CS237583B1 - Method of timing devices flywhees' flat spiral hairs adjustment especially with clockworks and device application of this method - Google Patents

Abstract

The invention relates to the manufacture of time-measuring instruments, especially clockwork and solves on the one hand, the method of adjusting the flat spiral flywheel hair, and equipment suitable for carrying out the method. The essence of the hair adjustment method The flywheel is that complete flywheel with a hairpin attached to its shaft inserts a shaping template into the notch on which the desired curvature and termination shape is displayed the free end of the thread, and after the exact one aligning the flywheel with respect to its position the shaft and the stub pin to the template makes the spiral termination curve shape according to the shape shown on the template. The essence of the apparatus for carrying out the method is that the forming template 3 is fixed at base 2 such that the forming template 3 a base 2 forms a hollow housing 1. In the cavity of the housing 1, it is mounted on the base 2 a clamping holder 5 of the flywheel 17 provided a hair 19 that is pivoted out of the cavity housing 1. The forming template 3 is provided with a notch 15, into which it is inserted by the clamping holder 5 in the locked position, the flywheel 17 with the hair 19. The surface of the forming template 3 is shown the desired shape of the spiral termination curve a thread 19 according to which the end of the thread 19 with tweezers or others appropriate tool.

Description

SUMMARY OF THE INVENTION The present invention provides a method for adjusting flywheel flat helical hairs, flywheels, and in particular, clockwork devices and devices suitable for carrying out the method.

So far, hair adjustment has generally been performed as follows. Flywheel with impulse pin and spiral hair, the inner end of which is fixed in the bead on the shaft and the outer end bent out of the spiral into the shape of the buttplate defining the required length of the hair, is inserted into the bearings.

The hairpin is threaded through the control lever lock and the outer end of the hairpin is pushed up to the nipple into the hole of the hairpin post, where it is secured with the pin. When the hair is pinned, the basic geometry of the hair spiral is normally violated.

Regularly spiraled spiral threads move to one side, disrupting the flatness of the spiral and creating an axial runout of the hair. These deformations must be removed manually with tweezers, which re-establish the correct shape.

. In this operation, the curve of the outer end of the hair passing through the lock of the control lever is simultaneously shaped. This work is also done manually, with the help of tweezers, but without any other aid that would allow accurate adjustment of the end of the hair.

The operator making this tweezer treatment must ensure that the end curve of the hair spiral is shaped so that the hair is in contact with the lock in the lock during the development of the hair, depending on the flywheel, depending on the motion of the flywheel.

It is clear from the description of these works that these are especially time-consuming and require a great deal of skill and long-term experience. Due to the fact that the adjustment of the hair is carried out experimentally and depending on the individual personal skill of the individual workers, the quality of the adjustment varies considerably from one instrument to another and a high number of defects in the adjustment of the hair is corrected subsequently. special devices.

The invention overcomes these drawbacks, and in particular reduces the effort of adjusting the hair, almost eliminates the need for additional adjustments and allows the use of unskilled, short-term workers.

The solution according to the invention, which removes the aforementioned drawbacks, consists in the method of adjusting the flywheel thread and in the device which is advantageous for carrying out the method.

The essence of the method of adjusting the spiral hairs of the flywheels of the handheld instruments, in particular the clockwork, is that the flywheel provided with an impulse pin and a hair whose outer end is bent out of the spiral into a shape elbow defining the necessary length of the spiral is inserted into the notch the desired shape of covering and ending of the free end of the hair, and after the flywheel has been positioned accurately with respect to the position of its flywheel and start pin relative to the stencil, the shape of the hair spiral termination curve is shaped according to the shape shown on the stencil.

A suitable device for carrying out the method comprises a hollow sleeve consisting of an L-shaped base and a forming template provided with a notch on the periphery for inserting a flywheel shaft with a hair, wherein the base below the forming template has a pivot shaft holder and flywheel pin.

The clamping bracket for the shaft and flywheel pin can be a one-arm lever pivotally mounted on a base, provided at its free end with a fixed clamping jaw with a first prismatic groove corresponding to a flywheel shaft diameter and a movable clamping jaw pivotally mounted on a fixed second a prismatic groove, the width of which corresponds to the diameter of the impulse pin, wherein the prismatic grooves in the clamped state of the fixed and movable jaws and the notch in the forming template are equidistant from the pivot axis of the clamping bracket, and the notch of the forming template is curved along the circle described by the prismatic grooves of both pivoting movement of the chuck.

