JP2003337500A - Fixing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To minimize an increase in the size of each of bearing support plate members 130 even though a pressure roller 140 is supported by the bearing support plate members 130 via ball bearings B2. <P>SOLUTION: The fixing device has: a heat roller 120 freely rotatably supported between both side walls 102 of a stationary frame 100, the bearing support plate members 130 pivotally supported on the side walls 102, and the pressure roller 140 freely rotatably supported by the members 130 via the ball bearings B2. The members 130 are pressed by tension coil springs 115, and thus the pressure roller 140 is brought into pressure contact with the heat roller 120. Each of the members 130 has a bearing support flange 133A having an arcuate internal surface 133a, which is formed on the outer peripheral edge of a main body 131. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a laser printer,
Each of a fixing device provided in an image forming machine using electrophotography such as a facsimile or an electrostatic copying machine, in particular, a heating rotator such as a heating roller, a metal bearing support plate member, and a bearing support plate member. The present invention relates to a fixing device including a pressure roller rotatably supported via a rolling bearing.

[0002]

2. Description of the Related Art In a fixing device provided in an image forming machine in recent years, an unfixed toner image transferred onto a sheet of plain paper is transferred onto a sheet such as a heating roller or a heating belt. In many cases, a heating rotator, which is generally heat-pressed and fused on a sheet while passing through a nip portion between a heating roller and a pressure roller, is widely used. The heating roller and pressure roller of such a fixing device are generally configured as follows. That is, the heating roller includes a metal pipe, which is a core metal, and a non-adhesive layer provided on the peripheral surface of the pipe. The non-adhesive layer is provided to prevent adhesion of the molten toner, and is made of fluororesin or the like. The pressure roller includes a metal pipe, which is a core metal, and a heat-resistant elastic layer provided on the peripheral surface of the pipe. The heat resistant elastic layer is formed of silicon rubber or the like.

In the fixing device of the above-mentioned form, as the image forming speed of the image forming machine is increased, the paper is surely left on the paper in a short time while passing through the nip portion between the heating roller and the pressure roller. Since it is necessary to fuse the toner, the tendency of increasing the pressure contact force of the pressure roller with the heating roller has become remarkable. By increasing the pressure contact force of the pressure roller against the heating roller, there is a strong demand for higher strength and lower torque in the bearing that supports the pressure roller, and as a bearing, instead of a small slide bearing, It is becoming more common to use larger rolling bearings (typically ball bearings). On the other hand, in recent color image forming machines, there is an increasing tendency to try to secure more stable fixing quality by incorporating a heater also in the pressure roller. When the heater is arranged inside the pressure roller, the diameter of the end portion of the pressure roller is inevitably increased, and the shape of the bearing and the member supporting the bearing is accompanied by this. Has been forced to become even larger. Further, the increase in size of the above-mentioned members leads to increase in size of the fixing device, and in turn, increase in size of the image forming machine and increase in cost.

Two typical examples will be described below as to how the conventional fixing device is specifically constructed in such a technical appreciation.

First, a first conventional example of a fixing device will be described with reference to FIGS. 4 and 5. The fixing device shown is
A stationary frame body 10 is provided. The stationary frame body 10 has a bottom wall 11
And both side walls 12 (only one side wall 12 is shown in FIG. 4) arranged on both sides of the bottom wall 11 in the longitudinal direction (front and back direction of paper in FIG. 4), and a top wall 13. There is. Between both side walls 12 of the stationary frame body 10, a heating roller 20 which is a heating rotating body having a heater 20H composed of a halogen lamp built therein is rotatably supported via a ball bearing B1 which is a rolling bearing. Heating roller 2
Reference numeral 0 includes a metal pipe which is a core metal, and both ends of the pipe are formed by drawing to have a smaller diameter than an intermediate region between the both ends. A non-adhesive layer is provided on the peripheral surface of the intermediate region of the pipe of the heating roller 20. The non-adhesive layer is provided to prevent the adhesion of the molten toner, and is made of a fluororesin or the like.
The ball bearings B1 are press-fitted into both ends of the pipe of the heating roller 20. In addition, in FIG. 4, the heating roller 20 shown by the cross section of the solid line is the heating roller 2
A circle concentric with the axis O1 of the heating roller 20, which is indicated by the two-dot chain line, indicates the peripheral surface of the intermediate region of the heating roller 20.

