DE3538551C1 - Auxiliary reference device for, in particular, three-dimensional measurement and/or marking apparatuses - Google Patents

Abstract

An auxiliary reference device is proposed for three-dimensional measurement and/or marking apparatuses, in whose tool holder various probe tools can be held replaceably in various positions within a three-axis coordinate system. The auxiliary reference device has a cube which has probe surfaces (which are aligned in the direction of the three spatial axes) on all six cube surfaces. All the cube edges are chamfered at the same angle to form oblique edge probe surfaces. The residual surfaces running inside the cube surfaces are connected to the oblique edge probe surfaces to form central probe surfaces. The chamfer angle is 45 DEG . An auxiliary reference point which is produced as the intersection of the longitudinal centre lines of the oblique edge probe surfaces running in the direction of all the spatial axes, is used for contact-free probing. In the case of probing where contact is made, this reference point consists of the cube corner. As a result of exact geometrical relationships between these reference points, a contact-free probe can be replaced by a contact-making probe, and vice versa, without any complicated recalculation processes or a computer, while a workpiece is being measured.

Description

Auxiliary reference devices of this type (DE-OS 28 50 517) are an important one Help with working with 3-dimensional measuring and / or scribing devices, e.g. B. the type, as described in DE-PS 1773282 and 1798419, to the explanation here Express reference is made to these devices, especially those with computer assistance work. Before probing and measuring a workpiece by probing z. B. by means of a touching probing tool, e.g. B. with a ball switch, which is in the tool holder in a predetermined position, e.g. Am to the Table top perpendicular direction, is added, the device must first be zeroed will. This is done when possible and accessible, e.g. B. using a workpiece-related Measuring point, z. B. a corner in the direction of all three spatial axes with each constant restraint and position z. B. the ball stylus is touched. at every probing in the direction of a spatial axis becomes the resulting one that deviates from zero The measured value is either held or the device is in this measuring position set to zero.

When probing and measuring other measuring points on the same workpiece later The result is the relative measured value per spatial axis, based on the workpiece-related one Measuring point when zeroing, from the difference between this measured value and that measured when zeroing Value or zero.

Depending on the nature of the workpiece, the necessary sequence of measuring points and others Parameters, it is necessary during the measuring process to use the probing tool as described To replace zeroing with an identical or a different one or in a different one to bring spatial position, e.g. B. to implement in the tool holder, with in all cases there are deviations from the initial zero setting. Even if you use a new, completely identical probe tool to replace it and this is used in the tool holder in the same spatial position becomes like the original probing tool, that is all that is needed to insert it and changing the necessary play between the tool holder and the probing tool is the cause for deviations and measurement inaccuracies, unless zeroed again before the start of the measurement will. Obviously larger deviations arise, of course, when the The spatial position of the probing tool or the type and function of the probing tool change, e.g. B. by moving the probing tool from the vertical to a horizontal one Position, in an angular position or the like. To result in measurement inaccuracies itself to exclude a smaller extent, must therefore after each change of the probing tool, be it when exchanging, be it when changing its spatial position, the device before the start of the measurement be zeroed again.

Often there are now difficulties, this zeroing always on one to undertake workpiece-related measuring point, e.g. B. because the workpiece itself does not have any has predestined measuring points or such measuring points in the new spatial position of the Probing tool are no longer accessible or the shape of the probing tool or the mode of operation of this probing of this workpiece-related measuring point is impossible power or other reasons.

Here creates an auxiliary reference device of the type mentioned Remedy, which as a separate reference element to create a reference point z. B.

arranged on the table top and touched each time before measuring will. The use of such auxiliary reference devices leads to a considerable increase the measurement accuracy. Known auxiliary reference devices have as an element to be touched z. B. a ball or a cube, the dimensions of which are known and accordingly be taken into account when zeroing. A cube with six faces cut each into sharp cube edges, enables touching by means of touching working probing tools, the respective reference point being the respective cube corner which is formed by the intersection of three in the direction of the three spatial axes Results in cube areas. A contactless probing, however, for example by means of a probing tool that works with a light beam fails with one such a cube, because here only one probing in one axial direction of the 3-axis coordinate system is possible, namely in the direction perpendicular to the cube surface, but not in the direction of the other two coordinate axes.

The invention is based on the object of an auxiliary reference device of the type mentioned to create the one as a single reference element Probing with both touching and non-contact probing tools and enables this to be done easily and quickly without the need for complicated conversion processes or a special computer.

In the case of an auxiliary reference device, the task is the one mentioned at the beginning Kind according to the invention solved by the features in the characterizing part of the claim 1.

