DE9010830U1 - Chamfer length measuring device - Google Patents

Description

The invention relates to a device for measuring the length of a chamfered workpiece.

Various comparatively complex devices are known for measuring bevel length . One such device has, for example, a probe in the form of a pivoting lever with a probe tip that can be moved along a path relative to a workpiece. A particular pivot angle is registered for each unit of travel and recorded in a diagram. The bevel angle or the length of the bevel can then be calculated from the ratio of the path covered and the pivot angle.
This device is not practical for measuring the chamfer length, and is also complex and expensive for such a measurement. In terms of the measuring principle, this measuring device is designed especially for shapes, threads, recesses and the like. The measuring method is too complex and laborious for checking the chamfer length on series parts, where the chamfer is to be checked for dimensional accuracy on a random basis, and is therefore practically unsuitable for ongoing monitoring, especially of series parts.

The object of the present invention is to provide a measuring device of the type mentioned at the beginning, in particular designed as a hand-held device.

To create a method for measuring the bevel length that is easy to handle and delivers a good measurement result with comparatively little effort. The measuring process itself should only take a short time and the measurement result should be available immediately. and, in particular, be available in a directly readable manner.

To achieve this object, the invention proposes in particular that the device has a support for the workpiece, that a measuring probe or the like connected to a displacement measuring device can be placed on the chamfered front side of the test object (workpiece) and that a stop edge is provided for contact with the chamfered surface.

Such a measuring device enables a quick measurement and checking of the chamfer length in a simple way. The workpiece to be checked is placed on the support, pushed with the chamfer surface against the stop edge and the projection of the chamfered front side of the workpiece beyond the stop edge is measured.

The measuring device is simple in its construction and can also be manufactured as a compact hand-held device. The measuring process only takes a very short time, so that frequent sample measurements can also be carried out in series production.

)25 The design of the device allows the flange length of various workpieces to be measured regardless of their diameter. It can be used to measure tubular workpieces or shafts.

A further development of the invention provides that the length of the measuring probe connected to the distance measuring device and/or the length of the stop edge can be adjusted relative to each other to compensate for different bevel angles. The position of the measuring probe, the height of the stop edge and also the bevel angle of the test piece are in a direct, geo-

metric context. By changing the length of the measuring probe or, if necessary, the height of the stop edge, it is possible to adapt to different bevel angles, which makes it unnecessary to adjust the position measuring device itself .

The workpiece support expediently has at least one support bolt which is designed to form a stop edge, preferably as a shoulder bolt.

This provides an exact assignment of the support plane and the position of the stop edge relative to the support, so that good measuring accuracy is promoted and a particularly simple structure is also possible.

Preferably, an adjustable threaded connection is provided to change the length of the measuring probe within its longitudinal extension. This can be achieved using simple means with good adjustment accuracy and is also easy to handle.

It is particularly advantageous if a dial gauge is used as the length measuring device. Such gauges are commercially available and are relatively inexpensive with good measuring accuracy.
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A particularly advantageous development of the invention provides that the support bolt(s) each have a shoulder collar with two stop edges b2w .
This significantly expands the application area of the measuring device, as it is now possible to seat internal phases , for example on ball bearing outer rings, in which the latter is practically placed at the back against the stop edge facing the measuring probe. Since the axial width of the shoulder collar and also the distance between the contact surface for the measuring probe on the one hand and the bevelled

Inner-St1rnflehe on the other hand are known, the Zero the dial gauge according to the respective measuring object. | In order to facilitate this, it is expediently provided that

if the measuring device has a \ and has a setting gauge that can be placed on ^the stop edge facing away from the measuring probe for zeroing the dial gauge. The distance between the workpiece-dependent distance between its contact surface on the measuring probe and the inner face with the inner phase to be measured can be set on this setting gauge. In addition, the width of the shoulder and thus the axial distance between the two stop edges is also taken into account. In addition, a correction dimension adjusted to the height of the stop edges is also included.

Additional embodiments of the invention are set out in the further subclaims.

The invention and its essential details are explained in more detail below with reference to the drawing.

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It shows: &Ggr;

( 25 Fig. 1 A partially sectioned side view of a bevel length measuring device,

Fig. 2 is a plan view of the device shown in Figure 1, 30

Fig. 3 is a front view of the device shown in Figures 1 and 2,

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. * a longitudinal section detail in the area of a measuring probe,

Fig. 5 a schematic diagram of the measuring arrangement and

Fig. 6 is a partial side view of a measuring device for measuring rear internal chamfers.

