DE2628124A1 - Single axis dimension inspection machine for small workpieces - has two linked inspection tables, one carrying master and other workpiece for checking against template - Google Patents

Abstract

A hand operated single axis workpiece dimension checking or inspection machine is suitable for workpieces of a wide range of accuracies. The workpieces are checked against a master or template, using an arrangement of two linked measurement tables. The machine, which is mounted on a heavy base (10) consists basically of a vertical column (12) carrying a cylindrical movable chassis member (14) which is turn carries two measurement heads (20, 24) on suitable arms (16, 18). Each of these heads is positioned over its own small table (26, 28) on one of which a master (30) or template is mounted, while on the other the test workpiece (32) is mounted. The head (20) associated with the template can be adjusted, while the other (24) is fixed.

Description

Attachment to

Patent and utility model auxiliary application measuring device for detecting a Measurement deviation of a test item, especially for testing endpoints Summary It becomes a measuring device for the rational and precise testing of gauge blocks of all accuracy classes proposed in which a gauge block to be tested and a standard gauge serving as a "normal" can be measured by means of two measuring tips simultaneously and at the same measuring pressure, with an immediate indication of the flow deviation of the gauge block from the standard will. The measuring pressure is given very precisely by means of pneumatic devices and measurement errors are avoided by a stable, torsion-free construction of the measuring device avoided. The measuring principle used in the measuring device can be quite general to Compare certain dimensions of a test specimen with the given dimensions of one Use Normally Prior Art The invention is based on known measuring devices for gauge blocks where the dimensional deviation is due to successive measurements of the The original dimension and the final dimension to be tested is determined. These known measuring devices are relatively accurate, but not suitable for efficient work, because two time-consuming measuring processes are required to determine a dimensional deviation are.

The erfindungsgerãße measuring device with the characteristic features of The main claim has the advantage that the dimensional deviation in the course of a single measurement process can be determined, with only a single measurement result is obtained, which is already the dimensional deviation you are looking for. This will be not only the individual measurement processes are shortened, but it is simultaneously the risk of errors when creating a measurement protocol is significantly reduced. aside from that simplify the possibilities of evaluating the measurement results by means of a Calculator, which immediately classifies the tested based on the measurement results Can carry out the final dimension and in addition, small deviations in the dimensions used as standard gauge blocks for correcting the measurement results can.

The measures listed in the subclaims are advantageous Further training and improvements regarding the mechanical design of the Measuring device and in particular with regard to ensuring a very precise measuring force possible. In addition, some of the subclaims are directed to such measures, which enable a particularly fast and efficient testing of entire sets of gauge blocks.

Drawing Further details and advantages of the invention are in the following description is explained in more detail in conjunction with a drawing, the individual figures show an embodiment of a measuring device according to the invention or essential parts of the same are shown. 1 shows a schematic Representation of the measuring device; Fig. 2 is a side view of the measuring device, partly in Section and FIG. 3 shows a vertical section through the holder for the measuring tips of the measuring device according to Fig. 2.

Description of the invention The principle according to which the invention Measuring device is working, is best seen in Fig. 1, where the individual elements are only indicated schematically.

From Fig. 1 it is clear that the meter has a horizontal base 10 has, on which a vertical support column 12 is provided. Along the support column 12 is a sleeve 14 slidable at its upper and each has a support arm 16 or 18 at its lower end. The upper support arm 16 carries a first probe tip 20, which is designed as a probe and with a Measuring instrument is connected, which is indicated as dial gauge 22. Furthermore carries the lower support arm 18 has a second measuring tip 24, which is designed as a rigid measuring tip Each measuring tip 20 and 24 is assigned a measuring table 26 and 28, respectively. On the in Fig. 1 upper measuring table 26 is a standard or a master dimension 30, while on the lower Measuring table 28, a test piece or a gauge block 32 to be tested is arranged.

