DE8017402U1 - Test standard for the summary accuracy test of multi-coordinate measuring devices - Google Patents

Description

Daimler-Benz Aktiengesellschaft

Stuttgart-Untertürkheim Daim 15 155/4

Test standard for the summary accuracy test of multi-coordinate measuring devices

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

According to the applicant's pillow are so far only essentially two-dimensional test standards known; that is, they contain only a single measuring point plane. With a Such test standards can only provide accuracy statements when measuring using only two coordinates of a measuring device, however, practice shows that the measuring accuracy of a multi-coordinate measuring device can only be assessed inadequately, even if a check is carried out with such a flat test standard in repeated on different spatial levels. One of the three measurement coordinates always remains unused and a possible one Errors within this one coordinate are not taken into account in the accuracy check.

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By arranging a flat test standard on the measuring table at an angle, it is possible to check all three possible movements of the measuring device at the same time to be included. The disadvantage of this procedure, however, is that in the case of an oblique arrangement the exact absolute The position of the individual measuring points is unknown; only their relative position to one another is known. Even if thus the measurement of such a test standard arranged at an incline along with the mutual relative position of the measuring points would confirm sufficient accuracy, there could still be an absolute error in the measurement, who would remain undetected.

The object of the invention is to create a test noi ^ times which reliable and practical statements about the measurement accuracy with simultaneous interaction or use of at least three possible movements of a multi-coordinate measuring device.

According to the invention, this object is achieved by the characterizing features of claim 1. Thanks to each other

f angular and immovable arrangement of at least two

different measuring point levels within a test standard is on the one hand a three-dimensionally extending test standard achieved; Thanks to the arrangement of the individual measuring points in measuring point planes, however, one is still indispensable extremely accurate original measurement of the test normal possible. The actual position of the individual measuring points must of course be at least be known an order of magnitude more precisely than the measuring accuracy of the most accurate to be checked with the test standard.

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Further useful refinements of the test standard and further advantages can be found in the dependent claims and the following Description of two embodiments shown in the drawings are taken; tend to:

Fig. 1 dn first embodiment of a spatial Test standards made of cast material,

FIG. 2 shows another diagonally spaced on a measuring table arranged embodiment of a spatial test standard made of hard rock and

Daim 13 15 3/4 *

fenden measuring machine. This is how accurate original measurements can be however, according to the applicant's pillow, with today's possibilities and with a reasonable amount of effort, only within one level make; the third room at right angles to this level

coordinate can only be added in the range of a few millimeters | can be recorded so precisely. Only to determine the exact

mutual relative position of the various measuring point planes f

an increased metrological effort must be made for the original measurement

be driven. However, then all measuring points |

and measuring surfaces of the spatial test standard in their position in?

within a reference system assigned to the test standard exactly f

fixed. By arranging different measuring point levels ! ',

a cube or cuboid test standard is also a ^: <.

better relation to the practical measuring tasks established; ('

there it is also mostly about the determination of Bohr- $

images that are located in spatially different levels 1

of a spatially extending object arranged 1

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Fig. 3-6 four different exemplary embodiments that can be placed on 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. I a section of a multi-coordinate measuring device is shown 5 indicated with a measuring table 2, which receives the test standard 1, and one perpendicular to the measuring table up and down as well Measuring quill 3 which can be moved parallel to the plane of the measuring table and carries a measuring probe 4. The embodiment shown in FIG a test standard is placed on the table parallel to the coordinates of the measuring device. It just has two measuring point planes 6 and 7 at right angles to one another, of which one (6) is parallel to the table plane lies. Each measuring point plane has a plurality of measuring point locations 9, which are precisely processed by one shown in more detail in FIG Bore / cone insert 12 are formed. These insert bodies are in the wall 25 of the test standard in severely supercooled Shrunk in condition and then sanded to the finished size with particular precision. It has a bore surface 19 and a coaxially to this lying outwardly facing conical surface 18, the outward by a precisely at right angles to the axis 24 of the bore or the cone lying 'end face 17 is limited. The intersection of the borehole 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, there is only one type of measuring point in the exemplary embodiment according to FIG. 1 9, namely only bore / cone inserts provided

