NON-CONTACT TOOL SETTING APPARATUS AND METHOD FOR MOVING TOOL ALONG TOOL INSPECTION PATH

Abstract

A method for assessing the profile of a tool using a non-contact tool setting apparatus that includes a transmitter for emitting a light beam and a receiver for receiving the beam. The receiver generates a beam intensity signal describing the intensity of received light. The setting apparatus is mounted to a coordinate positioning apparatus that allows the tool to be moved relative to the setting apparatus. The method includes using the coordinate positioning apparatus to move the tool relative to the setting apparatus along a tool inspection path, the tool inspection path being selected so that the light beam is traced substantially along a periphery of the tool to be inspected. Beam intensity data is collected describing the beam intensity signal that is generated by the receiver as the tool inspection path is traversed and analysis of the collected beam intensity data is used to assess the tool profile.

Claims

1. A method for assessing a profile of a tool using a non-contact tool setting apparatus comprising a transmitter for emitting a light beam and a receiver for receiving the light beam, the receiver generating a beam intensity signal describing intensity of received light, the non-contact tool setting apparatus being mounted to a coordinate positioning apparatus that allows the tool to be moved relative to the non-contact tool setting apparatus, and the method comprising steps of: (i) using the coordinate positioning apparatus to move the tool relative to the non-contact tool setting apparatus along a tool inspection path comprising a start position on an edge of the tool and an end position on the edge of the tool, the end position being spaced apart from the start position and the movement of the tool relative to the non-contact tool setting apparatus causing the light beam to be scanned along the edge of the tool from the start position to the end position without the tool moving out of the light beam; (ii) collecting beam intensity data describing the beam intensity signal that is generated by the receiver as the tool inspection path of step (i) is traversed, the beam intensity data being collected for a plurality of positions that are spaced apart along the edge of the tool between the start position and the end position; and (iii) analysing the beam intensity data collected in step (ii) to determine a profile of the edge of the tool between the start position and the end position.

2. The method according to claim 1, wherein the tool inspection path is pre-calculated prior to step (i).

3. The method according to claim 1, wherein step (iii) comprises comparing the beam intensity data collected in step (ii) with previously acquired beam intensity data.

4. The method according to claim 3, wherein the previously acquired beam intensity data comprises data collected from a previous measurement of the same tool or from a reference tool having the same nominal profile as the tool, and the analysis of step (iii) provides an indication of whether the tool profile has changed relative to the previous measurement.

5. The method according to claim 1, wherein the tool is held in a rotatable spindle of the coordinate positioning apparatus, the tool comprises one or more cutting teeth located around a radius of the tool, and the tool is rotated about a longitudinal axis of the tool while the tool is moved along the tool inspection path.

6. The method according to claim 5, wherein the one or more cutting teeth of the tool comprise a plurality of cutting teeth, and step (iii) comprises identifying minima and/or maxima associated with each tooth of the plurality of cutting teeth to separately assess the profile of each tooth.

7. The method according to claim 1, wherein the coordinate positioning apparatus is a machine tool.

8. A method for assessing a profile of a tool using a non-contact tool setting apparatus comprising a transmitter for emitting a light beam and a receiver for receiving the light beam, the receiver generating a beam intensity signal describing intensity of received light, the non-contact tool setting apparatus being mounted to a coordinate positioning apparatus that allows the tool to be moved relative to the non-contact tool setting apparatus, and the method comprising steps of: (i) using the coordinate positioning apparatus to move the tool relative to the non-contact tool setting apparatus along a tool inspection path comprising a start position on the tool and an end position on the tool, the start position and the end position being located at different positions along a longitudinal axis of the tool, and the movement of the tool relative to the non-contact tool setting apparatus causing the light beam to be scanned along the tool from the start position to the end position without the tool moving out of the light beam; (ii) collecting beam intensity data describing the beam intensity signal that is generated by the receiver as the tool inspection path of step (i) is traversed, the beam intensity data thereby being collected for a plurality of positions that are spaced apart along the edge of the tool between the start position and the end position; and (iii) analysing the beam intensity data collected in step (ii) to determine a profile of the edge of the tool between the start position and the end position.

