RU2055246C1 - Twisted rope vibration insulator - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: vibration insulator has races with fastening members. A flexible friction member made up as a rope segment is wound by rows on guides arranged in parallel rows perpendicular to the axis of vibration insulator. A part of the guides are coupled with the races. The other part of the guides are made up as flexible plates secured to each other. Each of the guides can be made up as a flexible plate, the flexible plates being secured to each other. EFFECT: enhanced vibration insulation. 3 cl, 3 dwg

Description

 The invention relates to mechanical engineering and can be used to protect equipment from dynamic effects.

Known vibration isolators containing holders and associated cable segments [1 and 2]
The disadvantages of these vibration isolators are their low reliability and service life due to the high concentration of stresses in the cable at the points of its exit from the cages, as well as the low efficiency of vibration isolation due to insignificant energy dissipation in the cable during vibrations of the vibration-insulated object.

The closest to the invention in technical essence and the achieved result is a vibration isolator containing clips with fasteners and connecting their elastic friction element from a piece of cable, zigzag wound around guides arranged in rows parallel to the axis of the vibration isolator [3]
In this vibration isolator, flat coil springs are used as guides, which are difficult to manufacture, can lose their elastic properties and shape when exposed to extreme loads, and also do not provide connections between the cable sections located in rows parallel to the axis of the vibration isolator, which does not allow the use of an elastic friction element vibration isolator as an independent element when placing it between the supports without fastening with them.

 The purpose of the invention is to simplify the design, improving reliability.

 To do this, in a vibration isolator containing holders with fasteners, connecting their elastic friction element from a piece of cable, zigzag wound around guides arranged in rows parallel to the axis of the vibration isolator, the guides are made in the form of elastic plates located between the inner surfaces of the zig peaks in planes perpendicular to the axis of the vibration isolator and fixed to each other in these planes, for example, using jumpers.

 In FIG. 1 shows the proposed vibration isolator, a longitudinal section; in FIG. 2 section AA in figure 1; figure 3 design variant of the elastic friction element of a twisted cable vibration isolator when placed between the supports without fastening with them, a longitudinal section.

 The twisted cable vibration isolator (Fig. 1) contains clips 1 and 2 with fasteners 3 and 4, connecting their elastic friction element from a piece of cable 5, zigzag wound on guides, some of which are made in the form of hollow bushings 6, connected with clips 1 and 2 using rivets 7, and the other part of the guides is made in the form of elastic metal plates 8 located in planes perpendicular to the axis of the vibration absorber between the inner surfaces of the peaks of the zigs 9 and fixed to each other in these planes with the help of sliver 10.

 In the embodiment shown in FIG. 3, all the guides are made in the form of plates 8 connected by jumpers 10, which makes it possible to use it as an independent element placed between supports 11 and 12 without fastening with supports.

 The cable 5 is winded onto the guides on a mandrel that fixes the relative position of the guides along a contour corresponding to the contour of the elastic-friction element.

 Twisted cable vibration isolator works as follows.

 The vibration energy from the vibrating object is transmitted through the cage 1 (or support 11 in the design shown in FIG. 3) to the elastic friction element 5, which undergoes cyclic deformation along the zigzag rows of the cable 5 in the direction of the longitudinal axis of the vibration isolator. At the same time, the crossing sections of the cable 5 located between adjacent plates 8 in each row will work for transverse bending. The working bend of the vibration isolator is provided due to the flat shape of the guides 8, which are information limiters when exposed to extreme loads. The jumpers 10 fix the relative position of the plates 8 relative to the vertices of the zigs 9, preventing the possibility of rotation of the plates 8 relative to the plane perpendicular to the longitudinal axis of the vibration isolator, which ensures the preservation of the shape of the cable 5 attached to it during winding.

 In addition, the jumpers 10 fix the adjacent zigzag rows of the cable 5, which makes it possible to use the elastic-friction element as an independent structure, which can be connected to the clips 1 and 2.

 The proposed design of a twisted cable vibration isolator is more technologically advanced, since the plates 8 are easier to manufacture than flat coil springs, more reliable, since extreme loads do not deform the plates 8 due to their almost infinite transverse compression rigidity, and can also be used without clips 1 and 2 as a standalone design.

Claims (2)

 1. A CIRCULAR CABLE VIBRATION ISOLATOR containing clips with fasteners, an elastic friction element from a piece of cable, zigzag wound in rows along guides arranged in parallel rows perpendicular to the axis of the vibration isolator, and part of the guides is connected to the clips, characterized in that the other part of the guides is made in the form of an elastic fixed to each other.  2. A twisted cable vibration isolator containing holders with fasteners and an elastic friction element placed between them from a cable segment zigzag wound in rows on guides arranged parallel to the rows perpendicular to the axis of the vibration isolator, characterized in that the guides are made in the form of elastic plates fixed to each other.

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