RU2340924C2 - Display device counter-recoil mechanism - Google Patents

Abstract

FIELD: physics; measurements.

SUBSTANCE: present invention pertains to the clock making industry and is aimed at making a counter-recoil mechanism for a display device, which is compact and efficient. This technical outcome can be achieved due to that, the counter-recoil mechanism of the display device comprises a star shaped element, joined to a tooth gear. The star shaped element is made from an array of sharp-pointed elements, each of which has a side surface to which, under the effect of a spring, a probe is pressed against, and fixed to a pointer. The structure and dimensions of the side surfaces of the sharp-pointed elements of the star-shaped element depend on the information to be displayed. It is desirable that, the probe, pointer and spring be mounted on a bushing, rotating on a support. The counter-recoil mechanism also has a support, capable of preventing the bushing from recoiling under the effect of the spring after the probe moves on a side surface and enabling it to move to the next side surface for the next cycle.

EFFECT: design of a counter-recoil mechanism for a display device, which is compact and efficient.

3 cl, 4 dwg

Description

The subject of this invention is the return mechanism of the indicating device.

Returnable indicating devices are known as indicating devices with a retarding (rack) mechanism, driven by gears with a small height of the tooth head. These stopping mechanisms include a rack gear rotating on a support with an arrow attached to the rack gear. The pinion gear is a relatively large part, which means that these mechanisms occupy a significant part of the space in the watch. A large number of mechanisms are also known that are formed from a probe in contact with a flat spiral (cochlea). The flat spiral rotates on a support and is attached to the arrow. A flat spiral is performed depending on the information to be reproduced on the display device, and has a rectilinear part at its end, which allows the probe to return to its original position under the action of a spring.

The technical task of the present invention is to create a return mechanism of the display device, which takes up little space and at the same time works reliably.

This technical problem is solved by creating a return mechanism of the indicating device, which according to the invention includes a star-shaped element attached to the gear wheel, while the star-shaped element is formed of a series of pointed elements, each of which has a side surface to which the probe is pressed by the spring, attached to the arrow, the design and dimensions of the side surfaces depend on the information to be displayed.

Preferably, the probe, arrow and spring are mounted on a sleeve rotating on a support.

Preferably, the mechanism comprises an abutment configured to prevent the sleeve from retreating under the action of the spring after the probe has been moved along the side surface and lowered to the next side surface to carry out the next cycle

Next will be considered as an example, an embodiment of the return mechanism of the display device according to the invention with reference to the accompanying drawings, in which:

- figure 1 is a top view of the mechanism;

- figure 2 is a section passing through a support holding the arrow in the mechanism;

- figure 3 is a view similar to the view in figure 1, with the returned probe in the final position before the arrow returns to its original position; and

- figure 4 is a top view of a star-shaped element of the return mechanism.

Figures 1-4 show a simplified return mechanism of a sector display device. In watchmaking, this display device is used, for example, to indicate the power supply of the watch or, in this case, the second hand. Its advantage is the absence of leaping. The arrow moves constantly, unlike many known return mechanisms.

The mechanism contains:

- star-shaped element 1 of the return mechanism,

- coil spring 2,

- probe 3 of the return mechanism,

- pin 4 for fixing the coil spring,

- pin stop 5, and

- arrow 6.

The return mechanism is driven by gears R1 and R2. The star-shaped element 1 of the return mechanism is attached to the gear wheel R2 and has several identical pointed elements evenly distributed around the circumference of the star-shaped element.

The tip of the probe 3 of the return mechanism is in constant contact with the pointed element of the star-shaped element 1 and is pressed against the side surface B of the pointed pointed element. The coil spring 2 maintains this constant contact. The cross section of the support A (figure 2) shows the mechanism in detail. The spiral spring 2 is attached to the sleeve 1. Similarly, the probe 3 of the return mechanism and the arrow 6 are pressed onto the sleeve 7. The sleeve is freely mounted on the support A. Pin 4 is used to hold the spiral spring 2.

During operation, the gearwheel R2 of the return mechanism rotates clockwise, causing the tip of the probe 3 of the return mechanism to move using the side surface B. When the tip reaches the end of its movement (Fig. 3), the side surface “releases” the probe, which drops to the next side surface C. The process is repeated on side surface C to the next side surface. Thus, the arrow is constantly in motion. The pin 5 serves as a stop during lowering and prevents the tip of the probe 3 of the return mechanism from falling onto the base of the profile of the star-shaped element 1 of the return mechanism.

The lateral surfaces B, C of the pointed elements of the star-shaped element 1 of the return mechanism are carefully designed so that the arrow 6 of the return mechanism moves linearly on the dial, which is not shown.

As shown in figure 2, the coil spring 2, the probe 3 of the return mechanism and arrow 6 are pressed onto the sleeve 7 and, therefore, are fixed in their respective positions on the specified sleeve 7.

The spiral spring 2 is stretched and attached to the frame of the mechanism by means of a pin 4. As shown in figure 1, the arrow 6 is at the beginning of its movement at the stop 5, and the probe 3 of the return mechanism is also at the beginning of its movement in contact with the side surface B of the pointed element star-shaped element 1 of the return mechanism. The star-shaped element 1, attached to the gear wheel R2, is driven in the direction of the arrow (see FIGS. 1 and 3) by means of the movable element R1 and, in turn, drives the stylus 3, which, as the gear wheel R1 rotates, moves along the lateral surface B of the pointed element of the star-shaped element 1. The arrow 6, which is in a fixed position relative to the probe, is driven by the specified probe 3 in the direction opposite to the direction of action of the spring 2 and indicates the values shown e on a dial not shown. When the probe 3 moves beyond the position shown in FIG. 3, the spring 2 will return the probe 3 and arrows 6 to their original position, in which they are pressed against the stop 5, and the cycle can begin again on the side surface C of the star element 1.

The mechanism described above with reference to FIGS. 1-4 may be adapted to indicate any type of information typically displayed using a clock, such as seconds, minutes, hours, dates, days, moon phases, etc. The movable elements R1 and R2 must simply be dimensioned, and the pointed elements of the star-shaped element 1 must be adapted to the values to be indicated.

The advantage of the described device is the simplicity and the presence of a display device with constant movement. As soon as the probe passes the end of the pointed element of the star-shaped element, the next cycle begins, and the display continues without interruption.

Claims (3)

1. The return mechanism of the indicating device, characterized in that it includes a star-shaped element (1) attached to the gear wheel (R2), wherein the star-shaped element is formed of a series of pointed elements, each of which has a side surface (B, C and etc.), to which under the action of the spring (2) the probe (3) is attached, attached to the arrow (6), while the design and dimensions of the side surfaces (B, C, etc.) depend on the information to be indicated . 2. The mechanism according to claim 1, characterized in that the probe (3), arrow (6) and spring (2) are mounted on a sleeve (7) rotating on a support (A). 3. The mechanism according to claim 2, characterized in that it contains a stop (5) configured to prevent the sleeve (7) from moving backward under the action of the spring (2) after completion of the probe movement along the lateral surface (B, C, etc.) and lowering it to the next side surface to perform the next cycle.

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