RU161107U1 - SELF-INSTALLING INDOOR BEARING - Google Patents

Abstract

A self-aligning main bearing, comprising a crankcase with a channel of the engine lubrication system, a cover and an intermediate detachable bearing mating with them on a spherical surface with a gap, characterized in that an annular open groove is made in the middle plane on the spherical surface of the intermediate detachable support, the end of which is connected by a drainage channel to the crankcase, on the unloaded half of the spherical surface of the crankcase and the cover, a pin is made, respectively, on the mating spherical surface The spacing of the intermediate detachable support is made with a groove of large overall dimensions; on the spherical surface of the crankcase and the cover, coaxial to the channel of the engine lubrication system, a cavity is made for continuous oil supply, the dimensions of which are larger than the dimensions of the channel of the engine lubrication system by an amount not less than the diametrical clearance between the groove and the pin, inside the intermediate detachable The bearings are equipped with main liners, to which the oil supply channel is connected from an annular open groove.

Description

The utility model relates to internal combustion engines and can be used in piston pumps, compressors, turbomachinery.

A known design of a thrust bearing of a turbine shaft (RU 2237200, F16C 17/02, F16C 23/02, publ. 09/27/2004), comprising a detachable cage of the bearing housing, provided with spherical pillows supporting the spherical pillows mutually conjugated with the upper half-liner and lower half-liner, in which channels of a metered supply of high-pressure lubricant are made from its working surface to the supporting spherical surface of the lower casing, moreover, between the contact spherical surfaces of the casing clips and the supporting pillows of the liners, they take a gap equal to at least 0.004 of the diameter of the sphere of the cage, and provide the lower cage with at least two branched internal channels for dosed supply of high-pressure lubricant alternately from an internal and external source. The design flaws are the presence of a complex oil supply system - the need for an additional high-pressure lubrication system, the design complexity, the presence of a large number of cavities and channels, a decrease in the load-bearing capacity of the oil layer in nominal mode due to the selection of lubricant from a hydrodynamic wedge in a sliding bearing on a spherical surface.

Closest to the claimed is the design of a thrust bearing (Truhniy A.D., Krupennikov B.N., Troitsky A.N. Atlas of constructions of turbine parts in 2 parts. Part 1, page 101. Part 2, page 74. 2007), containing two halves of the liner (support) pulled together by four special bolts and covered by two halves of the casing (crankcase and cover). The surfaces with which the insert (bearing) and the holder (crankcase and cover) are in contact are spherical. This makes it possible at the installation stage to establish the plane of the thrust segments parallel to the plane of the thrust rotor ridge. After assembly, the liner is rigidly fixed in the holder by means of a stopper that enters the slot of the insert and prevents its displacement relative to the holder.

The disadvantages of the closest analogue are the lack of the possibility of dynamic self-alignment of the bearing and, as a result, reduced performance due to the occurrence of uneven wear across the width of the bearing (edge effect), as well as the inability to use standard (standard) main bearings.

The utility model solves the problem of increasing the reliability of the main bearing of a piston machine by eliminating uneven wear across the width of the main bearings that occurs when the axes of the tenon (shaft) and the bearing are distorted under the action of perceived loads, and the possibility of using standard (standard) main bearings.

This is achieved by the fact that in a self-aligning main bearing containing a crankcase with a channel of the engine lubrication system, a cover and an intermediate detachable bearing mating with them on a spherical surface with a gap, according to a utility model, an annular open groove is made in the middle plane on the spherical surface of the intermediate split bearing, the end of which is connected by a drainage channel to the crankcase, a pin is made on the unloaded half of the spherical surface of the crankcase and cover, respectively a groove of the spherical surface of the intermediate detachable support is made a groove of large overall dimensions, on the spherical surface of the crankcase and cover coaxial to the channel of the engine lubrication system, a cavity is made for continuous oil supply, the dimensions of which are larger than the dimensions of the channel of the engine lubrication system by an amount not less than the diametrical clearance between the groove and the pin, inside intermediate detachable bearings installed main liners, which summed up the oil supply channel from the annular open groove.

The technical result is the self-alignment of the main bearing when the axes of the shaft and the bearing are skewed due to the rotation of the intermediate split bearing under the action of the moment that occurs when the diagram of hydrodynamic pressure is displaced along the width of the bearing relative to the vertical axis.

The essence of the utility model is illustrated by drawings. In FIG. 1 shows the upper half of the intermediate split support; FIG. 2 - lower half of the intermediate split support, in FIG. 3 is a cross-sectional view of the structure of a self-aligning main bearing; FIG. 4 is a view aa of FIG. 3, in FIG. 5 is a diagram of the forces acting upon rotation of the intermediate split bearing support; FIG. 6 is an example of a hodograph of forces acting on a first main bearing of a four-cylinder engine of type CHN 13/15.

