figure 4b, the carriage 6 and mounting members lla and 11b are arranged such that the styli 9a and 9b lie along a diameter of the turntable 4, in the example shown along a diameter perpendicular to a line between the rotational axis datum A and the axial straight datum B defined by the support column 5.

The probe arms 7a and 7b may be mounted so as to be longitudinally moveable by any suitable drive means within the mounting members 11a and 11b to effect minor adjustments in the position of the styli 9a and 9b in a direction parallel to the rotational axis datum A.

The styli 9a and 9b shown in Figure 4a are elongate members extending parallel to the rotational axis datum.

Each stylus 9a, 9b has a tip portion 9c, 9d projecting outwardly (that is away from the other tip portion) at, for example, a right angle to the stylus. The styli 9a and 9b shown in Figures 4a and 4b are thus suited for measuring the cylindrical form of an internal surface of a hollow body or workpiece 12 as indicated diagrammatically in Figure 4b.

The provision of twin styli means that the measurements of each point Pi(hy) and of each point P'j(hy) diametrically opposite to Pi(hy) can be made without having to re-position the probe or stylus. This means that any errors due to re-positioning of the stylus in the arrangement described above with reference to Figures 2 and 3 can be avoided. Also, the use of a pair of styli enables two sets of data to be obtained at the same time, one for the point Pi(hy) and the other for the point Pi+s(hy) 1800 displaced around the circumference of the workpiece from the point Pi(hy) This reduces the amount of time required to obtain a full set of data for the cylindrical form so that temporal and thermal changes should be less significant.

In use of the apparatus shown in Figures 4a and 4b, the hollow workpiece 12 is centred and levelled on the turntable 4 in the manner described above so that its nominal axis is coincident with the rotational axis datum A. The carriage 6 is then operated to cause the styli 9a and 9b to move into the hollow workpiece 12 until they reach a desired measurement height h. The mounting members lla and llb are then driven so as to move the styli 9a and 9b apart until the styli contact respective diametrically opposed points Pi(hy) and Pi+v(hy) on the internal surface of the workpiece 12.

The position of each stylus 9a and 9b is determined using any suitable conventional measurement transducer, (for example an optical or electromagnetic transducer arrangement) associated with the drive mechanisms of the mounting members lla and llb. The measurement obtained from one of the styli 9a and 9b thus provides an indication of the radius at point Pi(hy) while the measurement of the position of the other one of the styli 9a and 9b provides an indication of the radius at the point Pi+s(hy) The separation of the styli 9a and 9b may also be determined to give a measurement of the diameter dc between the points Pi(hy) and Pi+s(hy) This diameter dc is in dependent of the rotational axis datum A and the axial straight datum B and thus does not involve any errors resulting from inaccuracies in the axial straight datum B along the diameter dc It will, of course, be appreciated that measurements of the radial polar data can Pi(hy) be obtained using just one of the two styli 9a and 9b. However, as mentioned above, using both styli to obtain simultaneous measurements for diametrically opposed points reduces considerably the total time required for measurement of the cylindrical form and the effects of errors which are temporal in nature (for example thermal effects) are minimised.

As in the example described above with reference to Figures 2 and 3, the cylindrical form data P1K(hy) may be obtained by measurement at each height hy in turn sequentially for each measurement position P & P', that is in order, Pi(h), Pi(h2), Pi(h3) .... Pi(hn) and then Pj' (h1) , Pj' (h2) , Pi'(h3) .... Pi (hn)- In practice the full data required to describe the cylindrical form PiK(h1) can be determined by changing i, y and K in any order.

In the second embodiment illustrated in Figure 3 it is preferable to obtain both data sets Pi(hy) and Pi'(h9) whilst the carriage remains at height hy to avoid errors in repositioning the carriage 6 to the height hy which might arise if both the data sets are not taken at this time.

As will be appreciated, the radius R measured by one of the styli 9a and 9b at a point on the surface at an orientation o at height h will again be given by: Pe(h)=r-Er+Ec 4) while the radius measured by the other stylus of the same point on the surface of the workpiece will be: P#' (h)=r-#r-3c 5) where Sr is again the out of roundness of the workpiece at the point being measured and Sc is the deviation from straightness in the measurement direction in the axial straight datum B.