On both side walls 12 of the stationary frame 10, one end of a bearing support plate member 30 made of metal is supported so as to be rotatable around a rotation axis S. In each of the bearing support plate members 30,
A pressure roller 40 having a heater 40H formed of a halogen lamp therein is rotatably supported via a ball bearing B2 which is a rolling bearing. The pressure roller 40 includes a metal pipe, which is a core metal, and both ends of the pipe are formed by drawing to have a smaller diameter than an intermediate region between the both ends. A heat resistant elastic layer is provided on the peripheral surface of the intermediate region of the pipe of the pressure roller 40. This elastic layer is made of silicon rubber or the like. Ball bearings B2, which are rolling bearings, are press-fitted into both ends of the pipe of the heating roller 20. A tension coil spring 15 is arranged between the other end of each bearing support plate member 30 and the corresponding side wall 12. Each of the bearing support plate members 30 is biased in one of the turning directions (counterclockwise in FIG. 4) by the tension coil spring 15,
The pressure roller 40 is in pressure contact with the heating roller 20.

Each of the bearing support plate members 30 whose plane shape is substantially hook-shaped has a flat plate-shaped main body 31 and a flat plate-shaped main body 3.
1 integral with the main body 31 so as to extend at a right angle to the main body 31 from a partial region of the inner peripheral edge 31a located on the inner side in the radial direction with respect to the central axis O2 of the pressure roller 40 and thus the central axis O2 of the ball bearing B2 And a bearing support flange 32 formed in an arc shape by drawing and bending.
The arc-shaped bearing support flange 32 is concentric with the pressure roller 40 and has an arc-shaped inner peripheral surface 32a which can be aligned with a partial region of the outer peripheral surface of the corresponding ball bearing B2. Part of the outer peripheral surface of each ball bearing B2 of the pressure roller 40 is supported by the arcuate inner peripheral surface 32a of the bearing support flange 32 of the corresponding bearing support plate member 30. In FIG. 5, reference symbol L indicates the axis O2 of the pressure roller 40, and thus the axis O2 of the ball bearing B2.
An axis line passing through is shown.

Next, a second conventional example of the fixing device will be described with reference to FIGS. 6 and 7. The fixing device shown
The difference from the fixing device described with reference to FIGS. 4 and 5 is only the configuration of the metal bearing support plate member 50, and the other configurations are substantially the same, so the same portions are the same. It is indicated by a symbol and the description is omitted. Plane shape is almost L
Each of the bearing support plate members 50 having a shape includes a plate-shaped main body 51, an axial center O2 of the pressure roller 40 of the main body 51,
Therefore, the main body 51 extends from a partial region of the outer peripheral edge 51a located radially outside of the axial center O2 of the ball bearing B2, which extends linearly in the tangential direction of the outer peripheral surface of the ball bearing B2. A main body 51 and a bearing support flange 52 formed by bending are integrally formed so as to extend at a right angle with respect to the main body 51. Bearing support flange 52
Extends linearly in a tangential direction to the outer peripheral surface of the ball bearing B2. An inner side surface 52a of the bearing support flange 52 located radially inward of the axis O2 of the pressure roller 40, and thus the axis O2 of the ball bearing B2.
Extends linearly in the tangential direction of the outer peripheral surface of the ball bearing B2. The outer peripheral surface of each of the ball bearings B2 of the pressure roller 40 is substantially linearly supported by the inner surface 52a of the bearing support flange 52 of the corresponding bearing support plate member 50. Each of the ball bearings B2 is also fitted into an elongated hole (not shown) provided in the corresponding side wall 12, and is supported so as to be movable in the turning direction about the turning axis S by a predetermined angular range.