The measuring device shown in FIG. 1 operates as follows: The support arms 16 and 18, the measuring tips 20 and 24 and the measuring tables 26 and 28 are initially so aligned that the dial indicator 22 shows the value "zero" when on the two Measuring tables 26 and 28 have identical normals with regard to the length dimension to be tested or original dimensions. After this setting or calibration, measurements can now be made be performed. For each measurement, a standard is placed on one measuring table 26 30 is placed, while a gauge block 32 to be tested is placed on the other measuring table 28 will. Now the sleeve 14 with the support arms 16 and 18 and the measuring tips 20 and 24 lowered from a higher position into the position shown in FIG. 1, in which both Test tips 20 and 24 are in contact with standard 30 and test object 32, respectively. The measuring tips 20 and 24 are rigidly coupled to one another via the support arms 16 and 18 and the sleeve 14. The dial gauge 22 thus directly shows the dimensional deviation of the test object 32 the normal 30. This Abueichuil9 can have a positive or negative deviation be, which means that the first measuring tip designed as a probe 20 opposite their zero position is shifted either down or up. The measuring device or the dial gauge 22 thus shows the relative displacement of the two measuring tips with respect to one another at. In Fig. 1 it is indicated that the sleeve 14 by means of its downward movement brake 34 or the like. Is braked Such a damping is useful because the support arms 16 and 18 with the rKeßfühlern 20 and 24 and with the sleeve 14 in the Practice forming a relatively stable and heavy arrangement, moving it downwards should be damped in the course of a measuring process to avoid damage to the standard, of the test object and the measuring tips.

Fig. 2 shows a side view of a practical embodiment of a measuring device according to the invention, individual parts being shown in section are.

Further details of the measuring device according to FIG. 2 are shown in the sectional illustration according to Fig. 3 can be seen. The base 10 of the measuring device according to Fig. 2 has adjustable Feet 36, which can be formed in the usual way and preferably at the corners of a triangle are arranged on the underside of the base 10. The feet 36 serve an accurate horizontal alignment of the base 10 of the meter with respect to a Worktop, for example, a table or the like. At the base 10 is means Screws 38 fastened a housing 40, which, for example, made of sheet steel or may consist of another suitable material.

On the housing 40 and / or on the base 10 is by means of suitable Fasteners (not shown) a cylinder assembly 42 is attached. The cylinder assembly 42, related to the structure thereof in detail below to be discussed in more detail with FIG. 3 corresponds to the support column 12 of the measuring device according to Fig. 1.

As shown in FIG. 3, the interior of the cylinder assembly 42 is tubular Piston 44 is slidably guided. The piston 44 corresponds to the sleeve 14 of the measuring device according to Fig. 1.

The upper end of the piston 44 in the drawing and in operation has a reduced outer diameter and carries an upper cross member 46. In corresponding Way is a lower cross member at the lower end of the piston 44, which is also offset 48 attached. The cross members 46 and 48 are each with one at one end vertical strut 50 screwed to which perpendicular at a distance from each other upper support arm 16 for the first measuring tip 20 and the lower support arm 18 for the second Probe tip 24 are mounted. The support arms 16 and 18 have holes for receiving the measuring tips 20 and 24 and are slotted at their free end (not shown), so that the measuring tips in the usual way by means of adjusting screws 52, 54 in the slotted Area of the support arms 16, 18 can be clamped. On that of the vertical strut 50 facing away from the right end of the upper cross member 6 in the drawing is a guide pin 55 screwed, the between a pair of rollers 56 on the housing 40 in a vertical Direction is guided and a rotation of the piston 44 and the associated Components prevented. The piston 44 is common with the cross members 46 and 48, the vertical strut 50, the support arms 16, 18 with the sensors 20, 24 and the guide pin 55 in a perpendicular direction with respect to the cylinder arrangement 42 can be moved up and down.

To achieve the lowest possible friction or practically smooth Guide of the piston 44, the cylinder assembly 42 has two air bearings, which are similar Are designed as in an earlier application (official file number P16 23 137.1) is described. Each air bearing has a compressed air connection 58, of the conventional type from a suitable compressed air source (not shown) Compressed air is supplied. Arrived from the outlet side of the compressed air connection 58 the compressed air in an annular groove 60, which the piston 44 in the region of its upper or surrounds its lower end. The compressed air now flows through one in the Drawing not recognizable very narrow gap between the inner bore 62 of the cylinder arrangement and the outer wall of the piston 44. From this gap, the compressed air passes to the front Ends of the cylinder assembly 42 or through special radial bores 64, which each to an annular channel in the middle part of the inner bore 62 of the cylinder arrangement 42 lead. Due to the air bearings described, the piston 44 is in the area of his the upper and lower ends of the bearings are extremely low-friction.

