DE3024560A1 - Standard for multiple coordinate measuring device accuracy testing - has different geometrical bodies defining points on measurement planes - Google Patents

Abstract

A test standard for use in summary accuracy testing of multiple coordinate measurement equipment has several measurement points accurately positioned and distributed in a measurement point plane. It enables reliable evidence to be obtained regarding the measurement accuracy whilst exercising the equipment in at least three degrees of freedom. The test standard (1') has at least two different measurement point planes (6',7',8) inclined w.r.t. each other and fixed in position w.r.t. each other. The planes can be mutually perpendicular and each corresp. to a spatial direction. Different measurement points are defined within the measurement planes by bodies of different geometrical structure (12 to 16) mounted on or inset into the walls forming the planes. Measurement points in any plane differ in distance from a reference level associated with that plane.

Description

Test standard for the summary accuracy test

of multi-coordinate measuring devices The invention relates to a test standard for the summary accuracy test of multi-coordinate measuring devices according to the generic term of claim 1.

To the best of the applicant's knowledge, they have so far only been essentially two-dimensional Test standards known; that is, they contain only a single measuring point plane. With such a test standard only accuracy statements can be made when measuring under Utilization of only two coordinates of a measuring device can be obtained. The practice shows, however, that the measuring accuracy of a multi-coordinate measuring device is insufficient can be assessed, even if you have a Checking repeated in different room levels. It always remains one of the three measurement coordinates unused and a possible error within this one coordinate is not taken into account in the accuracy check.

It is due to the oblique arrangement of a level test standard possible on the measuring table, all three movement possibilities of the measuring device at the same time to be included in the review. The disadvantage of this procedure is, however, that with an oblique arrangement the exact absolute position of the individual measuring points is unknown; only their relative position to one another is known. Even if so the measurement of such an inclined test standard is the mutual Would confirm the relative position of the measuring points with sufficient accuracy, so could nevertheless there may still be an absolute error in the measurement that would remain undetected.

The object of the invention is to create a test standard which reliable and practical statements about the measuring accuracy during the simultaneous Interaction or use of at least three possible movements of a multi-coordinate measuring device supplies.

According to the invention, this object is achieved by the characterizing features solved by claim 1. Thanks to the mutually angled and immovable arrangement of at least two different measuring point levels within a test standard on the one hand, a three-dimensionally extending test standard is achieved; thanks to the arrangement of the individual measuring points in measuring point planes is still an essential one extremely precise original measurement of the test standard possible. The actual location of each Measurement points must be known more precisely by at least one order of magnitude than the measurement accuracy the most accurate to be checked with the test standard Measuring machine. However, as far as the applicant is aware, such exact original measurements can be made with today's Possibilities and with justifiable effort only undertake within one level; the third spatial coordinate transverse to this plane can only be used in the area less Millimeters can also be recorded so precisely. Only to determine the exact mutual relative position of the different measuring point planes must be an increased metrological Effort for the original measurement are driven. However, all of the measuring points are then located and measuring surfaces of the spatial test standard in their position within one of the test standard assigned reference system exactly. By arranging different measuring point levels A cube-shaped or cuboid-shaped test standard also provides a better reference to the practical measurement tasks made; there it is mostly about them as well Determination of drilling patterns that are located in spatially different planes of a spatially extending object are arranged.

Further useful configurations of the test standard as well as others Advantages can be found in the subclaims and the following description of two in the drawings illustrated embodiments are taken; show: 1 shows a first embodiment of a spatial test standard made of cast material, 2 shows a further embodiment example arranged at an angle on a measuring table a spatial test standard made of hard rock and Figures 3 - 6 four various embodiments for attachable to the wall of the test standard or precisely manufactured geometrical bodies which can be introduced into them and which represent the individual measuring points represent.

In Fig. 1, a section of a multi-coordinate measuring device 5 is indicated with a measuring table 2, which receives the test standard 1, and one perpendicular to the measuring table up and down as well as parallel to the measuring table level movable measuring quill 3, the one Probe 4 carries. The exemplary embodiment of a test standard shown in FIG. 1 is placed on the table parallel to the coordinates of the measuring device. It has only two measuring point planes 6 and 7 at right angles to one another, of which one (6) is parallel to the table plane. Each measuring point level has several measuring point locations 9, which by a precisely machined bore / cone insert shown in more detail in FIG 12 are formed. These insert bodies are in the wall 23 of the test standard in shrunk in severely hypothermic condition and then particularly precisely to the finished size sanded. It has a bore surface 19 as well as one lying coaxially with it outwardly facing conical surface 18, the outwardly by an exactly right angle to the axis 24 of the bore or the cone lying end face 17 is limited. Of the Intersection of the bore or. The cone axis 24 with the plane of the end face 17 is there a measuring point 11 before. Since the bore / cone inserts 12 can be touched in a particularly versatile manner are, in the embodiment of FIG. 1 is only a single type of measuring point locations 9, namely exclusively hole / cone inserts provided. the Thickness of the collar of the bore / cone insert protruding from the wall 23 can deliberately be chosen to be different in strength, as shown in FIG. 3 by different Line styles is indicated. This results in a certain variation in the position of the measuring points 11 at the various measuring point locations in relation to one, for example one of the measuring point locations predetermined reference level 31 of the relevant measuring point plane conditions.