The radial polar data obtained from each of the two styli 9a and 9b may thus be combined, as described above with reference to Figures 2a to 3d, for each measurement point Pi(hy) so as to obtain a set of data for the cylindrical form of the workpiece which is independent of any error in the straightness of the axial straight datum in the measurement direction.

As well as permitting assessment of .surfaces independent of the axial straight datum (and therefore of any error Sic), the apparatus shown in Figures 4a and 4b also enables an indication of the actual lack of straightness Sc in the axial straight datum at a given height to be determined. Thus, subtracting equations 4) and 5) gives: P0(h)-P61(h)=2Sc 6) Hence, taking the difference between any two corresponding data points and dividing by 2 gives Sc.

Assessment of Sc can thus be made at a nominated test orientation 6 or by a suitable averaging process over a number of values of 6.

In the above explanation, it has been assumed that the rotational axis of the cylindrical surface being measured is precisely positioned upon the spindle axis.

It has also been assumed that the stylus or styli are exactly positioned on a diameter (that is on crest).

However, in practice, the rotational axis C of the workpiece cylindrical surface may be somewhat offset from the spindle axis A.

Figures 5a and 5b illustrate this diagrammatically.

In Figure Sa, the radius at the point Pi is being measured by one stylus 9a of a pair of styli 9a and 9b.

In Figure Sb, the radius at the point Pi is being measured by the other stylus 9b when the workpiece 12 has rotated through 1800. Figures 5a and 5b show the rotational axis C of the workpiece cylindrical surface as being offset from the spindle axis A by a distance e (the eccentricity) at an angle a to the diameter between the styli 9a and 9b.

It is well known in the art that the surface traced out by a point on a circle which is rotated off-axis is approximated by a limicon in polar coordinates. Thus, the radius Rpl at point Pi in Figure 5a is given by: Rpl = F + g + e cos(a) 7) where 2F is the distance between the null positions of the two gauges or styli 9a and 9b (manually set to the component diameter) and g is the offset of the centre point OF between the two gauges from the spindle axis A in the direction of the gauge reading. The offset g will therefore include any error Sc in the straightness of the axial straight datum in the measurement direction.

When the workpiece has been rotated through 180a to the position shown in Figure 5b then the equation of the point Pi in polar coordinates is given by: Rp2 = F + g + e cos(a+R) 8) As indicated above, however, the styli may be slightly off-crest by a cresting distance H.For the first position of the point Pi on the surface of the workpiece shown in Figure 5a this is given by: sin#1 = H 9) Rp1(X+01) where 01 is the angle between the desired measurement position Pi and the actual measurement position (the cresting angle) and RP1(x+#1) represents the measurement at the point on the circumference of the workpiece 12 offset from the point Pi by the cresting angle 01.

The above equation can be solved for e by using an appropriate mathematical computing package or software program, for example "Maple 5" which is a symbolic mathematics package produced by Maple Software of 450 Phillips Street, Waterloo, Ontario, Canada.

Using the above-mentioned mathematics package to solve for the cresting angle #1 as a series in terms of the cresting error distance H gives: #1 = H2esin(a) + o(H3) 10) 6i (F+g+ecos(a) (F+g+ecos(a))3 where the series is truncated at terms of the order of H3.