A central section 62a of the inner bore 62 of the cylinder assembly 42 has a slightly larger diameter than the adjacent parts of the inner bore.

In the area of this section 62a, the piston 44 has a step 65, which can be acted upon with compressed air from a further compressed air connection 66 is to raise the piston 44. The further compressed air connection 66 is also available with a compressed air source (not shown) in connection, through a control valve (not shown), with the help of which the pressure effective at step 65 is very accurate can be adjusted. The just described configuration of the piston 44 as Stepped piston on the one hand and the cylinder arrangement 42 with the regulated supply of compressed air on the other hand it serves to reduce the weight of the piston 44 and the components connected therewith partially to be combined, so that for the probes 20 and 24 a relatively smaller measuring pressure that can be set and controlled very precisely via the Reyel valve or scanning pressure results. This is just at the testing of gauge blocks of particular importance, as these as well as the original dimensions, which are used as normals should be stressed by the measurement processes as little as possible.

A damping device 68 also serves the same purpose, which can be seen in Fig. 3 and which the attenuation links 34 of the measuring device according to. 1 corresponds. The damping device 68 consists of a substantially cylindrical one with a filled tub 70, in which a plate 74 provided with openings 72 is immersed, the rush shaft 75 with the lower end of the piston 44 or with the lower Cross member 48 is connected. When the piston 44 is to be described in more detail below Way of performing a measurement from its rest position to that shown in FIG Measurement position is lowered, then the damping device 68 prevents too rapid Lowering of the piston 44 and thus too hard an impact of the measuring tips 20, 24 to the normal or

the test item.

The measuring tables 26 and 28 are on in a manner not shown attached to the housing 40 and / or the base 10 and support the standard 30 and the DUT 32 from during the measurement. In detail, the measuring tables have 26 and 28 for this purpose an adjustable Auflayespitze 76 or 78, which by a few to about lateral support areas of their measuring table 26 and 28 protrudes and thus an accurate Two-point measurement enabled. The contact tips 76 and 78 and the measuring tips 22 and 24 beds in the illustrated preferred embodiment of a measuring device according to the invention on a common axis A, so that to achieve highly accurate Measurement results in addition to the two-point measurement principle, also the comparator principle is realized.

At the front of the meter - in Fig. 3 on the left - There is an operating lever 80, which is rotatably mounted on a horizontally Axle 82 is seated, which has an eccentric 84 at its inner - right in FIG. 3 - end wearing.

This eccentric cooperates with a guide roller 86 which is rotatable is attached to the vertical strut 50.

The measuring device according to Fig. 2 and 3 works after the setting with two Normals in the manner described above as follows: The measuring device is in the idle state raised by the eccentric 84 into a position in which the measuring tips 20, 24 are located at a greater distance from the measuring tables 26 and 28, respectively. If now one Measurement is to be carried out, the standard 30 is first placed on the upper measuring table 26 and the test object 32 lied onto the lower measuring table 28. Furthermore, the compressed air supply switched on for the compressed air connections 58 and the further compressed air connection 66 The pressure at the further Druci air connection 66 was set to the desired one The actual measuring process is then started by turning the Control lever initiated. By turning the operating lever 80 comes the Guide roller 86 free from the eccentric 84 serving as a stop and the piston 44 can now sink down together with the parts connected therewith, wherein the rate of descent is limited by the damping device 68. Finally put the two measuring tips 20 and 24 with a predetermined measuring pressure on the Normal 30 or the test item 32. The deflection of the stylus formed as a probe tip first measuring tip 20 is now a measure for the measurement of the test object 32 from the standard 30. This dimensional deviation can, as explained in connection with FIG. 1, directly can be displayed on a dial gauge. But there is also the option of an electrical one To generate a signal which is proportional to the deflection of the probe tip 20 from its zero position is. For example, the measuring tip 20 can have a magnetic core or a core made of magnetizable Contain material that corresponds to the deflection of this probe tip from its zero position is shifted and thus changes the inductance of a measuring coil. This change in inductance can be evaluated as a signal in a measuring circuit and shown in a display for the measured Deviation will be implemented. The measuring device and its associated facilities are of conventional design and not particularly shown in the drawing. One recognises, that a measuring process with a measuring device according to the invention is carried out very quickly and accurately can be and that in the course of a single measurement process information can be obtained immediately about the deviation to be determined. If several DUTs to be tested and if necessary still have to be compared with different normals, then one results further racionalization through the use of ladder-shaped magazines for the test items and / or the normal.

