DE4412682C2 - Device for measuring eccentrically rotating workpieces - Google Patents

Description

The invention relates to a device for measuring eccentrically rotating workpieces, especially the crank pin of crankshafts.

The crankpin and crankshaft journal, however other, eccentrically rotating workpieces also have to processing as well as after completion of processing Dimensional accuracy can be checked. So far, it has been customary for this Measure point by hand when the workpiece is at a standstill to carry out diameter errors, deviations from the Determine the circular shape and the shape of the cylinder and if necessary to be able to correct.

Due to the high processing speeds in modern, CNC-controlled machining centers means measuring the Workpiece by hand long, the degree of utilization of the Machining center minimizing downtimes.

The measuring device described in DE-OS 35 21 710 is used for  Measurement of the circular shape deviation of eccentric bearing surfaces, but not expressly for checking the dimensional accuracy of the Diameter. However, the device described is also for Suitable to measure the diameter of connecting rod bearings. At a Embodiment is a touch part with a touch edge on one Bearing surface of a connecting rod journal and by means of a guide edge on the side of this bearing surface. Due to horizontal Guides and vertical guides can be found under the Effect of a spring and due to its own weight the Follow the movement of the bearing surface, an electric Length measuring probe emits a measuring signal which corresponds to the movements of the Touch edge corresponds, so that this electrical signal taking into account the crank radius, the radial values of the Have the storage area determined. In this known device the entire stroke of the crankshaft to be measured therefore goes into the path of the length probe, which is therefore a very high must have absolute accuracy if diameter errors, Deviations from the circular shape as well as from the cylindrical shape should be determined and corrected. The touch edge and the Leading edge only take on management tasks and are with the weight of the measuring device and the force of the Spring acted upon, so that it should not be neglected Subject to wear.

A device for measurement described in DE-OS 31 47 424  the radial values of a cylinder, cam or the like a device for compensating for the eccentricity measuring cylinder, cam or the like. Aimed for is that a probe always radially to the center of a Cylinder is directed to the roundness measurement on one Turntable is arranged. This rotating body needs on the Rotary table not to be exactly centered, because with the Turntable a disc is rotatably connected via an axis and on this disc is a cam disc with a cylindrical outer surface is arranged eccentrically and rotatably, which over a Scanning roller, a lever system and one on a cross bar slidably mounted slide with a roller one Transverse movement of the probe device, which affects the Adjust the eccentricity of the rotating body according to size and direction leaves. This known device is used for minor Eccentricities of one arranged on a turntable Compensate the rotating body, so that the plunger of the electrical Length measuring probe also only relatively small Eccentricities must follow. Did you want this well-known Device for measuring a rotating crank pin from Using crankshafts, the stylus should cover the entire stroke of the Pick up the crank pin and small despite this long way Diameter errors and deviations from the circular as well as the Can measure cylinder shape.

The invention is therefore based on the object, a quick and to create a precisely working measuring device in order to avoid any or only brief interruptions in machining the workpiece to reach during the measurement process.

Based on this task, a device of the kind mentioned in the introduction proposed that they According to the invention, a probe arm with at one end arranged probes encompasses the workpiece and the circulation that follows with its other end the movement of the workpiece following on a CNC-controlled in the Y and X direction synchronously and can be moved with the same stroke as the workpiece to be measured Sled is guided on a circular path and one with the measuring probes interacting.

This arrangement is particularly advantageous because the guided end of the probe arm on the carriage one Arrange the CNC-controlled processing unit for the workpiece lets and the existing control for processing of the workpiece can also be used when measuring the workpiece is.

The probe arm can be moved around its guide point at its one End from a rest position outside the range of motion of the Folding the workpiece into a measuring position follows with its  Probe the eccentrically rotating workpiece during a or more revolutions and registered over the Transducer referring to the diameter of the workpiece corresponding angle of rotation, so that in this way shortest time diameter deviations, deviations from the Circular as well as cylindrical when the probe arm is axial is moved along the workpiece to be measured to let. Only the measuring forces act on the probe, since they have no management tasks to take on.

In the case of forced guidance in the Y and X directions, there are no large ones Requirements for the accuracy of the concentricity and the Agreement of the stroke of the positive control with the stroke of the measuring workpiece when the probe on the Work piece approximately diametrically opposite in one through the geometrical center and the Transducer the measured values of the two probes in one Sum circuit processed. In this case there will be deviations in concentricity and / or in the stroke of the positive control of the probe arm in the horizontal by the opposite probe compensated within their measuring range. Wrong movements in perpendicular direction form second order errors that are below the required measurement accuracy.

The probe arm can either be set with an adjustable support  the workpiece or on an adjustable stop on the slide lie on. In both cases, it is guaranteed that the probe in the plane passing through the geometric center Workpiece, apart from the through Concentricity inaccuracies or stroke deviations caused Shifts.

When the probe arm moves from the work area to a rest position is pivotable, this rest position as Use calibration position by in this calibration position a material measure of the workpiece in the area of the probe brought.

The invention is based on several, in the drawing illustrated embodiments of the closer explained. In the Show drawing:

Fig. 1 a arranged on a CNC-controlled machining center for crankshafts measuring device and

Fig. 2 is a detailed view of the probe arm with a different arrangement of the probe.

Eccentrically rotating crank pins 2 are to be measured by a crankshaft 1 clamped centrally to the main bearing journal.

