CH200428A - Device for damping vibrations in rotating shafts. - Google Patents

Description

Device for damping vibrations in rotating shafts. The invention relates to a device for damping vibrations in rotating shafts by means of masses which have at least one circular-cylindrical rolling surface and thus perform an oscillating rolling movement on circular-cylindrical rolling tracks of a component rigidly connected to the shaft, and consists in that the The radius of the circular-cylindrical taxiway is greater than half the radius of curvature of the taxiway depending on the mass. A pendulum mass is advantageously matched to the torsional vibration to be damped in such a way that the ratio of the distance between the center of gravity of the mass and the center of the shaft to the difference between the radius of curvature of the runway and the radius of the rolling surface of the mass is less than the square of the ordinal number of the .torsional vibration to be dampened.

An example of the subject of the invention is shown in the drawing in Fig. 1 in longitudinal section and in Fig. 2 in cross-section simplified. With the shaft 1, whose torsional vibrations are to be dampened, is with the aid of the screws 2 a. wheel-like component 3 rigidly connected. A plurality of bores 4 are provided in component 3, into which the steel rings 5 forming the runways are pressed.

The two circular-cylindrical rolling surfaces having masses 6 have a steel jacket 7, in which a lead filling 8 is poured sen. After these cylindrical masses are inserted into the bores of the rings 5, the cover 9 - which has a larger diameter than the Boh stanchions of the rings 5 - is placed on the masses and held together with a bolt 10, so that the masses can no longer fall out of the rings.

The rolling motions caused by the masses during rotation superimposed with torsional vibrations. of shaft 1 are apparently a pendulum of the center of gravity 11 of the dimensions -6 around the center 12 of the runway. The pendulum radius B has the size of the difference between the radius of curvature r1 of the runway and the radius r2 of the rolling surface of the crowd. To tune a pendulum mass to the oscillation to be damped, the ratio of the distance Ro -I- R of the mass's center of gravity 12 to the shaft center 13 to the difference between the radius of curvature r1 of the runway and the radius r2 of the rolling surface of the mass is smaller than the square of the ordinal number of the torsional vibration to be damped.

It has been shown that torsional vibrations, even those with the lowest ordinal number, can only be effectively damped if the radius r2 of the rolling surface of the mass is greater than half the radius of curvature r1 of the runway. In practice, the radius r2 is approximately in the range of 0.9. r1 lie.

Instead of the same masses as shown, different masses can also be arranged, each of which dampens different rotary vibrations of the shaft. It is then advantageous to use two opposite masses in relation to the shaft center for damping one and the same vibration. Other masses can then dampen vibrations of a different order. Both the steel rings and the steel jacket can be hardened so that there is as little rolling friction as possible and no or only insignificant wear occurs during operation.

The advantage of the device described is that the movement of the masses is opposed only by rolling friction, so that the vibrations of the masses themselves, which dampen the harmful vibrations of the shaft, are not significantly damped.

The pendulum masses can also be designed in other ways. For example, solid rollers made of iron, steel or any other metal or alloy can be used. It can also be in closed cylindrical hollow body solid cylindrical filling materials that are rotatably mounted about their axis of gravity

Claims (1)

EMI0002.0047 EMI0002.0048