By analogy, the cresting error H at the position 2 shown in Figure Sb is given by: sin#2 = H 11) Rp2(X+02) Using the same mathematics package to solve for 62 in terms of a series in H gives: #2 = (R-g-' H + H2esin(a) (R-g-ecos(α)) (F-g-ecos())3 (α))3 The signal S1 from the stylus 9a in Figure 5a with the cresting error given in equation 10) is: S1 = Rpl (x+#1)cos (01) 13) The signal from stylus 9b at position 2 in Figure 5b (that is when the component has been rotated through 1800) with the cresting error given in equation 12) is:: S2 = RP2(x+#2)COS(02) RP2(x+n-#2)cos(#2) 14) Solving for S, as a Taylor series in the cresting error H gives: S1 = (F+g+ecos(a))- Hesin(a) + o(H2) 15) (F+g+ecos(a)) Similarly, solving for S2 as a Taylor series in terms of the cresting error H gives: Taking the mean of the two signals S1 and S2 and S2 = (F-g+ecos(a)) + Hesin(a) + o(H2) 16) F-g-ecos (a) expanding this as a Taylor series in the cresting error H gives:: Smean = (F+ecos(α))

+ ( - esin(α) + esin(α)] H17) F+g+ecosa) F-g-ecos(α)) + o(H2) where, as in equations 10) and 12), 0 indicates terms of the order of the indicated power. Converting the series of equation 17) into a polynomial in the cresting error or distance H gives: PS = (F+ecos(a))

+ (-1/2 esin(a) ) + +esin(a) 18) F+g+ecosa) F-g-ecos(α)) Typically, F = 1.25mm, g = -.005mm, e = 0.001mm and H = 0.001mm.

Because F is very much larger than g and e, the terms in sina in equation 18) will be very similar to one another and will effectively cancel out. Thus, to first order, the measure of the radius obtained by taking the mean of the signals from the stylus 9a in Figure 5a and the stylus 9b in Figure 5b is not affected by the cresting error H or the offset g.

In the examples described above, the workpiece is itself rotated. However, other arrangements can be envisaged wherein the measuring arrangement (the stylus or styli) is rotated rather than the workpiece.

Figure 6a illustrates, very schematically, such a type of apparatus lb suitable for use in a method in accordance with the invention. The apparatus shown in Figure 6a is, like the apparatus shown in Figures 4a and 4b, a twin gauge system. However, in the apparatus shown in Figure 6a, the turntable 4 is omitted and replaced by a rotatable spindle 40 (which may have any suitable conventional form) mounted to an arm 6a fixed to the support column 5.

The spindle 40 carries a frame 60 having downwardly depending arms 61 to which is slidably mounted a crossbar 62 carrying respective mounting members 63 for the probe arms 7a and 7b. The cross-bar 62 is movable along the arms 61 in a manner similar to the manner in which the carriage 6 is movable along the support column 5 in Figure 1. In this example, the arms 61 define the axial straight or reference datum B. The position of the cross-bar 62 with respect to the arms 61 may be determined in a manner similar to that used to determine the position of the carriage 6 in Figure 1.

Figure 6b is a top plan view of part of the apparatus of Figure 6a showing more clearly the arrangement of the cross-bar 62 and probe arms 7a and 7b.

This arrangement enables the styli 9a and 9b to be moved along the height of the workpiece 13 to enable measurements to be taken at different heights.

In the example shown in Figure 6a, the styli 9a and 9b are configured with inwardly pointing tip portions 9c and 9d for measuring an external surface. However, the styli 9a and 9b shown in Figures 6a and 6b could be replaced by the styli shown in Figure 4 to enable an internal surface to be measured, with appropriate dimensioning of the components of the apparatus to enable the styli to be accommodated within the workpiece being measured.

The apparatus lb shown in Figure 6 is used in a similar manner to the apparatus shown in Figures 4a and 4b except, in this case, the workpiece 13 is mounted to the work bench 2 so as to be aligned with the spindle axis A' and the spindle 40 rather than the turntable 4 is rotated to obtained the polar data.

In the examples described above, the cylindrical form is determined by making measurements of the radial form at different heights along the workpiece by raising or lowering the stylus or styli. However, another way of measuring cylindrical form is to provide two or more styli or pairs of styli spaced at calibrated fixed distances from one another in a direction defining the axial straight datum.

Figure 7 shows schematically part of an apparatus to illustrate the principle of providing a number of twin gauges 90a. In the example shown in Figure 7, three twin gauges 90 are mounted to a common support 61, causing the sets of twin gauges to be nominally aligned to the component axis which defines the equivalent to the axial straight datum B. Of course, if it is desired only to make measurements at three distinct heights along a workpiece, then the support carrying the twin gauges may be fixed to the support column 5.

