DE803005C - Measuring device, especially for crankshaft journals - Google Patents

Description

Measuring device, especially for crankshaft journals The invention relates on a built-in 1 machine tool measuring device for tenons and shafts and is especially used for measuring in fine drawing grinding machines used crankshafts determined.

According to the invention, the crankshaft to be tested is on three Roller steady rest running bearing rollers, two of which by eccentric bushings are adjustable. These three bearing rollers help you to learn more. Additionally carries the device has a dial gauge for scanning the test object. With the device according to the invention every pin of the crankshaft can be checked to see what dimensions it is after different processing times. In particular, the final dimensions of the precision machined Center bearings should be as equal as possible to one another.

In the drawing, the invention is in one embodiment shown schematically, namely the figure shows a with the measuring device equipped fine drawing grinding machine in cross section.

As the illustration shows, the crankshaft is used as a central bearing three center bearings I, 2, 3 running on roller bezels for the one indicated by dash-dotted lines Crankshaft 4 is provided, which is placed on the bearings from above. Through the Cover 5 of one of the side bearings is a leaf spring 6 clamped, which is attached to her protruding free end carries a double-armed lever 7a, 7b. The one, weird upwardly pointing lever arm 7a is designed as a sensing lever. It protrudes below the crankshaft 4 and carries a stylus 8 at its end. The other, at an angle downwardly protruding lever arm 7b also carries a pin 9, the one in the grinding arm The dial gauge used has an influence. The whole arrangement is supported by a slide 1 1 carried on a bench 12 along a swallow tail guide 13 shifted and fixed in a manner known per se by a clamping screw 14 can be.

The dial gauge 10 is inserted into a bore 15 of the slide 1 1, and for the purpose of its fine adjustment it is stored in a sleeve I6 on the outside is provided with a toothing 17. The external toothing I8 engages in this Adjusting sleeve 19, which also acts as a bearing for a locking pin 20 serves. This passes through a slot 21 arranged in the lever arm 7b (Fig. 2 and 3) and lies with a head 22 behind the lever arm 7b as a rear stop. A pin 24 seated on an eccentric 23 serves as a front locking device.

By adjusting the head 22 and the eccentric pin accordingly 24 the feeler lever 7a, 7b can be precisely adjusted with respect to the dial gauge.

In addition, the head and pin protect the watch from damage. Vice versa can with the help of the adjusting sleeve i6 the clock 10 in its associated bore 15 exactly set and fixed by a screw 25 on the side.

The setting of the bearing washers I and 2 with respect to the sample crankshaft 4 takes place z. B. by eccentric bushes 26, 27 of the associated bearings.

The mode of operation of the described arrangement results from the Drawing without further ado: By means of the sample shaft placed on bearings I, 2 and 3 4, dial gauge 10 and feeler levers 7a, 7b are precisely adjusted. Then the pattern wave exchanged for the shaft to be machined, and the dial gauge then shows the deviations from the sample shaft as long as the diameter of the test object is larger than the the pattern wave. If the diameter of the test object is too small, which results in that simultaneous contact with the previously set bearing rollers I, 2 and 3 no longer takes place, the examinee is deemed to be a committee. By repeatedly measuring of the test specimen during machining, you can read from the dial gauge when the shaft has hit has the desired dimensions after a certain processing.

When using two dial gauges, it is advisable to use a mirror image would be attached symmetrically to the vertical plane of the figure, one could also form errors in the axial direction of the journal to be tested. The clocks can do this be arranged in one plane and their styli are in different planes.

PATENT CLAIM: I. Measuring device built into a machine tool for pins and shafts, especially for measuring the grinding surfaces from into one Precision drawing grinding machine used crankshafts, characterized in that three bearing rollers (I, 2, 3) running on roller steadies, two of which (I, 2) are adjustable are, act as a rider gauge and additionally a dial gauge (10) for scanning the test item is arranged.

Claims (1)

2. Measuring device according to claim I, characterized in that as the measuring device (io) influencing sensor a two-armed lever (7a, 7b) is provided is, whose one lever arm (7a) scans the surface to be tested, while the other Lever arm (7b) influences the dial gauge (Io). 3. Measuring device according to claims 1 and 2, characterized in that that. the feeler lever (7a, 7b) is supported without play by means of a leaf spring (6). 4. Measuring device according to claims 1 to 3, characterized in that that the feeler lever retaining spring (6) through the cover (5) of a steady roller bearing is clamped and held by this. 5. Measuring device according to claims 1 to 4, characterized in that that the feeler lever (7a, 7b) opposite the dial gauge (Io) through a front and rear Lock can be adjusted. 6. Measuring device according to claims I to 5, characterized in that that the front feeler lever lock consists of an eccentrically mounted pin (24) and the rear locking is formed by the head (22) of a pin (20) which penetrates a slot (2I) of the feeler lever (7b). 7. Measuring device according to claims I to 6, characterized in that that the dial gauge (10) except in its associated slide bore (15) in one with an external toothing provided sleeve (I6) is mounted, in which the counter toothing a fine adjustment screw (19) engages. 8. Measuring device according to claims I to 7, characterized in that that the fine adjustment screw (I9) for the dial gauge (10) acts as a bearing for the feeler lever locking pin (20) is formed. 9. Measuring device according to claims I to 8, characterized in that that the roller bezels (I, 2) on z. B. adjustable by eccentric bushes (26, 27) Bearings run in order to be able to adjust the steady rests on an applied sample shaft.