For this purpose, a probe arm 3 is pivoted into the area of the crank pin 2 about a pivot point 8 in the measuring position shown in solid lines, so that an adjustable support 4 rests on the crank pin 2 . In this position, parallel arms 5 extend vertically downward from the probe arm 3 and measuring probes 6 are arranged at their ends. The distance between the measuring buttons 6 can be adjusted to the diameter of the crank pin 2 and both measuring buttons 6 can be moved in the arms 5 . The support 4 is set so that the probe 6 engage the crank pin 2 in a plane running through the geometric center. The measuring buttons 6 are connected to a sensor 7 which evaluates the measured values via a summation circuit. Via the articulation point 8 at the end of the probe arm 3 , the latter is arranged so that it can be swiveled up on a carriage 12 of a processing unit 11 that can be moved in a CNC-controlled manner in the Y direction. On this carriage 12 is z. B. a spindle 13 for receiving drills or milling heads.

Instead of the adjustable support 4 on the probe arm 3 , an adjustable stop 9 can also be provided on the slide 12 , which defines the measuring position of the probe arm 3 .

The probe arm 3 can be pivoted from the measuring position shown in solid lines into a rest position shown in dashed lines outside the working area and is then in contact with another stop 10 . In this position, a measuring standard 17 , the size and shape of which corresponds exactly to that of the crank pin 2 , can be brought into the area of the measuring probe 6 in order to calibrate the measuring arrangement.

The carriage 12 is arranged on a column on a further carriage 14 which can be moved in the X direction under CNC control.

The articulation point 8 can be given the same circular path movement, which also the crank pin 2 passes through when the crankshaft 1 rotates, via the CNC control, which is not shown in detail and is generally customary on machine tools. In this way, the measuring arm 3 with the measuring buttons 6 is synchronized with the crankshaft 1 and positively guided with the same stroke, so that a simple relationship between the angular position of the crankshaft 1 and the measured values can be established.

If the carriage 14, which can be moved in the X direction, is arranged on a further carriage 15 , which can be moved in the Z direction, which can be moved on a machine bed 16 , the entire surface of the crank pin 2 can be moved with the probe arm 3 and the measuring probes 6 , so that Have concentricity, diameter errors and deviations from the cylindrical shape of the spigot 2 measured with great accuracy. Concentricity errors of the articulation point 8 , which result from the CNC control and also stroke deviations when the articulation point 8 rotates, are only extremely negligible in the measurement result, since this results in only slight changes in the angle of the contact points of the measurement buttons 6 or displacements in the ones running through the measurement buttons 6 Straight lines result which are either compensated for by the summation circuit of the transducer 7 or are negligible with regard to the required measurement accuracy.

Instead of arranging the probe arm 3 approximately horizontally as shown in FIGS . 1 and 2, it can also assume any angular position, in particular a vertical position.

None occurs in the measuring device according to the invention Influencing the measurement result by errors from the measuring system the processing machine. Thermal influences can be minimize by having a calibration immediately before Performing a measurement. The evaluation of the Measured values by a computer, not shown, enables a Feedback to the CNC control of the processing machine, which enables automatic error compensation during processing is achievable.

Claims (7)

1. Device for measuring eccentrically rotating workpieces, in particular the crank pin ( 2 ) of crankshafts ( 1 )

• 1. - a probe arm ( 3 ), the
• 2. - grips the workpiece ( 2 ) with measuring probes ( 6 ) arranged at one end and follows the rotation,
• 3. - With its other end ( 8 ), the movement of the workpiece ( 2 ) following on a CNC-controlled in the Y and X directions synchronously and with the same stroke as the workpiece movable carriage ( 12 ) is positively guided on a circular path and
• 4. - with a measuring sensor ( 7 ) interacting with the measuring keys ( 6 ).

2. Apparatus according to claim 1, characterized in that the probe arm ( 3 ) is pivotally articulated at a pivot point ( 8 ) on the slide ( 12 ), the pivot point ( 8 ) being a parallel to the crankshaft axis and horizontally aligned pivot axis when the device is in operational position mediated for the probe arm ( 3 ). 3. Apparatus according to claim 1 or 2, characterized in that the guided end ( 8 ) of the probe arm ( 3 ) on the carriage ( 12 ) of a CNC-controlled processing unit ( 11 ) for the workpiece ( 2 ) is arranged. 4. Device according to one or more of claims 1 to 3, characterized in that the displaceable probe ( 6 ) on the workpiece ( 2 ) lie diametrically opposite in a plane passing through the geometric center and the transducer ( 7 ) the measured values of the two probes ( 6 ) processed in a summation circuit. 5. The device according to claim 4, characterized in that the probe arm ( 3 ) can be pivoted from the working area into a calibration position in which a measuring standard ( 17 ) of the workpiece ( 2 ) in the area of the probe ( 6 ) can be brought. 6. The device according to one or more of claims 1 to 5, characterized in that the probe arm ( 3 ) in the direction of the axis of rotation of the workpiece ( 2 ) (Z direction) is displaceable. 7. The device according to one or more of claims 1 to 6, characterized in that the probe arm ( 3 ) with an adjustable support ( 4 ) rests on the workpiece ( 2 ) or on an adjustable stop ( 9 ) and the probe ( 6 ) are adjustable.