As shown very diagrammatically in Figure 7, each of the twin gauges 90a is in the form of a fixed U-shaped member 91 with the arms 9la and 9lb extending perpendicularly of the support or carriage 6'. The free end of each arm 9la and 91b supports a stylus 9c (shown simply by an arrow in Figure 7) in any suitable conventional manner.

In the arrangement shown in Figure 7, the arms 9la and 91b of the U-shaped members 91 are fixed in position.

It may, however, be possible to mount the arms 91a and 91b on guide rails in a manner similar to that discussed above with reference to Figure 4a so as to enable the nominal separation of the styli 9c of each twin gauge 90a to be adjusted to allow differently sized work pieces to be measured using the same apparatus.

In operation of the apparatus illustrated by Figure 7, the workpiece 14 is mounted and centred in conventional manner on the turntable (not shown in Figure 7) so as to be positioned between the respective styli of the gauges 90a. The styli are then driven in conventional manner to bring them into contact with the surface of the workpiece. Measurements of the radial data sets Pe(h) can then be made in the manner described above simultaneously at each of three heights hl, h2 and h3 along the workpiece 14. Because, as described above, deviations from straightness of the axial straight datum are compensated for using a method embodying the invention, it is not necessary for the twin gauges 90a to be calibrated with respect to one another. Of course, each individual gauge should be calibrated in a conventional manner.In addition, in order to ensure compatibility of the twin gauges 9a, calibration of the gauge separation is also required.

The arrangement shown in Figure 7 may be modified to enable simultaneous measurement of radial form at a number of different heights of an internal surface of a workpiece.

Figure 8 illustrates very diagrammatically a modified form of the apparatus shown in Figure 6a. In the example shown in Figure 8, the frame 60 and depending arms 61 are replaced by a rigid rod 65 to which are fixedly attached pairs of opposed radially extending arms 66a,b,c each of which carries a respective stylus 9e.

The apparatus shown in Figure 8 also differs from that shown in Figure 6a in that a movable carriage 6 is supported on the support column 5 in a manner similar to that shown in Figure 1. However any suitable arrangement for nominally aligning the rigid rod 65 with the component axis may be used. For example, the spindle 40 and rigid rod 65 may be carried by a frame which is designed to be portable and to be secured directly to a component to be measured. As in the apparatus of Figure 7, the reference datum B is defined by the alignment of the twin gauges 9e.

In this example, a workpiece 15 is first mounted on the work bench 2 so as to be aligned with the rotation axis A' of the spindle 40. The carriage 6 is then lowered so as to insert the rigid rod 65 carrying the probe arm 66 and styli 9c into the hollow workpiece.

Once the rod 65 has been correctly inserted within the hollow workpiece 15, the probe arms 66c are driven so as to bring the styli 9c into contact with the interior surface of the workpiece 15. Measurements of radial form at each of three different heights are then taken in the manner described above by rotating the spindle 40.

The apparatus shown in Figure 8 has the advantage that, as in the apparatus shown in Figure 6, the alignment of the twin gauges 9e (as determined by the rigid rod 65 in this case) is not critical because any deviations or errors are compensated for in the manner described above.

Of course, the apparatus shown in Figure 8 could be modified by providing a turntable 4 on the workbench 2 and fixing the rod 65 against rotation to the carriage 6.

The apparatus shown in Figures 7 and 8 may, of course, be modified to provide any desired number of pairs of twin gauges. It may also be possible to mount the twin gauges of Figure 7 on a movable carriage similar to the carriage 6 shown in Figure 1 to enable three simultaneous sets of polar data to be obtained at two or more different sets of three heights along the workpiece.

Similarly, the carriage 6 shown in Figure 8 may be moved to enable measurements to be made at more than one set of three heights.

A method embodying the present invention may also applied to a modified coordinate measuring machine in which, as described in, for example, GB-A-1137238 or GB A-2160975 (the contents of which are herein incorporated by reference) measurements are made on an x, y, z rectangular coordinate system.

