KR100360232B1 - Axial gas sealing structure for foil bearing - Google Patents

Abstract

The present invention relates to an axial gas leakage preventing structure of a foil bearing, the present invention is a plurality of foil mounting grooves are formed on the inner peripheral surface of the cylindrical foil housing, the shaft is supported by the bending force in each foil mounting groove of the foil housing A foil segment is inserted, and between the foil segments is formed in the shape of a triangular cross section having an arc side in the axial direction with the same thickness in the axial direction and a gap shape with a neighboring foil segment in the arc direction perpendicular to the axial direction. By interposing the flexible blocking member so as to be in close contact with both adjacent foil segments, it is possible to prevent the leakage of gas into the gaps between the foil segments.

Description

AXIAL GAS SEALING STRUCTURE FOR FOIL BEARING}

The present invention relates to a foil bearing, and more particularly to an axial gas leakage prevention structure of a foil bearing suitable for preventing leakage of compressed gas between each piece of foil.

In general, the bearing supports a shaft that is rotating or reciprocating and receives a load acting on the shaft. The bearing is roughly divided into a sliding bearing and a rolling bearing according to the form in which the bearing contacts the shaft. Depending on the direction, it is divided into radial bearing and thrust bearing.

In the sliding bearing, the contact between the shaft and the bearing is sliding friction, whereas the rolling bearing is rolling friction of the rotating body, so the friction loss is much smaller in the rolling bearing. Therefore, in the sliding bearings, a gap is provided between the shaft and the bearing to supply a lubricant, such as gas, to support the shaft by fluid friction without direct contact between the metal and the metal. In the case of support by the roller, the clearance between the shaft and the bearing was minute and the shaft and the bearing might collide. Accordingly, a foil bearing or a tilting bearing having a large allowable gap between the shaft and the bearing has been proposed.

1 is a longitudinal cross-sectional view showing an example of a spiral-type foil bearing among conventional foil bearings.

As shown in the related art, a conventional bent foil bearing (hereinafter referred to as a foil bearing) has a plurality of foil mounting grooves 1a formed at equal intervals on an inner circumferential surface of a cylindrical foil housing 1. Each foil mounting groove 1a of the foil housing 1 is individually inserted with a foil segment 2 supporting the shaft 3 by a bending force.

The foil segment 2 is formed in the same thickness as in Fig. 2a and 2b, the insertion end (2a) that is fitted to the foil mounting groove (1a) of the foil housing (1) of the both ends are It is formed to be bent several times so as to have elastic force by being caught in one foil mounting groove 1a, and the other end of the support end 2b is loaded (hereinafter, referred to as the surface where the shaft is in contact with, and its back surface is called an elastic surface). It is formed to be curved toward the side.

In the drawings, reference numeral C denotes a bearing gap.

The conventional foil bearing configured as described above is assembled and operated as follows.

That is, the foil segments 2 are inserted into and mounted in the same direction, one by one in each foil mounting groove 1a provided on the inner circumferential surface of the foil housing 1, and the shaft is formed in the space formed by the load surfaces of the foil segments 2. Insert and support (3) in close contact.

At this time, if the shaft 3 rotates at a high speed and then swings in the lateral direction due to various factors, the shaft 3 while being in contact with the swinging direction of the shaft 3 is shaking. The fluctuation of (3) was elastically buffered to support the original allowable rotation radius.

However, such a conventional foil bearing has been pointed out as a major problem of gas leakage in the axial direction. For example, when a conventional foil bearing is mounted on a turbo compressor as shown in FIG. 3, the radial void C between the foil housing 1 and the shaft 3 of the foil bearing becomes relatively large, so that the compression chamber and the motor chamber are relatively large. The sealing member 4 also seals the air gap C with the shaft 3, so that the compressed gas leaking from the relatively high pressure compression chamber into the low pressure motor chamber is prevented from each foil of the foil bearing. It was easily introduced into the motor room through the segments (2), which would reduce the efficiency of the compressor.

The present invention has been made in view of the problems of the conventional foil bearing as described above, to provide an axial gas leakage prevention structure of the foil bearing that can prevent the leakage of gas between each foil segment is inserted into the shaft support There is an object of the present invention.

1 is a longitudinal cross-sectional view showing a conventional foil bearing.

2A and 2B are a perspective view and a longitudinal sectional view showing a foil segment of a conventional foil bearing.

3 is a half sectional view of a turbo compressor equipped with a conventional foil bearing;

Figure 4 is a longitudinal sectional view showing an example of the present invention foil bearing.

