JPH08170646A - Holding structure for slide bearing - Google Patents

Abstract

PURPOSE: To prevent a slide bearing and a rotation shaft from corotating in a high temperature environment. CONSTITUTION: Between a slide bearing formed of ceramics and a holding member formed of metal with a coefficient of thermal expansion larger than this bearing, a spacer, formed of metal with a coefficient of thermal expansion larger than the holding member, is interposed. In a high temperature environment, a difference between thermal expansion amounts in a diametric direction of the slide bearing 1 and the holding member 2 can be compensated by thermal expansion in a diametric direction thickness of the spacer 3. Consequently, even in the high temperature environment, turning the slide bearing 1 with a rotary shaft S can be prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sliding bearing holding structure used in a high temperature environment.

[0002]

[Prior Art and Problems to be Solved by the Invention]
In a pump that handles high-temperature fluids such as oil and chemicals, or in various rotary devices that are used in a high-temperature environment, a slide bearing 91 made of a ceramic cylindrical body is often used to support the rotating shaft S ( (See FIG. 11). The slide bearing 91 is held at a predetermined position by a metal holding member 92 that is tightly fitted on the outer circumference of the slide bearing 91. The metal rotation shaft S is relatively rotatable on the inner circumference of the slide bearing 91. By fitting, the rotation shaft S can be slidably supported. Further, as the ceramics which is the material of the slide bearing 91, silicon carbide (SiC), silicon nitride (Si ₃ N ₄ ), aluminum oxide (Al
₂ O ₃ ), zirconium oxide (ZrO ₂ ), etc. are used, and the material of the holding member 92 is carbon steel, stainless steel, copper alloy, aluminum alloy, etc. having a larger coefficient of thermal expansion than the slide bearing 91. Has been adopted.

By the way, the holding member 92 is generally fitted into the slide bearing 91 by shrink fitting, but since the coefficient of thermal expansion of the holding member 92 is larger than that of the slide bearing 91, it is, for example, 100 ° C. In the above high temperature environment, the holding member 92 expands more in the radial direction than the sliding bearing 91, and the holding force for the sliding bearing 91 is lost. As a result, a so-called co-rotation phenomenon occurs and the holding member 92 wears. However, there is a problem in that it may cause abnormal vibration. Therefore, a pin or a key for preventing rotation is also interposed between the slide bearing 91 and the holding member 92, but in this case, the driving torque is concentrated on the rotation preventing portion, There was a risk that the site would be damaged. Therefore, there is also one in which the sliding bearing 91 is formed of a copper alloy or the like having a thermal expansion coefficient close to that of the holding member 92, but in this case, there is a drawback that the wear resistance is poor. Further, even at room temperature, as the shrink-fitted holding member 92 contracts, an excessive load is applied to the sliding bearing 91 toward the center, and the sliding bearing 91 is damaged, so that the rotating shaft S is smoothed. There was also the problem of being unable to support the slip.

On the other hand, as shown in FIG. 12, a pair of slide bearings 91 in which a ceramic bearing member 91b is relatively rotatably fitted around the outer periphery of a ceramic sliding sleeve 91a are axially separated by a predetermined distance. The rotary shaft S is rotatably supported by the pair of slide bearings 91. In this case, a step portion S1 is provided in the middle of the rotary shaft S so as to project.
One end face of each sliding sleeve 91a is abutted against 1, and the other end face is fitted to the rotating shaft S, and movement of the sliding sleeve 91a in a direction away from the slide bearing 91 is restricted by the backup sleeve 94. By pressing with the pair of retainers 93, the sliding sleeve 91a and the rotating shaft S are restricted from rotating together. In addition, each bearing member 91
As for b, a cylindrical holding member 92 fitted on the outer circumference thereof.
Is held in place by the holding member 92.
By abutting one end surface of the bearing member 91b against the stepped portion 92a protruding in the middle of the inner periphery of the bearing, and pressing the other end surface slidably by the retainer 93 via the thrust plate 95. The sliding sleeve 91a and the bearing member 91b are prevented from rotating together.

