SU1663465A1 - Balancer - Google Patents

Abstract

The invention can be used to balance rotors and improves reliability by duplicating body fixation. The device comprises a base 1 mounted on the rotor 2. A cylindrical body 3 is mounted on the base with a gear wheel 5 with a cone 6 mounted on the end wall 4 on the outside. A planetary mechanism with two corrective masses 7, 8 rotated in the same direction with close ones is placed inside the cylindrical body. speeds The cylindrical housing interacts with an electromagnetic brake 13. The housing fixation mechanism comprises an annular coil 14 and an axially mounted ring 15 on the rotor with fingers 16 axially spring-loaded and intended to interact with the gear wheel 5. The annularly mounted axially moves and The conical sleeve 17, designed to interact with the cone 6, is spring-loaded in the same direction. 3 Il.

Description

masses 7 and 8, rotated in one direction with close velocities. The cylindrical housing interacts with the electromagnetic brake 13. The fixation mechanism of the housing contains an annular coil 14 and a ring 15 mounted on the rotor with the possibility of axial movement.

with the fingers 16, spring-loaded in the axial direction and intended to interact with the gear wheel 5. On the ring, the sleeve 17 is mounted for axial movement and spring-loaded in the same direction, designed to interact with the cone 6. 3 Il.

The invention relates to mechanical engineering and can be used for balancing rotors.

The aim of the invention is to increase reliability by duplicating the fixation of the case.

FIG. 1 shows the proposed device, the cut; in fig. 2 — node I in FIG. one; in fig. 3 - node II in FIG. one.

The device contains a base 1 mounted on a rotor 2. A cylindrical body 3 with a gear 5 with a cone 6 mounted on the end wall 4 is mounted on the base. A planetary mechanism with two correcting masses 7 and 8 rotated in one direction is placed inside the cylindrical body with close speeds. The planetary mechanism is made up of wheels 9 and 10 connected to the base, the ratio of the teeth of which is in the range of 0.95-1, and two associated satellites 11 and 12, which are installed eccentrically in a cylindrical housing. The numbers of the teeth of the corrective masses differ from the wheels 9 and 10 per unit up or down. The cylindrical case, which is the carrier of the satellites, interacts with an electromagnetic brake 13. The case fixation mechanism contains an annular coil 14 and an axially mounted ring 15 on the rotor with fingers 16 axially spring-loaded and intended to interact with the gear wheel 5. On the ring mounted with the possibility of axial movement and spring-loaded in the same direction conical sleeve 17, designed to interact with the cone.

The device works as follows.

By turning on the coil 14, the ring 15 is retracted from the housing 3. In this case, the frictional interaction of the cone 6 and the conical sleeve 17 opens, and the finger 16 is disengaged from the gear wheel 5 and the cylindrical body is completely released. Then the electromagnetic brake 13 is turned on and the casing starts to rotate relative to the base 1. Satellites 11 and 12 run in wheels 9 and 10 and transmit rotation to correction masses 7 and 8, which begin to rotate in one direction with close speeds. As a result, the total unbalance vector of the corrective masses in the correction plane describes the Archimedes spiral, and the vibration level makes

periodic changes. After the permissible vibration level is reached, the brake 13 and the coil 14 are disconnected. The conical sleeve 17 and the finger 16 carry out a duplicated fixation of the cylindrical body 3 with high reliability, and the balancing is completed.

Claims (1)

The claims of the rotor balancing device containing an electromagnetic brake, a base, a cylindrical body mounted on it with a gear wheel mounted on the end wall outside and a planetary mechanism with two correcting masses rotated in one direction at close speeds placed inside, a movable ring and fingers designed to interact with a gear wheel, characterized in that, in order to increase reliability by duplicating the fixation of the housing, a cone is made on the gear wheel, the ring is mounted for axial movement, the finger is spring-loaded in the axial direction, and the device is equipped with an axial movement on the ring and the conical sleeve is spring-loaded in the same direction, designed to interact with the conus nus. four FIG. / FIG. five Editor A.Lezhnina Compiled by V.Sutormin Tehred M. Morgent.al I (turned) Proofreader S.Shevkun