KR20220134129A - Air foil thrust bearing - Google Patents

Abstract

The present invention relates to an airfoil thrust bearing comprising: a base plate; a bump foil which has uneven elastic bumps, and which is layered on the base plate so that one circumferential end portion thereof can be coupled to the base plate; and a top foil which is layered thereon to cover the bump foil, and which has one circumferential end portion coupled to the base plate, wherein the bump foil is formed so that the height of the elastic bumps in a partial region adjacent to an outer diameter side in a radial direction can be lower than the height of the elastic bumps in the remaining region, and the bump foil has a cutting part where at least part of the elastic bumps disposed in a region between the elastic bumps disposed on the outer diameter side in the radial direction and the elastic bumps disposed on an inner diameter side have been deleted, so the airfoil thrust bearing has higher durability since a primary damping friction part is separated from the region with the greatest energy loss depending on the speed of a rotating body during excitation.

Description

Air foil thrust bearing {Air foil thrust bearing}

The present invention relates to an air foil thrust bearing supporting an axial load acting on a rotating shaft, such as a turbo blower or a turbo compressor that compresses and supplies air by rotating an impeller at high speed using the rotational force of a motor.

Thrust bearings are used to support axial loads in turbo blowers and turbo compressors. Among thrust bearings, air foil thrust bearings are mainly used to support axial loads of rotating shafts rotating at high speed.

The conventional air foil thrust bearing includes a base plate 10 formed of a donut-shaped plate as shown in FIG. 1, a plurality of bump foils 20 spaced apart from each other along the circumferential direction, and each of the bump foils 20 disposed on the Consists of a plurality of top foils (30).

Here, the air foil thrust bearing is fixed by spot welding a plurality of bump foils 20 on the base plate 10, and after the top foil 30 is disposed on each bump foil 20, the base plate 10 ), the top foils 30 are fixed by spot welding. In addition, when these air foil thrust bearings are mounted on a turbo blower or the like, a lot of frictional heat is generated by contact between the disk-shaped thrust runner coupled to the rotating shaft and rotating together and the top foil of the air foil thrust bearing.

Here, in the conventional air foil thrust bearing, since the thrust runner, which is a rotating body, moves in a circular motion, the angular velocity is the same, but the linear velocity according to the radial position gradually increases toward the outer diameter side. However, according to the increased linear speed, the load bearing capacity of the air flowing between the top foil and the rotating body of the air foil thrust bearing increases, but high heat is generated due to the friction between the air and the top foil, and the rotating body is about 100,000 RPM. In the case of the outer diameter side during high-speed rotation exceeding In addition, friction occurs first in the area of the top foil corresponding to the height of the elastic bump of the bump foil during excitation (main excitation support). That is, as shown in FIG. 2 , the conventional air foil journal bearing partially overlaps the area A1 having the highest energy loss and the main excitation support A2 on the top foil 30 , so durability is deteriorated.

KR 10-0954066 B1 (2010.04.13.)

The present invention has been devised to solve the above-described problems, and an object of the present invention is to first support a load when it has a portion with the largest energy loss according to the rotational speed of a rotating body to primarily cause damping friction. It is to provide an air foil thrust bearing capable of improving durability by allowing the support portion to be separated.

In addition, since the height of the top foil may be affected by the inner-diameter elastic bumps in the radial direction, an air foil thrust bearing capable of minimizing the influence on the height of the top foil by the inner-diameter elastic bumps is provided.

Air foil thrust bearing of the present invention for achieving the object as described above, the base plate; a bump foil having concave-convex elastic bumps formed thereon, the bump foil being laminated on the base plate and having one circumferential end coupled to the base plate; and a top foil laminated to cover the bump foil and having one end of the circumferential direction coupled to the base plate. In the bump foil, the heights of the elastic bumps in some areas adjacent to the outer diameter in the radial direction are lower than the heights of the elastic bumps in the remaining areas, and the bump foil includes elastic bumps disposed on the outer diameter side in the radial direction. A cutout may be formed in which at least a portion of the elastic bumps disposed in the area between the elastic bumps disposed on the inner diameter side is removed.

In addition, the cut-out portion of the bump foil may be formed to be connected across a plurality of elastic bumps adjacent to each other in the circumferential direction.

In addition, the bump foil may be formed with a slit passing through both surfaces in the thickness direction from the free end along the circumferential direction.