The device contains the upper 1 and lower 2 halves of the intermediate detachable support, an annular open groove 3, a drainage channel 4, a groove 5, a pin 6, an oil supply channel 7, tightening screws 8, the crankcase 9, the cavity 10, the channel of the engine lubrication system 11, the upper 12 and lower 13 main bearings, cover 14. Position 15 denotes the main neck of the crankshaft.

The self-aligning main bearing contains an intermediate split bearing consisting of an upper half 1 and a lower half 2. An intermediate split bearing is installed in the crankcase 9 and secured from below by a cover 14. Each half of the intermediate split bearing is interfaced with the crankcase 9 and the cover 14 on a spherical surface. The coupling of the spherical surfaces is made with a gap.

In the middle plane of the bearing on the spherical surface of the intermediate split support, an open annular groove 3 is made with a drainage channel 4 of a reduced cross-section, which ensures continuous oil circulation.

A pin 6 is made on the unloaded (upper) half of the spherical surface of the crankcase and the cover (in the crankcase) to limit the rotation of the intermediate split support. Accordingly, on the mating spherical surface of the intermediate split support, a groove 5 of large overall dimensions is made.

Two standard (standard) main liners are installed inside the intermediate split support: the upper 12 and lower 13. Two halves of the intermediate movable support are rigidly connected, for example, with four clamping screws 8. An oil supply channel 7 is made inside the intermediate split support for supplying grease to the main bearings 12 and 13. On the spherical surface of the crankcase and the cover (in the crankcase), a cavity 10 is made coaxially with the channel 11 for continuous supply of engine oil from the channel of the engine lubrication system 11. The dimensions of the cavity 10 should be large the diameter of the channel 11 by an amount not less than the diametrical gap between the pin 6 and the groove 5, to ensure continuous communication between the oil supply channel 7 and the channel of the engine lubrication system 11 through an open ring groove 3 when the intermediate detachable support is rotated, the value of which is limited by the size of the diametrical clearance between the pin 6 and groove 5.

Self-aligning main bearing operates as follows. When the axes of the shaft 15 and the bearing are distorted, the diagram of hydrodynamic pressures in the lubricating layer is shifted along the width of the main liner 13 so that the maximum hydrodynamic pressure in the lubricating layer P _max is shifted by L _X from the central axis of the main liner (Fig. 5). The resulting force F _X (Fig. 5) acting on the intermediate movable support from the side of the oil layer is also shifted by the value of L _X. The resulting moment of force F _X overcomes the moment caused by the friction force F _TP by

shoulder R, the intermediate detachable support rotates in the direction of decreasing the skew angle of the axes of the shaft 15 and the bearing.

When the engine is running, the supply of engine oil to the main liners is carried out through the oil feed channel 7 in the intermediate split support. Ensuring continuous communication between the oil supply channel 7 and the channel of the engine lubrication system 11 through an open annular groove 3 is achieved by performing on the spherical surface coaxially with the channel 11 of the cavity 10 with overall dimensions greater than the diameter of the channel 11 by an amount not less than the diametrical clearance between the pin 6 and the groove 5.

Moreover, the presence of lubricant in the gap between the intermediate detachable support and the crankcase 9 is ensured by the presence of an open ring groove 3. The supply of lubricant is carried out, firstly, due to excess pressure in the annular open groove 3, due to the reduced cross-section of the drainage channel 4, and, secondly, due to changes in the magnitude and direction of the force acting on the main bearing during the working cycle.

Claims (1)

A self-aligning main bearing, comprising a crankcase with a channel of the engine lubrication system, a cover and an intermediate detachable bearing mating with them on a spherical surface with a gap, characterized in that an annular open groove is made in the middle plane on the spherical surface of the intermediate detachable support, the end of which is connected by a drainage channel to the crankcase, on the unloaded half of the spherical surface of the crankcase and the cover, a pin is made, respectively, on the mating spherical surface The spacing of the intermediate detachable support is made with a groove of large overall dimensions; on the spherical surface of the crankcase and the cover, coaxial to the channel of the engine lubrication system, a cavity is made for continuous oil supply, the dimensions of which are larger than the dimensions of the channel of the engine lubrication system by an amount not less than the diametrical clearance between the groove and the pin, inside the intermediate detachable The bearings are equipped with main liners, to which the oil supply channel is connected from an annular open groove.

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