DE1187381B - Device for measuring the runout of round workpieces - Google Patents

Description

Device for measuring the runout of round workpieces The invention relates to a device for measuring the vertical and / or lateral runout of round workpieces, in particular of automobile wheels, with a mechanical with a measuring device, preferably a dial gauge, cooperating probe arm, the the rotating workpiece scans under the action of spring pressure and the transmits its movements to the measuring device, and with means by which the measuring device is automatically set to the zero position.

In the case of devices for measuring impact on those that are heated It is known to machine runners to achieve a fixed zero display on the measuring device a holder carrying a length measuring gauge with a measuring sensor to be adjusted by means of an electric motor so that the measuring gauge system fixed to the holder relative to the sensor to a fixed predetermined, from the zero position of the gauge different value is adjusted, whereupon a reverse adjustment of the system to another fixed, corresponding to the zero position of the teaching Value takes place. It is also known to check geometric tolerances Workpieces, especially for checking the out-of-roundness, with a good friction a stylus in operative connection between two limit stops to move, one of which is adjustable at a distance from the other and at least one is designed as an electrical contact element. The by the distance of the The tolerance range given to the contact elements is automatically set to the Maximum of the dimension of the test object in question, regardless of the size of this dimension a. If the tolerance range is exceeded, the electrical contact closes.

Finally, it is also known for the radial run-out control of rotating Machine parts include a slidable member, the test specimen like a connecting rod to let and the maximum longitudinal displacement of the limb by a micrometer to determine while the relative adjustment of a scale on the micrometer opposite a fixed mark enables the size of the out-of-round deflections to be measured.

In contrast, the invention is based on the object of the measuring device to be trained with simple means so that the automatic setting of the zero position with mainly mechanical means to avoid electrical adjustments given greater susceptibility to failure and to avoid the device even with rough Operation in the hand of inexperienced persons in metrology is satisfactory and to let work quickly indicating. Furthermore, with the device according to the invention can be achieved that, in addition to the current measurement result, the greatest achieved Impact of the workpiece is displayed starting from the zero position and that also a quick test for impact tolerance is possible.

The solution to this problem is that on a solid base plate of the device, the probe arm designed as a two-armed lever around one on the base plate fixed axis pivotable and the measuring device on one about the same axis against in one direction acting spring pressure pivotably articulated movable measuring frame are arranged, further that the one lever arm of the probe arm, which is mechanically with the measuring device is connected against the spring pressure present in both directions is supported on the measuring frame and contacts between the probe arm and the measuring frame are arranged, which are connected to arranged on the measuring frame electromagnets.

In a further embodiment of the subject matter of the invention, a actuated the probe arm, known per se measuring device for the optical display of the Exceeding an adjustable tolerance range between limit stops is provided be.

The lever arm of the cooperating with the measuring frame of the device Probe arm can advantageously be made of two in one direction independently of one another around the arranged on the base plate axis pivotable arm parts exist, of which one arm part is firmly connected to the other lever arm of the probe arm and the other arm part connected as a measuring arm with the measuring device arranged on the measuring frame is. Furthermore, an electromagnet can be provided, which the measuring arm with the measuring frame couples.

The contacts can have a stop between the fixed arm part and form the measuring frame.

The measuring device can advantageously consist of a dial gauge which Via pinion, lever or the like. Is connected to the measuring arm and its zero position assumes when the measuring arm with the arm part fixed to the Tastarn together on the measuring frame strikes.

In order to be able to determine quickly and reliably for each workpiece, whether a possible blow is still within the tolerance can be determined after a Another feature of the invention is the free end of the measuring arm an electrical contact have, which in both directions of movement of the measuring arm with arranged on the measuring frame, by a vernier od. The like. Adjustable mating contacts are in contact.

The adjustable mating contacts can advantageously work in the opposite direction be resiliently hinged to the measuring frame.