In addition, the cutout portion of the bump foil may be connected to the slit to be concave in a radial direction.

In addition, in the bump foil in which the cutout is formed, an offset portion having a shape corresponding to the shape of the cutout may be convexly formed on the opposite side where the cutout is formed in a radial direction.

In addition, a concave portion may be formed in a shape corresponding to the offset portion in an elastic bump radially adjacent to the elastic bump on which the offset portion is formed.

Also, a protruding distance of the offset portion in the radial direction may be smaller than a depth of the cutout portion.

The air foil thrust bearing of the present invention has the advantage of having higher durability because the primary damping friction part is separated when the region having the largest energy loss according to the speed of the rotating body is separated.

In addition, it is possible to minimize the influence on the height of the top foil due to the inner diameter side elastic bumps, there is an advantage that can secure high durability against excitation.

1 is a perspective view showing a conventional air foil thrust bearing.
FIG. 2 is a partial plan view showing a region having the largest energy loss and a main excitation support in a conventional air foil thrust bearing.
3 to 5 are an exploded perspective view, an assembled perspective view, and an upper plan view showing the air foil thrust bearing according to the first embodiment of the present invention.
6 and 7 are cross-sectional views AA′ and BB′ of FIG. 5 .
FIG. 8 is a cross-sectional view illustrating a state in which a part of the top foil is elastically deformed when the thrust runner, which is a rotating body, is in contact with the top foil in a state of being rotated at a high speed in the cross section of FIG. 7 .
9 is a cross-sectional view showing a case in which there is no cutout according to the present invention as compared with FIG. 8 .
10 is a plan view illustrating a bump foil of an air foil thrust bearing according to a second embodiment of the present invention.

Hereinafter, the air foil thrust bearing of the present invention as described above will be described in detail with reference to the accompanying drawings.

<Example 1>

3 to 5 are an exploded perspective view, an assembled perspective view, and an upper plan view showing an air foil thrust bearing according to the first embodiment of the present invention, and FIGS.

As shown, the air foil thrust bearing according to the first embodiment of the present invention may be largely composed of a base plate 100 , a bump foil 200 , and a top foil 300 .

The base plate 100 may be formed in the form of a disk in which a hollow hole penetrating both surfaces in the thickness direction is formed in the central portion.

A plurality of bump foils 200 may be arranged to be spaced apart from each other in the circumferential direction. In addition, the bump foils 200 may be fixed by being coupled to the base plate 100 by welding, etc., only the coupling portion 210, which is one end of the bump foils 200, respectively, and the other end in the circumferential direction may be formed as a free end. In addition, each of the bump foils 200 may be formed with concave-convex elastic bumps 220 , and the elastic bumps 220 may be separated from each other without being fixed although their lower ends are in contact with the base plate 100 . That is, the bump foil 200 may be in a state in which the remaining parts except for the coupling part 210 are not coupled to the base plate 100 and are separated, and the elastic bumps 220 are fitted to the base plate 100 . It can be in contact with or with a slight gap. In addition, the bump foil 200 may be formed with slits 230 penetrating both sides in the thickness direction from the free end along the circumferential direction. In addition, the slits 230 may be radially spaced apart and formed in parallel. Thus, for example, the region in which the elastic bumps 220 of the bump foil 200 are formed by the slits 230 may be formed in a form in which the region is divided into four parts in the radial direction. In this case, the four parts may be in a state of being connected to each other by the coupling part 210 which is one end. Here, the bump foil 200 is cut in a form in which at least a portion of the elastic bump 220 disposed in the region between the elastic bump 220 disposed on the outer diameter side and the elastic bump 220 disposed on the inner diameter side in the radial direction is deleted. A portion 240 may be formed. For example, the cutout 240 may be connected to the slit 230 to be concave in the radial direction, and the cutout 240 may be connected over a plurality of elastic bumps 220 adjacent to each other in the circumferential direction. can be formed.

