JP2012052632A - Flexible pad bearing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a flexible pad bearing which can enhance the damping property of whirl vibration and forced vibration.SOLUTION: A flexible pad bearing 10 which supports the radial load or the thrust load of a rotary shaft 1 consists of: a fixed member 12 (outer shell) facing a rotation surface 11 (column outer face) rotating centering the axis of the rotary shaft, being fixed spaced apart from this; a plurality of support portions 14 extending toward the direction of the rotation surface from the fixed member; and a plurality of plate-like pads 16 having a sliding surface 16a (arc-shaped inner plane) extending along the rotation surface 11 to which a part is fixed to the end portion of the rotation surface side, of a support portion. The pad 16 has a through-hole 17 penetrating from the sliding surface 16a to the back surface 16b thereof.

Description

  The present invention relates to a flexible pad bearing for a rotating shaft that rotates at a high speed.

  A tilting pad bearing schematically shown in FIG. 1 is known as a bearing for a rotating shaft that rotates at a high speed, such as a turbo compressor. The tilting pad bearing has a pad 2 that follows the movement of the axis of the rotating shaft 1, and the pad 2 freely swings to cause self-excited vibration (referred to as a whirl) of the rotating shaft 1. It has features that can be suppressed.

  However, the tilting pad bearing has a complicated structure because the pad 2 and the bearing housing 3 are separated from each other, and another member is required to position the plurality of pads 2.

  In view of this, a bearing (such as a flexible pad bearing, a flex bearing, or a differential pad bearing) in which the pad and the bearing housing are integrated has been created and used (see Patent Document 1 and Patent Document 2).

  Hereinafter, a bearing in which the pad and the bearing housing are integrated is referred to as a “flexible pad bearing”.

Japanese Unexamined Patent Publication No. 09-1000082, “Zero Clearance Bearing” JP 2000-205251 A, “Bearing Mechanism”

In the above-described flexible pad bearing, since a part of the pad is integrated with the bearing housing, when the pad swings, a moment for supporting the pad deformation is generated at the connecting portion of the pad. Therefore, the pad cannot swing freely, and the off-diagonal term of the oil film rigidity does not become zero like the tilting pad bearing, and the self-excited vibration (whirle) of the rotating shaft 1 may occur.
Therefore, in the flexible pad bearing, in order to suppress self-excited vibration and forced vibration, it is necessary to improve the damping characteristics.

  The present invention has been developed to meet the above-described needs. That is, the objective of this invention is providing the flexible pad bearing which can improve the damping characteristic of a self-excited vibration and a forced vibration.

According to the present invention, a flexible pad bearing for supporting a radial load or a thrust load of a rotating shaft,
A fixing member that faces a rotating surface that rotates about the axis of the rotating shaft and is fixed at a distance from the rotating surface;
A plurality of support portions extending in a direction of the rotation surface from the fixing member;
A plurality of flat pads having a sliding surface partially fixed to the rotating surface side end portion of the support portion and extending along the rotating surface;
The pad has a through-hole penetrating from the sliding surface to the back surface thereof, and a flexible pad bearing is provided.

According to an embodiment of the present invention, the rotating surface is a circular or hollow circular rotating disk orthogonal to the axis of the rotating shaft,
The fixed member is a circular or hollow circular fixed disk facing the rotating disk,
The support portion is fixed to one surface of the fixed disk and extends in the axial direction.
The pad is cantilevered at the center or end,
The sliding surface is a fan-shaped plane along the rotating disk.

According to another embodiment of the present invention, the rotating surface is a cylindrical outer surface centered on the axis of the rotating shaft,
The fixing member is an outer shell having a cylindrical inner surface surrounding the column outer surface,
The support portion is fixed to the inner surface of the outer shell and extends radially inward,
The pad is cantilevered at the center or end,
The sliding surface is an arc-shaped inner surface along the cylindrical outer surface.

According to the present invention, the plurality of flat pads having sliding surfaces extending along the rotating surface have through holes penetrating from the sliding surface supporting the rotating surface to the back surface thereof. When the pad is deformed and the pad is deformed, an action of moving the fluid located in the back surface gap of the pad and an action of moving the fluid from the sliding surface to the back surface through the through hole are generated.
Therefore, since both the viscous resistance of the back surface gap of the pad and the viscous resistance of the flow passing through the through hole act on the pad, a large damping force works, and self-excited vibration and forced vibration can be suppressed.

It is a schematic diagram of the conventional tilting pad bearing. 1 is a first embodiment of a flexible pad bearing according to the present invention. It is 2nd Embodiment figure of the flexible pad bearing by this invention. It is a 3rd embodiment figure of a flexible pad bearing by the present invention.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, the same code | symbol is attached | subjected to the common part in each figure, and the overlapping description is abbreviate | omitted.