[0009]

In the first conventional example of the fixing device, each body 3 of the bearing support plate member 30 is provided.
1, an arc-shaped bearing support flange 32 is formed in a partial area of the inner peripheral edge 31a, and each of the ball bearings B2 of the pressure roller 40 has a corresponding bearing support plate member 30.
Of the bearing support flange 32 is supported in close contact with the arcuate inner peripheral surface 32a of the bearing support flange 32. With the pressure roller 40 in pressure contact with the heating roller 20, the lower region of the outer peripheral edge 31b of each main body 31 of the bearing support plate member 30 extends from the bearing support flange 32 to the axis O2 of the pressure roller 40. It extends outward in the radial direction and close to the bottom wall 11 of the stationary frame body 13. In order to give each of the bearing support plate members 30 sufficient strength, the bearing support flange 3
It is necessary to sufficiently increase the dimension a1 from the lowermost part of the second arcuate inner peripheral surface 32a to the lowermost surface of the outer peripheral edge 31b of the main body 31. If the dimension a1 is made sufficiently large, the bottom wall 11 of the stationary frame body 13 must also be lowered. That is, in the first conventional example, the pressure roller 40
Since the ball bearing B2, which is a rolling bearing larger than the slide bearing, is used as the bearing, the outer diameter of the bearing increases, so that each of the bearing support plate members 30 increases. Along with that, the position of the bottom wall 11 of the stationary frame body 13 must be lowered, resulting in an increase in the size of the fixing device, an increase in the size of the image forming machine, and an increase in cost.

On the other hand, in the second conventional example of the fixing device, the bearing support flange 52 is formed so as to extend linearly in a part of the outer peripheral edge 51a of each main body 51 of the bearing support plate member 50. Each of the ball bearings B2 of the pressure roller 40 has a corresponding bearing support plate member 50.
Of the bearing support flange 52 and the side wall 12
Is supported by a long hole (not shown) arranged in the. In each of the bearing support plate members 50, the space required below the ball bearing B2 is approximately equal to the thickness of the bearing support flange 52, that is, approximately the thickness a2 of the bearing support plate member 50. Since this dimension a2 is much smaller than the dimension a1 in the first conventional example, it is possible to suppress the increase in size of the fixing device as compared with the first conventional example. However, each bearing support flange 52 of the bearing support plate member 50 is formed by bending so as to extend at a right angle to the main body 51 and linearly in a partial region of the outer peripheral edge 51 a of the main body 51. Ball bearing B
The stress due to the load for supporting 2 is concentrated on the bent base end of the bearing support flange 52. Therefore, the bearing support flange 52
In order to sufficiently secure the bending rigidity of each of the bearing support plate members 50, the plate thickness of each of the bearing support plate members 50 may be made sufficiently thick, or a V notch may be formed at each bent base end of the bearing support flange 52. It was necessary to take measures, which resulted in cost increase.

An object of the present invention is to support the pressure roller on each of the bearing supporting plate members via a rolling bearing larger than the slide bearing, but to minimize the size increase of each of the bearing supporting plate members. It is an object of the present invention to provide a novel fixing device that can suppress the cost and reduce the cost while ensuring sufficient strength.

[0012]