However, in the above holding structure for the slide bearing 91, when used in a high temperature environment of, for example, 100 ° C. or more, the coefficient of thermal expansion of the rotating shaft S made of metal and the sliding sleeve 91a made of ceramics Due to the difference, a gap is created between one end surface of the sliding sleeve 91a and the step portion S1 of the rotating shaft S, or between the other end surface of the sliding sleeve 91a and the retainer 93, and the retainer 93 causes the sliding sleeve 91a to move. However, there is a problem that the rotation shaft S and the sliding sleeve 91a rotate together with each other. Further, in the case where the holding member 92 is made of a metal having a thermal expansion coefficient larger than that of the bearing member 91b, the bearing member 91 is concerned.
b between the one end surface of the bearing member 91b and the stepped portion 92a of the holding member 92 due to the difference in thermal expansion coefficient between the holding member 92 and b.
Alternatively, a gap is created between the other end surface of the bearing member 91b and the thrust plate 95, and the bearing member 91b cannot be pressed by the retainer 93, so that the sliding sleeve 91a and the bearing member 9
There was a problem that it co-rotated with 1b.

The present invention has been made in view of the above-mentioned problems, and it is possible to prevent the holding member and the slide bearing from rotating together in a high temperature environment, and at the same time, when the holding member contracts, the slip occurs. An object of the present invention is to provide a holding structure for a sliding bearing that can prevent the bearing from being damaged. Another object of the present invention is to provide a holding structure for a sliding bearing, which can prevent the sliding sleeve of the sliding bearing and the rotating shaft from rotating together in a high temperature environment. A further object of the present invention is to provide a slide bearing holding structure capable of preventing the sliding sleeve of the slide bearing and the bearing member from rotating together in a high temperature environment.

[0007]

According to a first aspect of the present invention, there is provided a holding structure for a slide bearing, which comprises a cylindrical slide bearing made of ceramics, into which a metal rotating shaft is fitted so as to be rotatable relative to each other. In a holding structure of a sliding bearing that is held by a holding member that is fitted to the outer circumference of the sliding bearing and has a coefficient of thermal expansion larger than that of the sliding bearing, a holding member is provided between the outer circumference of the sliding bearing and the inner circumference of the holding member. It is characterized in that a spacer made of a metal having a larger thermal expansion coefficient than the member is interposed.

A holding structure for a slide bearing according to claim 2 is
The holding structure for a plain bearing according to a first aspect of the invention is characterized in that the spacer has a gap that absorbs thermal expansion in the circumferential direction. According to a third aspect of the present invention, there is provided the plain bearing holding structure according to the first aspect, wherein the gap that absorbs the thermal expansion in the circumferential direction of the spacer is an axially extending gap. It is characterized in that a plurality of spacers are arranged along the axial direction in a state in which the phases of the respective gaps are shifted.

A holding structure for a slide bearing according to claim 4 is
A pair of slide bearings in which a cylindrical bearing member made of ceramics is rotatably fitted relative to each other is arranged on the outer periphery of a sliding sleeve made of ceramics, separated by a predetermined distance in the axial direction. A rotary shaft made of metal having a coefficient of thermal expansion larger than that of the sliding sleeve is fitted around the circumference, and the end faces of the sliding sleeves are pressed to allow relative rotation between the sliding sleeve and the rotating shaft. In the structure for holding the sliding bearing that regulates the above, a cylindrical spacer made of metal having a coefficient of thermal expansion larger than that of the rotating shaft is interposed between the end surfaces of the sliding sleeves facing each other. is there. A slide bearing holding structure according to a fifth aspect of the present invention is the slide bearing holding structure according to the fourth aspect, wherein a contact surface between the spacer and each sliding sleeve is a tapered surface.

