DE1045669B - Device for determining the mean diameter of threads - Google Patents

Description

Device for determining the mean diameter of threads The invention relates to a device for determining the mean diameter of threads, which are known to come from a device for measuring material thicknesses consists of two opposite legs, each carrying a button, of which the rope engages in the thread and with the opposite flanks two consecutive threads comes into contact while the other the thread takes up and with the two flanks one and the same thread turn comes into contact, whereby the two buttons are axially adjustable against each other, a common plane of symmetry and beveled, by plane, perpendicular to the axis of motion the stop surfaces extending from the button have limited ends of the same slope as the threads and of a length which is only a fraction of the height of the Threads.

It has been found that to achieve the greatest possible Measurement accuracy is required, the height of the beveled surfaces of the stylus by to make the theoretical height of the threads to be measured dependent and this To give ratio a very specific critical value. According to the invention thus, for this purpose, the height of the beveled surfaces of the buttons is chosen so that it is two tenths of the theoretical height of the threads to be measured.

The drawing shows an exemplary embodiment of the subject matter of the invention, namely, Figs. 1 to 4 are diagrammatic views, on an enlarged scale, which show the obliquely truncated ends of the thread engaging or the thread representing the receiving organs of the buttons, Fig. 5 is a side view showing the Measurement of the mean diameter of a thread by means of a probe according to Fig. 4 reproduces, Figs. 6 and 7 are a side and an end view of the thread receiving Feeler element, Fig. 8 is a side view of a dial gauge with a feeler according to the invention, 9 shows a section along line TX-IX in FIG. 8, FIG. 10 is a schematic representation of the thread measurement, FIG. 11 is a partially sectioned one Side view of a micrometer screw according to the invention, FIG. 12 a section along line XII-XII in Fig. 11, Fig. 13 is a plan view of the central part of the micrometer screw, 14 and 15 are a front and a side view of a side part of the micrometer screw, 16 shows a partial view of a slide caliper according to the invention and 17 is a section along line XVII-XVII in Fig. 16.

In the embodiments according to FIGS. 1 to 4, 1 is the thread engaging and 2 the sensing element receiving the thread. These organs of touch are arranged opposite one another so that the plane of symmetry of the thread receiving feeler also the plane of symmetry of the engaging in the thread The tactile organ is, the tactile organs extending in opposite directions.

In the case of measuring external threads, e.g. B. on screws or bolts certain buttons (Fig. 1, 2 and 4) have the bevels 3 and 4 advantageously flat and mutually parallel boundary surfaces 5 and 6.

With probes for measuring internal threads z. B. in bores (Fig. 3), on the other hand, surfaces 5 and 6 are surfaces of revolution.

In the embodiment of Fig. 1, the beveled ends have 3 and 4 of the tactile elements 1 and 2 prismatic shape, while the end surfaces 5 and 6 run perpendicular to the common plane of symmetry of the tactile organs 1 and 2. at the embodiment of FIG. 2, the ends 3 and 4 are truncated cones, their axes are parallel to each other and to the aforementioned plane of symmetry.

In the embodiment according to FIG. 3, the end parts 3 and 4 are conical and the surfaces 5 and 6 cylindrical, the axes of these surfaces being perpendicular to the mentioned plane of symmetry run.

Finally, FIG. 4 shows an embodiment in which the in the thread engaging feeler element 1 corresponds to that of FIG. 2, while the sensing element 2 accommodating the thread is similar to that of FIG.

The practical implementation of the invention is below for the Case of the tactile organs like those of FIG. 4 explained. But these apply Explanations of course also for tactile organs according to FIGS. 1 and 2.

The tactile organs 1 and 2 are connected to two cylinders 7 and $ (Fig. 5, 6 and 7) which are attached to a measuring instrument for material thicknesses, which will be discussed further below. That way the two can Cylinders 7 and 8 are displaced along their axes 11 and 12. The distance of the opposing end surfaces 5 and 6 is first determined by doing this Bringing surfaces into contact with a prismatic wedge of calibrated thickness. This calibrates the ringing instrument. 13 is the thread (for example a Screw), from which the mean diameter d is to be determined. p is the Gangh (iheh the theoretical height of the thread turns and a the flank angle. The organs of touch 1 and 2 are selected according to the values of p and a. The bevels of the Touch organs 1 and 2 determining the angle must be equal to, while the mean diameter determined by 3 and the mean distance of the inclined surfaces 4 as a function of p so that there is a contact over the full length of the inclined surfaces and the thread flank is available.