A reference device designed in this way makes a probe both with contact working probing tools as well as with contactless, z. B. by means of Light beam working, probing tools possible.

Reference line is used for probing with non-contact probing tools when probing any longitudinal line of the inclined edge probe surface, in particular z. B. their longitudinal center line. The incline of this edge contact surface results in there is a surface on which the light beam can still work, especially then, if such a contactless probing tool inclined surfaces still up to up to an angle of inclination of 70 ". The incline of the edge contact surfaces thus enables this probing by means of a non-contact probing tool. Since the relative distance of a longitudinal line of the inclined contact surface, in particular knows exactly the longitudinal center line of this, from other reference points than fixed values, can do this right at the transition from a touching probing tool are taken into account and entered on a contactless probing tool, without the need for a special computer or complicated conversion processes requirement. The auxiliary reference device according to the invention does so without any problems possible, when working with a non-contact probing tool, a first, original To create a starting point from which to start. Equally is no problem a change of the probing tool is possible, namely a change of a contactless one to another probing tool that also works without contact, as well as a change one touching tool to another, also touching tool and above all a change from a touching probing tool a contactless probing tool as well as vice versa. Implementing the Probing tool from one axis direction to the other is possible without problems, also a change of the probing tools. With everything is the auxiliary reference device extremely simple, inexpensive and cheap.

An advantageous embodiment results from claim 2. Hereafter is in one case a part of the table top itself mentioned as an auxiliary reference device Art designed, which is hereby also to be regarded as the originator. In the other case is an auxiliary body of this type, the z. B. can also be a model plate the z. B.

starting from an unprocessed raw material through processing after and after a model is created, attached to the table top, which serves as a starting point of reference is used for the values within the 3-axis coordinate system. as Auxiliary bodies of different geometrical shapes can be used, which have at least one inclined edge contact surface. Before starting the probing or measurement are the individual existing inclined contact surfaces and horizontally and / or vertically extending residual surfaces are touched.

Another, particularly advantageous embodiment results from Claim 3 and also from Claim 4.

For probing with non-contact probing tools, the intersection z. B.

three longitudinal center lines running in the direction of the three coordinate axes of the inclined edge contact surfaces are used, with this reference point at a symmetrical cube is the same for all eight corner areas of the cube and each has the same dimensions, based on the cube surfaces. All six Here, cube surfaces can be touched as well as non-contact.

The bevel angle of the inclined edge contact surfaces is fundamental Any, as there is a geometric relationship between the reference points for every angle size can be produced for contact probing and for non-contact probing. One advantageous embodiment results from claim 5. A 45 "angle has the advantage that particularly simple values can result for the geometric relationship, one chooses the edge dimensions of the cube accordingly.

Further advantageous refinements emerge from the claims 6-14.

As shown, auxiliary bodies are of the most varied geometrical shapes can be used for contactless probing with at least one inclined edge probe surface are provided with basically any bevel angle. The auxiliary bodies can be attached as a source of origin to a model plate that carries the model, as well as aligned by means of a foot, but detachably attached to a table top will. Such auxiliary bodies not only create reference values for the implementation of Probing tools, but also origin values for the very first origin when starting the measurement. So much for the dimensions up to another virtual reference point of the geometrical any auxiliary body are known, what z. B. with a symmetrical cube the edge length is given, one can also choose a reference point as with a cube z. B. its center. A more precise reference point is advantageous the cube.

Even if the inclined contact surfaces are essentially for non-contact Probing tools are provided, but in one case or the other there is also one Touching this is possible using a probe tip.

Further details and advantages result from the following Description.

The full wording of the claims is only for Avoidance of unnecessary repetitions are not reproduced, but only instead by naming the claim number it is referred to, whereby however all these Claim features as expressly disclosed at this point and essential to the invention have to apply.

The invention is shown below with reference to one in the drawings Embodiment explained in more detail. It shows F i g. 1 is a schematic, perspective View of only the cube of an auxiliary reference device, FIG. 2 a schematic vertical section of the auxiliary reference device aligned on a table top.