The conical surface 18 is designed to be relatively long in the axial direction (24), so that with a perfectly possible wobble of the cone axis relative to the cylinder axis or with respect to the exact perpendicular direction on the reference plane 31 through the conical surface 18 a certain measuring surface is given, the exact shape and location of a Multiple probing can be determined. This is the multi-coordinate measuring device to be checked posed a particularly hard task, since they have the relatively small shape or. Positional deviations must recognize.

Except for the measuring point locations 9 are within each measuring point level still rulers 1o provided with a precisely machined surface that can be touched run parallel to the measuring point plane, for example within the reference level 31. These rulers, which in the embodiment of FIG. 1 T-shaped within a Measuring point level are arranged to each other, serve on the one hand to the test standard to be aligned on the measuring table in a certain way or

to precisely determine its current position on the measuring table. For this purpose, certain contact points are particularly highlighted on the rulers. About that also serve the But rulers also serve the purpose of a large essentially to pretend evenly extending measuring surface, their albeit very small, however unavoidable form deviations from the exact planar form - these form deviations are also known for each individual test standard and for each individual ruler - a measuring device to be checked also as a particularly difficult recognition task can be asked.

The test standard according to FIG. 1 is - as I said - made of cast material and designed as a hollow body. Artificial aging ensures that the material is particularly stress-free, so that due to storage or temperature fluctuations no or only negligible changes in shape occur on the test standard. By a good ribbing and outer reinforcement is also essential for structural stability Paths taken care of. The surfaces of the substantially opposite the measuring point planes cuboid-shaped test standards are provided with large-area recesses 29, so that measuring points and measuring surfaces are also arranged inside the test standard can. These measuring points or areas are only available with wide side buttons accessible; such a task is also presented frequently enough in practice, so that a practical accuracy check is also possible through such a configuration is possible with the test standard.

The further exemplary embodiment of a test standard shown in FIG. 2 1 'has three measuring point planes 6', 7 'and 8, all three of which are at right angles to one another stand and the different spatial directions or coordinate planes correspond. In this exemplary embodiment, the measuring point locations 9 'are within a measuring point plane designed differently. The rulers 10 'are arranged on the edges of the test standard and are arranged in an L- or U-shape to one another within a measuring point plane. on Three ball feet 28 are arranged on the underside of the test standard. By the number by three ball feet it is ensured that in each case a clear and blur-free The test standard is set up on a base. The design of the Feet as ball feet makes it possible by using differently sized bases 30 under each foot an oblique arrangement of the test standard on the measuring table to pretend. When using very precisely machined base pieces 30 can the inclination of the test standard can be precisely specified by these dimensions, so that the actual position of the individual measuring points in space is therefore precisely known.

Except bore / cone inserts 12 are at the measuring point locations Measuring points also given by other attachments in the test standard 1 '. the Fig. 4 shows enlarged a ball attachment 13, in which the measuring point 11 by the The center of the touchable spherical surface 22 is given. This one has recognizable a clear distance from the reference level 31 of the corresponding measuring point plane.

Furthermore, at the individual measuring point levels of the test standard 1 Cube attachments 16 immovably firmly attached, the edges of which are parallel to the rulers 10 lie.

The measuring point that is assigned to these measuring points can either be defined by the center point of a flat side of the cube or by the Center of the whole cube itself. The cube itself can also be used as a measuring surface serve, with which the measuring machine to be checked is given the task of any Detect deviations in shape of the cube attachment from the exact cube shape.

Finally, FIG. 5 shows a cylinder attachment 15 in which the measuring point 11 is defined by the axis 25 of the cylinder surface 20 and the end surface 17. In addition to a single measuring point, this cylinder attachment can also have one to be measured Specify surface, namely the cylinder surface 20.

As a further, cone attachments 15 can also be attached, like them Fig. 6 shows. The focus of interest with this type of attachment is less a measuring point 11, which can be defined by the imaginary cone tip; it results as the point of intersection of the cone axis 26 with a surface line of the conical surface 21. When using cone attachments, the surface of the cone is of primary interest 21 itself, which is precisely known, including any positional and form errors, and which is to be re-measured by a gauge coordinate measuring device to be checked. Such measuring surfaces are also used to check active touch probes.