9. The method according to claim 8, wherein the tool inspection path is pre-calculated prior to step (i).

10. The method according to claim 8, wherein step (iii) comprises comparing the beam intensity data collected in step (ii) with previously acquired beam intensity data.

11. The method according to claim 10, wherein the previously acquired beam intensity data comprises data collected from a previous measurement of the same tool or from a reference tool having the same nominal profile as the tool, and the analysis of step (iii) provides an indication of whether the tool profile has changed relative to the previous measurement.

12. The method according to claim 8, wherein the tool is held in a rotatable spindle of the coordinate positioning apparatus, the tool comprises one or more cutting teeth located around a radius of the tool, and the tool is rotated about the longitudinal axis of the tool while the tool is moved along the tool inspection path.

13. The method according to claim 12, wherein the one or more cutting teeth of the tool comprise a plurality of cutting teeth, and step (iii) comprises identifying minima and/or maxima associated with each tooth of the plurality of cutting teeth to separately assess the profile of each tooth.

14. The method according to claim 8, wherein the coordinate positioning apparatus is a machine tool.

15. A method for assessing a profile of a non-rotating tool using a non-contact tool setting apparatus comprising a transmitter for emitting a light beam and a receiver for receiving the light beam, the receiver generating a beam intensity signal describing intensity of received light, the non-contact tool setting apparatus being mounted to a coordinate positioning apparatus that allows the non-rotating tool to be translated along three mutually orthogonal linear axes relative to the non-contact tool setting apparatus, and the method comprising steps of: (i) using the coordinate positioning apparatus to translate the non-rotating tool relative to the non-contact tool setting apparatus along one or more of the three mutually orthogonal linear axes so that the light beam is moved along an edge of the non-rotating tool; (ii) collecting beam intensity data describing the beam intensity signal that is generated by the receiver while the light beam is moved along the edge of the non-rotating tool during step (i); and (iii) analysing the beam intensity data collected in step (ii) to determine a profile of the edge of the tool.

16. The method according to claim 15, wherein the tool inspection path is pre-calculated prior to step (i).

17. The method according to claim 15, wherein step (iii) comprises comparing the beam intensity data collected in step (ii) with previously acquired beam intensity data.

18. The method according to claim 17, wherein the previously acquired beam intensity data comprises data collected from a previous measurement of the same tool or from a reference tool having the same nominal profile as the tool, and the analysis of step (iii) provides an indication of whether the tool profile has changed relative to the previous measurement.

19. The method according to claim 15, wherein the coordinate positioning apparatus is a machine tool.

20. The method according to claim 15, wherein step (ii) comprises digitising the beam intensity signal to generate the beam intensity data, and step (iii) comprises using a digital signal processor to analyse the beam intensity data.

Description

[0028] The invention will now be described, by way of example only, with reference to the accompanying drawings, in which;

[0029] FIG. 1 shows a non-contact tool setting apparatus of the present invention,

[0030] FIG. 2 shows a cutting tool with a light beam moved along its periphery,

[0031] FIG. 3 shows the beam intensity data collected as the path shown in FIG. 2 is traversed,

[0032] FIG. 4 shows a multi-tooth cutting tool that is rotated whilst a light beam is moved along an inspection path along its periphery,

[0033] FIG. 5 shows the beam intensity data collected as the path shown in FIG. 4 is traversed,

[0034] FIG. 6 shows the intensity minima associated with the different teeth of the tool shown in FIG. 5 plotted as a function of the position along the inspection path,

[0035] FIG. 7 shows the intensity minima curve plotted against a previous measurement of the same tool,

[0036] FIG. 8 shows how a camera could be used to photograph any identified tool defects,

[0037] FIG. 9a illustrates a prior art tool inspection process, and

[0038] FIGS. 9b and 9c illustrate tool periphery scanning of the present invention.

[0039] Referring to FIG. 1, a tool setting apparatus of the present invention is illustrated. The apparatus comprises a transmitter 10 for generating a substantially collimated beam of light 12. The transmitter 10 includes a laser diode and suitable optics (not shown) for generating the collimated beam of light 12. A receiver 14 is also illustrated for receiving the beam of light 12. The receiver comprises a photodiode (not shown) for detecting the beam of light 12.

