DE854584C - Device for measuring the circumference of round bodies, such as bolts, bearing shells, shafts or the like. - Google Patents

Description

Device for measuring the circumference of round bodies such as bolts, bearing shells, Waves or the like

The present invention relates to a device for measuring circumference of round bodies, such as bolts, bearing shells, shafts or the like., with one to the to measure the circumference of the test object and by a movable measuring slide too exciting band.

The invention consists in that between the carriage and his Actuating member is arranged a spring. The one opposite the measuring slide The end of the spring is attached to an eccentric pin, and this in turn is on arranged a swivel body which can be adjusted by a hand lever. In addition, the eccentric bolt is attached to a swivel body in a radially adjustable manner.

The measuring tape is tensioned by the spring with a soft force, and there is no need for the worker to fear that he might lose the tape at something too coarse displacement of the measuring slide tears off by hand or the tape with the Time extends so far that the measurement accuracy suffers. Also the spring tension be set so that 14. always the tension tensioning the tape at the time of measurement is exactly the same. This also increases the measurement accuracy. Another advantage the arrangement made is that the measuring device is also used by unskilled workers fail to deal immediately, and due to the low demands on the Care must be taken in handling the device also in the measuring process self accelerated. The arrangement of a dial gauge also contributes to this, because it is on one the measured value can be read faster and more reliably than z. B. on a vernier, as is the case with the known measuring devices of a similar type.

In the drawing, a device according to the invention is in one Exemplary embodiment shown, namely Fig. I and 3 show a plan view a device for measuring the circumference of bearing shells with two different positions of the measuring device; Fig. 2 is a longitudinal section through the measuring device along the line II-II from Fig. 1; Fig. 4 the dial gauge with a measuring slide stop located in front of its sensor, in single representation, seen from above; Fig. 5 shows a cross section through the measuring slide and its storage; Fig. 6 and 7 the suspension and tensioning device for the measuring slide spring of the device in longitudinal section and in plan view.

Figs. 4 to 7 are larger than Figs. I to 3 Drawn to scale and Figs. I to 4 are somewhat more schematic than Figs. 5 to 7 held.

As shown in Figs. I to 3, the measuring device consists of a short one Feet 1 provided plate 2, of which a longer arm 2a in the same plane protrudes. A longitudinally guided measuring slide runs on the plate 2 and its arm 2a 3 with a front stop 4 and a rear angled end 5. The stop 4 is located in front of the sensor 6 of a dial gauge 7, which is from a protruding from the plate 2 Web 8 is held. In the bend 5 of the measuring slide 3 is the end of a Suspended spring g, the other end of which is held by a pin 10. The cone 10 sits eccentrically on a rotatably mounted disc I I, which is under overcoming a self-locking can be pivoted by a lever arm I2. Before the attack 4, a clamping device I3 for a measuring tape 14 is arranged on the measuring slide 3. The measuring tape I4 forms a loop 14a over the plate 2, and its second end is firmly clamped at 15 above the plate 2 at the same height as on the measuring slide 3. Approximately in the middle of the loop I4a is under the same on the plate 2 an interchangeable and, if necessary, adjustable within the plate level Centering device I6.

As Fig. 5 shows in detail, the carriage 3 is on balls 17 mounted, the rails I8 attached to the plate 2 and its arm 2a to run. Furthermore, as a suspension member for the spring g on the pin Ioein U-bracket 19 (Fig. 6 and 7) arranged, which is with its legs on the side of the frame 2a the plate 2 leads and the web is provided with a cross section 20 (Fig. 7).

This slot is penetrated by a convex lining 21 (Fig. 6), which on the pin 10 is pushed.

The pin 10 sits radially adjustable in a slot 22 (Fig. 6) the disk II.

The handling and mode of operation of the devices described is as follows: The hand lever 12 assumes the position shown in Fig. 3.

The spring g is in this position of the pin 10 on the disc I I relaxed, and the measuring slide 3 is against the fixed clamping point I5 of the measuring tape 2 moved forward. The clamping point has changed accordingly 13 approached on the measuring slide 3 of the clamping point 15, and the measuring tape loop 14 is freely floating above the centering device I6. As a result of the rapprochement of the two clamping points I3 and I5 of the measuring tape, the loop I4a has so wide open that the workpiece to be tested, z. B. a bearing ring 23, easily placed in the loop 14a and placed on the centering device can. Once this is done, the lever I2 turns into that shown by the Fig Swiveled position. As a result, the spring g is tensioned, the measuring slide 3 becomes shifted back towards the disk I I and at the two ends of the measuring tape at the clamping points I3 and 15 exerted a tensile force because when going back of the slide 3 remove the two clamping points mentioned from each other.