FIG. 2 is a first embodiment of the flexible pad bearing 10 according to the present invention. In this figure, (A) is a front view from the axial direction of the rotating shaft 1, and (B) is a BB cross-sectional view of (A). In FIG. 2B, reference numeral 11 denotes a rotating surface that rotates around the axis of the rotating shaft.
In this figure, the rotation surface 11 is shown by a plane. However, the rotation surface 11 may be other than a plane.
In FIG. 2A, illustration of the rotating surface 11 (rotating disk) is omitted.
This figure shows a case where the rotating surface 11 is a circular or hollow circular rotating disk orthogonal to the axis of the rotating shaft 1, and the flexible pad bearing 10 of the present invention supports the thrust load of the rotating shaft 1. It functions as a thrust bearing.

  2A and 2B, the flexible pad bearing 10 includes a fixed member 12, a plurality of support portions 14, and a plurality of pads 16 that are integrally formed.

  The fixed member 12 is a circular or hollow circular fixed disk that faces the rotating disk 11, faces the rotating surface 11, and is fixed at a distance from the rotating surface 11. The distance between the surface 12a (upper surface in the figure) of the fixing member 12 and the rotating surface 11 is constant in this example, but may be changed.

  The plurality of support portions 14 extend from the surface 12 a of the fixing member 12 in the direction of the rotation surface 11. That is, the support portion 14 is fixed to one surface of the fixed disk 12 and extends in the axial direction. In this example, the shape of the support portion 14 is a rod shape linearly extending in the direction of the rotation surface 11, but may be other shapes (circular, triangular, S-shaped, etc.). The support portions 14 are preferably provided at the same interval along the surface 12a of the fixing member 12, but may be provided at different intervals.

  The plurality of pads 16 are partially fixed to the rotation surface side end portion (upper end in the drawing) of the support portion 14, and have a sliding surface 16 a extending along the rotation surface 11. In this example, the pad 16 is cantilevered at the center. The shape of the pad 16 is a flat plate having a constant thickness in this example, but may be another shape (for example, a tapered shape). Moreover, although the length along the rotation surface 11 of the pad 16 is the same in this example, different lengths may be sufficient.

  The sliding surface 16a is preferably parallel to the rotating surface 11, but may be inclined partially or entirely. In this example, the sliding surface 16 a is a fan-shaped plane along the rotating disk 11.

  The pad 16 further has a through hole 17 penetrating from the sliding surface 16a to the back surface thereof. In this example, one through hole 17 is provided near the free end of the pad 16, but two or more may be provided. Moreover, you may change suitably the magnitude | size of the through-hole 17 with use conditions.

2A and 2B, the center of the pad 16 is fixed to the support portion 14, and both ends are cantilevered at the center.
This configuration is suitable when the rotating surface 11 moves in both the left and right directions in FIG.

FIG. 3 is a second embodiment of the flexible pad bearing according to the present invention. In this figure, (A) is a front view from the axial direction of the rotating shaft 1, and (B) is a BB cross-sectional view of (A).
This figure shows a case where the rotating surface 11 is a circular or hollow circular rotating disk orthogonal to the axis of the rotating shaft 1, and the flexible pad bearing 10 of the present invention supports the thrust load of the rotating shaft 1. It functions as a thrust bearing.

  In this example, the fixing member 12 is a circular or hollow circular fixed disk facing the rotating disk 11. The support portion 14 is fixed to one surface of the fixed disk 12 and extends in the axial direction. The sliding surface 16 a is a fan-shaped flat surface along the rotating disk 11.

3A and 3B, one end of the pad 16 is fixed to the support portion 14 and the other end is cantilevered as a free end.
This configuration is suitable when the rotating surface 11 moves only in the right direction in FIG.
The pad 16 further has a through hole 17 penetrating from the sliding surface 16a to the back surface thereof. In this example, two through holes 17 are provided in the vicinity of the free end of the pad 16, but may be one or three or more. Moreover, you may change suitably the magnitude | size of the through-hole 17 with use conditions.
Other configurations are the same as those of the first embodiment.

In the configuration of the first embodiment and the second embodiment, the pad 16 is deformed in accordance with the load on the rotating surface 11 on the free end side that is cantilevered. The degree of deformation is set by the shape and thickness of the pad 16.
Further, the gap between the front surface 12a of the fixing member 12 and the back surface 16b of the pad 16 is set to be the same as or substantially the same as the clearance between the rotating surface 11 and the sliding surface 16a. The fluid pressure located in the gap also varies, and the deformation of the pad 16 is suppressed by the viscous resistance of the back gap of the pad 16.
Here, the fluid is, for example, lubricating oil or water.