A holding structure for a plain bearing according to claim 6 is
A pair of slide bearings in which a cylindrical bearing member made of ceramics is rotatably fitted relative to each other is arranged on the outer periphery of a sliding sleeve made of ceramics, separated by a predetermined distance in the axial direction. A rotating shaft made of metal having a larger thermal expansion coefficient than the sliding sleeve is fitted around the circumference, and the outer circumference of each bearing member is made into a holding member made of metal having a larger thermal expansion coefficient than the bearing member. Mating,
By pressing the end faces of each sliding sleeve and the bearing member, relative rotation between the sliding sleeve and the rotating shaft,
Also, in the holding structure of the slide bearing that restricts relative rotation between the bearing member and the holding member, between the end faces of the sliding sleeves facing each other, a cylindrical first member made of a metal having a thermal expansion coefficient larger than that of the rotating shaft is used. The first spacer is interposed, and the cylindrical second spacer made of metal having a thermal expansion coefficient larger than that of the holding member is interposed between the end surfaces of the bearing members facing each other.

[0011]

According to the holding structure of the sliding bearing of the first aspect, the spacer interposed between the sliding bearing and the holding member is made of metal having a coefficient of thermal expansion larger than that of the holding member. The difference in thermal expansion amount between the plain bearing and the holding member in the radial direction can be compensated by the thermal expansion in the radial thickness of the spacer. Therefore, the sliding bearing can be reliably held by the holding member even in a high temperature environment. Further, even when the holding member is shrink-fitted to the slide bearing, the shrinking force generated at room temperature is relaxed by the spacer and acts on the slide bearing. Therefore, it is possible to prevent an excessive load from acting on the slide bearing due to the contraction of the holding member.

According to the holding structure of the slide bearing of the second aspect, the thermal expansion in the circumferential direction can be absorbed by the gap of the spacer. Therefore, it is possible to prevent the spacer from excessively expanding in the radial direction by restricting the thermal expansion of the spacer in the circumferential direction. According to the holding structure of the slide bearing of the third aspect, the phases of the gaps extending in the axial direction of the plurality of spacers arranged along the axial direction are shifted, so that the contracting force of the holding member is reduced. It is possible to prevent concentrated action on a specific portion on the circumference of the plain bearing.

According to the holding structure of the slide bearing of the fourth aspect, the spacer interposed between the end surfaces of the respective sliding sleeves facing each other is made of a metal having a coefficient of thermal expansion larger than that of the rotating shaft. The difference in the amount of thermal expansion in the axial direction between the rotating shaft and the sliding sleeve can be compensated by the thermal expansion in the axial direction of the spacer. Therefore, the end surface of the sliding sleeve can be reliably pressed even in a high temperature environment. According to the holding structure of the slide bearing of the fifth aspect, since the contact surface between the spacer and each sliding sleeve is a tapered surface, it is possible to restrict the relative rotation between the sliding sleeves. it can. Therefore, it is possible to prevent any one of the sliding sleeves from rotating together with the rotating shaft due to a difference in load or sliding resistance acting on each sliding sleeve.

According to the holding structure of the slide bearing of the sixth aspect, the first spacer interposed between the end surfaces of the sliding sleeves facing each other is made of metal having a thermal expansion coefficient larger than that of the rotating shaft. The difference in the amount of thermal expansion in the axial direction between the rotary shaft and the sliding sleeve in a high temperature environment can be compensated by the thermal expansion in the axial direction of the spacer. Further, since the second spacer interposed between the end surfaces of the bearing members facing each other is made of a metal having a coefficient of thermal expansion larger than that of the holding member, the thermal expansion of the holding member and the bearing member in the axial direction in a high temperature environment. The difference in the amount can be compensated by the axial thermal expansion of the second spacer. Therefore, even under a high temperature environment, the respective end faces of the sliding sleeves and the bearing members can be reliably pressed.

[0015]

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. FIG. 1 is a sectional view showing an embodiment of a holding structure for a plain bearing of the present invention, and FIG.
FIG. 11 is a sectional view taken along line II-II. The holding structure of this plain bearing is
The slide bearing 1 in which the rotary shaft S is relatively rotatably fitted,
It is held by the holding member 2 via the spacer 3. The plain bearing 1 is composed of a single ceramic cylindrical body having a small coefficient of thermal expansion. As the ceramic material of the slide bearing 1, SiC,
Si ₃ N ₄ , Al ₂ O ₃ , ZrO ₂ or the like is used.

