RU96921U1 - ROPE VIBRATION INSULATOR - Google Patents

Abstract

 A cable vibration isolator, consisting of an elastic cable element in the form of a closed ring, fixed in two diametrically opposite places in two clips, used to fasten the vibration isolator to the base and the protected object, characterized in that a similar elastic element of smaller diameter is located inside the elastic element in a perpendicular plane, attached to the first elastic element by clamps.

Description

The utility model relates to the field of mechanical engineering, in particular, to elastic damping elements, and can be used to protect devices, assemblies and equipment from overloads, shock and vibration in any field of technology.

Known cable vibration isolator containing two rectangular clips, consisting of strips with recesses, in which, symmetrically relative to the axis of the vibration isolator, fixed elastic elements in the form of rings made of a cable. (Ponomarev Yu.K., Kraynov V.I. et al. RF Patent No. 2044190, IPC F16F 7/14, published September 20, 1995).

A disadvantage of the known cable vibration isolator is insufficient stability under the influence of axial loads. As a result, reliability is reduced and the life of the vibration isolator is reduced.

The closest in technical essence is a cable vibration isolator, consisting of an elastic cable element in the form of a closed ring, fixed in two diametrically opposite places in two clips, used to attach the vibration isolator to the base and the protected object (Antipov V.A., Gunin V.A. et al. RF Patent No. 2179667, IPC F16F 7/14, F16G 11/00. Published on February 20, 2002).

The disadvantage of the prototype is the significant nonlinearity of the elastic characteristics in three mutually perpendicular directions, which, under certain conditions, can provoke the occurrence of sub- and superharmonic resonances of the mechanical system in the operating frequency range.

The technical result, the achievement of which the creation of this utility model is aimed, is to obtain an equal-rigidity linear characteristic in three mutually perpendicular directions, which eliminates the occurrence of sub- and superharmonic resonances in the working frequency zone of the vibration-proof system.

The technical result is achieved by the fact that in the known cable vibration isolator, consisting of an elastic cable element in the form of a closed ring, fixed in two diametrically opposite places in two clips, used to fasten the vibration isolator to the base and the protected object, according to the utility model, inside the elastic element perpendicular the plane is a similar elastic element of smaller diameter, attached to the first elastic element by means of clamps.

The principal difference of the proposed design is the following. Due to the fact that inside the elastic element in the perpendicular plane there is a similar elastic element of smaller diameter, attached to the first by means of clamps, the equal-rigidity linear characteristic is performed in three mutually perpendicular directions, which, in turn, eliminates the occurrence of sub- and superharmonic resonances in the working area of the vibration protection system frequencies.

The essence of the utility model is illustrated by drawings, where:

figure 1 shows the appearance of a cable vibration isolator;

figure 2 shows a clip for attaching an elastic cable element with a local neckline;

figure 3 shows the appearance of the clamps for elastic cable elements.

The cable vibration isolator consists of an elastic element 1, which is a ring twisted from a cable connecting two mounting clips: upper 2 and lower 3, located in diametrically opposite directions (see figures 1, 2). The clips 2, 3 are identical. Each clip consists of a rod in the form of a body of revolution 4 with hemispherical 5, conical 6 and cylindrical 7 threaded sections. On the conical sections of the rods 4 are planted conical bushings 8 with cones mating with respect to the rods 4 on their inner surfaces. Hemispherical, conical and a small part of the cylindrical part of the rods 4 are made with cuts along their common axis. Perpendicular to the axes of each rod in the joint plane of their hemispherical and conical sections, holes are made with a diameter equal to the diameter of the elastic element. An elastic element 1 is installed in these holes on the cage rods. For its installation, the cut parts of the rods 4 are previously parted apart to a distance that can allow the cable ring 1. To jam the cable in the holes, the nuts 9 are screwed together with the conical bushings 8, which compress the split conical sections of the rods when screwing the nuts, tightly clamp the elastic element 1 in its two diametrically opposite places. To prevent the nuts 9 from being unfolded, spring washers 10 are installed between them and the conical bushings 8 (see Fig. 2).

Inside the elastic element 1 in a perpendicular plane there is an elastic element 11 of smaller diameter, which also represents a ring twisted from a cable attached to the elastic element 1 by means of clamps 12 and 13 (see figures 1, 3). Terminals 12 and 13 are identical. The clamp is an all-metal part in which two holes 15 and 16 are made, the axes of which are perpendicular to each other, designed to accommodate the elastic elements 1 and 11. From the ends of the clamp 12, cuts 14 are made along its axis to the holes 15 and 16. For installation the elastic element 1 is pre-parted to the sides of the cut parts 17 of the clamp 12 to a distance capable of skipping the ring of the cable 1. To install the elastic element 11 is pre-parted to the sides of the cut parts 18 of the clamp 12 to a distance that is able to skip have a ring of cable 11. In order to ensure reliable pinching of the elastic elements 1 and 11, holes for rivets 19 are provided in the design of the clamps 12 and 13. Reliability of fastening of the elastic elements 1 and 11 in the clamps 12 and 13 is provided by rivets 20 and 21 (see Fig. 1 , 3).

Cable vibration isolator works as follows. Under the action of a load of a vibrational or shock nature originating from the base or vibrating object, the coils of the elastic element are deformed, compensating for the effect of the applied loads and dissipating their energy. Compared with the prototype, the inventive cable vibration isolator has a greater uniformity of the stiffness and resonant frequencies in the direction of the main mutually orthogonal axes.

The proposed utility model can be used in transport engineering, light industry, other industries and implemented using known means. A theoretical study by the authors showed that a cable vibration isolator is able to provide a given level of stability of characteristics, and the design as a whole is able to maintain these characteristics in an unchanged state during operation. This proves the achievement of the technical result perceived by the applicant - ensuring high reliability of vibration protection and obtaining equal-linear linear characteristics in three mutually perpendicular directions, which eliminates the occurrence of sub- and superharmonic resonances in the working frequency zone of the vibration protection system.

Claims (1)

A cable vibration isolator, consisting of an elastic cable element in the form of a closed ring, fixed in two diametrically opposite places in two clips, used to fasten the vibration isolator to the base and the protected object, characterized in that a similar elastic element of smaller diameter is located inside the elastic element in a perpendicular plane, attached to the first elastic element by clamps.