SU568922A1 - Vibrograph - Google Patents

Claims (2)

at the same time, the converter is made in the form of tezistorsistors glued to the spring. The polar angle is chosen from 10 to 290 °. The shape of the spring, which corresponds to the above-stated relation, was obtained experimentally, with this shape of the spring, the force is transmitted to the tangent, creating its "negative elasticity. This force is directed along the axis of the tambour to its center. In addition, the same spring is a measuring element, since strain gages are attached to it. FIG. 1 shows the structure of the device; in fig. 2 position of the ribbon spring until it is fixed. The vibrograph contains a lever 1 with an inertial mass 2, suspended from the base 3 by means of help, and two pairs of mutually perpendicular springs 4. In the equilibrium position, the head is held by a tensioned ribbon spring 5, i.e. above. To register the oscillations on the spring 5, wire strain gauges 6 are glued. In addition, there is an electromagnetic damper 7. The vibrograph works in the following way. When an object oscillates with a vibrograph installed on it, the inertia mass of the latter remains stationary due to the fact that the natural frequency of the vibrograph is several times lower than the oscillation frequency of the object. The transformation of mechanical oscillations of the antenna into electrical ones is carried out with wire strain gauges glued to a flat spring. The use of a ribbon spring as an elastic suspension simplifies the design of the vibrograph, since this spring, with strain gages attached to it, is itself a measuring element and performs the function of a spring creating a "negative elasticity in the horizontal plate. The proposed design of the vibrograph allows one to expand the range of the studied oscillations, i.e., to obtain stable natural oscillations with a frequency constituting fractions of a hertz and an amplitude of up to 26 mm or more. In addition, the proposed vibrograph allows one to record the vibration displacements themselves, while the known devices equipped with induction sensors require additional conversion (integration) of the signal coming from the vibrograph, which leads to an increase in the measurement error, especially in the region of infra-low frequencies (0.5 -10 Hz). Claim 1. Vibrograph containing a transducer, an tiller and a spring holding the tiller in the equilibrium position, one end of which is fixed on the housing and the other on the lever, characterized in that, in order to simplify the design, the spring is made with a tensioned ribbon, the shape of the spring is chosen in accordance with the ratio where r is the radius vector; a is the distance between the polar axis and the asymptote of the hyperbolic spiral and is the polar angle, while the converter is made in the form of strain gauges glued to the spring. 2. Vibrograph according to claim 1, characterized in that the polar angle φ is selected in the range from 10 to 290 °. g / g / 9ig.2