Figure 9 illustrates very schematically an example of coordinate measuring machine modified to be used in a method in accordance with the present invention.

As shown in Figure 9, the coordinate measuring machine comprises a work bench 20 carrying two guide rails 21a and 21b which extend spaced-apart and parallel to one another in a direction perpendicular to the plane of the paper (the x direction). A U-shaped frame 22 is supported so as to be drivable along the guide rails 21a and 21b by any suitable drive means and using any suitable form of bearing arrangement. The cross-bar 22a of the U-shaped frame 22 carries a movable carriage 23 which supports a support member 24. The support member 24 is moveable relative to the carriage 23 in the z direction by any appropriate drive mechanism.Suitable measurement transducers are associated with the x, y and z direction drive mechanisms, for example optical or electromagnetic transducers as mentioned above, to enable the precise location in x, y and z coordinates of a probe carried by the support 24 to be determined.

The components of the coordinate measuring machine described above are conventional.

As shown in Figure 9 the work bench 20 is provided with a rotatable support or turntable 4b similar to that shown in Figure 1. In this case, the z axis support 24 carries a fixed probe arm 7a carrying a single stylus 9a.

The coordinate measuring machine shown in Figure 10 may be used in the manner described above with reference to Figs. 2a to 2d and 3a to 3d by causing the carriage 23 to move along the cross-bar 22a to enable a first measurement of the radius at a point P on the circumference at height h of the workpiece 15 to be measured with the carriage 23 at a first position yl and a second measurement of the radius at the point P to be measured when the turntable has been rotated through 1800 and the carriage 23 moved to a position y2 shown in phantom lines in Figure 9. The radial and cylindrical form can then be determined as described above with reference to Figures 2a to 2d and 3a to 3d.As another possibility, the apparatus shown in Figure 9 may be modified by replacing the single stylus with one, or possibly more, calliper gauges to enable the methods described above with reference to Figure 4 to be performed.

In each of the examples described above, the radial and cylindrical form data are generally calculated by a suitable programmed computer processing system which receives input signals from the transducers of the apparatus. Figure 10 shows a simplified block diagram of a suitable processing system comprising a central processing unit 50 associated with a memory comprising ROM and RAM for storing operational programs and data, respectively.

During the measurement of the cylindrical form of a workpiece, data from the transducers is logged by the computer processing system and then used to determine the radial and cylindrical form of the workpiece in the manner described above. Figure 10 shows the central processing unit 50 as being coupled to three transducers T1, T2 and T3 providing signals representing the rotation of the turntable, the height of the carriage along the column support 5 and the position of the probe arm 7.

Of course, the number of transducers will depend upon the particular apparatus, as described above.

The processing system may be provided with an input device 52 in the form of a keyboard which may be associated with a mouse 52a or other appropriate pointing device to enable a user to input information concerning, for example, recent calibration of the apparatus or machine, or instructions regarding the particular method to be used. In addition, a display unit such as a cathode ray tube 53 may be associated with the control processing unit 50 to enable, using appropriate conventional software, visual displays of the measurements made with the apparatus to be provided. As an alternative or addition to the visual display unit, an output device such as a printer or plotter may be provided to enable a hard copy to be provided of the measured data in the form of, for example, tabulated radial data and/or a graphical representation of the measured data.

Although in the examples described above, two measurements of the polar data at a single position at a given height on a workpiece are made, if desired three or more such measurements may be made by, for example, providing three or more measurements stylised equally angularly spaced around the periphery of the workpiece.

Also, although in the examples described above a set of polar data is first obtained at a given height, it may be possible or desirable in some circumstances to move the stylus or stylii axially of the workpiece or component to obtain data at different heights h and then to effect relative rotation between the workpiece and the sensing means.

If desired, where a twin gauge is provided, a first measurement of diameter may be made by determining the relative separation of the two gauges. This first measurement is independent of any errors in the axial straight datum B and may be compared with a second measurement of diameter obtained by combining the radii measured at the two opposed points by the stylii to give an indication of the actual deviation or error in the axial straight datum at that diameter.