The essential parts of a chamfer length measuring device - in short: measuring device - can be seen in Figures 1 and 2 and in principle also in Figure 5. These are a support 2 for the workpiece 3 to be checked, a measuring probe 6 connected to a distance measuring device 4 that can be placed on the chamfered front side 5 of the workpiece 3, and a stop edge 7 for contact with the chamfer surface 8.

With the aid of the measuring device 1, the chamfer length I of a chamfer 9 can be determined, whereby this is usually the axially parallel length between the front face 5 and the end of the chamfer surface 8 facing away from it.

During the measuring process, the workpiece 3 is placed with its outer surface on the support 2 and then moved in the axial direction parallel to the support against the stepped stop edge 7. At the same time, the measuring probe 6 is deflected according to the axial projection ü (Figure 5) beyond the stop edges 7. With a fixed height h of the stop edge 7 above the support 2 and a fixed bevel angle W, a correspondingly different projection ü results for different bevel lengths I, which is recorded by the measuring probe 6 and passed on to the distance measuring device 4.

In order to achieve the same chamfer width with different chamfer angles W

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In order to obtain the same readings for the distance measuring device 4 for all lengths, the resulting different projections ü must be compensated. For this purpose, in the present embodiment, a length adjustment device 11 implemented by an adjustable threaded connection 1o is provided within the longitudinal extension of the measuring probe 6. On the one hand, the probe 6a of the distance measuring device 4 is connected to this length adjustment device 11 and, on the other hand, the measuring probe 6 that can be placed on the workpiece 3.

The structure of the length adjustment device 11 can be seen in Figure 4. The threaded connection 1o of this length adjustment device 11 has an external thread part 13 connected to the probe 6a and an internal thread part H ₁ connected to the measuring probe 6. By turning the internal thread part with The total length of the measuring probe 6 connected to it and thus also its starting length can be varied and adapted to different bevel angles. The measuring probe part 6a is rotationally fixed and the external thread part 13 connected to it is also secured against twisting.

The internal thread part 14 forms a manually operated adjusting screw and has a knurled ring 15 on its outer surface.

The length adjustment of the measuring tangent 6 provided for length compensation of different bevel angles requires

)25 given thread pitch of the threaded connection 1o a corresponding angle of rotation. For control purposes a scale 16 with chamfer angle measurements is provided on the outer surface of the internal thread part 14. A pointer 17 is assigned to this scale 16. This enables adjustment to different Chamfer angle can be easily carried out and also controlled. To further simplify the setting, a locking device 18 with a ball 2o loaded by a spring 19 is used. Inside the internal thread part 14 and on the circumference of the external thread part 13, locking recesses 21 are provided at certain

Places assigned to chamfer angles are provided. For example,

these locking recesses 21 can be provided at locations that correspond to the bevel angles most commonly encountered in practice, for example 15°, 2o°, 3o° and 45°.

It should also be mentioned that in order to adapt to different bevel angles, the total length of the measuring probe 6 can also remain unchanged, in which case the height h of the stop edge 7 would have to be varied. The preferred position measuring device 4 is, as shown in the As shown in the examples, a dial gauge 12 is used. Either mechanical or electronic dial gauges, either with analogue or digital display, can be used. Figure 2 clearly shows that the dial gauge probe 6a is connected to the

External thread part 13 is connected.

In the embodiment shown, two support bolts 23 arranged parallel to one another are provided as support 2. To form the stop edge(s) 7, the support bolts 23 has a larger diameter projection 24 so that a fixed relationship between the support plane and the height as well as the position of the stop edge 7 is provided.

The initial position of the measuring probe 6, which springs into this initial position without any pressure, is the position of the stop edge 7 assigned.

As can be seen from Figure 1, the support bolts are arranged approximately horizontally so that a workpiece 3 - for example a bolt or a ring - can be placed or suspended there. By axially moving it against the stop edge 7 the workpiece is then brought into the measuring position, where the measuring probe 6 is already acted upon by the front side 5 of the workpiece and is axially displaced. The measuring result can then be read directly from the dial gauge 12. Such a measuring process can be carried out in a very short time, for example within one or

4K two seconds,

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In principle, a support bolt 23 would be sufficient for the In practice, however, the position of the workpiece to be measured is

two spaced apart support bolts 23 so that better measurement accuracy can be achieved even with short heating processes.

The position of the two support bolts 23 can be changed to adapt to different workpieces. Fig. 3 shows that a circular slot 25 is arranged in the carrier plate 26 for this purpose. The two support bolts 23 are held by screws 27 (Figure 2) and after loosening these screws 27, the clamps stiffen* The measuring probe 6 is, as can be seen from Figures 2 and 3, located at its probe end approximately between the two support bolts 23 and | with a lateral projection to a connecting line between these arranged on both support bolts.