The magazines shown in section in Fig. 3 and with the reference numerals 92 and 94, for example, can each have a set of standard dimensions and Include a corresponding set of gauge blocks if a Measurement protocol is to be created for a complete set of gauge blocks. the Magazines 92, 94 are preferably facing each other for each compartment Provided recesses in which latching elements 96 on the measuring tables 26, 28 fall can. By means of such magazines, the normals and the test specimens can be carried out gently be moved over the measuring tables without affecting the accuracy of the measuring process the magazines would be affected, as this is so far in the respective measuring position be lowered that the standards and test specimens only on the adjusted parts of the Measuring tables are in contact.

L e r s e i t e

Claims (10)

Claims 1. Measuring device for detecting a dimensional deviation of a DUT from a nominal value, in particular for detecting a; outlet deviation of a End size of a master size, characterized in that two rigidly coupled, with the same measuring force acted upon measuring tips (20 24) are provided by at least one of which (20) is designed as a probe with a defined zero setting The fact is that two measuring tables C26, 28) are provided, one of which is each measuring tip (20 or 24) is assigned and of which one (28) is assigned to the recording of the test object (32) and the other (26) recording a standard (30) with one of the target values corresponding length dimension is used so that both measuring tables (26, 28) have the same Distance from its associated measuring tip (20, 24) or from the zero setting of the same have and that a measuring device (22) for determining the relative displacement one measuring tip opposite the other when the two are in contact at the same time Measuring tips (20, 24) are provided on the test item (32) or the standard (30). 2. Measuring device according to claim 1, characterized in that the one Measuring tip (24) is designed as a rigid measuring tip and that the measuring device (22) is connected to the probe tip (20) designed as a probe tip. 3. Measuring device according to claim 1 or 2, characterized in that the Measuring tables (26, 28) are adjustable in height. 4. Measuring device according to one of claims 1 - 3, characterized in that that the measuring tables (26, 28) are designed in such a way that they hold the test item (32) or the standard (30) on a measuring tip (20 or 24) support the lying point. 5. Measuring device according to one of claims 1 - 4, characterized in that that the measuring tips (20, 24) on the legs (16, 18) of a rigid U-shaped yoke are arranged on a common axis (A). 6. Measuring device according to claim 5, characterized in that the measuring tips (20, 24) are arranged vertically one above the other. 7. Measuring device according to claim 5 or 6, characterized in that the Measuring tables (26, 28) are arranged stationary and that the yoke on a carrier (piston 44) is attached1 by means of at least one air bearing in a housing (cylinder arrangement 42) is slidable with low friction. 8. Measuring device according to one of claims 1 - 7, characterized in that that the dining tables (26, 28) magazines (92, 94) for holding several test objects (32) or normal (30) are assigned. 9. Measuring device according to claim 8, characterized in that the magazine (92, 94) are ladder-shaped and open to the top between their rungs Compartments for receiving the test items (32) or the standards (30). 10. Measuring device according to claim 8 or 9, characterized in that the Magazines (92, 94) have recesses, which with latching elements (96) on the measuring tables (26, 28) cooperate in such a way that the test items (32) or the normal (30) when Measuring process from the adjacent parts of the magazine (92,94) come free and only still bear against elements of the measuring tables (26, 28).