[0040] The transmitter 10 and receiver 14 are both affixed to a common base 20 by pillars 18. This arrangement ensures the transmitter 10 and receiver 14 maintain a fixed spacing and orientation relative to one another. The base 20 may then be mounted directly to the bed, or indeed any appropriate part, of a machine tool. It should also be noted that various alternative structures for mounting the transmitter and receiver could be used. For example, a common housing for the transmitter and receiver could be provided or discrete transmitter and receiver units could be separately mounted to the machine tool.

[0041] The apparatus also comprises an interface 15 connected to the transmitter 10 and receiver 14 via electrical cables 17. The interface 15 provides electrical power to the transmitter 10 and receiver 14 and also receives a beam intensity signal from the photodiode detector of the receiver 14. The interface 15 comprises an analogue to digital convertor (ADC) 18 that samples the analogue beam intensity signal generated by the receiver 14 and generates a stream of digital beam intensity values. This stream of digital beam intensity values, also termed beam intensity data, are passed to a digital signal processor (DSP) 20 for analysis. The results of the analysis may be passed to the machine tool 30 via link 28. In this example, the ADC 18 and DSP 20 are provided in the interface 15 but they could be included in any part of the system (e.g. in the receiver, machine tool controller etc). Thus far, the apparatus is analogous to that described in EP1587648.

[0042] Referring next to FIGS. 2 and 3, the tool profile assessment technique of the present invention will be described for a non-rotating tool. FIG. 2 illustrates a cutting tool 50 that comprises a cutting edge 52. The cutting tool has a nominal tool profile and is held by the moveable spindle of the machine tool (not shown). The location of the cutting tool and the location of the tool setting apparatus within the machine tool are known and the machine tool can be programmed to move the cutting tool 50 relative to the tool setting device.

[0043] In use, the machine tool is configured to move the tool so the light beam initially impinges on a first point 54 on the tool periphery. In this initial location, approximately fifty percent of the light beam is obscured. The tool is then moved so that the light beam traces the tool inspection path (as indicated by the pair of dashed lines 56) around the tool periphery until it reaches the second point 58. It can be seen that motion along the tool inspection path is substantially tangential to the tool periphery. During the movement of the beam along the tool inspection path 56, the beam intensity data generated by the ADC 18 of the tool setter device from the beam intensity signal is collected and stored.

[0044] Referring next to FIG. 3, the beam intensity data 60 is plotted as a function of the position P along the tool inspection path. If the machine tool moves the tool at a constant speed, then the relative position along the tool inspection path can simply be inferred from the time of acquisition of the beam intensity data. FIG. 3 also shows the nominal or predicted beam intensity data 62 that would be expected if a tool of nominal dimensions was moved along the same tool inspection path. The difference between the collected beam intensity data 60 and the predicted beam intensity data 62 provide a measure of how much the tool 50 deviates from its nominal size and shape.

[0045] Referring next to FIG. 4, a rotatable cutting tool 80 is illustrated that has four cutting teeth. It should be noted that the three teeth 82a, 82b and 82c are shown in solid outline whilst the fourth tooth 82d, which is located on the rear face of the tool shaft in the orientation illustrated in FIG. 4, is shown in dashed outline. The tool 80 is measured whilst it is being rotated about its longitudinal axis R by the machine tool spindle in which it is retained. The light beam is traced around the periphery of the tool along the tool inspection path. In particular, the tool inspection path extends around the periphery of the tool from the first point 84 to the second point 86. The spatial extent of the light beam as it traverses the path is illustrated by the dashed lines 88. During the movement of the beam along the tool inspection path, the beam intensity data generated by the ADC 18 of the tool setter device is collected and stored.