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see. The strength of the collar of the bore / cone insert protruding from the wall 23 can be deliberately different can be selected strongly, as indicated in Fig. 3 by different types of lines. This comes about a certain variation in the position of the measuring points 11 at the various measuring point locations in relation to one example by one of the measuring point points predetermined reference level 51 of the relevant measuring point plane. The conical surface 18 is designed to be relatively long in the axial direction (24), so that in the event of a possible wobble of the cone axis with respect to the cylinder axis or with respect to the exact perpendicular direction on the reference plane 31 a certain measuring surface is given by the conical surface 18, the exact shape and position of which by multiple probing can be determined. This makes the multi-coordinate measuring device to be checked a special one hard task, because they have the relatively small shape or Must recognize positional deviations.

In addition to the measuring point points 9, rulers 1o \ 'are also provided within each measuring point plane, which are marked with a precisely machined touchable surface parallel to the measuring point plane, for example within the reference level 51 run. These rulers, which in the embodiment according to FIG. 1 are T-shaped within a measuring point plane to one another are arranged, serve on the one hand to the test standard on the measuring table in certain iVeise or precisely to its current position on the measuring table determine. For this purpose, certain contact points are particularly highlighted on the rulers. In addition, the

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Rulers, however, also have the purpose of specifying a large, essentially flat, measuring surface, albeit a very large one small but unavoidable form deviations from the exact planar form - these form deviations are also for every single test standard and known for every single ruler - also as special to a measuring device to be checked difficult recognition task can be set.

The test standard according to FIG. 1 is - as I said - made of cast material and designed as a hollow body. By Artificial aging ensures that the material is particularly stress-free, so that due to storage or temperature fluctuations no or only negligible form- ■■ Changes to the test occur normally. Thanks to a good

\ ribs and stiffening are also important for dimensional stability

did care in a constructive way. The measuring point planes

opposite surfaces of the test standard, which is essentially cuboid, have large recesses 2 9 provided so that inside the test standard

;; les measuring points and measuring surfaces can be arranged. The-

These measuring points or areas are only with widely spreading. Side buttons accessible; such a task arises ; ■ "'also often enough in practice, so that through

such a configuration is also a practical matter ^. 'Accuracy check with the test standard is possible.

ζ The further embodiment shown in Fig. 2

of a test standard 1 'has three measuring point planes 6', 7 'and 8, all three of which are at right angles to one another and

the different spatial directions or coordinate planes

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correspond. In this exemplary embodiment, the measuring point locations 9 'are designed differently within a measuring point plane. The rulers 1o 'are arranged at the edges of the test standard and are arranged in an L-shape or U-shape with respect to one another within a measuring point plane. Three ball feet 28 are arranged on the underside of the test standard. The number of three ball feet ensures that the test standard is set up unambiguously and without shaking on a base in any case. The design of the feet as ball feet makes it possible, by using differently sized bases 50 under each foot, to specify an oblique arrangement of the test standard on the measuring table. In \ ^r SE OF very precisely machined pieces subset 5o, the skew can be precisely predetermined by the Prüfnormales these dimensions, so that the actual position of the individual measurement points in space thereby is accurately known.

In addition to bore / cone inserts 12, the measuring points are also provided by other attachment bodies at the measuring point locations the test standard 1 'specified. Fig. 4 shows enlarged a ball attachment 15, in which the measuring point 11 by the The center of the touchable spherical surface 22 is given. This has a noticeable distance from it the reference level 51 of the corresponding measuring point level.

Furthermore, at the individual measuring point levels of the test standard 1 'curb attachments 16 are immovably firmly attached, whose edges are parallel to the rulers 1o.

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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 through 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 form deviations of the cube attachment recognizable from the exact cube shape.

Finally, FIG. 5 shows a cylinder attachment 15 in which the measuring point 11 passes through the axis 25 of the cylinder surface 2o and the end face 17 is defined. In addition to a single measuring point, this cylinder attachment can also have a to measuring surface, namely the cylinder surface 2o.

As a further option, cone attachments 15 can also be attached, as shown in FIG. 6. 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 from the intersection of the cone axis 26 with a Generating line of the conical surface 21. When using conical attachments, the conical surface is of primary interest 21 itself, which, including any positional and form errors, is precisely known and that of a person to be checked Multi-coordinate measuring device is to be remeasured. Such measuring surfaces are also used to check active ones Touch probes.