The top foil 300 may be configured in plurality and may be arranged to be spaced apart from each other in the circumferential direction. And, each of the top foils 300 may be fixed by being coupled to the base plate 100 by welding only the coupling portion 310, which is one end of the top foil 300, and the other end in the circumferential direction may be formed as a free end. In this case, the top foils 300 are disposed at positions corresponding to the bump foils 200 , and the top foil 300 may be stacked in a manner that covers the bump foils 200 . That is, the bump foil 200 may be interposed between the base plate 100 and the top foil 300 . In addition, when viewing a cross-section cut along the circumferential direction on a specific radius as shown in FIG. 6 , the top foil 300 extends from the coupling part 310 in the circumferential direction to the upper right of the connection part 320 in a curved or flat shape. formed, and a flat portion 330 of a flat shape is extended from the connecting portion 320 , and the flat portion 330 may be formed in parallel with the base plate 100 . And the bump foil 200 corresponds to a partial area in one direction from the free end, which is the other end in the circumferential direction, on a specific radius, that is, the elastic bumps 220 corresponding to the flat portion 330 of the top foil 300 have a height of each other. The same may be formed, and the elastic bumps 220 in the region corresponding to the connection part 320 of the top foil 300 may be formed to have a relatively low height. Also, the lower surface of the connection part 320 and the mountains of the elastic bumps 220 may be spaced apart.

Here, referring to FIG. 7, when the cross section cut in the radial direction from the portion where the flat portion 330 of the top foil 300 is located, the bump foil 200 is an elastic bump in a partial area adjacent to the outer diameter in the radial direction ( The height h4 of the 220 may be formed to be lower than the heights h1, h2, and h3 of the elastic bumps 220 in the central region and the region adjacent to the inner diameter in the radial direction of the remaining region. At this time, for example, one elastic bump radially adjacent to the outer diameter side (on the right) is an outer-diameter elastic bump, and the other elastic bump radially adjacent to the inner-diameter side (left) is an inner-diameter elastic bump, and the outer diameter side in the radial direction. If the remaining two elastic bumps located between the elastic bump and the inner-diameter elastic bump are referred to as the central elastic bumps, the top foil 300 has an inner diameter among the inner-diameter elastic bumps and the central elastic bumps in a state where external force such as air pressure is not applied. The side elastic bump and the adjacent elastic bump may come into contact, and in this state, the outer diameter-side elastic bump and the central elastic bump, the outer-diameter elastic bump and the adjacent elastic bump's peak, are caused by a height difference (Δh). It may be spaced apart from the top foil 300 . At this time, since the cutout 240 is formed in the elastic bump adjacent to the inner diameter side elastic bump in the radial direction, only a part of the elastic bump 220 having the cutout 240 is in contact with the top foil in the sectional view as shown in FIG. 7 , or may not be in contact.

FIG. 8 is a cross-sectional view illustrating a state in which a part of the top foil is elastically deformed when the thrust runner, which is a rotating body, is in contact with the top foil in a state of being rotated at a high speed in the cross section of FIG. 7 .

As shown, when the cross section of the air foil thrust bearing according to the present invention is cut in the radial direction, the thrust runner 400, which is a rotating body, is rotated at a high speed due to an axial load or excitation. When the top foil 300 is in contact, the top foil 300 in the area corresponding to the portion where the outer diameter side elastic bump is located by the pressure of the air flowing between the thrust runner 400 and the top foil 300 is the elastic bump It may not be in contact with the thrust runner 400 by bending toward the side. That is, in the area adjacent to the outer diameter in the radial direction, the linear speed is relatively high, so energy loss (heat) due to friction with air is relatively large. Except for this part, the thrust runner 400 supports the load. And the top foil 300 may be in direct contact with damping and friction. In addition, when the thrust runner 400 comes into contact with the top foil 300 due to excitation, etc., it first comes into contact with the flat portion 330 of the top foil 300 to primarily cause damping and friction. The flat portion 330 of the top foil 300 of the portion corresponding to the region where the inner diameter side elastic bumps of 200 and the central portion elastic bumps exist is primarily a supporting part with the main excitation for supporting the load of the thrust runner 400 do.

Accordingly, the air foil thrust bearing of the present invention can have higher durability because the primary damping friction parts are formed at different positions without overlapping with the region having the largest energy loss according to the speed of the rotating body. In addition, since direct friction between the thrust runner and the top foil is reduced on the outer diameter side, where the energy loss is the largest, damage (crack marks) of the coating layer coated on the surface of the top foil may not occur.

9 is a cross-sectional view showing a case in which there is no cutout according to the present invention compared with FIG. 8 .