The measuring device 1 has a frame 28 with a base plate 29 for setting up on a surface and the approximately vertical support plate 26 connected to it. A dial indicator holder 3o is located on the support plate 26 and the support bolts 23 are also connected to the support plate 26 on the other side than the dial indicator holder 3o. Overall, the measuring device 1 forms a handy, compact hand-held device.

As already mentioned, the length of the projection of the chamfered front side 5 of the workpiece 3 depends on the height h of the stop edge 7 above the support 2 and also on the angle of the feet. In practice, the height h of the stop edge 7 is dimensioned so that even the smallest of the gaps on the workpiece 3 occurs. the chamfer heights corresponding to the distance of the outer edge of the front face 5 perpendicular to the extension of the outer surface of the workpiece, result in a slight overhang ü. The height h of the stop edge 7 is expediently a few tenths of a millimetre. In a practical design guide form, in which the length adjustment device 11 for

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If the bevel angle compensation probe 6 works with a threaded connection 1o that has a pitch of one millimeter, a corresponding step height h of the stop edge 7 of o.183 mm would result for half a revolution.

Between a largest bevel angle of 45° and a smallest bevel angle of 15°, the resulting different projection ü of 0.5 mm could be compensated for with half a turn of the angle pre-selection screw ü (length adjustment device 11) with the same bevel length. In relation to the length of a 45° bevel, a bevel angle of 3° would result in a compensation length of 0.15 mm, and a compensation length of 2° would result in c,Z? nsns.

It should also be mentioned that the _t >;igenver *-el Ivorrich chtung 11 Df-eh-

begräniwitgen so that the deep probe length does not exceed adjusted beyond the intended length compensation becomes.

In Figure 5, two different workpieces 3 are shown in Measuring position shown. Both workpieces 3 have the

pale chamfer length I, but different chamfer angles W1 and W2. The workpiece 3 shown in solid lines has a chamfer angle W2 of 45°. This results in a projection Ü2 that is larger than the projection Ü1 of the workpiece 3 shown in dashed lines with a chamfer angle W1 of

(25 15°. In order to obtain the same reading on the dial gauge 12 corresponding to the same bevel length I of the bevels 9, 9' despite these different projections ü1 and Ü2, the measuring probe 6 must be adapted to the different bevel angles by changing its length by the distance V. This is done with the length adjustment device 11.

The bevel length measuring device 1a shown in part in Figure 6 has an additional stop edge 7a on its workpiece support 2, through which even internal bevels 9a can be easily measured, e.g.

Ball bearings—outer rings 31 or similar workpieces can be recovered.

This additional stop edge 7a is located on the side of a collar 24a facing the measuring probe 6, which on the other hand has the stop edge 7 already described. In front of and behind the collar 24a there are flush outer piece surfaces 2 and the outer surface of the collar runs parallel to these supports with slightly larger outer diameters, so that the two stop edges 7, 7a also have the same height. Here too, a step height h of 0.83 mm is expediently provided, which is advantageous for the intended bevel angles and the design of the length adjustment device 11.

Since the zero point set for the front stop edge 7 on the dial gauge 7 and the zero position related to the rear stop edge 7a do not match, a new zeroing must be carried out according to the shift position. This is done first by pushing the measuring probe 6 back by a distance that is made up of the axial length a of the collar 24a and the ring thickness of the workpiece b. In addition, the setting of the length adjustment device 11 must also be taken into account here. It is advisable to use the length adjustment device 11 set to a bevel angle of 45°, so that the correction dimension is twice the height h, which must be subtracted from the sum of the lengths a and b. If the measuring probe 6 is moved by this final dimension, the dial can be turned. This is then the starting position for measurement. If the If the workpiece to be measured is then placed with the rear inner bevel 9a on the stop edge 7a, this results in a negative display value, which then corresponds to the actual bevel length. With digital clocks, this value can be displayed directly with a negative sign, while with mechanical clocks Analogue dial gauges use the difference between the zeroing dimension and the displayed value as the measured value, which represents the measured bevel length.

To simplify the zeroing process, a setting gauge can also be used, which is designed, for example, like a bolt with a perpendicular stop surface and an axially extending setting screw. The setting gauge is placed on the workpiece support 2 and moved with its front stop surface to the front stop edge 7. With the help of the setting screw, the measuring probe 6 can then be adjusted to the respective dimension b on the workpiece, taking into account the dimension a and the correction value described above.

IQ dimension. The setting gauge is designed so that only the workpiece-dependent dimension b needs to be taken into account, since the other dimensions are fixed. Furthermore, the setting gauge can be designed so that it can also be used to zero the dial gauge 12 at

Measurement can be used at the front stop canal 7.