5 is a perspective view showing a blocking member of the present invention foil bearing.

** Detailed description of the symbols in the drawings **

1: foil housing 1a: foil mounting groove

2: foil segment 10: blocking member

C: bearing gap

In order to achieve the object of the present invention, a plurality of foil mounting grooves are formed on the inner circumferential surface of the cylindrical foil housing, and a foil segment for supporting the shaft with bending force is inserted into each foil mounting groove of the foil housing, and the foil segment Both foils adjacent to the flexible barrier member formed in a triangular cross-sectional shape having an arc side in the axial direction with the same thickness in the axial direction and in the arc direction perpendicular to the axial direction to fit the gap shape with the adjacent foil segment. An axial gas leakage preventing structure of a foil bearing is provided which is interposed so as to be in close contact with a segment.

Hereinafter, the axial gas leakage preventing structure of the foil bearing according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

Figure 4 is a longitudinal sectional view showing an example of the foil bearing of the present invention, Figure 5 is a perspective view showing a blocking member of the foil bearing of the present invention.

As shown in the present invention, in the foil bearing having the axial gas leakage preventing structure according to the present invention, a plurality of foil mounting grooves 1a are formed on the inner circumferential surface of the cylindrical foil housing 1 at equal intervals, and the foil Each foil mounting groove 1a of the housing 1 is individually inserted with a foil segment 2 supporting the shaft with a bending force, and a gap between each foil segment 2 between each foil segment 2. Blocking member 10 for blocking is made.

The foil segment 2 is formed to be bent so that both ends of the negative pressure surface (unsigned) are made to have the same thickness as a whole, and the insertion end 2a is inserted into the foil mounting groove 1a. The bending end is formed several times to exert elastic force, and the other end of the supporting end 2b is formed by overlapping each foil segment 2 with each other to form a circular shaft space, and the shaft 3 is in close contact with the circular shaft space. do.

Here, the blocking member 10 has the same thickness in the axial direction as shown in FIG. 5 in consideration of the gap between the foil segments 2 being formed in a triangular cross-sectional shape having an arc side. The arc direction perpendicular to the axial direction is preferably formed in a triangular cross-sectional shape having an arc side in accordance with a gap shape between neighboring foil segments 2. Each of the foil segments 2 is an axis 3. ) When the swing is strictly bent at a time difference from each other, the blocking member 10 should be formed to a thickness that does not interfere with the bending movement of each foil segment (2).

In the drawings, the same reference numerals are given to the same parts as in the prior art.

In the drawings, reference numeral C denotes a bearing gap.

In the foil bearing of the present invention as described above, the foil segments 2 are inserted into and mounted in the same direction, one by one in each foil mounting groove 1a provided on the inner circumferential surface of the foil housing 1, and the portion of the foil segment 2 is mounted. The shaft is inserted and supported to be in close contact with a space formed by lower surfaces (unsigned), and the gap C is pushed in between the coil segments 2 by pushing a blocking member 10 having a triangular cross section. To complete the assembly.

Subsequently, even if the shaft 3 swings in the transverse direction due to various factors during the rotation of the shaft 3 at high speed, one or more foil segments that are in contact with the swinging direction of the shaft 3 ( As 2) is whistled, it is supported to maintain the original allowable radius by elastically buffering the swing.

At this time, a predetermined void C is generated between the elastic surface (unsigned) of the foil segment 2 and the unloaded surface (unsigned) of another foil segment adjacent to the foil segment 2, but this void ( C) is blocked by the blocking member 10 interposed between each foil segment 2 to prevent axial leakage of gas.

In the axial gas leakage preventing structure of the foil bearing according to the present invention, a plurality of foil mounting grooves are formed on the inner circumferential surface of the cylindrical foil housing at equal intervals, and each foil mounting groove has a foil segment for elastically supporting the shaft with bending force. By mounting a flexible blocking member in the gap between the foil segments to block the gap, it is possible to prevent the leakage of gas into the gap between the foil segments.

Claims (1)

A plurality of foil mounting grooves are formed on the inner circumferential surface of the cylindrical foil housing, and a foil segment supporting the shaft with bending force is inserted into each foil mounting groove of the foil housing, and the thickness of the foil housing is axially between the foil segments. In the same arc direction perpendicular to this axial direction, the flexible blocking member formed in the triangular cross-sectional shape which has an arc side according to the gap shape with neighboring foil segments is interposed so that it may contact nearly both neighboring foil segments. Axial gas leakage preventing structure of the foil bearing.