According to another feature of the invention, a switch can be provided be by which the electromagnet holding the measuring arm on the measuring frame can be switched off is. This ensures that the measuring arm is in its position in relation to the probe arm corresponds to this, so it runs so that the dial gauge shows the respective impact. The exact position of the field can thereby be determined.

The compressive force of the arranged between the probe arm and the measuring frame Springs can also be less than the force of the electromagnets.

Finally, between the measuring frame and the base plate a Be arranged spring that the measuring frame in the direction of the largest blow of the workpiece In the drawing, the subject matter of the invention is in one embodiment shown schematically.

The device for measuring the vertical and / or lateral runout of round workpieces consists essentially of the base plate, which is clamped can be, from the measuring frame 2 and designed as a two-way lever Sensing arm 3, which is provided with the sensing roller 5 rotating around the axis 4. Of the The measuring frame 2 is arranged pivotably about the axis 6 which is arranged on the base plate 1 is. The compression spring 7 supported on the base plate 1 presses the measuring frame 2 in the position shown obliquely to the longitudinal axis of the base plate 1. Between the Base plate 1 and the measuring frame 2 is also pivotable about the axis 6 of the probe arm 3 arranged, whose arm opposite the feeler roller 5 is divided into two arm parts is.

Of this, the arm part 8 is firmly connected to the arm that has the feeler roller 5 carries, and the other arm part is designed as a measuring arm 9 and around the axis 6 pivotally attached to this. The arm part 8 and the measuring arm 9 lie in the recess 10 of the measuring frame 2. Otherwise, the movement of the probe arm 3 about the axis 6 secured by the longitudinal groove 11 arranged in the measuring frame 2. Inside the recess 10 of the measuring frame 2, the compression springs 12, 13 are arranged, of which the compression spring 12 is supported on the measuring frame 2 and presses against the arm part 8 of the probe arm 3, while the spring 13 pressing in the opposite direction and also supported on the measuring frame 2 against the measuring arm 9 presses.

The spring 12 is stronger than the spring 13, so that the probe arm 3 and the measuring arm in the non-actuated position of the device can be seen from the drawing Assume position to measuring frame 2. Inside the recess 10 of the measuring frame 2 is between the arm part 8 and the measuring frame 2 the Contact spring 14 arranged whose free end 15 in the position shown of the probe arm 3 close to the arm part 8 arranged contact 16 lies, opposite to which the contact 17 is arranged on the measuring frame 2 is. If the contact 16 touches the end 15 of the contact spring 14, the on the measuring frame 2 above the axis 6 arranged electromagnets 18 put into operation, in such a way, that the measuring frame 2 is held on the base plate 1 and pivoting of the measuring frame 2 relative to the base plate 1 about the axis 6 only by overcoming it the force of the electromagnet 18 is possible.

If the end 15 of the contact spring 14 touches the contact 17, the am Measuring frame 2 arranged electromagnet 19 via a relay, not shown in FIG Put into operation, the effect of which is directed against the measuring arm 9, such that a Pivoting of the measuring arm 9 about the axis 6 with respect to the probe arm 3 or its arm part 8 and with respect to the measuring frame 2 only by overcoming the force of the electromagnet 19 is possible. The relay, not shown, prevents the Electromagnet 19 when the contacts 15, 17 open and switches the electromagnet 19 only when the contacts 15, 16 open.

Above the cutout 10 is on the measuring frame 2 that of clarity the drawing sake of dash-dotted dial gauge 20 fixedly arranged, whose Measuring mechanism by means of levers, pinions, etc., not shown, mechanical transmission elements is connected to the measuring arm 9 in such a way that each pivot position of the measuring arm 9 in relation a certain position of the pointer 21 of the dial gauge 20 corresponds to the measuring frame 2. If the contact 16 is on the arm part 8 with the end 15 of the contact spring 14 on the contact 17, the pointer 21 of the dial gauge 20 is in the zero position 22.