According to the present invention, a heating rotator rotatably supported between both side walls of a stationary frame and having a built-in heater, and rotatably supported by both side walls of the stationary frame. In addition, a metal bearing support plate member and a pressure roller rotatably supported by each of the bearing support plate members via rolling bearings are provided, and each of the bearing support plate members is provided between the stationary frame member and the stationary frame member. In the fixing device in which the pressure roller is pressed against the heating rotator by being biased in one direction of rotation by the spring means disposed in the main body, each of the bearing support plate members has a substantially flat plate shape. And a flange integrally formed with the main body so as to extend at a right angle to the main body from a partial region of an outer peripheral edge of the main body located radially outside with respect to the axis of the pressure roller, The flange is at least concentric with the pressure roller. A bearing support flange portion having an arcuate inner peripheral surface that can be aligned with a corresponding partial area of the outer peripheral surface of the bearing, and a partial area of the outer peripheral surface of each of the bearings of the pressure roller corresponds to the corresponding bearing. Provided is a fixing device, which is supported on an arcuate inner peripheral surface of a bearing support flange portion of a support plate member. It is preferable that the flange of the main body of each of the bearing support plate members includes a reinforcing flange portion that is continuous with the bearing support flange portion. It is preferable that the arcuate inner peripheral surface of each bearing support flange portion of the bearing support plate member is formed by drawing and bending and is formed of a superior arc or an inferior arc.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of a fixing device constructed according to the present invention will be described below with reference to FIGS. The illustrated fixing device includes a stationary frame body 100. The stationary frame body 100 includes a bottom wall 101, side walls 102 arranged on both sides of the bottom wall 101 in the longitudinal direction, and a ceiling wall 103. Between both side walls 102 of the stationary frame body 100, a heating roller 120 which is a heating rotating body having a heater 120H formed of a halogen lamp built therein is rotatably supported via a ball bearing B1 which is a rolling bearing.
The heating roller 120 includes a metal pipe which is a core metal, and both ends 121 of the pipe are formed by drawing to have a smaller diameter than an intermediate region 122 between the ends. A non-adhesive layer made of fluororesin or the like is provided on the peripheral surface of the intermediate region 122 of the pipe of the heating roller 120. The ball bearing B1 is press-fitted into both ends 121 of the pipe of the heating roller 120.

The heating roller 120 configured as described above
Each of the ball bearings B1 has a corresponding side wall 10
The upper end portion 111 of the through hole 110 formed in No. 2 is fitted and supported. The upper end 111 of each of the through holes 110
Is a circular arc larger than a semicircle, that is, a superior arc, and the lower end portion 112 has a width larger than the diameter of the ball bearing B2 supporting the heating roller 120. One end 121 of the pipe of the heating roller 120 projects outward from the side wall 102, and a drive gear 123 is attached to this projection. The drive gear 123 is drivably coupled to a drive source, which may be an electric motor, via a power transmission mechanism (not shown). In addition, in FIG. 1, it is shown by a two-dot chain line,
A circle concentric with the axis O1 of the heating roller 120 indicates the peripheral surface of the intermediate region 122 of the heating roller 120 (more accurately, the outer peripheral surface of the non-adhesive layer). Both ends of the heater 120H project from both ends of the heating roller 120, and the projecting both ends are held by holders 124 arranged on the side walls 102, respectively. In this way, the heater 120H
Is the heating roller 1 without contacting the heating roller 120.
Both ends are held by the holder 124 while penetrating through the inside of 20.

Inside the both side walls 102 of the stationary frame 100, one end of a bearing support plate member 130 made of metal is provided with a swivel axis S.
It is supported so that it can turn around. Bearing support plate member 1
Each of the 30 has a heater 140 including a halogen lamp.
A pressure roller 140 containing H is rotatably supported via a ball bearing B2 which is a rolling bearing.
The pressure roller 140 includes a metal pipe that is a core metal, and both ends 141 of the pipe are formed by drawing to have a smaller diameter than the intermediate region 142 between the ends. A heat-resistant elastic layer made of silicon rubber or the like is provided on the peripheral surface of the intermediate region 142 of the pipe of the pressure roller 140. The ball bearings B2 are press-fitted into both ends 141 of the pipe of the heating roller 140. The other end of each bearing support plate member 130 and the corresponding side wall 102
An extension coil spring 115, which is a spring unit, is disposed between the and. Each of the bearing support plate members 130 is biased in one of the turning directions (counterclockwise in FIG. 1) by the tension coil spring 115, so that the pressure roller 1 is pressed.
40 is pressed against the heating roller 120.