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In the development of reciprocating piston machines, it often happens that cylinder bores in the crankcase of such machines have to be precisely measured for shape and position. In order to simulate such a measurement task with the test standard practice, is in each case incorporated in the embodiment of FIG. 2 in the two Meßpunktebenen 6 ¹ and T is a cylindrical measuring surface 27 in the body of the Prüfnormales extending perpendicular to the respective Meßpunktebene. Despite the most precise possible manufacture of this cylindrical measuring surface, it will also have certain shape and position errors compared to an exact cylindrical shape and compared to the exact normal position. A multi-coordinate measuring device to be checked must then not only determine the position of this cylindrical measuring surface as a whole, but also reproduce the position and shape errors as precisely as possible. In the case of a monolithic, solid design of the body of the test standard made of hard stone, the cylindrical measuring surface 27 can be incorporated directly into the latter. Instead, however, a sleeve made of hardened steel or the like can also be drawn into the body of the test standard. Such a configuration is recommended above all in the case of a cast version of the test standard based on the example of FIG.

Claims (2)

·> Il ■ · a a Daimler-Benz Aktiengesellschaft Stuttgart-Untertürkheim. Daim 13 153/4 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 cut and / or center point of geometrically defined and precisely manufactured probable Areas given their exact position according to known measuring points, characterized in that that at least two different, angled too mutually arranged measuring point planes (6, 7; 6 ", 7 ', 8) located in immovable mutual position the test standard (Ί, 1 ') are provided. _. 2. Test standard according to claim 1, characterized that the measuring point planes (6, 7; 6 ', 7', S) are arranged at right angles to one another. 3. ' Test standard according to claim 1 or 2, characterized characterized in that three different measuring point planes i; 6 ', "', S) corresponding to the three spatial directions are provided on the test standard [1 '). • · * · ft If «·« «« · ft ■■ - 2 - Daim 13 153/4 4. Test standard according to claim 1, 2 or 3, characterized in that two on opposite sides Measuring point planes lying on the sides of the test standard are provided. 5. Test standard according to one of claims 1 to 4, characterized in that within a measuring point plane (6, 7; 6 ', 7', 8) different measuring points (11) given by different geometric bodies I 12-16) are provided. 6. Test standard according to claim 5, characterized in that that measuring points (11) by permanently on the wall of the measuring point plane (6, 7; 6 ', 7', S) attached or embedded geometric bodies (12-16) are given. 7. Test standard according to one of claims 1 to 6, characterized in that the measuring points (11) of a measuring point plane (6, 7; 6 ', 7 ¹ , 8) have a different distance from a reference level (31) of the measuring point plane (6, 7 ; 6 ', 7', S) have. 8. Test standard according to one of claims 1 to 7, characterized in that perpendicular to at least one of the measuring point planes (6 ', 7') a bore l27) is incorporated into the test standard (1 ^! ), The diameter and axial extent of which is a multiple the main dimensions of the body (12-16) or surfaces (17, - 22) which specify the measuring points (11) is. -j- Since in 13 153/4 Test standard according to one of Claims 1 to 8, characterized in that each measurement point level (6, 8) at least two mi precisely manufactured touchable surface parallel measuring point plane (6, 7, 6 ', 7', 8) lying ruler 1ο ') are provided. t a 1 for 1o. Test standard according to claim 9, characterized in that £ indicates that the rulers (1o, 1o ') are arranged in an H, L, X or T shape relative to one another 11. Test standard according to one of claims 1 to 1o, characterized in that dai; Three ball feet (28) attached to the underside, see fig 12. Test standard according to one of claims 1 to 11, characterized in that an artificially aged, stress-free cast. there - on desind. th a s made of plastic 13. Test standard according to one of claims 1 to 12, I thereby marked that ias im ■ the interior is essentially cuboid or cube-shaped hollow test standard (1) on one measuring point <; level (6, 7) opposite cuboid or cube surface is largely recessed (21). 14. Test standard according to claim 15, characterized in that probable measuring surfaces and measuring points are also arranged inside the test standard. - 4 - Daim 15 155/4 15. Test standard according to one of claims 1 to 11, characterized in that it is in is made essentially monolithic from a natural hard stone, in particular from granite.