The in F i g. Auxiliary reference device 10 shown in FIGS. 1 and 2 is particularly intended for 3-dimensional measuring and / or scribing devices, e.g. B. those according to DE-PS 17 73 282, and in particular for NC or CNC devices of this type. In the tool holder these devices are different types of probing tools in different positions exchangeable within a three-axis coordinate system. As probing tools come into question those who make a touching probing, z. B. Ball stylus, Prism probes, disc probes, conical probes or the like, as well as such probing tools, which work by means of a light beam and consequently without contact. Such Contactless probing tools have in comparison to the contact probing tools following advantages. Probing is easier, faster and safer. It must no attention is paid to contact with the workpiece. The risk of accidents that otherwise by z. B. probe tips is given is reduced. There are also deformations the probing tool and / or the workpiece excluded. It can also be soft and sensitive materials such as clay, wood, plaster of paris, plasticine, plastic, Touch foam parts, painted surfaces, etc. The need to stretch of the workpiece, in order to absorb the reaction forces when touching it, is omitted. This creates tension, especially in the case of very thin-walled sheet metal or plastic parts avoided. The otherwise with a probe ball of a touching working probing tool No correction is required because the light beam from a non-contact probing tool acts like a probe tip. This is particularly useful for surfaces with multiple inclines noticeable, for which a stylus ball correction would otherwise lead to greater inaccuracies can. It is also advantageous that inclined surfaces up to an angle of inclination from Z. B. about 70 "can still be touched, making the probing tool less often has to be implemented.

Since a visible light beam acts when probing, the probing process can be carried out closely follow through the visible point of light. Because mechanical wear parts omitted, such a contactless button is maintenance-free. He builds compact and small and light in weight. In the absence of mechanically moving parts, a Such buttons have a relatively high long-term stable and short-term stable button accuracy.

The auxiliary reference device 10 has a cube 11 which, for. B. is massive. The cube 11 consists in particular of ceramic material. He's on the top Attached to the end of a column 12 by means of a schematically indicated foot 13 is placed on a table top 14 and fixed there. The attachment takes place z. B. by means of indicated screws 15 and / or by means not shown further Magnets or the like. The foot 13 is aligned on the table top 14 so that the individual cube edges in the direction of the three coordinates X, Y and Z of the three-axis Coordinate system run.

This is ensured by the fact that parallel strips arranged on the foot 13 16, 17 engage in associated grooves 18 and 19 of the table top 14 in a form-fitting manner can, so that the foot 13 and with this the cube 11 around the axis of the column 12 is fixed in a fixed predetermined orientation.

The cube 11 carries on all six cube faces, of which in F i g. 1 and 2 only the two cube surfaces running within the X-Y plane 20, 21, furthermore the cube surfaces 22,24 and extending in the direction of the Z-Y plane the cube surface 23 running in the direction of the Z-X plane can be seen, respectively Probe surfaces in the direction of the three spatial axes X, Y and Z of the three-axis coordinate system are aligned and using probing tools, both touching and non-contact, are touchable.

The specialty is that all twelve edges of the cube 11 are beveled at the same angle a, forming more oblique there Edge contact surfaces, of which in FIG. 1 and 2 the inclined edge contact surfaces 25-35 you can see.

Close to these inclined edge contact surfaces 25-35 formed in this way The remaining areas within the six cube areas become the center contact areas 36-40 on.

The bevel angle of the edge contact surfaces 25-35 is 45 " Projection of the inclined edge contact surfaces 25-35 into the plane of the adjacent ones Center touch surfaces are each z. B. one fifth of the edge dimension of the cube 11. The edge dimension of the cube 11 is indicated in Fig.2 with b, the one mentioned above Projection of the inclined edge contact surface with 2a. Is the edge dimension of the cube 11 z.

what is advantageous, 50 mm, is what the projection of the inclined edge contact surfaces has a dimension of 10 mm in each case in the plane of the adjacent center contact surfaces. This Projection dimension 2a is the same within each cube area, as is half a of this projection dimension 2a, which is based on the in F i g. 1 longitudinal center line indicated by dashed lines 41-46 of the respective inclined edge contact surface 25-28 or 31 or 32 runs. As As can be seen, the longitudinal center lines 43, 41 and 45, which extend in the direction the coordinate axes X, Y and Z of the spatial coordinate system run in Point of intersection 47. The longitudinal center lines 43, 42 and 42 intersect in the same way 46 at the point of intersection 48 and the longitudinal center lines 44, 42 at the point of intersection 49, in which also the longitudinal center line, not shown, of the inclined edge contact surface 35 intersects the other longitudinal center lines 42,44.

All inclined edge contact surfaces 25-35 and all within the remaining center contact surfaces 36-40 running on the cube surfaces have a matt surface through which the light beam of a non-contact Probe tool is still well spread.