[0046] FIG. 5 illustrates some of the beam intensity data collected during inspection of the tool described with reference to FIG. 4. The beam intensity data is plotted as a function of the position P along the tool inspection path. Again, this position may be inferred from the time of data collection if the path is traversed at constant speed. The tool is rotating during the measurement and hence the beam intensity data includes minima that occur when each one of the four cutting teeth further occlude the beam. The series of minima are generated by each of the four teeth in turn as they rotate into the beam. The minima labelled a, b, c, and d in FIG. 5 thus correspond to the beam occlusion obtained when each of the four different cutting teeth 82a-d respectively occlude the beam. The minima may be identified by the DSP 20 using any of the techniques described in EP1587648. Furthermore, the DSP 20 can be configured to separate out the minimum values that are obtained from the different teeth of the cutting tool.

[0047] FIG. 6 shows the beam intensity at each identified minima, plotted as a function of position along the tool inspection path. In particular, curves 90a, 90b, 90c and 90d show the minima arising from the teeth 82a, 82b, 82c and 82d respectively. It should be noted that only a very small amount of the collected beam intensity data (i.e. data collected during three rotations of the tool) is shown in FIG. 5 and that the curves of FIG. 6 are generated from a large number of such minima. Curves 90a, 90b, 90c and 90d thus show the extent that each of the four different teeth 82a, 82b, 82c and 82d of the cutting tool occlude the light beam as the tool inspection path is traversed by the rotating tool.

[0048] The data plotted in FIG. 6 allows any chips or build-up of material on the teeth of the cutting tool to be identified. In particular, the peak 92 in curve 90d shows there is a chip in the tooth 82d of the tool; this peak 92 results from the intensity of the minima associated with tooth 82d increasing due to the chip allowing more light to pass to the receiver. Similarly, the trough 94 in curve 90c shows a build-up of excess material on the tooth 82c; this trough 94 results from the intensity of the minima associated with tooth 82c decreasing further due to the excess material blocking more light. Furthermore, the location of the defect (e.g. the chip or excess material) on each tooth can be determined from the position P of the peak and/or trough along the tool inspection path.

[0049] The minima shown in FIG. 6 will alone allow the presence and position of defects to be determined. As shown in FIG. 7, it is also possible to compare a plot of minima values measured for a certain tool to previously acquired minima data for that tool. In particular, the process of determining the intensity of certain identified minima as a function of position along the tool inspection path can be repeated multiple times. For example, such minima data may be collected from a tool prior to use of that tool for cutting purposes. A reference curve 100 can thus be obtained that provides information on the profile of the unused tool. After the tool has been used for a cutting operation, the measurement process can be repeated using the same tool inspection path. A minima value curve 102 can then be generated and compared to the reference curve 100. Any differences between the curve indicates wear of the cutting surface and any chips or build-up of material can also be identified from the differences between the curve 102 and the reference curve 100. A difference plot (i.e. curve 100 minus curve 102 or vice versa) may be used to provide a visual indication of any differences that are present.

[0050] Referring to FIG. 8, the addition of a camera for visually inspecting a tool is described. In particular, FIG. 8 shows a tool setting apparatus 150 of the type described above that emits a light beam 152 and is mounted to the bed 160 of a machine tool. The tool setting apparatus 150 is arranged to inspect a tool 170 held by a spindle 172 of the machine tool when that tool is located in the region 174 of the light beam 152. As described above, the tool setting apparatus 150 allows defects 188 in the tool 170 to be identified and in particular it permits the position of such defects on a tool to be determined. In addition to the tool setting apparatus 150, a front lit camera system 180 is also provided. The camera system emits a white light beam 182 and can take images of any objects located within its field of view 184. The location of the field of view 184 is known relative to the tool setting apparatus 150; i.e. they are separated by the positional difference V.

[0051] In use, the tool setting apparatus 150 is used to identify defects 188 on the tool 170. The positions of the tool setting apparatus 150, the camera's field of view 184 and the tool 170 are all known in the coordinate system of the machine tool. This means that the machine tool can move the spindle 172 so that the defect 188 on the tool 170 that has been identified by the tool setting apparatus 150 can be placed in the field of view 184 of the camera system 180. This allows an image of the tool defect to be captured, which in turn can allow an operator to assess the nature of the detected defect. Although the tool setting apparatus 150 is preferably of the type described above, it could comprise any tool setting apparatus.

