DEP0002496BA - Precision measuring device for tactile measurements - Google Patents

Description

The usual precision measuring devices for tactile measurements are provided with incised scales and the special fine parts (micrometer cones, verniers, etc.) also have incised graduations that are exposed and exposed to soiling and various damage during use. In addition, the precision of the graduation demands that very thin scratches are used, which are difficult to see even for the healthy eye in poor lighting, but force most users to wear glasses. The periodic use of glasses in workshops is extremely troublesome, especially since it often has to be done with dirty hands.

All of these deficiencies make a remedy appear desirable. According to the invention, one remedy is that the precision measuring device is provided with a counter showing numerals for displaying the measurement result. The display of such a counter can easily be made extremely well recognizable by making the most possible use of the available space, strong numerical design (the line thickness no longer plays a role) and high-contrast contrasting of the numerals from the background. If the counter is enclosed in a housing with a window, the risk of soiling is avoided and good readability is ensured for a long time.

The setting movements of the measuring device itself are used to advance the counter. To accommodate the counter, at least the handle of the device is suitable, and if the measuring device is a screw micrometer, a particularly advantageous arrangement of the counter results if it is provided coaxially to the measuring pin, which is enclosed by the ring-shaped discs of the counter. Further details and parts of the invention can be found in the following text and the drawing, which shows the application of the invention to a screw micrometer. Show it:

1 shows a longitudinal section through a screw micrometer equipped according to the invention, greatly enlarged,

FIG. 2 is a plan view of the screw micrometer according to FIG. 1, partially with the jacket sleeve removed,

3 shows a view of the screw micrometer according to FIGS. 1 and 2 in approximately natural size.

In the screw micrometer according to Fig. 1-3, a threaded sleeve 2 is rotatably mounted in the measuring bracket 1, the internal thread of which cooperates with the external thread m the rear part of the measuring pin 3, which is itself supported by a screw 4 of the measuring bracket, which is inserted into the groove 5 in the front, stepped part of the measuring pin is immersed, is secured against rotation. The rear end of the threaded sleeve is clamped by a slotted, externally conical sleeve 6 to a roller 8 surrounding this, which has a section provided with numerals on the front part; the clamping tightening of the edge nut 7, which is screwed onto the rear threaded part of the tapered bushing. The digit roller 8 is of the, at the same time forming the handle of the device

Surrounding jacket sleeve 9, in which an axially parallel recess allows only one rectangular part of the number cylinder 8 corresponding to a single row of numbers to be visible. In addition to the numbers already mentioned, the roller 8 also has ten evenly distributed circumferential lines 21 forming a ten-thread screw, the beginning of a circumferential line and the end of the adjacent line being on the same cylinder generating line and the start and end points of the circumferential lines being on two circumferential circles of the roller 8, the distance between which is equal to ten graduation lines on a division which is applied to the upper edge 22 of a window covering the above-mentioned recess rectangle 10. The lines 21 cooperate with the graduation marks on the window edge like a nonius. One graduation line at the edge of the window corresponds to z. B. one hundredth of a millimeter, one rotation of the roller 8 by 36 ° (one tenth of a full revolution) one tenth of a millimeter; the labeling of the peripheral fields between the peripheral lines 21 is corresponding. In this way, the tenths of a millimeter can be read with digits; the hundredths can only be recorded in a vernier-like manner, but due to the length of the window and the distance between the graduation marks 22, this acquisition can be carried out much better than with the vernier devices of known measuring devices.