The fixed clamping jaw and the movable clamping jaw may be connected to each other by a tension spring and the clamping bracket as a whole is connected by another tension spring to the base, the tension force of the tension spring of the clamping jaws being higher than that of another clamping spring.

Advantageously, in the base wall of the adjusting stop there is a stop screw for precisely limiting the adjusting movement of the clamping holder and in the pivoting space of the clamping holder in the base body a support stop for limiting the pivoting movement of the clamping holder outside the housing.

An exemplary embodiment of the device according to the invention is shown in the drawings, wherein FIG. 1 is a plan view of the device for adjusting flywheel hairs with the clamping bracket in the working position; FIG. 2 is a view of the same device with the clamping bracket in the open position; Fig. 3 is a cross-sectional view of the device in plane III-III of Fig. 1, Fig. 4 is a cross-sectional view of the device in plane IV-IV of Fig. 1 and Fig. 5 a detailed view of prismatic grooves of clamping jaws with clamped shaft and a flywheel start pin in cross section.

The device for adjusting the flat spiral hairs of the flywheels of the timing instruments is formed by a hollow sleeve 5 composed of a base 8 having a basic L-shape and a shaping template 6 fixed thereto forming a cover plate of the base 6.

The clamping holder 8 is formed by a single-arm lever 6, on which a fixed clamping jaw 6 is mounted. In the fixed clamping jaw 4, a movable clamping jaw 4, provided with a handle 10, is pivotably mounted on a further pin 4 relative to the fixed clamping jaw 4.

The movable clamping jaw 8 is pulled into contact with the fixed clamping jaw 4 by a tension spring 60 suspended by one end on the movable clamping jaw 9 and the other end on a post 12 connected to the fixed clamping jaw 8.

The clamping bracket 8 as a whole is connected by a further tension spring 13 to a hinge pin 14 fixed in the wall of the base 8. This further tension spring 13 has a lower tension force than the first tension spring 11, preferably half.

The shaping template 8 is provided in the peripheral open portion of the housing 8 with a notch 65 for guiding and aligning the shaft 60 of the flywheel 17 provided with an impulse pin 18 and a hairpin 9.

The width of the notch 15 corresponds to the diameter of the flywheel shaft 16. The desired geometric shape of the curvature 20 of the end of the spiral of the hair 19 is shown on the upper surface of the shaping template 6, for example by engraving or durable drawing.

Other adjusting positions are also indicated by lines on the upper surface of the mold template. The first line 21 is a waste adjustment line and the second line 22 is a line for initial adjustment of the end of the hair 19.

The fixed clamping jaw 4 is provided with a first prismatic groove 23, the width of which also corresponds to the diameter of the flywheel shaft 16, and the movable clamping jaw 4 has a second prismatic groove 24, whose width corresponds to the diameter of the start pin 18.

The axes of the first prismatic groove 23, the second prismatic groove 24, and the notch 15 of the forming template 4 are equidistant from the pivot axis x of the clamping bracket 4, and the notch 15 of the forming template 4 is curved according to the circle described by prismatic grooves 23 and 24 of both clamping jaws 4 and 6. movement of the clamping holder 6.

The thickness of the molding template 6 is chosen to be less than the axial distance of the flywheel 17 and the hair 19.

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In the vertical wall of the base 8, an adjusting stop screw 25 is provided, which protrudes into the inner space of the housing 4 and forms a support stop for the clamping bracket 8 when the flywheel 17 with the hair 19 is brought into working position.

In the pivoting space of the single-arm lever 6 of the clamping bracket 6, a support stop 26 is provided in the base body 6 to limit the pivoting movement of the clamping bracket 7 outside the housing space when inserting a new flywheel 17 with hair 19 into the clamping jaws 6 and 6.

By means of the described device it is possible to make absolutely accurate and practically independent of the skill and experience of the worker the free adjustment of the free ends of the flywheels of the timing instruments, thus achieving a more uniform quality of adjustment with minimal deviations.

When placing the flywheel 17 with the impulse pin 18 and the hair 19 coaxially mounted on the shaft 54, into the adjusting device according to the invention, first a manual force is applied to the handle 10, by which the tension spring port 13 is folded out with the arm. and with the movable clamping jaw směrem away from the cavity space of the housing..

In the initial stage of this movement, the two clamping jaws 6 and 6 remain in the closed position. As soon as the single-arm lever 6 abuts the abutment surface of the abutment stop 26, the further movement of the single-arm lever 6 and the fixed clamping jaw 8 stops, and by further application of force on the handle 10 in the same direction the jaw 5 moves away from the fixed clamping jaw 6.