On the dial gauge 20 there is the green signal light 23 and the red signal light 24. Both signal lights are indicated by the one at the end of the measuring arm 9 arranged contact 25 and by the arranged on both sides of the contact 25 Contact pins 26, 27 controlled. The contact pins 26, 27 are in bores of the im Measuring frame 2 guided adjustment part 28 arranged opposite the measuring frame 2 with the help of the vernier 29 is displaceable. By contact springs attached to the measuring frame 30, the contact pins 26, 27 are pressed in the direction of the contact 25 until their Heads 31, if the position of the contact 25 allows, rest against the setting part 28. If the measuring arm 9 with its contact 25 comes into contact with the contact pin 26, then the green signal light 23 on the dial gauge 20 lights up and contact is made 25 in contact with contact 27, then the red signal light 24 lights up.

When applying the rim 32 to be checked for permissible runout, one Vehicle wheel 33 to the measuring device described, or vice versa, is the probe arm 3 with the feeler roller 5 around the axis 6 in the direction of arrow 34 against the action of the compression spring 12 pivoted. Due to the pressure of the spring 13, the measuring arm 9 follows the probe arm 3 or its arm part 8.

The measuring frame 2 remains in its position because the compression spring 7 is stronger than the compression spring 12.

As soon as the probe arm 3 has covered a short pivoting path, the contact 16 hits the end 15 of the contact spring 14, and the electromagnets 18 respond. The measuring frame 2 is thus at the Base plate 1 held magnetically. If the probe arm 3 is moved further in the direction of arrow 34, it strikes the contact 16 with the end 15 of the contact spring 14 on the contact 17. Through this the electromagnet 19 is excited and the measuring arm 9 is held on the measuring frame 2. At the Hitting the contact 16 on contact 17 is the pointer 21 of the dial gauge 20 on the Moved to zero position 22 of the dial gauge. At the same time, the contact 25 on the measuring arm 9 touch the contact pin 26 so that the green signal light 23 lights up, and will press the contact pin 26 against the action of its contact spring 30 to the outside.

The distance between the head 31 of the contact pin 26 and the adjustment part When contact 16 hits contact 17, 28 is the same as that set on vernier 29 Value. The contact pin 27 is at the same time under the action of its contact spring 30 followed the contact pin 25, but only until the head 31 of the contact pin 27 strikes the adjustment part 28. The remaining distance between the contact pin 27 and contact 25 is equal to the value set on vernier 29, with for Determination of whether the permitted stroke of the workpiece is exceeded, the set one The value on vernier 29 corresponds to the maximum allowable stroke.

After the probe arm 3 or its arm part 8 strikes the contact 17 is, with a further movement of the probe arm 3 in the direction of arrow 34 with the probe arm the measuring frame 2 taken along against the action of the electric magnets 18. The zero position the dial gauge remains. Only when the probe arm 3 comes from one position the rim 32, in which it indicates the slightest run, by the spring 12 against the direction of arrow 34 follows a stroke of the rim 32, the measuring arm 9 is through the Arm part 8 of the probe arm 3 against the action of the electromagnet 19 and opposite the magnetically held measuring frame 2 is pivoted. This pivoting will transferred to the dial gauge 20, the pointer 21 of the deviation of the run from the smallest Indicates blow. When the impact tolerance set with the Nonins 29 is exceeded strikes the head 31 of the contact pin 26 on the setting part 28, at the same time open contacts 25 and 26, the green signal light 23, which has been lit up until then, goes out, the contacts 25 and 27 have come into contact at the same time, and the red signal light 24 lights up.

After removing the vehicle wheel 33 from the feeler arm 3 this goes into back to its original position, contacts 15 and 16 open, causing the electromagnet 18 and 19 are de-energized and the measuring frame 2 moves under the action of the spring 7 applies to the stop 35 on the base plate 1. By arranging a switch in the line exciting the electromagnet 19, it is possible to close this line interrupt so that the measuring arm 9 is no longer attracted by the electromagnet 19 will.

