DE1673664C - Oscillating system with two rotating masses - Google Patents

Claims (8)

1 2 The invention relates to a directly driven very small and from a certain deflection oscillation system for utility watches with two opposite increases. .
phased oscillating rotating masses in the frame With such a design of the connection "temporarily stored and connected to one another via a spring spring and frame, it is possible that with Absind, with between the spring at the oscillation 5 equal to the oscillation system at the target frequency, at knots and the frame a connecting element. Adjustment of only a rotating mass, the permissible tension or a connecting spring is arranged, according to the tuning of a rotating mass in relation to the fastening patent 1 548 150. 'point of application, 10% of the other rotating mass, also The main patent deals with a directly related to the attachment point, can be driven oscillation system for utility watches io With regard to the oscillation node, which is with two rotating masses oscillating out of phase, speaking distance from the fastening point which can be connected to each other via spring elements, have both transducer halves exactly which in turn have the same frequency at their nodes of vibration. In the event of vibrations, the are elastically attached to the frame. In this case, the aforementioned effect of in-phase oscillation is created beaten that the rotating masses directly in the frame 15 of both oscillator halves not on. stored and by a single spring element with- Embodiments of the invention are on hand are connected to each other that the connection between the F i g. 1 to 5 shown. see the spring element and frame in the zero position of FIG. 1 shows a fastening by means of an on the System is tension-free and so elastic that the spring attached pin; the attachment point between the spring element and 20 F i g. 2 and 3 show another type of fastening, elastic connecting element movements, FIG. 2 being the top view and FIG. 3 being the able to perform, which represents the oscillatory movement of the side view; in Correspond to the spring element in the vicinity of the node. Fig. 4 is the attachment of the oscillating system to the To adjust the frequency of this oscillation system, the frame is shown via a spring while
the adjustment on just one rotating mass is sufficient. Through 25 F i g. 5 shows a further exemplary embodiment of the elastic ¹ connection between the spring and the fastening by means of a spring,
alternatively, the location of the node in FIG. 1 is to change the spring 1 in the vicinity of the oscillation adjustment, so that both oscillator halves are provided with a pin 2, which is mounted in a socket 3 to oscillate at exactly the same frequency, which may be attached to the frame 4 without that beats in one of the Schwin 30. Occur between the bore of the socket 3 and the gerhälften. The permissible deviation of pin 2 is such that the location of the vibration node can move from the location of the attachment point on the spring by ± Vioo mm. Free movement of the connecting element on the spring. the greater, the more elastic the connection between In the embodiment according to FIG. 2 and 3 is Spring and frame is executed. This means that 35 a pin 5 near the node with the connected with a relatively rigid connection between spring spring 1. The pen is used in its possible and frame the permissible frequency deviation between the circular movement borne by the frame fixed view the two halves of the transducer with respect to the beat 6 and 7 limited. A movement of the The attachment point may only be small, d. i.e., the pin S only occurs when the location of the The vibration node must be very close to the fastening point, not the 40 vibration node lie. With an elastic connection point of the pin 5 coincides. The permissible The permissible free play of the pin 5 between the spring and the frame is also in turn infrequency deviation both transducer halves with respect to about ± V100 mm relatively large on the attachment point, d. e., the In Fig. 8 is the movement of the mounting spring Node of vibration of the spring can be limited accordingly by stops 9 and 10. The return away from the attachment point. The actuating torque of this connecting spring 10 is mentioned in the latter A case worth striving for is therefore a depreciation before the stops 8 and 9 strike only one rotating mass to the setpoint frequency is relatively small, while with larger deflections of the oscillation system within very wide limits. by hitting stops 8 and 9 It has been shown, however, that when using a shortening of the active length of the connecting manure of a very elastic connection between springs is brought about. Spring and frame z. B. in a non-stationary clock in FIG. 5, the spring 11 is in a trumpet shape Occurring vibrations can cause the hole in a socket fixed to the frame. the both transducers no longer oscillate in phase opposition. Walls 12 and 13 of the bore are here like this Rather, the two halves of the oscillator oscillate in a 55-shaped manner that they depend on the in the same direction, i.e. in phase, whereby the bending of the spring forms variable stops, the connecting spring is involved in the vibrations. The greater the deflection of the spring 11, the more so shares. their active spring length becomes shorter. This disadvantage is to be avoided by the present invention. With an oscillating system 60 claims:
of the type mentioned above, this is achieved according to the invention once in that the fastening '1. Directly driven oscillation system for point on the spring is loosely rotatable around a small angular range of utility clocks with two counter-phase oscillating. Rotary masses, which are stored in the frame and connected to one another via a spring, whereby the same inventive concept consists in the fact that the deflections of the fastening point on the frame are arranged between the spring at the oscillation node and the restoring torque of the connecting spring with a small connecting element According to patent 1 548 150, the spring is characterized shows that the attachment point on the spring is loosely rotatable through a small angular range. 2. Directly driven oscillation system for utility watches with two rotating masses oscillating in opposite phase, which are mounted in the frame and connected to one another via a spring, a connecting spring being arranged between the spring at the vibration node and the frame, according to patent 1,548,150, characterized in that the restoring torque of the connecting spring is very small with small deflections of the attachment point on the spring and increases steeply from a certain deflection. 3. Oscillating system according to claim 2, characterized in that the connecting spring from a certain deflection of the fastening point strikes the frame-mounted stops that cause a shortening of the active length of the connecting spring. 4. Oscillating system according to claim 1 to 3, characterized in that the freely rotatable area or the area of very small restoring elements of the connecting spring at the fastening point of the spring is ± V100 mm. 5. Oscillating system according to claim 1 or 4, characterized in that the on the spring (1) At right angles to its axis attached pin (2) mounted in a most placed socket (3) with play is. 6. oscillation system according to claim 1 and 4, characterized in that the on the spring (1) fixed stop pin (5) limited in its movement by two frame-fixed stops (6, 7) is. 7. Oscillating system according to claim 2, 3 or 4, characterized in that the on the spring (1) attached connecting spring (10) in its movement by two frame-fixed stops (8, 9) is limited. 8. Oscillating system according to claim 2, 3 or 4, characterized in that the on the spring (1) attached connecting spring (11) is embedded in a frame-fixed trumpet-shaped bore, the walls (12, 13) than with the Bending of the spring (11) variable stops are used. 1 sheet of drawings