At least the tip of the holding member 2 is formed in a cylindrical shape, and a step portion 21 for abutting the one end surfaces of the slide bearing 1 and the spacer 3 is formed on the inner periphery of the inner depth of the holding member 2. . The inner periphery of the holding member 2 is tightly fitted to the outer periphery of the spacer 3 by shrink fitting. As the material of the spacer 3, a metal such as carbon steel, stainless steel, copper alloy, aluminum alloy or the like having a thermal expansion coefficient larger than that of the slide bearing 1 is adopted.

The spacer 3 is made of a cylindrical body having substantially the same width as that of the slide bearing 1, and the inner circumference thereof is closely fitted to the outer circumference of the slide bearing 1. As the material of the spacer 3, a metal similar to that of the holding member 2 such as carbon steel, stainless steel, copper alloy, and aluminum alloy is adopted, but the spacer 3 has a coefficient of thermal expansion larger than that of the holding member 2. It is appropriately selected according to the material of the holding member 2. For example, the material of the holding member 2 has a thermal expansion coefficient of 9.6 × 10 ^{6 to} 11.7 × 10.
^In the case of ⁶ K ^-1 carbon steel, the coefficient of thermal expansion is 17.3 x 1
0 ⁶ K ^-1 austenitic stainless steel, bronze having a thermal expansion coefficient of 20 × 10 ⁶ K ^-1 or more, copper alloy such as brass, or aluminum alloy is adopted, and the material of the holding member 2 is the austenitic In the case of stainless steel, the above copper alloy or aluminum alloy is adopted.

With the above configuration, for example, in a high temperature environment of 100 ° C. or higher, the difference in the thermal expansion amount in the radial direction due to the difference in the thermal expansion coefficient between the slide bearing 1 and the holding member 2 is
This can be compensated by thermal expansion of the radial thickness of the spacer 3 interposed between the two. Therefore, even in a high temperature environment, the slide bearing 1 can be reliably held by the holding member 2 and the rotating shaft S and the slide bearing 1 can be prevented from rotating together. Further, the shrinkage force due to the shrink fitting of the holding member 2 is relaxed by the spacer 3, and the sliding bearing 1
It is possible to prevent excessive stress from being applied to. Therefore, it is possible to prevent the slide bearing 1 from being damaged.

The spacer 3 may be provided with a gap C that absorbs thermal expansion in the circumferential direction (see FIGS. 3 to 5). In this case, thermal expansion in the circumferential direction of the spacer 3 is possible. It is possible to suppress excessive expansion of the spacer 3 in the radial direction that occurs when the above is restricted. Therefore, it is possible to prevent the slide bearing 1 from being distorted due to a large load acting on the slide bearing 1 due to the thermal expansion of the spacer 3. The gap C of the spacer 3 can be configured by dividing the spacer 3 at at least one location on its circumference (see FIG. 3). Further, along the generatrix of the spacer 3, a slit 31 extending from one end to the vicinity of the other end and a slit 32 extending from the other end to the vicinity of the one end.
And may be formed by alternately forming them in the circumferential direction (see FIG. 4), and further by slits 33 formed in a spiral shape along the circumferential surface (see FIG. 5). .

FIG. 6 is a sectional view showing still another embodiment, and FIG. 7 is a sectional view taken along line VII-VII thereof. In this embodiment, the spacer 3 is composed of a narrow annular body, and a plurality of the spacers are arranged so as to be in close contact with each other in the axial direction. The gap C is formed by the slits formed at the points and extending along the entire axial length. Further, the spacers 3 are arranged in a state in which their phases are shifted from each other so that the respective gaps C do not coincide in the circumferential direction. In this embodiment, since the gaps C of the spacers 3 are displaced from each other in the circumferential direction, the shrinkage force due to the shrink fitting of the holding member 2 is concentrated on a specific portion on the outer circumference of the slide bearing 1. Can be suppressed. Therefore, it is possible to effectively prevent the sliding bearing 1 from being damaged by the contracting force.