This contact is on either side of the vertical line b, which is on the mean diameter is located on the generatrix of the inclined surfaces 3 and 4 available. When the tactile organs are in the position according to the thread 5, it is only necessary to determine d read the distance between the opposing surfaces 5 and 6 and to do so half the sum of the heights of the inclined surfaces 3 and 4, which is expediently equal to! i / 10 is to add.

In the manner described, the measurement can be made very quickly, very easily and still be carried out with great accuracy. When the thread axis does not run exactly perpendicular to the axes 11 and 12, this does arise only a very small reading error, because the end surfaces 3 and 4 only a small one Have expansion. For the same reason it is possible to take measurements with good accuracy even with threads, the threads of which are outside by an electrolytic Order 15 are deformed (Fig. 10). The contact with the flanks of the thread namely takes place in the least deformed places, and the entry of the The thread turn in the feeler element receiving the thread remains despite the order 15 possible because of the distance between the opposing surfaces 4.

The accuracy of the measurement depends on constant conditions on the accuracy with which the material thickness measurements are made by means of the device carrying the probes can perform.

For measurements of particularly high accuracy one uses one usual dial gauge (Fig. 8), the supports of which are designated by 21 and 22 and bearing sleeves carry, in which the coaxial rods 23 and 24 can be moved, the end in stop pieces 25 and 26. 17 is the drum of the micrometer screw and 18 the knurled button, by means of which the rod 23 is displaced in its longitudinal direction can be. According to the invention, the carried by the cylinders 7 and 8 in the Thread engaging or the same aufnellineilele tactile organs with the stop pieces 25 and 26 connected by means of sleeves 27 and 28 and clamping screws 31 and 32. Appropriately, the sleeves. such as B. the sleeve 27, in its interior two in the Ribs 33 running in the longitudinal direction, which are symmetrical with respect to the clamping screw 31 are arranged.

The centering and fastening of the tactile organs thus takes place under very favorable conditions. During the measurement, the thread is taken from the console 35 worn, which can be adjusted by means of the screw 36 to the desired height can. The accuracy achieved under these conditions is about 1 micron.

Buttons according to the invention can also be attached to a micrometer screw be attached, as shown in FIGS. 11-15. In this embodiment the cylinder 7 carrying the probe element 1 engaging in the thread can be inside the bearing sleeve 41 of the bracket 43 with the aid of a clamping screw 45 in any position to be established.

The cylinder 8 can receive an axial displacement movement, and with the help of the microineter screw 46, the one with the knurled knob 47 and the one with a division provided drum 48 is in communication. Appropriately directed the sensing element 2 accommodating the thread by itself. To this end can be the cylinder 8 rotate freely in a hollow cylinder 49 which is mounted in the sleeve 51 which extends the bracket 43 and is provided with a threaded ring 52. aside from that the cylinder 8 is held in the sleeve 49 by a spring 53, which is supported on a sleeve 54 with a flange ring 55. The sleeve 54 is with the help of projections 56, which can engage in recesses of the cylinder 49, in releasably attached to this cylinder. So by simply turning the Flange 55 separate the sleeve 54 from the hollow cylinder 49, whereupon the cylinder 8 can be pulled out and replaced by a similar camel, which has a different, the thread receiving stylus carries. In addition, the entire micrometer screw easily peeled off after the ring 52 is loosened '.

In order to measure the thread resting on the bracket 61, this scanned by the tactile organs 1 and 2, the tactile organ 2 automatically in sets the desired direction to follow the slope of the threads. With With the help of this device it is easily possible to achieve an accuracy above 0.01 mm to be achieved.