Further, in the configuration of the first embodiment and the second embodiment, when the pad 16 is deformed, an action of moving the fluid from the sliding surface 16a to the back surface through the through hole 17 is generated. The viscous resistance of the fluid acting on the pad 16 acts on the pad 16.
The size and quantity of the through holes 17 are set so that a desired amount of viscous resistance can be obtained.

  Therefore, with the above-described configuration, both the viscous resistance of the back surface gap of the pad 16 and the viscous resistance of the fluid passing through the through hole 17 act on the pad 16, so that a large damping force acts and self-excited vibration and forced vibration Can be suppressed.

  FIG. 4 is a diagram of a third embodiment of a flexible pad bearing according to the present invention. This figure shows a case where the rotating surface 11 is a cylindrical outer surface centered on the axis of the rotating shaft 1, and the flexible pad bearing 10 of the present invention functions as a radial bearing that supports the radial load of the rotating shaft 1. .

In FIG. 4A, the fixing member 12 described above is an outer shell having a cylindrical inner surface 12 a surrounding the column outer surface 11, faces the rotating surface 11, and is fixed at a distance from the rotating surface 11. .
The support portion 14 extends from the surface 12 a of the fixing member 12 in the direction of the rotation surface 11. That is, the support portion 14 is fixed to the inner surface of the outer shell 12 and extends radially inward.
The pad 16 has a sliding surface 16 a that is partially fixed to the end portion (upper end in the drawing) of the support portion 14 and extends along the rotation surface 11. In this example, it is cantilevered at the center.
The sliding surface 16 a is an arc-shaped inner surface along the outer cylindrical surface 11.

In this example, the gap between the end faces of the pad 16 is set to be the same as or substantially the same as the gap between the front surface 12a of the fixing member 12 and the back surface 16b of the pad 16, but may be a gap close to zero.
In this figure, the gap between the surface 12a of the fixing member 12 and the back surface 16b of the pad 16 is shown larger than the gap between the rotating surface 11 and the sliding surface 16a, but may be the same or similar.
Other configurations are the same as those of the first embodiment.

With this configuration, as schematically shown in FIGS. 4B and 4C, when the load on the rotating surface 11 (cylinder outer surface) fluctuates and the pad 16 is deformed, the fluid located in the back gap of the pad 16 is moved. The action and the action of moving the fluid from the sliding surface 16a to the back surface through the through hole 17 occur.
Therefore, since both the viscous resistance of the back surface gap of the pad 16 and the viscous resistance of the fluid passing through the through hole 17 act on the pad 16, a large damping force works to suppress self-excited vibration and forced vibration. it can.
Although the third embodiment has been schematically shown and described here, the same operation occurs in the first and second embodiments.

  According to the configuration of the present invention described above, when the rotating surface 11 vibrates and approaches the pad 16, fluid pressure is generated and the pad is deformed. At this time, a damping force is applied by the fluid filled in the gap on the back surface of the pad. The damping force also acts when the lubricating oil passes through the through hole 17 between the pad back surface and the rotating surface 11. The latter action also has an effect of increasing the pressure on the back surface of the pad, and generates a greater damping force.

  In addition, this invention is not limited to embodiment mentioned above, is shown by description of a claim, and also includes all the changes within the meaning and range equivalent to description of a claim.

1 rotating shaft, 10 flexible pad bearing, 11 rotating surface (cylindrical outer surface, rotating disk),
12 fixing member (outer shell, fixed disk), 12a surface,
14 support parts, 16 pads,
16a sliding surface (arc-shaped inner surface, fan-shaped plane), 16b back surface,
17 Through hole

Claims (3)

A flexible pad bearing that supports a radial load or a thrust load of a rotating shaft,
A fixing member that faces a rotating surface that rotates about the axis of the rotating shaft and is fixed at a distance from the rotating surface;
A plurality of support portions extending in a direction of the rotation surface from the fixing member;
A plurality of flat pads having a sliding surface partially fixed to the rotating surface side end portion of the support portion and extending along the rotating surface;
The said pad has a through-hole penetrated from the said sliding surface to the back surface, The flexible pad bearing characterized by the above-mentioned. The rotating surface is a circular or hollow circular rotating disk orthogonal to the axis of the rotating shaft,
The fixed member is a circular or hollow circular fixed disk facing the rotating disk,
The support portion is fixed to one surface of the fixed disk and extends in the axial direction.
The pad is cantilevered at the center or end,
The flexible pad bearing according to claim 1, wherein the sliding surface is a fan-shaped flat surface along the rotating disk. The rotating surface is a cylindrical outer surface centered on the axis of the rotating shaft,
The fixing member is an outer shell having a cylindrical inner surface surrounding the column outer surface,
The support portion is fixed to the inner surface of the outer shell and extends radially inward,
The pad is cantilevered at the center or end,
The flexible pad bearing according to claim 1, wherein the sliding surface is an arc-shaped inner surface along the outer surface of the cylinder.