As a result, the loop 14a is pulled together and the latter lays close to the circumference to be measured of the workpiece 23. When the slide is going back 3, the stop 4 approaches the sensor 6 of the dial gauge 7, which is set in such a way that that their pointer z. B. assumes the basic position a. It corresponds to this pointer position that position a 'of the stop 4 relative to the dial gauge sensor 6, in which the Stop 4 just touches sensor 6.

The displayed measured value a on the dial gauge simultaneously represents the the outer dimension of the circumference to be measured, while the inner dimension is determined by the position of the pointer b is displayed, which corresponds to the stop position b '. The position c of the dial indicator pointer indicates the nominal size. It corresponds to the position c 'of the stop 4. Touches the Stop 4 does not touch the dial gauge sensor at all, the dial gauge pointer remains in its set basic position are immediately in front of the set value a, and the workpiece is to be assessed as scrap. The latter is also the case when the stop 4 is moved beyond the position b 'and the pointer over the Position b be pivoted out.

It is not necessary for the clock hand to be straight when measuring plays over the scale section shown in the drawing. Rather, it can any conventional dial gauge can be used, the pointer of which is released Sensor z. B. goes back to position d. The pointer then strikes when it is accepted the same tolerance limits just around the angle e or e '. So it's the reading the set tolerance values are not tied to a specific scale segment. The dial gauge can also be replaced by a display device whose pointer moves along a straight line, or instead of the pointer device, a Writing implement or an electrical device arranged with a light indicator be. The tension spring g can also be replaced by an analogously arranged thrust spring will.

In the device described there is still an advantage in that when the pointer of the dial indicator only moves over a short section of the dial and when releasing the dial gauge sensor, e.g. B. when replacing the tested workpieces, does not play across the scale several times. This becomes the clockwork of the clock extremely spared. Instead of the wide measuring tape, within the scope of the invention a wire can also be used, which is particularly useful when the The circumference of a thread core, a thread flank or a narrow groove is measured shall be. Appropriate as material for the measuring tape or for the measuring wire, but at least for the piece of the to be laid around the circumference to be measured Spring steel measuring tape used.

PATENT ANALYSIS 1. Device for measuring the circumference of round bodies, such as bolts, bearing shells, shafts or the like. With a to be measured scope of the Test specimen to be laid around and to be tensioned by means of a movable measuring switch Band, characterized in that between the carriage (3, 4, 5) and its actuator (12) a spring (g) is arranged.

Claims (1)

2. Measuring device according to claim I, characterized in that the the measuring slide (3,4,5) opposite end of the spring (g) on the eccentric pin (Io) of a swivel body (II) is attached, which is adjusted by a hand lever (I2) will. 3. Measuring device according to claims 1 and 2, characterized in that that the eccentric bolt (Io) holding the spring (g) in relation to its swivel body (11) is radially adjustable (22). 4. Measuring device according to claims 1 to 3, characterized in that that as a suspension element for the tension spring end (9) on the eccentric bolt (I0) on the frame (2a) of the measuring device longitudinally guided U-bracket (19) is used, whose web with a transverse slot (20) is provided, through which a spherical bearing chuck (2I) of the eccentric bolt (1 o) protrudes. 5. Measuring device according to claims 1 to 4, characterized in that that the spring (9) the measuring slide (3 to 5) in the tensioned state against the feeler pin (6) pulls a dial gauge (7) which is set so that its pointer is relaxed Spring (g) or, if the slide is moved away from the dial indicator (7), in a small amount Distance in front of or exactly in zero position, while he is with the spring tensioned the size of the approach of the measuring slide to the dial gauge, as far as this is about the to be measured workpiece looped measuring tape allows, so that on the dial gauge the measured value can be read off precisely. 6. Measuring device according to claims 1 to 5, characterized in that that the dial gauge (7) between the measuring slide spring (9) and the measuring slide (3 to 5) a measuring slide guide (8) is attached and between this and the measuring tape attachment (I3) a stop (4) for the filling pin (6) of the dial gauge (7) is provided on the slide is.