The U-gauge can have a radially oriented stop face, which simultaneously serves as a stop surface for the stop edge 7 and also for the contact of the measuring probe 6. If the dial gauge and the measuring probe 6a, 6 are correctly set,

_2C, when the length adjustment device 11 is set to a bevel angle of 45°, the clock must indicate the height h of the stop edge 7, for example 0.183 mm. The embodiment according to Figure 6 with an additional, rear stop edge 7a enables the height h of the stop edge 7 to be The range of applications of the bevel length measuring device has been significantly expanded.

It should also be mentioned that the length adjustment device 11 can also be designed in such a way that the correction dimension, e.g. of twice the height h (at 45°), is taken into account in an adjustment position. Furthermore, in another adjustment device

setting, the fixed axial width a of the collar must also be taken into account, so that when the dial gauge with zeroing is switched to the rear stop edge 7a by a user, only the dimension b of the workpiece is decisive. Ir

the adjustment position only with consideration of the above-mentioned whether

To correct the dimension, the length adjustment device 11 would have to be rotated into a position that practically corresponds to a chamfer angle of 90° (no chamfer).

All features shown in the description, the claims and the drawings can be essential to the invention both individually and in any combination with one another.

- Expectations -

Claims (1)

43 Expectations 1. Device for measuring the bevel length of chamfered workpieces, characterized in that it has a support (2) for the workpiece (3), that a measuring probe (6) connected to a distance measuring device (4) and which can be placed on the chamfered end face (5) of the test object (workpiece 3) and a stop edge (7) for contact with the chamfer surface (8) are provided, ' 2. Device according to claim 1, characterized in that the length of the measuring probe (6) connected to the distance measuring device and/or the position of the stop edge (7) are each adjustable relative to one another to compensate for different bevel angles (W). 3. Device according to claim 1 or 2, characterized in that the workpiece support (2) has at least one support bolt (23) which is preferably designed as a shoulder bolt with a larger diameter shoulder (24) to form a stop edge (7). &igr; 25 *· Device according to one of claims 1 to 3, characterized in that the height (h) of the stop edge (7) projecting over the support (2) is smaller than the smallest ! Chamfer height of a chamfer to be measured. oQ 5. Device according to one of claims 1 to 4, characterized in that an adjustable threaded connection (1o) is provided as a length adjustment device (11) for changing the length of the measuring probe (6) within its longitudinal extent. 6. Device according to claim 5, characterized in that the threaded connection do) of the measuring probe (6) has an external thread part (13) and an internal thread part (14) which can be screwed onto this external thread part and that preferably a rotation limit is provided for the largest bevel angle and also for the smallest bevel angle. 7. Device according to claim 6, characterized in that the internal thread part (14) is designed as an adjusting screw with a the pre rgssshsr.crs Fasensinkle formed is . ) 8. Device according to one of claims 1 to 7, characterized in that in the length adjustment device (11) of the ,j- measuring probe (6) a locking device is provided which releasably engages at the intended bevel angles. 9. Device according to one of claims 1 to 8, characterized in that a measuring 2Q clock (12) is provided as the length measuring device (11). 10. Device according to one of claims 1 to 9, characterized in that the axial length adjustability of the measuring probe (6) is 45 or 15 mm for the largest or smallest chamfer angles provided, respectively, and that, in coordination with this, the chamfer stop edge (7) projects 0.183 mm (0.183o127) beyond the support plane (2) for the workpiece. _11. Device according to one of claims 1 to 10, characterized in that two parallel support bolts (23) are provided as the support (2), which are preferably adjustable in their parallel distance from one another, in particular on a circular arc. 12. Device according to one of claims 1 to 11, characterized in that the probe end of the measuring probe (6) is approximately between the two support bolts C23) and preferably at a lateral distance from a connecting line between these two support bolts. 13. Device according to one of claims 1 to 12, characterized in that a frame (28) with a base plate (29) and an approximately vertical support plate (26) with a dial gauge holder (30) located thereon and a workpiece support (2) connected thereto is provided. (14. Device according to one of claims 1 to 13, characterized in that the support bolt or bolts (23) each have a shoulder collar (24a) and two stop edges (7, 7a). 15. Device according to claim 14, characterized in that the respective stop edges (7, 7a) on closing workpiece supports (2) are aligned with each other and that the heights (h) of the stop edges (7, 7a) protruding over the supports (2) are preferably equal. 16. Device according to one of claims 1 to 15, characterized in that it comprises a workpiece support (2) setting gauge for zeroing the dial gauge that can be placed on the stop edge (7) facing away from the measuring probe (6). - 17. Device according to claim 16, characterized in that &ogr; U the setting gauge is designed like a bolt with a front stop surface and an axially extending setting screw. Patent Attorney