The prismatic grooves 23 and 24 are spaced apart and a complete flywheel 17 is inserted into the prismatic grooves 23 and 24 thus opened by inserting a flywheel shaft 16 and an impulse pin 18 with partial release of the traction force into the first prismatic groove 23 of the clamping jaw 7. the gripper 10 grips into the second prismatic groove 24 of the movable gripper jaw. The flywheel 17 is loaded with the hair 19 in the up position.

By further releasing the pulling force on the handle 10, the whole of the flywheel-clamped holder 5 returns to the cavity of the sleeve 5 by the tension of the spring 13, the shaft 16 of the clamped flywheel 17 being inserted into the notch 15 of the forming template. to the end of the adjusting stop screw 25.

At this point, the desired exact positioning of the hair flank on the surface of the molding surface 4 has been desired. The flywheel 17 is below the shaping template 6.

After the tweezers have been adjusted with the tweezers to the desired position exactly corresponding to the geometric shape of the curvature 20 shown on the template, the adjustment of the twine 19 is completed. By returning the handle 10, the clamping bracket 8 extends out of the housing 4 and thus the flywheel 17 with the shaft 16 and the modified hair 19 from the notch 15 of the forming template 6.

By further pulling the handle 10, the two clamping jaws 6 and 6 open, thereby releasing the entire flywheel 17 and being ready for removal. A further flywheel 17 with a thread 19 is inserted into the clamping jaws 6 and 6 and the process is repeated.

The hairs treated in this device have a standard quality, which results in considerable savings of the additional adjustments necessary until now, after accurate measurement of the flywheel oscillations.

Further possible deformation of the hair during the flywheel assembly, which occurred when the flywheel is mounted in the timing apparatus while securing the hair in the post with a pin, can be prevented by sticking the end of the hair into the post opening.

The described method of adjusting the flywheel flat helical hairs and the apparatus for carrying out this method can be easily applied to flywheels and hairs of any size, for all instruments using the flywheel with the hair. In addition, the device according to the invention allows precise adjustment of hairs of different qualities.

Claims (6)

A method of adjusting flat helical hairpins of timing gears, especially clockwork movements, characterized in that the flywheel provided with an impulse pin and a hairplate, the outer end of which is bent out of the spiral into a shape elbow defining the required spiral length, is inserted into the notch of the forming template. in which the desired shape of the curvature and the end of the free end of the hair is shown, and after the flywheel has been accurately positioned relative to its shaft and impulse pin position relative to the template, the hair helix termination curve is shaped according to the shape shown on the template. Device for carrying out the method according to claim 1, characterized in that it comprises a hollow housing (1) consisting of a L-shaped base (2) and a shaping template (3) provided with a notch (15) at the edge for receiving the shaft (16). of the flywheel (17) with the thread (19), wherein in the base (2) below the shaping template (3), outside the shaping template (3), there is a pivot clamp (5) for the shaft (16) and an impulse pin (18) /. Device according to claim 2, characterized in that the clamping bracket (5) for the shaft (16) and the start pin (18) of the flywheel (17) is formed by a single-arm lever (6) pivotably mounted on the base (2). a fixed clamping jaw (7) with a first prismatic groove (23) having a width corresponding to the diameter of the flywheel shaft (16) and a movable clamping jaw (9) pivotally mounted on a fixed clamping jaw (7) provided with a second prismatic groove (24), the width of which corresponds to the diameter of the impulse pin (18), wherein the prismatic grooves (23, 24) are fixed and movable clamping jaws (7, 9) and notch (15) in the shaping template (3). the axis (x) of rotation of the clamping holder (5), and the notch (15) of the forming template (3) is curved according to the circle described by the prismatic grooves (23, 24) of both clamping jaws (7). 9 / during the pivoting movement of the clamping bracket (5). Device according to Claims 2 and 3, characterized in that the fixed clamping jaw (7) and the movable clamping jaw (9) are resiliently connected to each other by a traction band (11) and the clamping bracket (5) as a whole is connected by another traction spring. 13) with the base (2), wherein the tension force of the tension spring (11) of the clamping jaws (7, 9) is higher than that of the other tension spring (13) of the clamping bracket (5). Device according to Claims 2 to 4, characterized in that in the wall of the base (2) there is an adjusting stop screw (25) for precisely limiting the adjusting movement of the clamping holder (5). Device according to any one of Claims 2 to 5, characterized in that in the pivoting housing of the clamping bracket (5), a support stop (26) is provided in the base body (2) to limit the pivoting movement of the clamping bracket (5) outside the housing. .