The auxiliary reference device 10 is equally suitable for the touching Probing as well as contactless probing. In the case of touching probing Without exception, the center contact surfaces 36-40, the ones within the cube surfaces run away, used. Should in the course of a measuring process with an inserted, touching working probing tool are worked, then a zeroing of the measuring and Scribing device necessary. For this purpose, before starting the measurement of the cube 11 probed with the probing tool. To secure the value in the Z direction, move the 3-dimensional measuring and scribing device in such a way that the probing tool approaches the X-Y plane from above in the direction of the Z-axis and touches it touches. The resulting value is recorded as a reference value. Then will If the device is clamped in the Z direction, move it in the direction of the Y axis, the probing tool the The Z-X plane of the cube 11 is scanned in a touching manner. Which the resulting value for this is also recorded. In the same way is used to determine of the value in the direction of the X-axis, the Z-Y plane of the cube 11 is scanned touching. It is therefore proceeded in the same way as with known reference cubes and as described in DE-OS 28 50 517, with this touching probing the reference point is the corner of the cube in which the cube faces 20, 23 and 24, if you extend them beyond the inclined edge contact surfaces, they hit. It deals in this case around the cube corner, which is in this case with not beveled cube edges Area would exist.

Should, however, work with a non-contact probing tool that works with a light beam, the intersection points 47-49 are used here and all other corresponding intersection points not visible in the drawings as corner reference points. First of all, the three-dimensional measuring and scribing device is used the center contact surface 36 is touched in the direction of the Z-axis. This is in FIG. 2 indicated by the arrow Z drawn in with solid lines. The touch in the Z-direction prepares with the non-contact probing tool by means of Light beam no trouble. Should then the probing in the direction of the X-axis take place, is used for this purpose on the inclined edge contact surface 25, the one Scattering of the light beam due to its inclination makes this possible Move the device so that the light beam in FIG. 2 outside the area of the center probe surface 36, preferably outside the cube 11, runs. Then the previously touched Z coordinate value an amount of size a is delivered, d. H. the device towards move the Z-axis downwards by the amount a. Hereafter, the device is with regard to the mobility in the direction of the Z-axis is fixed, where the coordinate value Z + a is recorded because it is the Z coordinate value for the now used as a reference point Forms intersection 47 (Fig. 1). Then the device is so far in the direction of the X-axis move until the light beam of the contactless probing tool is like this stands, as in FIG. 2 is indicated by dashed lines. The light beam hits here on the longitudinal center line 41 of the inclined edge contact surface 25, where precisely then, when the light beam is at this height, the probing tool emits a signal gives. The value determined in the X direction is then recorded. In the same way the value for the Y-axis is determined by moving the device in the Y-direction against the inclined edge contact surface 27 is moved up.

If the light beam is at the level of the longitudinal center line 43, a signal generated by the probing tool.

The Y value is then recorded.

The contactless probing tool does not cause any problems starting from the position described, with the probing tool in the Z direction runs to implement, e.g. B. so that it is now perpendicular to the Z-Y plane. this takes place on the device side by loosening in the direction of the Z-axis and repositioning the probing tool into an alignment in the direction of the X-axis. Then the machine-side counter for the X-axis using the "Preset" key on the X coordinate value before relocating of the probing tool plus value a + half the cube edge length preset and then the center touch surface 40 is touched.

The result is the value in the direction of the X-axis that is recorded will. Then, analogously to the method described, the device is moved so far that the probing tool stands outside the cube area.

After this, the value a becomes negative for the touched X coordinate value Coordinate direction delivered and the device then fixed in the direction of the X-axis.

Then the device-side counter for the Z-axis is set to the previously recorded Z-coordinate value that resulted before moving the touch tool, preset and now the inclined contact surface 26 from above in the direction of the Z-axis approached. Then the counter for the Y-axis is set to the one before Implementation of the probing tool, the Y coordinate value determined is preset and then the inclined edge contact surface 32 is touched in the direction of the Y-axis. Go out of it the following advantages of this auxiliary reference device emerge. It's one with no problems Change of the probing tool possible, namely a change of a contactless one Probing tool on a likewise non-contacting probing tool, as well a change from a touching probing tool to another one, too Touching probing tool and, above all, a change from one touching one working probing tool on a contactless working probing tool such as also vice versa. This is possible because of the exact geometric relationships between the the reference points used for this purpose exist. When probing by means of touching working probing tools, these reference points consist of the extension of the center contact surfaces 36-40 resulting cube corners, without taking into account the Bevel.

With contactless probing, the reference points consist of the Intersections of the longitudinal center lines of the inclined edge contact surfaces, e.g. B. from the Intersection points 47-49 visible in FIG. 2. It is also of particular advantage that In the case of contactless probing, the probing tool can be relocated, without the need for a computer, as without the need at all complicated conversion processes.