[0052] For completeness, a detailed comparison of prior art tool setting techniques to the technique of the present invention will be given with reference to FIGS. 9a-9c

[0053] Referring to FIG. 9a, a prior art tool measurement process is illustrated. As explained in the introduction above, the light beam of a prior art non-contact tool setter is moved towards a tool 202 from an initial position 204 spaced apart from the tool 202. In practise, the light beam is usually stationary and the tool is moved into the beam, but the same relative motion occurs as if the light beam was being moved. The light beam thus moves along a path that is substantially perpendicular to the edge of the tool 202 to be measured. In FIG. 9a, the light beam is initially at a start position 204. At the point 206 when the tool 202 obscures 50% of the light beam, a trigger signal is issued by the non-contact tool setter. The machine tool receives the trigger signal and records the position at which the trigger event occurred. This allows the position of a single point 208 on the surface of the tool 202 to be determined. This process may be repeated to measure multiple points on the tool edge.

[0054] FIG. 9b show a tool measurement process according to the present invention. As described above, the light beam is directed to a start position 222 on the edge of the tool. In this example, a tool of nominal dimensions will obscure approximately fifty percent of the light beam. The light beam is then traced along the peripheral edge of the tool from the start position 222 to an end position 224 (the path followed by the light beam is the so-called tool inspection path). At multiple points 226 along the tool inspection path, beam intensity data are collected. The tool inspection path may be traced in a continuous motion (e.g. at constant speed) or the speed may be varied as the path is traversed. It is also possible to dwell at each of the points 226 (i.e. momentarily halt the motion of the light beam relative to the tool) and to optionally perform an averaging procedure at each point (e.g. to improve the signal-to-noise ratio of the beam intensity data and/or to obtain a more accurate measurement of the position of the tool relative to the non-contact tool setter).

[0055] For a perfect tool (i.e. a tool that corresponds exactly to the nominal tool profile) there will be (in this example) fifty percent of the light beam obscured at each point along the tool inspection path. For an actual tool (which may have become worn or experienced material build-up during a machining operation) any local deviations in the tool edge position will result in the amount of the light beam that is obscured being different to the fifty percent level expected for a nominal tool. In other words, deviations in the beam intensity data from the expected fifty percent at each of the points 226 indicates the tool is larger (obscuring more of the light beam) or smaller (obscuring less of the light beam) than expected. The beam intensity data are combined with information from the machine tool describing the position of the light beam 220 at each point 226 to provide multiple measurements of the surface position of the tool. In this manner, multiple points 226 can be measured in a rapid scanning-type action without a need to move the tool back-and-forth into the beam as per the prior art technique illustrated in FIG. 9a.

[0056] Referring to FIG. 9c, it is noted that the tool inspection path may comprise multiple traverses along the peripheral edge of the tool. This may be done, for example, if the uncertainly in the nominal location of the tool edge is significantly greater than the width of the light beam.

[0057] FIG. 9c shows a tool inspection path in which a light beam is moved linearly downwards from an initial position 250 to a first position 252. The light beam is then stepped sideways to a second position 254 before being moved linearly upwards to the third position 256. It is then stepped sideways to a fourth position 258 before being moved linearly downwards to an end position 260. Although the linear move between the second position 254 and third position 256 alone is sufficient to measure the edge of a tool 264 in a nominal location, it would not be able to measure a tool shifted from that nominal location by more than the beam width (e.g. to the tool position indicated by the dashed outline tool 266). Providing multiple passes will, however, enable any such larger deviations in position (or tool size) to be measured. For example, beam intensity data collected when the light beam moves from the fourth position 258 to the end position 260 would be able to measure the edge of the dashed outline tool 266. It would, of course, also be possible to use beam intensity data from different traverses of the light beam if, for example, the tool was angled so different areas of the tool edge were present in different traverses of the light beam. As an alternative to such a multi-pass technique, the width of the light beam could be increased.

[0058] The skilled person would appreciate that variations to the above embodiments are possible. For example, the method could be implemented using non-contact tool setting apparatus mounted on any co-ordinate positioning apparatus (e.g. a CMM, robot, off-line tool inspection system etc) and not just a machine tool.