SU1689779A1 - Resonator for vibration stand - Google Patents

Description

The invention relates to a testing technique, in particular to resonators mounted on vibrating tables to obtain an increased level of vibration. The purpose of the invention is to expand the operational capabilities by providing control of the asymmetry factor of the loading cycle.

The drawing shows the resonator, a longitudinal section.

The resonator contains a beam 1 of rectangular cross section with cylindrical hinged supports at the ends oriented across beam 1 and formed by elements 2 and 3 with a concave cylindrical surface of radius R and convex cylindrical surfaces of radius r of the 4 beams. Beam 1 has a protrusion 5 in the center for fixing the product under test (not shown). Each of the elements 2 and 3 is an annular segment and is rigidly attached in the middle part with screws 6 to a rack 7 fixed by a screw 8 on the table 9 of the vibrostand. To obtain an asymmetrical loading cycle for a product with an adjustable cycle asymmetry factor elements 2 and 3, including bar 10, supported at the ends on the stops 11, made in particular, in one piece with the pillars 7, and screw 12, which is screwed into the shaker table and serves to apply a bending load to the beam ky 10 in the middle part. The lower ends of the elements 2 and 3 are supported on the bar. The flexural rigidity of the bar 10 must be higher than the flexural rigidity of the deformable portions (from the fixing point to the end, supported on bar 1 0) of elements 2 and 3. If this condition is not fulfilled, the said portions are not deformed. The distances from the axis of the screw 12 to the places of support of the bar 10 should be the same, in order to ensure equality of the amplitudes of the movements of the ends 4 of the beam 1 during an asymmetric cycle of oscillations. Beam 1 must be installed between concave cylindrical surfaces. so that, during oscillations, the beam could be displaced with respect to elements 2 and 3. To prevent beam 1 from escaping from elements 2 and 3, the maximum value of radius R should be chosen from the ratio r R H2 / 8K D D |, where LF is the height of elements 2 and 3; Кн (1,2, ..., 3) - safety factor; R1 is the change in half the length of the span of beam 1 during its oscillations.

The resonator works as follows.

In the process of resonant bending vibrations of the beam 1, periodic vertical slippage of the ends 4 of the beam 1 relative to elements 2 and 3 occurs due to a periodic decrease in the length

span of the beam when it fluctuates. If it is necessary to obtain an asymmetrical cycle of loading oscillations, bend the bar 10 by tightening the screw 12. At the same time, the ends of the bar 10 are raised and act on

The ends of elements 2 and 3 supported on them, as a result of which their sections from the fixing point to the supporting point are deformed and the radius of curvature of the concave cylindrical surfaces on these sections changes. As a result, the amplitudes of displacements of the beam when moving up and down are different, i.e. an asymmetrical product oscillation (loading) cycle is obtained. The cycle asymmetry factor can

is adjusted by varying the tightening torque of the screw 12. With the screw 12 unseen, a symmetrical cycle is obtained.

Claims (1)

Claims of the invention A resonator for a vibrostand, comprising a rectangular beam with cylindrical hinged supports at the ends formed by elements attached to the vibrator table with a concave cylindrical surface on the side the end of the beam and the convex cylindrical surfaces of the ends of the beam, while the beam is installed with the possibility of vertical displacement relative to the above-mentioned elements during its oscillations, and with the aim of expanding the operational capabilities by ensuring the regulation of the asymmetry factor of the loading cycle, provided with a device for deforming elements with a concave cylindrical surface including a bar supported at the ends, on which the ends of the elements are supported, and a screw serving for application and bending load to the bar in the middle part, while the bending stiffness of the bar is higher flexural rigidity of the deformable parts of the elements, and the latter are made in the form of annular segments rigidly attached in the middle part to the posts fixed on the vibrating table. 0