Claims (14)

Claims: 1. Auxiliary reference device, especially for three-dimensional ones Measuring and / or scribing devices with various probing tools in their tool holders exchangeable in different positions within a 3-axis coordinate system can be accommodated, which carries probing surfaces that can be probed by means of probing tools, characterized in that each is at right angles to each other through at least two running contact surfaces formed edge is beveled to form a sloping one Edge contact surface (25-35) and that this inclined edge contact surface (25-35) connect the remaining surfaces as center contact surfaces (36-40). 2. Auxiliary reference device according to claim 1, characterized in that that the at least one inclined edge contact surface (25-35) and the remaining surfaces immediately on a tabletop (14) receiving the measuring and / or scribing device, in particular at the edge, on a plate-side nose, a plate-side projection od. Like., Or are provided on an auxiliary body, which in turn on the table top (14) can be fastened. 3. Auxiliary reference device according to claim 2, characterized in that that the auxiliary body at least three in the direction of the three spatial axes (X, K Z) of the Spatial coordinate system aligned center probe surfaces (36-40) and on this carries adjacent inclined edge contact surfaces (25-35). 4. Auxiliary reference device according to one of claims 1-3, characterized in that that the auxiliary body is designed as a cube (11) on all six cube faces (20-24) aligned in the direction of the three spatial axes of the 3-axis coordinate system Carrying contact surfaces in which some or all of the cube edges are preferably below are beveled at the same angle (ear) to form sloping edge contact surfaces there (25-35), to which those within the six cube faces (20-24) extend Connect remaining surfaces as center contact surfaces (36-40). 5. Auxiliary reference device according to one of claims 1-4, characterized in that that the bevel angle (ux) of the inclined edge contact surfaces (25-35) each 45 " amounts to. 6. Auxiliary reference device according to one of claims 1-5, characterized in that that the longitudinal center lines (41-46) of three each in the direction of the axes of the 3-axis Coordinate system running, beveled at the same angle (ear) Edge contact surfaces (25-35) intersect at a corner-sided intersection (47-49), the one reference point for probing by means of a contactless, in particular forms by means of a light beam, probing probing tool 7. Auxiliary reference device according to one of claims 1-6, characterized in that three in each direction Center probe surfaces (36-40) running along the axes of the 3-axis coordinate system, extended beyond its areal extension in a virtual reference point cut that corresponds to the cube corner of a non-beveled cube and one Reference point for probing by means of a contact or non-contact one Forms probing tool. 8. Auxiliary reference device according to claims 6 and 7, characterized in that that the intersection (47-49) of the longitudinal center lines (41-46) of the inclined edge contact surfaces (25-35) from the respectively assigned point of intersection of the cube surfaces (20-24) an in the same distance in all three axis directions of the 3-axis coordinate system Üa has, which is fixed and known as a computational variable. 9. Auxiliary reference device according to claim 8, characterized in that that the distance everywhere is half of the projection of the inclined edge contact surfaces (25-35) in the planes of the adjacent center probe surfaces (36-40) 10. Auxiliary cover device according to one of claims 4-9, characterized in that the projection of the inclined edge contact surfaces (25-35) into the plane of the adjacent ones Center contact surfaces (36-40) each one fifth of the edge dimension of the cube (11) amounts to 11. Auxiliary reference device according to one of claims 4-l0, characterized in that that the projection of the inclined edge contact surfaces (25-35) in the plane of the adjacent Center contact surfaces (36-40) each 10 mm with an edge dimension of the cube (11) of 50 mm. 12. Auxiliary cover device according to one of claims 6-11, characterized characterized in that the cube corner in all three axial directions of the spatial coordinate system the same distance from the center of the cube, corresponding to half the length of the edge (11) has that the intersection (47-49) of the longitudinal center lines (41-46) of the inclined Edge contact surfaces (25-35) are the same in all three axial directions, half of them Edge length minus the distance (a) corresponding distance from the center of the Cube (11) and that the center of the cube is the reference point for the probing tool forms. 13. Auxiliary reference device according to one of claims 1 - 12, characterized characterized in that the inclined edge contact surfaces (25-35) and the center contact surfaces (36-40) have a matt surface. 14. Auxiliary cover device according to one of claims 2-13, characterized characterized in that the auxiliary body is formed from ceramic material. The invention relates to an auxiliary reference device for in particular 3-dimensional measuring and / or scribing devices, in their tool holder various Probing tools in different positions within a 3-axis coordinate system The probing surfaces that can be touched by means of probing tools can be exchanged wearing.