In the development of reciprocating engines, it often happens that Cylinder bores in the crankcases of such machines according to shape and position must be measured precisely. To also carry out such a measuring task with the test standard To be able to simulate in a practical manner, is in the embodiment of FIG. 2 in the two measuring point planes 6 'and 7 £ each have a cylindrical measuring surface 27 in the body of the test standard incorporated, which is perpendicular to the respective measuring point level extends. Despite the most precise possible manufacture of this cylindrical measuring surface it is also compared to an exact cylindrical shape and compared to the exact normal position have certain form and position errors.

A multi-coordinate measuring device to be checked then not only has to dle Determine the position of this cylindrical measuring surface as a whole, but also the position and reproduce form errors as precisely as possible. The cylindrical measuring surface 27 can in the case of a monolithic, solid design of the body of the test standard made of hard stone be incorporated directly into this. Instead, however, a rifle can also be used made of hardened steel or the like. Be drawn into the body of the test standard. One Such a configuration will be found above all in a cast version of the test standard recommend following the example of Fig. 1.

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Claims (15)

Claims 1. Test standard for the summary accuracy test of multi-coordinate measuring devices, with several at least approximately scattered in a measuring point plane each through the intersection and / or center of geometrically defined and precisely manufactured touchable surfaces given their exact position according to known measuring points, d a d u r c h e k e n n z e i c h -n e t that at least two different, angular measuring point planes arranged in relation to one another and in immovable mutual position (6, 7; 6 ', 7', 8) are provided on the test standard (1, 1 '). 2. Test standard according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the measuring point planes (6, 7; 6 ', 7', 8) are arranged at right angles to one another are. 3. Test standard according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that three different measuring point levels (6 ', 7', 8) according to the three spatial directions are provided on the test standard (1 '). 4. Test standard according to claim 1, 2 or 3, d a d u r c h g e k e n n notices that two lying on opposite sides of the test standard Measuring point levels are provided. 5. Test standard according to one of claims 1 to 4, d a -d u r c h g e It is not possible to state that within a measuring point plane (6, 7; 6 ', 7', 8) different provided by different geometric bodies (12-16) predetermined measuring points (11) are. 6. Test standard according to claim 5, d a d u r c h g e -k e n n z e i c h n e t that measuring points (11) by permanently atf the wall of the measuring point plane (6, 7; 6 ', 7', 8) attached or embedded geometrical bodies (12 - 16) are given. 7. Test standard according to one of claims 1 to 6, d a -d u r c h g e k e n n n z e i c h n e t that the measuring points (11) of a measuring point plane (6, 7; 6 ', 7 ', 8) a different distance from a reference level (31) of the measuring point plane (6, 7; 6 ', 7', 8) have. 8. Test standard according to one of claims 1 to 7, d a -d u r c h g e it is not indicated that perpendicular to at least one of the measuring point planes (6 ', 7 ') a bore (27) is machined into the test standard (1'), the diameter of which and axial extension a multiple of the main dimensions of the body (12 - 16) respectively. Areas (17-22) which specify the measuring points (11). amounts to. 9. Test standard according to one of claims 1 to 8, d a -d u r c h g e k e n n n n z e i c h n e t that per measuring point plane (6, 7; 6 ', 7', 8) at least two with a precisely manufactured touchable surface parallel to the measuring point plane (6, 7, 6 ', 7', 8) horizontal rulers (10, 10 ') are provided. 1o. Test standard according to claim 9, d a d u r c h g e -k e n n z e i c h n e t that the rulers (1o, 1o ') are arranged in an H, L, X or T shape relative to one another are. 11. Test standard according to one of claims 1 to 10, d a -d u r c h g It is not noted that three ball feet (28) are attached to its underside are. 12. Test standard according to one of claims 1 to 11, d a -d u r c h g I do not know that it consists of an artificially aged stress-free Cast material consists. 13. Test standard according to one of claims 1 to 12, d a -d u r c h g I do not know that the essentially cuboid or cube-shaped structure internally hollow test standard (1) on the one opposite a measuring point plane (6, 7) Cuboid or cube surface is largely recessed (21). 14. Test standard according to claim 13, d a d u r c h g e -k e n n z e i c h n e t that touchable measuring surfaces and measuring points also inside the test standard are arranged. 15. Test standard according to one of claims 1 to 11, d a -d u r c h g I do not know that it is essentially monolithic from a natural one Hard rock, in particular made of granite.