The measuring arm 9 thus exactly follows the probe arm 3, and the dial gauge 20 shows the respective impact on which the probe arm 3 is currently located. This is it is possible to determine the exact location of a field.

As a result of the independent articulation of the measuring arm in one direction 9 from the probe arm 3 is achieved that the measuring arm 9 from the arm part 8 of the probe arm 3 against can be pivoted in the direction of arrow 34, but no longer in the direction of arrow 34.

The dial gauge 20 thus always remains at the ranged largest Impact of the workpiece when it is rotated. When the permissible impact tolerance, the red signal light remains on.

Instead of the vehicle wheels, the measuring device according to the invention can of course also be used successfully on other round parts.

Claims (11)

Claims: 1. Device for measuring the vertical and / or lateral runout of round workpieces, in particular of automobile wheels, with a mechanical with a measuring device, preferably a dial gauge, cooperating probe arm, the the rotating workpiece scans under the action of spring pressure and the transmits its movements to the measuring device, and with means by which the measuring device is automatically set to the zero position, characterized in that that formed as a two-armed lever on a fixed base plate (1) of the device Probe arm (3) pivotable about an axis (6) attached to the base plate and the Measuring device (20) on a counter-acting around the same axis (6) in one direction Spring pressure pivotably articulated movable measuring frame (2) are arranged, furthermore, that the one lever arm of the probe arm, which is mechanically connected to the measuring device is supported against spring pressure in both directions on the measuring frame (2) is and arranged between the probe arm and the measuring frame (2) contacts (15, 16) are connected to the electromagnet (18) arranged on the measuring frame (2). 2. Apparatus according to claim 1, characterized in that one by the probe arm (3) actuated, known measuring device (20) for the optical Display (23, 24) of the exceeding of an adjustable limit stop (26, 27) Tolerance range is provided. 3. Device according to claims 1 and 2, characterized in that that the lever arm of the probe arm which interacts with the measuring frame (2) of the device (3) of two in one direction independently around those on the base plate (1) the device arranged axis (6) pivotable arm parts consists of which one arm part (8) is firmly connected to the other lever arm of the probe arm and the other arm part as the measuring arm (9) with the measuring device arranged on the measuring frame (2) (20) is connected. 4. Device according to claims 1 to 3, characterized in that that an electromagnet (19) is provided which connects the measuring arm (9) to the measuring frame (2) couples. 5. Device according to claims 1 to 4, characterized in that that the contacts (15 to 17) a stop between the fixed arm part (8) and form the measuring frame (2). 6. Device according to claims 1 to 5, characterized in that that the measuring device (20) consists of a dial gauge that od via pinion, lever. Like. Is connected to the measuring arm (9) and which assumes its zero position when the Measuring arm (9) with the one fixed on the probe arm (3) Arm part (8) together on Measuring frame (2) strikes. 7. Device according to claims 1 to 6, characterized in that that the free end of the measuring arm (9) has an electrical contact (25) which in both directions of movement of the measuring arm with arranged on the measuring frame (2) through a vernier (29) or the like. Adjustable mating contacts (26,27) there is contact. 8. Device according to claims 1 to 7, characterized in that that the adjustable mating contacts (26, 27) 27) are resiliently resilient in the opposite direction are hinged to the measuring frame (2). 9. Device according to claims 1 to 8, characterized in that that a switch is provided through which the measuring arm is held on the measuring frame (2) Electromagnet (19) can be switched off. 10. Device according to claims 1 to 9, characterized in that that the pressure force between the probe arm (3) and the measuring frame (2) arranged Springs (12, 13) is less than the force of the electromagnet (18), the force of the The spring (12) is stronger than the force of the spring (13) and the electromagnet (19) together. 11. Device according to claims 1 to 10, characterized in that that a spring (7) is arranged between the measuring frame (2) and the base plate (1) is, which pushes the measuring frame (2) in the direction of the largest stroke of the workpiece. ~~~~~~~ Publications taken into consideration: German Patent Specifications No. 842853, 902791; German interpretation document No. 1 015229.