SU1155804A1 - Damper of torsional vibrations - Google Patents

Abstract

1. A torsional oscillation damper containing a flywheel and a hub mounted coaxially on a shaft with poles providing an elastic connection, differing in teM; that, in order to expand the range of frequencies and amplitudes of damped vibrations, it is equipped with a stack made of non-magnetic material, the bottom of which is mounted on the shaft, and the cylindrical part is located between the poles, it has holes for the pole, filled together with the gap between the flywheel and the magnetic hub fluid. 2, Damper according to claim 1, characterized in that the cylindrical c-cup is installed with the possibility of limited rotation relative to the hub and flywheel. "

Description

one

The invention relates to mechanical engineering, namely to torsional vibration damping devices.

A torsional vibration damper is known, where magnetic fluid is used as a friction element, the viscosity of which increases in a magnetic field lj.

However, this damper is not sufficiently effective due to a small change in the viscosity of the magnetic fluid.

Closest to the proposed technical essence and the achieved result is a torsional vibration damper containing a flywheel and an axle mounted coaxially on the shaft with poles providing their elastic coupling with the help of L2J electromagnetic forces.

In the indicated damper, an increase in the damping force does not exclude the occurrence of low-frequency oscillations of considerable amplitude.

The purpose of the invention is to expand the range of frequencies and amplitudes of damped vibrations.

This goal is achieved by the fact that the torsional vibration damper containing the installed coaxial

but on the shaft the flywheel and the hub with poles providing elastic coupling are provided with a nonmagnetic material cup, the bottom of which is mounted on the shaft, and the cylindrical part is located between the poles in it there are holes for the poles filled as well as the gap between the flywheel and the hub magnetic fluid .

In addition, the cylindrical stack is installed with the possibility of limited rotation relative to the hub and flywheel.

Fig. 1 shows a torsional vibration damper; a longitudinal section; ka fig. 2 same. Cross-section; in fig. 3 - experimental dependences of the moment, hpto-actionable introduction of a non-magnetic cup into the gap under the poles of the damper on the angle of rotation for different values of the induction of the magnetic field in the gap.

The torsional vibration damper contains a hub 2 mounted on a shaft 1 and a flywheel 3 with poles coaxially, a cylindrical design made of non-magnetic material

Cann 4 with slots (not indicated) under the poles and magnetic fluid 5, located in the gap between the hub 1 and the flywheel 3 and filling the slots under the poles of the cup 4. The interpolar spaces at the hub and flywheel are filled with non-magnetic material 6 (for example, filled with epoxy resin ). The handwheel 3 is rotatable with respect to the hub .2.

The magnetic field is created by poles, which are permanent magnets or excitation windings, which are located at the poles and are fed by electric current through brush contacts.

The device works as follows.

When the shaft 1 rotates with the hub 2, the field created by the poles carries along the pole field of the flywheel 3 linked to it and the latter rotates synchronously with the hub 2 and

shaft 1. The torsional vibrations appearing on shaft 1 due to magnetic coupling are transmitted to the flywheel 3 and are eliminated by the dynamic damping effect of the flywheel 3 relative to the hub 2. Magnetic fluid 5 located in the gap between the hub 2 and the macvic 3 and filling the slots in the cup 4, increases the magnetic coupling of the poles, which increases the efficiency of the damping. This is facilitated by the viscosity of the magnetic fluid, which increases with increasing magnetic field. Non-magnetic cylindrical cup 4 can be fixed

on the shaft, and the stepper has the ability to rotate relative to the shaft and the glass by an angle smaller than the angle corresponding to the width of the pole, or

the cup can rotate relative to the hub and shaft, and the hub is rigidly connected to the shaft. Other connection options are possible - a non-magnetic cylindrical cup can

be mounted on the flywheel rigidly or with the possibility of limited displacement or mounted on the shaft without restriction of rotation, or placed in the gap between; the hub and the flywheel without fastening in any part of the damper. The choice of the method of fastening a non-magnetic cylindrical cup depends on the type of wear. fluctuations.

Claims (1)

1. Torsional vibration damper, comprising a flywheel and a hub mounted coaxially on a shaft, with a cylindrical cup mounted with the possibility of limited rotation relative to the hub and the flywheel. figure 1