FIG. 8 is a sectional view showing still another embodiment. In this embodiment, the rotary shaft S is rotatably supported by a pair of slide bearings 1 each composed of a ceramic sliding sleeve 1a and a ceramic bearing member 1b. The pair of slide bearings 1
Are axially separated from each other by a predetermined distance, and the sliding sleeves 1a rotate integrally with the rotating shaft S with the cylindrical spacer 3 interposed between the end surfaces on the inner back sides facing each other. Mating is possible. Further, the outer end surface of each slide bearing 1 has a disk-shaped retainer 4 fitted to the rotating shaft S.
The sliding sleeves 1 are pressed against each other, thereby restricting the relative rotation of each sliding sleeve 1 with respect to the rotating shaft S. That is, the retainer 4 on the right side in the figure is locked to a predetermined portion of the rotary shaft S via the backup sleeve 5 fitted to the rotary shaft S, and its movement in the arrow X direction is restricted. In this state, the retainer 4 on the left side is pressed in the arrow X direction via the backup sleeve 5 by the tightening force of the nut 6 screwed onto the rotating shaft S, so that each sliding sleeve 1a and the spacer 3 are paired. By being sandwiched by the retainer 4, the relative rotation of each sliding sleeve 1 with respect to the rotation axis S is restricted.

The bearing member 1b has a cylindrical shape, and is fitted to the outer circumference of the sliding sleeve 1a so as to be rotatable relative to the outer circumference of the sliding sleeve 1a. The cylindrical holding member 2 is shrink-fitted to the outer circumference. Is held by. Further, the inner end side end surface of each bearing member 1b is abutted against the step portion 22 formed on the inner circumference of the holding member 2, and the outer end surface is made of the same material as the bearing member 1b or equivalent wear resistance. Relative rotation with respect to the holding member 2 is regulated by being slidably pressed by the retainer 4 via the annular thrust plate 7 made of a material having properties. The holding member 2 is made of a metal such as titanium having a small coefficient of thermal expansion,
A flange 23 for mounting is provided so as to project from the outer periphery thereof. Further, the spacer 3 is formed of a metal having a larger thermal expansion coefficient than the rotating shaft S, the retainer 4, the backup sleeve 5, and the holding member 2.

With the above configuration, the difference in the amount of thermal expansion in the axial direction between the rotary shaft S and the sliding sleeve 1a that occurs in a high temperature environment is determined by the thermal expansion of the spacer 3 having a larger thermal expansion coefficient than the rotary shaft S. Can be compensated by. For this reason,
The pressing state of the sliding sleeve 1a by the retainer 4 can be maintained. Therefore, it is possible to prevent the rotating shaft S and the sliding sleeve 1a from rotating together even in a high temperature environment.

In the above embodiment, the contact surface between the pair of sliding sleeves 1 and the spacer 3 may be formed by a tapered surface (see FIG. 9). It is possible to restrict the relative rotation between the sleeves 1a. Therefore, one sliding sleeve 1
Even if one of the sliding sleeves 1a tries to rotate relative to the rotation axis S due to a difference in load, sliding resistance, or the like acting on each of the a and the other sliding sleeve 1a, it is It can be regulated by the sliding sleeve 1a. Therefore, it is possible to more reliably prevent the sliding sleeve 1a and the rotating shaft S from rotating together.

Further, in this embodiment, a resin having heat resistance such as tetrafluoroethylene resin (PTFE) is provided between the end faces of the pair of sliding sleeves 1 facing each other and the end faces of the spacers 3. The cushioning material 8 is interposed, and the cushioning material 8 prevents the end faces of the sliding sleeve 1a and the spacer 3 on the abutting side from being cracked or chipped.

FIG. 10 is a sectional view showing still another embodiment. In this embodiment, the holding member 2 is composed of a pair of tubular members 2a made of metal having a larger thermal expansion coefficient than the bearing member 1b, and the tubular member is provided between the pair of bearing members 1b. A second spacer 9 made of a metal having a coefficient of thermal expansion larger than that of the member 2a is interposed. A flange 23 is provided on the abutting end surface side of the pair of cylindrical members 2a.
The two are integrated by connecting them with a bolt (not shown). With this integration, the bearing members 1b are sandwiched and pressed together with the second spacer 9 between the flange portions 24 projecting from the inner peripheral end of each tubular member 2a. This restricts the holding member 2 and the bearing members 1b from rotating relative to each other.
The spacer 3 (first spacer) 3 interposed between the sliding sleeves 1a is a retainer 4 made of the same material as the bearing member 1b or a material having the same wear resistance as the bearing member 1b. Being pressed by.

