RU142894U1 - ROPE VIBRATION INSULATOR - Google Patents

Abstract

A cable vibration isolator consisting of lower and upper bases with cable segments fixed between them, characterized in that the upper and lower bases are made in the form of plates having two or more plane lines of symmetry, and the cables are fixed with their ends in the holes drilled at the ends of these plates , and are fixed by a polymer compound poured into these holes.

Description

The proposed utility model relates to techniques for protection against vibration impacts, in particular to the design of vibration isolators with a cable spring-damping element.

Known existing vibration isolators of the cable type, including as a spring-damping element of a piece of steel cable. An example of such vibration isolators are vibration isolators [SU 1756687 A1, 08.23.1992; RU 2185548 N2, 11.27.1996; EP 1122458 A1, January 28, 2001]. Their disadvantages are the complexity of the design.

The closest analogue of the proposed utility model is a vibration isolator [RU 2340810 C1, 10.25.2007] containing upper and lower bases, with elastic-damping elements mechanically fixed between them in the form of separate cable segments.

The disadvantage of the shock absorber [RU 2340810 C1, 10.25.2007] also lies in the complexity of its design. The complexity of the design of cable-type vibration isolators is determined by the fact that it is necessary to secure the cable in a certain way in order to ensure the reliability of the product. With the advent of more stranded steel cables, with the number of wires significantly (2-3 times or more) higher than in previously existing steel cables (for example, aircraft steel cable (cable) GOST 2172-80 or its foreign analogues), almost any design the vibration isolator provides its required amplitude-frequency and reliability characteristics. The latter is explained by the fact that the more veins in the cable, the higher its damping ability (the greater the number of mutually rubbing wire elements) and the lesser residual deformation (residual deformation of the entire cable, as a function of the residual deformation of the thinner wires that make up its veins). Thus, the key task is to achieve a technical result, consisting in the maximum simplification of the design while maintaining its reliability, which will minimize the complexity of manufacturing a vibration isolator.

The technical result of the claimed utility model is that the proposed vibration isolator has the simplest possible construction that reduces labor costs in its production and ensures the safety of high technical characteristics.

The technical result is achieved due to the fact that the vibration isolator consists of lower and upper bases, with cable segments fixed between them. In this case, the upper and lower bases are made in the form of plates having two or more lines of symmetry of the plane, and the cables with their ends are fixed in holes drilled at the ends of these plates and fixed with a polymer compound embedded in these holes.

Figure 1 shows a photograph of the inventive vibrator.

The design of the shock absorber consists of spring-damping elements 1 made of pieces of steel cable, upper and lower bases 2, made in the form of plates with at least two lines of symmetry. The plates have in the end part of the hole 3, where the spring-damping elements 1 are fixed using a polymer compound.

With a vertical or horizontal directional vibration shock, the spring-damping element (the cable segment) is deformed, and due to positional friction in the cable segment between its elements (the wires of which it consists), the mechanical energy is dissipated into heat. This principle of operation is common to all cable-type vibration isolators, regardless of how the cable is secured.

The design of the vibration isolator can include a base in the form of not only square plates, as shown in the figure, but also plates of any other shape, for example, round, in the form of a six or octagon, etc., since this will not affect the technical characteristics of the vibration isolator and design principle, however, the square shape of the plates is preferable, since such a shape of the plates is the most technologically advanced in their manufacture. The main thing is the claimed condition that the plates must have two or more lines of symmetry of the plane, since this condition allows you to distribute the cable elastic damping elements around the perimeter of the plates, in the most rational and universal way, from the point of view of considering the entire oscillatory system (vibration isolator - protected product) as a single whole. The number of cable elements - is determined by the required characteristics of a particular vibration isolator, for a specific load and is not fundamental, from the point of view of patenting this utility model. Thus, taking into account the foregoing, the technical solution itself, which laid the foundation for the development of the design of the proposed vibration isolator, and which allows to reduce the cost of its production, remains unchanged.

Based on the proposed solutions, a prototype of a vibration isolator was manufactured and tested. Below are the main characteristics of the prototype vibration shock absorber:

The mass of vibration-proofing, not more than 132 g.

Dimensions of vibration shock absorber -

HEIGHT × (OVERALL DIMENSIONS) = 70 × (95 × 95) mm.

Depreciable weight - 30 kg.

Work resource - over 35000 hours.

The amplitude-frequency characteristics of the inventive vibration isolator are given in the form of a table below.

The tests confirm the reliability of the claimed technical result.

Sources of information taken into account when drawing up an application for a utility model

1.SU 1756687 A1, 08.23.1992

2. RU 2185548 N2, 11.27.1996

3. EP 1122458 A1, 01/28/2001

4. RU 2340810 C1, 10.25.2007 (prototype)

Claims (1)

A cable vibration isolator consisting of lower and upper bases with cable segments fixed between them, characterized in that the upper and lower bases are made in the form of plates having two or more plane lines of symmetry, and the cables are fixed with their ends in the holes drilled at the ends of these plates , and are fixed by the polymer compound poured into these holes.