Although the above examples describe ways of determining the cylindrical form of a workpiece surface, the present invention may be used to determine the form of any suitable surface, for example any surface which is nominally symmetric about an axis of rotation. For example, the present invention may be used to determine the form of a surface of constant polygonal, ellipsoidal or irregular cross-section or a tapered surface such as a frustoconical or conical surface or a surface of nonconstant cross-section.

The present invention may also be used to determine the form of any surface that is produced by a machine tool such as a lathe or grinder. For example, the apparatus may be provided as an attachment to a lathe or grinder with for example a twin gauge pair being attached to the tool post and the spindle of the lathe or grinder being used to effect rotation to obtain data while the workpiece or component is still in the chuck or jaw of the machine tool. Such an arrangement may allow measurements of the form of a surface to be made at an intermediate stage in the working of the component by the machine tool to check that the machining is proceeding correctly.

Although specific examples of the present invention have been described above, various modifications and alternatives will be apparent to those skilled in the art.

Claims (28)

CLAIMS:

1. A method of determining information relating to the form of a surface of an object such as a workpiece, which method comprises sensing the surface using sensing means displaceable relative to a reference datum so as to follow the surface, effecting relative rotation about a rotation axis between the surface and the sensing means and using measurements made by the sensing means to determine information relating to the form of the surface, characterised by using measurements made by the sensing means at at least two positions equiangularly spaced apart around the axis of rotation to compensate for any error in the reference datum.

2. A method of determining the form of a surface which is nominally symmetric about an axis, which method comprises effecting relative rotation of the surface and sensing means displaceable relative to a reference datum so that the sensing means follows the surface and using the sensing means to make measurements at a number of different distances along the said axis of the surface to determine the form of the surface, characterised by using, for each distance along the axis of the surface, measurements made by the sensing means at at least two positions equiangularly spaced apart around the axis of rotation to compensate for any deviation or error in the reference datum.

3. A method according to claim 1 or 2, which comprises using two measurements made at positions spaced apart by 1800 to compensate for any deviation or error in the reference datum.

4. A method according to claim 1, 2 or 3, which comprises using as the at least two measurements, measurements of the same location on the surface made at different angles of relative rotation between the sensing means and the surface.

5. A method according to claim 4, which comprises determining the mean of the two measurements to obtain a value for the radius at that location.

6. A method of determining the form of a surface which is nominally symmetric about an axis, which method comprises sensing the surface using sensing means displaceable relative to a reference datum so as to follow the surface, effecting relative rotation of the surface and the sensing means and using the sensing means to make measurements at a number of different measurement distances or heights along the said axis of the surface to determine the form of the surface, characterised by, for each measurement distance along the said axis, using the sensing means to obtain a first measurement of the displacement from the reference datum of a given position on the surface, effecting relative rotation through 1800 between the surface and the sensing means and then using the sensing means to obtain a second measurement of the displacement from the reference datum of the same given position on the surface and using the mean of the first and second measurements to provide data representing that given position.

7. A method according to claim 4, 5 or 6, which comprises determining any deviation in the reference datum from the difference between the two measurements.

8. A method according to any one of the preceding claims, which comprises using a sensing means having two opposed sensing elements for sensing simultaneously two opposed locations on the surface.

9. A method according to claim 8, which comprises using the sensing means to make a first measurement of the distance between the two opposed locations by determining the relative separation of the two sensing elements, determining the displacement of each sensing element from the reference datum, combining the two displacements to provide a second measurement of the distance between the two opposed locations, and comparing the first and second distance measurements to determine any deviation in the reference datum.

10. A method according to any one of the preceding claims, which comprises using the sensing means to make at least two measurements at different degrees of relative rotation between the surface and the sensing means of each of a set of locations distributed around the said axis of the surface.

11. A method according to any one of the preceding claims, which comprises providing a number of sensing mean spaced apart along the reference datum for enabling measurements to be made simultaneously at locations spaced along the said axis of the surface.