According to this embodiment, the difference in the amount of thermal expansion in the axial direction between the rotary shaft S and the sliding sleeve 1a generated in a high temperature environment is compensated by the thermal expansion of the first spacer 3 and the retainer 4 is used. The pressed state of the sliding sleeve 1a can be maintained. Therefore, it is possible to prevent the sliding sleeve 1a and the rotating shaft S from rotating together. Further, the difference in the amount of thermal expansion in the axial direction between the holding member 2 and the bearing member 1b can be compensated by the thermal expansion of the second spacer 9, so that the holding member 2 can maintain the pressed state of the bearing member 1b. Therefore, it is possible to prevent the sliding sleeve 1a and the bearing member 1b from rotating together.

[0028]

As described above, according to the holding structure of the sliding bearing of the first aspect, the difference in the thermal expansion amount between the sliding bearing and the holding member in the high temperature environment is interposed between the two. Since it can be compensated by the thermal expansion of the radial thickness of the spacer, the plain bearing can be reliably held by the holding member even in a high temperature environment. For this reason, it is possible to prevent the slide bearing and the rotating shaft from rotating together, and it is possible to prevent the holding member from wearing and abnormal vibration. Further, even when the holding member is shrink-fitted to the slide bearing, the shrinkage force at room temperature can be mitigated by the spacer to prevent an excessive load from acting on the slide bearing.
Therefore, the sliding bearing can be prevented from cracking or being greatly distorted, and as a result, the rotary shaft can be smoothly supported by the sliding bearing.

According to the holding structure of the slide bearing of the second aspect, the thermal expansion in the circumferential direction is absorbed by the gap provided in the spacer, and excessive expansion in the radial direction due to the thermal expansion in the circumferential direction of the spacer. Can be suppressed. For this reason,
Since it is possible to prevent a large load from being applied to the slide bearing due to the thermal expansion of the spacer, it is possible to smoothly support the rotating shaft.

In the slide bearing holding structure according to the third aspect of the present invention, the plurality of spacers arranged along the axial direction are shifted in phase from the gaps extending in the axial direction, so that the holding member contracts. The force can be distributed and applied to the plain bearing. Therefore, the sliding bearing can be prevented from being distorted, and as a result, the rotating shaft can be more smoothly supported by sliding.

According to the holding structure of the slide bearing of the fourth aspect of the invention, the difference in the amount of thermal expansion in the axial direction between the rotating shaft and the sliding sleeve under high temperature environment is interposed between the sliding sleeves. Can be compensated by the thermal expansion of
Even under a high temperature environment, it is possible to reliably press the end surface of the sliding sleeve and prevent the sliding sleeve and the rotating shaft from rotating together. Therefore, it is possible to prevent the rotating shaft from being worn or abnormal vibration.

According to the holding structure of the slide bearing of the fifth aspect, since the contact surface between the spacer and each sliding sleeve is a tapered surface, it is possible to prevent relative rotation between the sliding sleeves. Then, it is possible to prevent one of the sliding sleeves from co-rotating with the rotating shaft due to the difference in the load acting on each sliding sleeve, the sliding resistance, or the like. Therefore, it is possible to more reliably prevent the sliding sleeve and the rotating shaft from rotating together.

According to the holding structure of the sliding bearing of the sixth aspect, the difference in the amount of thermal expansion in the axial direction between the rotary shaft and the sliding sleeve in a high temperature environment is interposed between the sliding sleeves. No. 1 spacer can compensate for the difference in the amount of thermal expansion in the axial direction between the holding member and the bearing member.
It can be supplemented by the second spacer interposed between the bearing members. Therefore, even in a high temperature environment,
It is possible to reliably press the respective end surfaces of the respective sliding sleeves and the bearing member, and prevent relative rotation between the respective sliding sleeves and the rotating shaft and between the bearing member and the holding member. . As a result, it is possible to prevent the rotating shaft and the holding member from being worn and abnormal vibration from occurring.