The described equipment of the digit roller 8 thus allows the numerical determination of a measuring pin feed of less than 1 mm in a clear and safe manner. The following device is used to display the entire millimeter of feed. A cam ring 11 (with a cam 11a directed to the right) is axially displaceable within the roller 8; it is inevitably connected by the driver pin 12 to the roller 8 in a radial relationship. In the measuring bracket sleeve 1 sits a control pin 13 which protrudes into the path of revolution of the cam 11a and pushes it (including the cam ring 11) after each full revolution of the roller 8 to the left against a ring 14 (raster ring) provided with 10 notches, namely so far that the ratchet ring comes out of the area of a control pin 15 and, due to a compression spring, the next notch of the ratchet ring 14 jumps back to the control pin 15. The detent ring 14 is positively radially connected to a number roller 17 surrounding it by a driver pin 18; With each step of the notch roller 14, the number roller 17 (corresponding to a conventional decimal disc of a counter) is rotated by a tenth of its circumference and the next higher unit digit appears in the reading window.

The same arrangement has been made for the digit roller 17 'of the next higher order (a tenth of a turn corresponding to a measuring pin feed of 10 mm). A cam ring 11 'works together with the raster ring 14' in the already known manner via a control pin 13 'and rotates this further by one notch after each full revolution of the number roller 17. Due to the driver pin 15 'and the compression spring 16' as well as the driver pin 18 ', the number roller 17' must then continue to rotate by a tenth of its circumference.

As with conventional screw micrometers, the grip bolt 20 is not necessarily connected to the measuring bolt here either, so that the measuring pressure does not exceed a certain value or. every measurement can take place at the same measuring pressure. However, while in known measuring devices a coupling that is flexible in only one direction of rotation is used, in the example shown a slip clutch that acts in both directions of rotation is used. This is formed by parts 23, 24 and 6 det, where part 23 represents a ring which is arranged between the nut 7 and the tapered bushing 6 and enables the bushing 6 to be jammed with the roller 8 as an abutment on the nut 7. The ring 23 is provided with a tangentially inserted, spring-hard steel plate 24, which lies in an axially continuous groove and exerts a certain pressure on the circumference of the grip bolt part enclosed by the ring 23. This handle bolt part is designed as a regular, in the present case hexahedral prism; During its rotation it takes the steel plate 24 and with it the clamped parts 2, 6 and 8 with it only as long as the counterpressure on the steel plate 24 remains below the intended maximum pressure; If this is exceeded, the prism bolt jumps one area further, etc. The jacket sleeve 9 is secured against turning by the adjusting ring 18a and the screw 19 (on the measuring bracket).

The threaded sleeve 2 can be determined at any time by means of the ring 25, as is also provided in the case of the known screw micrometers, so that the measurement result can be viewed in peace and also accessible for later control.

In the example shown, a further advantageous device is also made. The measuring pin 3 and the measuring pin 26 located in the bracket 1 can be provided with slots in each of which a measuring tongue 27 intended for internal measurements is pivotably mounted about a pin 28 and can be locked in its respective position by bushings 29. For this purpose, the bushes 29 are also provided with slots on their circumference, into which the measuring tongues 27 can be folded back by 180 °, the tongues then exposing the test surfaces of the measuring pin 3 and the measuring pin 26 in order to be able to take external measurements. The particular advantage of this facility is among other things. also in the fact that in both end positions of the tongues, i.e. for inside and outside measurements, the measurement result is the same and not, as with conventional slide calipers when the same legs are used twice, the reading amount for the two types of measurement by a certain amount, usually 10 mm, is different.

As is well known, with internal measurements one must first set a smaller diameter and gradually enlarge it until the intended measurement pressure is reached, while it is the other way around with external measurements. So if a measuring device is to be used equally well for both purposes (which is particularly favorable here due to the pivoting tongues), a slip clutch acting on both sides is also particularly valuable because it is only through it, in cohesion with the pivoting tongues, that it can really be used on an absolutely equal basis of the measuring device for indoor and outdoor measurements is secured.

