RU2020316C1 - Rope vibration insulator - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: rope vibration insulator has two races provided with fastening members. Coaxial flexible bushings are interposed between the races. Flexible member is interposed between the bushings. Lateral rigidity of the flexible bushings is of the same order of lateral rigidity of the flexible member. EFFECT: improved design. 2 dwg

Description

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

 Known vibration isolators containing clips and related cable segments [1].

 The disadvantages of these vibration isolators are their low reliability and resource due to the high concentration of stresses in the cable in the places where it exits the cages and 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 two clips with fasteners, an elastic element, wound with a piece of cable on the bushings, evenly distributed around the circle, with the formation of loops consisting of arcuate sections of the cable, enveloping the bushings with diametrically opposite them sides and rectilinear crossing sections of the cable located between the bushings, and part of the bushings is fixed on the clips [2].

 The known vibration isolator has high reliability, but has insufficient bearing capacity due to low stiffness in the transverse bending of the elastic element, as well as insufficiently high vibration-proof qualities at resonant operation modes due to low dissipative properties.

 The purpose of the invention is to increase the bearing capacity and quality of vibration isolation at resonant modes of operation.

 This goal is achieved by the fact that in the vibration isolator containing two cages with fasteners, an elastic element wound by a piece of cable onto bushings uniformly distributed around the circle, with the formation of loops consisting of arcuate sections of the cable, enveloping the bushings from their diametrically opposite sides, and rectilinear crossing sections of the cable located between the bushings. Part of the bushings is fixed on the clips. The elastic element is enclosed between two additional coaxially located elastic bushings, the transverse stiffness of which is commensurate with the transverse stiffness of the elastic element, wound with a cable.

 The claimed technical solution differs from the prototype in that the elastic element is enclosed between two additional coaxially located elastic bushings, the transverse rigidity of which is comparable with the transverse rigidity of the elastic element. This difference allows us to conclude that the proposed technical solution meets the criterion of "Novelty."

 Signs that distinguish the claimed technical solution from the prototype, are not identified in other technical solutions, and, therefore, provide the claimed solution corresponding to the criterion of "Significant differences".

 In FIG. 1 shows the proposed vibration isolator, section; figure 2 is the same, left view.

 The vibration isolator contains clips 1 and 2 with fasteners 3 and 4, an elastic element, wound with a piece of cable on bushings 5, 6 and 7, distributed around the circle, with the formation of loops consisting of arcuate sections 8 of the cable enveloping the bushings from their diametrically opposite sides, and rectilinear crossing sections 9 of the cable located between the bushings. The bushings 6 and 7 are fixed on the clips 1 and 2 with rivets 10 passing through the bushings 6 and 7 and the clips 1 and 2. The ends 11 of the cable are threaded through the bushings 5 and fixed in them from opposite sides by soldering. An elastic element is enclosed between two coaxially located elastic bushings 12 and 13 so that the vertices of the arcuate sections of the cable 8 are in contact with the surfaces of the additional bushings 12 and 13. The cable is wound onto the bushings 5, 6 and 7 on a special technological mandrel.

 Vibration isolator works as follows.

 The vibration energy from the vibrating object transmitted through the clip 1 and the rivets 10 of the sleeve 6 connected to it to the elastic friction element, consisting of a cable and bushings 5, 6 and 7, and enclosed between two coaxial elastic bushings 12 and 13, is dissipated by the elastic friction element due to internal friction between the wires and strands of the cable, the friction of the cable on the bushings 5, 6 and 7, the friction between the rectilinear crossing sections of the cable 9, the additional friction of the vertices of the arcuate sections of the 8 cable on the bushings 12 and 13.

 Large total frictional forces provide the vibration isolator with high quality vibration isolation at resonant modes of operation.

 The increase in the bearing capacity of the vibration isolator is ensured by its greater transverse bending rigidity compared to the prototype due to the presence of additional bushings 12 and 13, which significantly increase the moment of inertia of the cross section of the vibration isolator in all directions of the loads acting on it.

Claims (1)

 CABLE VIBRATION INSULATOR containing two clips with fasteners and placed between the clips an elastic element in the form of bushings evenly distributed around the circumference, and a piece of cable wound on the bushings from their diametrically opposite sides with the formation of loops consisting of arcuate sections of the cable and straight crossing sections of the cable located between the bushings, some of which are fixed on the clips, characterized in that it is equipped with two additional elastic bushings mounted coaxially relative but one other and the elastic element, the elastic element is placed between additional bushings, the transverse stiffness of which is comparable with the transverse stiffness of the elastic element.

Images