As shown, in the case where there is no cutout in the elastic bump according to the present invention, it can be seen that the height of the top foil is affected by the inner diameter-side elastic bump and the adjacent elastic bump. That is, when the thrust runner 400 is in contact with the top foil 300 due to an axial load or excitation in a state in which the thrust runner 400 is rotated at a high speed, the thrust runner 400 and the top foil 300 are Even when the top foil 300 is pressed by the pressure of the air flowing therebetween, between the elastic bumps adjacent to the outer-diameter elastic bumps and the top foil remain floating, and the top foil has a gentle slope form from the inner-diameter side to the outer-diameter side. will not be able to achieve Therefore, when a cutout is formed in the elastic bump adjacent to the outer diameter side elastic bump in the radial direction as shown in FIG. 8, the elastic bump does not support the lower end of the top foil at the portion where the cutout is formed, or even though the elastic bump does not support the lower end of the top foil, the elasticity is relatively weak. The foil is in a state where it can be bent freely. Accordingly, it is possible to form a more gentle inclination from the inner diameter side to the outer diameter side of the top foil in the radial direction, and as a result, it is possible to have higher durability.

<Example 2>

10 is a plan view illustrating a bump foil of an air foil thrust bearing according to a second embodiment of the present invention.

As shown, the bump foil of the air foil thrust bearing according to the present invention corresponds to the shape of the cutout 240 on the opposite side of the cutout 240 in the radial direction in the elastic bump 220 where the cutout 240 is formed. The offset part 250 may be formed to be convex. That is, since the elastic bump 220 of the portion in which the cutout 240 is formed has relatively weak elasticity compared to the remaining elastic bumps 220 in which the cutout 240 is not formed, the portion in which the cutout 240 is formed. The elasticity of the elastic bump 220 may be reinforced by forming an offset portion 250 having a convex shape in the radial direction on the opposite side of the cutout 240 in the radial direction.

In addition, in the elastic bump 220 adjacent to the offset part 250 in the radial direction, a concave part 260 may be formed to be concave in the radial direction in a shape corresponding to the shape of the offset part 250 .

In addition, the protrusion distance W of the offset part 250 in the radial direction may be formed to be smaller than the depth D of the cutout part 240 .

The present invention is not limited to the above-described embodiments, and the scope of application is varied, and anyone with ordinary knowledge in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims It goes without saying that various modifications are possible.

100: base plate
200: bump foil
210: coupling part 220: elastic bump
230: slit 240: cutout
250: offset part 260: concave part
300: top foil
310: coupling part 320: connection part
330: flat part
400: thrust runner

Claims (7)

base plate;
a bump foil having concave-convex elastic bumps formed thereon, the bump foil being laminated on the base plate and having one circumferential end coupled to the base plate; and
a top foil laminated to cover the bump foil, one end of which is coupled to the base plate in the circumferential direction; is made, including
The bump foil is formed so that the height of the elastic bumps in some areas adjacent to the outer diameter in the radial direction is lower than the heights of the elastic bumps in the remaining areas,
The bump foil is an air foil thrust bearing, characterized in that the cutout is formed in a form in which at least a portion of the elastic bumps disposed in a region between the elastic bumps disposed on the outer diameter side and the elastic bumps disposed on the inner diameter side in the radial direction are removed.
According to claim 1,
The cutout of the bump foil,
Air foil thrust bearing, characterized in that formed in a form connected over a plurality of elastic bumps adjacent to each other in the circumferential direction.
According to claim 1,
Air foil thrust bearing, characterized in that the bump foil is formed with a slit passing through both surfaces in the thickness direction from the free end along the circumferential direction.
4. The method of claim 3,
The air foil thrust bearing, characterized in that the cut-out portion of the bump foil is connected to the slit and concave in the radial direction.
5. The method of claim 4,
The bump foil on which the cutout is formed,
The air foil thrust bearing, characterized in that the offset portion having a shape corresponding to the shape of the cutout is convexly formed opposite to the cutout portion in the radial direction.
6. The method of claim 5,
The air foil thrust bearing according to claim 1, wherein a concave portion is formed in a shape corresponding to the offset portion in an elastic bump radially adjacent to the elastic bump on which the offset portion is formed.
6. The method of claim 5,
An air foil thrust bearing, characterized in that the protruding distance of the offset portion in the radial direction is formed to be smaller than the depth of the cutout portion.

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