The invention can also be used with other precision measuring devices for tactile measurement curiosity, i.e. also with slide gauges, height measuring devices, etc., with similar advantages as with screw micrometers, whereby analogous, but within the inventive concept, modifications and adaptations may be necessary or expedient. So z. B. one can make the application on slide gauges in such a way that the back of the measuring ruler is toothed and the movable leg is moved by turning a toothed wheel on this toothing, the rotation of the toothed wheel representing the setting movement of the measuring device that is transmitted to the counter. The use of the counter instead of the scoring scales is particularly advantageous in that adding a single additional decimal disc to the counter increases the measuring range of the device tenfold, but the space required by the counter increases very little. However With long slide gauges, it will be necessary to be able to disengage the setting movement and the counter so that the counter does not have to go along with it over the entire displacement path for large displacement paths of the movable leg, but z. B. the coarse adjustment can be done by whole centimeters in the disengaged state of the counter and the latter can be brought to the correct centimeter position for fine adjustment by direct rotation of the counter disks.

The tongues 27 according to the invention can also be used with advantage in slide gauges. As already mentioned, the common slide gauges mostly allow outside

and inside measurements with the same legs, which are then usually made exactly 5 mm thick, so that the unavoidable difference in both types of measurement makes up the round sum of 10 mm.

If, however, pivoting tongues are used that dip into the legs, similar to the screw micrometer shown in the drawing, the need for differential compensation and the constant attention required in this regard are completely eliminated.

Claims (12)

1.) Precision measuring device for tactile measurements, characterized in that it is provided with a counter showing numerals, which is actuated by the <not readable> of the measuring device, for displaying the measurement result. 2.) precision measuring device according to claim 1, characterized in that the counter is housed in the handle of the precision measuring device. 3.) Precision measuring device according to claim 1 to 2 in the form of a screw micrometer, characterized in that the counter is arranged coaxially to the measuring pin (3) of the micrometer and the measuring pin is enclosed by the annular discs of the counter. 4.) Screw micrometer according to claim 3, characterized in that the lowest order tens wheel of the counter consisting of tens disks (possibly the two lowest order tens wheels) is replaced by a cylinder part (8) which is provided with ten evenly distributed circumferential lines forming a ten-thread screw which cooperate like a nonius with a division of ten on the edge (22) of a window that releases the display of the measurement result, the latter being cut out in a cover surrounding the counter. 5.) Screw micrometer according to claim 4, characterized in that the beginning of a circumferential line and the end of the adjacent line are on the same generatrix of the cylinder part (8), and the start and end points of the circumferential lines are on two circumferential circles of the cylinder part (8), the distance between them is equal to ten tick marks on the window edge division. 6.) screw micrometer according to claim 4 and 5, characterized in that the incrementation of the ten disks of the counter is carried out by pairs of rings (11, 14 and 11 ', 14') located within the ten disks, which by cams and detents the disk in question by a tenth continue to rotate their circumference when the disk of the next lower order BEZW. of the cylinder part has completed a complete rotation. 7.) Screw micrometer according to claim 3 to 6, characterized in that the rotating adjustment movements are transmitted to a rotatably mounted threaded sleeve (2), the internal thread of which cooperates with the external thread of the measuring pin (3), which is itself secured against rotation. 8.) Screw micrometer according to claim 1 and precision measuring device according to claim 1 and 2, characterized in that the probe parts touching the material to be measured (measuring pin, measuring pin, slide gauge legs, etc.) are equipped with pivotable tongues (27) which, during external measurements, are inserted into the body of the probe parts (16) are swiveled in and inactive, while they are swiveled out during internal measurements and form the direct tactile organs. 9.) Precision measuring device according to claim 8, characterized in that the test lines of the tongues are flush with the touch surfaces of the touch parts in the pivoted-out position. 10.) Precision measuring device according to claim 8 and 9, characterized in that the tongues (27) are secured in the swiveled-out position by recessed sleeves (29) which are pushed over the probe parts, 11.) precision measuring device according to claim 1 to 9, characterized in that the adjustment movements via a sliding clutch (23, 24, 6) effective on both sides on the BEZW. the organs of touch are brought into action. 12.) Precision measuring device according to claim 11, characterized in that the slip clutch consists of a prism on which a spring plate (24) mounted in the ring (23) surrounding the prism rests.