SU498274A1 - Chamber Oscillator for Electronic Time Instruments - Google Patents

Description

The invention relates to a tuning fork oscillators used primarily in electronic mechanical devices.

A tuning fork oscillator for an electronic-mechanical time instrument is known, containing two sym: metric branches, conjugated in a mount, each of which has a curvilinear section, the concavity of which is directed IB to the side of the axis of symmetry, and extending its straight linear portion carrying the mass, for example elements of the oscillator excitation system.

Tuning fork oscillators with two symmetric with respect to the axis of the oscillator branches are known / are along the length of each rectangular part carrying a mass, such as elements of the excitation system, and a curvilinear portion extending it with a concavity facing the axis of symmetry that conjugates Light with an oscillator mount. In such ka: merton oscillators, the ends of the winds describe arcuate trajectories with the center located near the attachment point.

The trajectories of the ends of the winds carrying the mass formed by the magnetic drive system or the motion transducer are such that, in the mount, there appears to be an uncompensated component directed

along the axis of symmetry of the oscillator, causing the base of the oscillator to swing and, as a result, energy dissipation. This leads to an increase in energy consumption, a decrease in the efficiency and a deterioration in the accuracy characteristics of the device itself.

In addition, such branch paths do not allow the pushing paw of the transducer to perform strictly linear movement, which adversely affects the reliability of the transducer.

The purpose of the present invention is to eliminate the dissipation of energy in the mount and ensure the linear movement of the ends of the branches.

The goal is achieved by selecting the distance from the axis of symmetry of the oscillator to a straight line segment, which must be less than the distance to the point of the curvilinear segment furthest from the axis of symmetry. The curved section can be made in the form of an arc of a circle.

FIG. 1 shows a symmetrical branch of the proposed tuning fork oscillator; FIG. 2 is one of the forms for making a curvilinear section of an oscillator branch.

The tuning fork oscillator (Fig. 1) has

two symmetrical branches 1, 2 converging in

mount 3. Each of the branches I, 2 contains a plurality of 4, which in

3

point 5 passes into the curvilinear section 6, ending in the attachment unit 3.

The curvilinear section 6 is cis-filled in such a way that the straight line section 4 is intersecting point 5 with respect to it, while the concavity of the curvilinear section 6 faces towards the axis of symmetry 7 of the tuning fork oscillator.

The curvilinear section has the simplest geometrical form, if it is made in the form of an arc of a circle (FIG. 2) for the sake of co-m)

L (-k: + a) cosa - si na

g (1 + sina) (tg + a) cosa - sina +

3 + (11 -f a) sina cosa --- sin-a -f 1 + cosa,

where L is the length of the tuning fork oscillator, a is the central angle of the arc of a circle between the straight line passing through the conjugation point of the straight linear and curvilinear sections, and the straight, Lerlendendural axis of symmetry of the oscillator,

Ovo: the free ends of the rectilinear sections 4 (Fig. 1) serve to fasten the elements of the primer system 8 and / or a transducer (not shown) or other mass that interacts magnetically with the drive system.

When the oscillator is excited, its branches I, 2 oscillate: linear area 4 of each branch is bent relative to point 5, and curvilinear section -6- relative to mount 3. At the same time, the free end of section 4 tends to describe an arcuate trajectory (9, 9, 9 ), at which, at point 8, delivering forces of Pl and F arise, acting, respectively, along the axis of the oscillator and perpendicular to it.

The curvilinear section 6, due to the specificity of its shape, is bent relative to the attachment point 5 so that at the point of conjugation with the straight line section it describes an arc-shaped trajectory (5, 5, 5). In this case, a component F2 arises, directed along the axis of the oscillator, opposite to the force FI and compensating for the latter. As a result, the Ovobad Konets of the rectilinear section 4 (point 9) carrying elements of the drive system, the converter, etc., is bent relative to point 5 and simultaneously moves along with it along the arc 5, 5, 5, making almost linear motion on the plot, 9, 9.

Thus, due to the fact that the rectilinear section of the branch I1 is intersecting to a curvilinear one, at the point of conjugation, the effect of the component forces directed along the axis of the oscillator and causing the leakage of energy to the base is achieved.

Claims (2)

1. A tuning fork oscillator for electronic-mechanical time devices, containing two symmetric branches, conjugated in a mount, each of which has a curvilinear section, the concavity of which is directed toward the axis of symmetry, and the adjacent straight section of it. Mass, for example, elements of an oscillator excitation system, characterized in that, in order to eliminate energy dissipation in the mount and achieve a straight linear movement of the ends of the branches, the distance from the axis of symmetry of the oscillator to the straight line is chosen to be less than the distance to the most distant from the axis of symmetry of the point of 1 curvilinear part. 2. Oscillator on. 1, characterized in that the curved section is in the form of an arc of a circle. 2