To carry out faster measurements, the invention provides the attachment the sensing elements on the legs that engage in the thread or receive it 71 and 72 of a slide gauge 73. In this case the button parts have beveled the profile shown in Fig. 1. The tactile organs are located on sleeves 75 and 76 (FIG. 16), which are releasably attached to the legs 71 and 72. According to the invention these sleeves have a certain amount of play in relation to the said legs. To this In this way, the mutual alignment of the beveled surfaces can be brought about be that the legs 71 and 72 approach each other, so that the inclined surfaces come into contact with each other, whereupon they can be fixed with the help of screws 77, 78, 79 and 80 notices. Because the contact surfaces with the thread ropes on are reduced to a minimum, then there are measurement inaccuracies which are due to an inclined position of the screw are based, in most cases negligible, as these measurement inaccuracies can be kept below 0.05 mm. The measurement using the device according to Fig. 16 is particularly easy and quick.

If the inside measurement of threaded holes is concerned, then it is sufficient it to attach to the legs 71 and 72 touch organs according to FIG. The invention thus offers the possibility of using the usual ones available in the workshop Measuring instruments to make measurements of great accuracy, with some arithmetic work not required silnd. Due to the interchangeability of the tactile organs, the measurement different threads.

Where the set of required to measure all threads is Organs of touch very low because the organs of touch are held only by two factors as usual are determined by three. As a result, the invention is characterized by great economic efficiency the end.

The described exemplary embodiments can be modified, without leaving the scope of the invention. In particular, it is possible for measuring threads with curved flanks, e.g. B. with spherical Threads to form the beveled surfaces accordingly by adding their generatrices have a curved profile.

Claims (10)

PATENT CLAIMS: 1. Device for determining the mean diameter of threads, consisting of a device for measuring material thicknesses with two opposing legs, each carrying a button, of which the one engages in the thread and with the opposite flanks of two successive ones Thread turns comes into contact while the other takes up the thread and with the two flanks of one and the same thread turn comes into contact, the both buttons are axially adjustable with respect to one another, a common plane of symmetry and beveled, by plane, perpendicular to the movement axis of the buttons Stop surfaces limited ends of the same slope as the threads and of have a length that is only a fraction of the height of the threads, thereby characterized in that the height of the beveled surfaces of the buttons is two tenths of that theoretical height of the thread turns to be measured. 2. Apparatus according to claim 1 for measuring the mean diameter of external threads, characterized in that the sloping ends of the buttons through prismatic surfaces are formed. 3. Apparatus according to claim 1 for measuring the mean diameter of external threads, characterized in that the inclined surfaces of the buttons are truncated cones form whose axes run parallel to the common plane of symmetry of the buttons. 4. Apparatus according to claim 1 for measuring the mean diameter of internal threads, characterized in that the engaging in the thread and the thread-receiving button body of revolution around a perpendicular to the common Show the axis of symmetry of the probe. 5. Apparatus according to claim 2 for measuring the mean diameter of external threads, characterized in that the button engaging in the thread has a truncated cone whose axis lies in the common plane of symmetry, while the button receiving the thread has a prismatic surface. 6. The device according to claim 1 with a dial gauge with two legs, each of which carries an axially adjustable stop piece, whereupon a removable Button is attached, characterized in that the connection between the stop piece and a cylindrical rod carrying the associated button through a cylindrical one Sleeve is secured, which rests on both by means of two narrow longitudinal ribs and is fastened with clamping members provided in the plane of symmetry of the ribs. 7. Apparatus according to claim 5 for measuring the mean diameter of external threads, consisting of a screw gauge with two connected by a bracket Legs and a button on each of the legs, characterized in that the Button engaging in the thread with an axially adjustable rod in connection stands, while the button receiving the thread can adjust itself. 8. Apparatus according to claim 7, characterized in that the the Thread-receiving button rotates on a cylindrical inside a sleeve mounted rod is located, the sleeve by means of a bayonet connection detachable ring is closed and the rod is further held in place by elastic organs that are supported on it and the ring, while the bracket of the screw gauge also carries a height-adjustable console. 9. The device according to claim 2 for measuring the mean diameter of external threads by means of a calliper, in which each leg has an adjustable, with a button provided sleeve, characterized in that the plane of symmetry the button contains the two legs. 10. The device according to claim 4 for measuring the mean diameter internal threads by means of a calliper, in which each leg has an adjustable, with a button provided sleeve, characterized in that the plane of symmetry the button is perpendicular to the plane containing the legs. Documents considered: German Patent No. 377 547; U.S. Patent No. 2,410,571; Catalog »Dial Gauges and Measuring Instruments« 51 U and Catalog »Precision Tools« 52 M from Carl Mahr, Esslingen.