SU1510971A1 - Movable carrier mechanism - Google Patents

Abstract

The invention relates to the processing of metals by pressure and can be used in devices for forging by rolling. The purpose of the invention is to increase reliability. The spherical motion mechanism contains a compactor with a planet carrier 6 connected through a self-aligning bearing (SP) with an eccentric rotor 2. In the radial cavity 1 of the rotor 2 there is a cylindrical pin (CC) 3 of the housing 4 SP. The latter is made in the form of a ring 5 with a spherical outer surface and a spherical surface of the housing 4 SP mated with it. From the side of the central cooling center 3, the hermetic cavity (P) 11 is made, which is connected with P 1 under CC 3. The working areas of the communicated P 11 and 1 are equal. When operating in P 11 and 1, the pressure is almost the same and the force from the carrier 6 is not transmitted through the housing 4, which reduces the wear of the working surfaces of the SP. 1 il.

Description

The invention relates to the processing of metals by pressure and can be used in devices for forging by rolling.

The aim of the invention is to increase reliability by reducing the loads in the bearing pair under eccentric loading of its more intensive lubrication and, accordingly, the durability of the bearing assembly.

The drawing schematically shows a spherical mechanism in the plane of the greatest eccentricity of the rotor, a longitudinal section.

In the cavity 1 of the eccentric rotor 2 there is a cylindrical pin 3

housing 4, covering the spherical ring S self-aligning bearing, located on the carrier 6 of the press. In the trunnion 3 there is a spool housing 7 with a rolling pin 8, a spring-loaded spring 9 and abutting it. through the probe 10 into the bottom of the cavity 1. In the housing A, on the side of the spherical ring S, a cavity 11 is made, which is connected by a channel 12 to the cavity 1 connected through the valve with a high line

pressure 13 or with discharge 14.

Spiro-moving mechanism works as follows.

The axis of the carrier 6 position of the press is determined by the position of the rolling pin 8 in the body of the spool 7.

with

3151

The scientific research institute of efforts from the side of the carrier 6 along its axis the axle pivot 3 of the body moves to the left under the pressure of fluid in the cavity 1. The body of the spool 7 is displaced relative to the rolling pin 8 and the cavity 1 communicates with the drain 1. The fluid pressure in the cavity 1 drops to a value proportional to the force on the carrier 6. When the force on the carrier 6 increases, the body of the spool 7 together with the body 4 is displaced relative to the rolling pin 8 to the right. In this case, the high pressure line 13 communicates through the valve with the cavity 1, the pressure in the latter increases to equalize the forces on the carrier side 6. Since the cavity 11 is connected by channel 12 to the cavity 1, the pressure in them is always almost equal. Consequently, the housing 4 at any pressure in the cavity 11 and T is unloaded in the direction of the axis of the axle 3, i.e. force from the carrier 6 through the body k does not transmit, c.

The force on the carrier 6 always acts along the axis of the trunnion 3 of the housing 4, since during rotation of the eccentric rotor 2. The force displaced relative to the vertical axis of the spider-moving mechanism is perceived by the pressing tool and rotates at the same angular velocity. Regardless of the position of the eccentric rotor 2, the body k, which encloses the spherical ring 5 of the bearing, is relieved by forces on the carrier 6, which reduces wear on the working surface of the bearing. In addition, the hydrostatic sliding bearing with respect to the rolling bearing of the same dimensions has a greater bearing capacity. This circumstance, intensive cooling of the bearing due to the natural flow of the fluid and effective lubrication contribute to the efficiency of the sphere-movable mechanism, which allows to increase the frequency of oscillations of the extruder and, consequently, the performance of the forging process by rolling.

Claims (1)

Invention Formula Spherical motion mechanism containing an extruder with a carrier connected through a self-driving inflowing sub-hip with an eccentric rotor, in a radially directed cavity of which a cylindrical pin of the bearing housing is placed in its radially directed cavity. In order to increase reliability, the self-aligning bearing is made in the form of a ring mounted on a carrier with a spherical outer surface. spherical surface and conjugate to it. the housing on which the cavity is made from the side of the cylindrical pin of the bearing housing is hydraulically sealed and communicated with the cavity under the journal, while the working areas of the reported cavities are equal. / V