[Brief description of drawings]

FIG. 1 is a sectional view showing an embodiment of a holding structure for a slide bearing according to the present invention.

FIG. 2 is a sectional view taken along line II-II in FIG.

FIG. 3 is a view showing another embodiment of the spacer, (a)
Is a front view, and (b) is a side view.

FIG. 4 is a view showing still another embodiment of the spacer,
(A) is a front view and (b) is a side view.

FIG. 5 is a view showing still another embodiment of the spacer,
(A) is a front view and (b) is a side view.

FIG. 6 is a sectional view showing another embodiment.

7 is a sectional view taken along line VII-VII of FIG.

FIG. 8 is a sectional view showing still another embodiment.

FIG. 9 is a sectional view showing still another embodiment.

FIG. 10 is a sectional view showing still another embodiment.

FIG. 11 is a cross-sectional view showing a conventional example.

FIG. 12 is a cross-sectional view showing another conventional example.

[Explanation of symbols]

 1 sliding bearing 1a sliding sleeve 1b bearing member 2 holding member 3 spacer (first spacer) S rotating shaft C clearance

Claims (6)

[Claims] 1. A holding member made of a metal having a larger coefficient of thermal expansion than that of a sliding bearing, which is fitted on the outer periphery of a cylindrical sliding bearing made of ceramics, into which a metal rotating shaft is relatively rotatably fitted. In a holding structure for a sliding bearing that is held by means of a sliding bearing characterized in that a spacer made of metal having a thermal expansion coefficient larger than that of the holding member is interposed between the outer circumference of the sliding bearing and the inner circumference of the holding member. Retention structure. 2. The holding structure for a slide bearing according to claim 1, wherein the spacer has a gap that absorbs thermal expansion in the circumferential direction. 3. A gap for absorbing thermal expansion in the circumferential direction of the spacer is a gap extending in the axial direction, and a plurality of spacers provided with this gap are axially shifted in a state in which the phases of the gaps are shifted. The retaining structure for a plain bearing according to claim 2, wherein the retaining structures are arranged along the line. 4. A pair of slide bearings in which a cylindrical bearing member made of ceramics is relatively rotatably fitted are arranged on the outer periphery of a sliding sleeve made of ceramics so as to be axially separated by a predetermined distance. A rotating shaft made of metal having a larger coefficient of thermal expansion than the sliding sleeve is fitted to the inner circumference of the sliding sleeve, and the end surface of each sliding sleeve is pressed to rotate with the sliding sleeve. In the sliding bearing holding structure that regulates relative rotation with respect to the shaft, a cylindrical spacer made of metal with a coefficient of thermal expansion larger than that of the rotating shaft is interposed between the end faces of the sliding sleeves facing each other. Characteristic slide bearing holding structure. 5. The structure for holding a sliding bearing according to claim 4, wherein the contact surface between the spacer and each sliding sleeve is a tapered surface. 6. A pair of slide bearings in which a cylindrical bearing member made of ceramics is relatively rotatably fitted are arranged on the outer periphery of a sliding sleeve made of ceramics so as to be axially separated by a predetermined distance. A rotating shaft made of a metal having a larger thermal expansion coefficient than the sliding sleeve is fitted to the inner circumference of the sliding sleeve, and the outer circumference of each bearing member is made of a metal having a larger thermal expansion coefficient than the bearing member. By restricting the relative rotation between the sliding sleeve and the rotating shaft and the relative rotation between the bearing member and the holding member, the end faces of the sliding sleeve and the bearing member are pressed against each other. In the structure for holding a sliding bearing, a cylindrical first spacer made of a metal having a coefficient of thermal expansion larger than that of the rotating shaft is interposed between the end surfaces of the sliding sleeves facing each other, and the bearing members are mutually supported. A holding structure for a slide bearing, characterized in that a cylindrical second spacer made of a metal having a coefficient of thermal expansion larger than that of the holding member is interposed between the opposing end faces.