12. A method according to any one of the preceding claims, which comprises effecting relative rotation of the surface and the sensing means by mounting the surface on a rotatable support and rotating the support.

13. A method according to any one of claims 1 to 11, which comprises effecting relative rotation of the surface and the sensing means by rotatably mounting the sensing means to a support and rotating the sensing means.

14. Apparatus for determining information relating to the form of a surface of an object such as a workpiece, comprising sensing means displaceable relative to a reference datum so as to follow the surface, means for effecting relative rotation between the surface and the sensing means and means for determining from measurements made by the sensing means information relating to the form of the surface, characterised in that processing means are provided for using measurements made by the sensing means at at least two positions equiangularly spaced apart around the axis of rotation to compensate for any error or deviation in the reference datum.

15. Apparatus for determining the form of a surface which is nominally symmetric about an axis, which apparatus comprises sensing means displaceable relative to a reference datum so as to follow the surface, means for effecting relative rotation of the surface and the sensing means and means for using the sensing means to make measurements at a number of different distances along the axis of the surface to determine the form of the surface, characterised in that processing means are provided for using measurements made by the sensing means at at least two positions equiangularly spaced apart around the axis of rotation to compensate for any deviation or error in the reference datum at each distance along the axis of the surface.

16. Apparatus according to claim 14 or 15, wherein the processing means are adapted to use two measurements made at positions spaced apart by 1800 to compensate for any deviation or error in the reference datum.

17. Apparatus according to claim 14, 15 or 16, wherein the processing means are adapted to use as the at least two measurements, measurements of the same location on the surface made at different angles of relative rotation between the sensing means and the surface.

18. Apparatus according to claim 17, wherein the processing means are adapted to determine the mean of the two measurements to obtain a measurement for that location.

19. Apparatus according to claim 17 or 18, wherein the processing means are adapted to determine any deviation or error in the reference datum from the difference between the two measurements.

20. Apparatus for determining the form of a surface which is nominally symmetric about an axis, comprising sensing means displaceable relative to a reference datum so as to follow the surface, means for effecting relative rotation of the surface and the sensing means and means for using the sensing means to make measurements at a number of different measurement distances or heights along the axis of the surface to determine the form of the surface, characterised by control means for, for each measurement distance along the axis of the surface, using the sensing means to obtain a first measurement of the displacement from the reference datum of a given position on the surface, causing relative rotation through 1800 between the surface and the sensing means and then using the sensing means to obtain a second measurement of the displacement from the reference datum of the same given position on the surface and processing means for determining the mean of the first and second measurements to provide data representing that given position.

21. Apparatus according to any one of claims 14 to 20, wherein the sensing means comprises two opposed sensing elements for sensing simultaneously respective opposed locations on the surface.

22. Apparatus according to claim 21, wherein the processing means comprises means for making a first measurement of the distance between the two opposed locations by determining the relative separation of the two sensing elements, means for determining the displacement of each sensing element from the reference datum and combining the two displacements to provide a second measurement of the distance between the first and second locations, and means for comparing the first and second measurements of the distance between the first and second locations to determine any deviation or error in the reference datum.

23. Apparatus according to any one of claims 14 to 22, wherein the processing means is adapted to use measurements made by the sensing means at a number of different sets of at least two positions equiangularly spaced apart around the axis of rotation to compensate for a respective deviation from straightness in the reference datum.

24. Apparatus according to any one of claims 14 to 23, wherein a number of sensing means are provided spaced apart along the reference datum for enabling measurements to be made simultaneously at spaced locations on the surface.

25. Apparatus according to any one of claims 14 to 24, wherein the means for effecting relative rotation of the surface and the sensing means comprises a rotatable support for the object.

26. Apparatus according to any one of claims 14 to 24, wherein the means for effecting relative rotation of the surface and the sensing means comprises a rotatable mounting for the sensing means.

27. A method of determining the form of a surface substantially as hereinbefore described with reference to the accompanying drawings.

28. An apparatus for determining the form of a surface substantially as hereinbefore described with reference to the accompanying drawings.