Each of the bearing support plate members 130, which can be formed from a metal plate having a predetermined thickness by sheet metal working and has a generally L-shaped planar shape as a whole, has a substantially flat plate-shaped main body. 131 is provided. Body 131
Is a linear portion 131A that extends substantially linearly with a predetermined width.
And a bulging portion 131B that bulges in one direction from the lower end of the linear portion 131A. A through hole 132 having an inner diameter larger than the outer diameter of the small-diameter end portion 141 of the pressure roller 140 is formed in the bulging portion 131B. Body 1
A protrusion that extends in the same one direction as the bulging portion 131B is formed at the tip of the protrusion 31, and a locking hole 130a for the extension coil spring 115 is formed in the protrusion. Further, a protruding portion that extends in one direction is formed at the tip of the bulging portion 131B, and the rotating hole 130b that is fitted to the rotating shaft S is formed in the protruding portion.

The main body 131 is also integrated with the main body 131 so as to extend at a right angle to the main body 131 from a part of an outer peripheral edge 131a of the main body 131 which is located radially outward of the axial center O2 of the pressure roller 140. And a flange 133 formed in. In the embodiment, the flange 13
3 is formed to extend along the L-shaped outer peripheral edge 131a of the main body 131. This flange 133
Has a bearing support flange portion 133A which is concentric with the pressure roller 140 and has an arcuate inner peripheral surface 133a which can be aligned with a partial region of the outer peripheral surface of the corresponding ball bearing B2. In the embodiment, the flange 133 includes a reinforcing flange portion 133B formed continuously with the bearing support flange portion 133A. The bearing support flange portion 133A is almost the same as the bulging portion 1 of the main body 131.
The reinforcing flange portion 133B is formed along the outer peripheral edge 131a of the body 31B, and the reinforcing flange portion 133B is substantially the straight portion 13 of the body 131.
It is formed along the outer peripheral edge 131a of 1A. The flange 133 is drawn and bent (the arc-shaped linear portion 13
1A) and a bending process (reinforcing flange portion 133B) are integrally formed with the main body 131. In addition, in FIG. 3, reference symbol L indicates an axis line passing through the axis O2 of the pressure roller 140, and thus the axis O2 of the ball bearing B2.

Ball bearing B2 of pressure roller 140
A partial area of each outer peripheral surface, in the embodiment, an outer peripheral surface area below a horizontal line passing through each axis O of the ball bearing B2 and which is close to a semicircle, corresponds to the corresponding bearing. The support plate member 130 is supported while being in close contact with the arcuate inner peripheral surface 133a of the bearing support flange portion 133A. Each of the bearing support plate members 130 is urged by the tension coil spring 132 so as to be rotated about the rotation axis S in one direction of the rotation direction, that is, in the counterclockwise direction in FIG. As a result, each bearing support flange portion 133A of the bearing support plate member 130 pushes up the corresponding ball bearing B2 upward, so that the pressure roller 140 causes the pressure roller 140 to move to the outer peripheral surface of the intermediate region 142 (more accurately, The outer peripheral surface of the elastic layer is pressed against the outer peripheral surface of the intermediate region 122 of the heating roller 120 (more accurately, the outer peripheral surface of the non-adhesive layer). In this state, a part of the outer peripheral surface of each ball bearing B2 in the axial direction is positioned with a gap in the lower end portion 112 of the through hole 110 of the corresponding side wall 102, and is slightly moved around the turning axis S. It is configured to allow the turning movement. Further, the outer peripheral surface of each of the ball bearings B2 is formed of the through hole 110 of the corresponding side wall 102.
It is positioned with a gap from the lower end 113 having a semicircular shape. Furthermore, both ends of the heater 140H are
The pressure roller 140 projects from both ends, and both projecting ends are held by holders 144 disposed on the sidewalls 102, respectively. The heater 140H is the pressure roller 14
It penetrates through the pressure roller 140 without touching 0,
Both ends are held by the holder 144. In FIG. 1, a circle concentric with the axis O2 of the pressure roller 140, which is indicated by a chain double-dashed line, is an intermediate region 142 of the pressure roller 140.
The outer peripheral surface (more accurately, the outer peripheral surface of the heat-resistant elastic layer) is shown.

In each bearing support plate member 130, the space required below the ball bearing B2 is approximately equal to the thickness of the bearing support flange 133A (that is, the thickness of the bearing support plate member 130) a3. This dimension a3 is
Since the size is much smaller than the dimension a1 in the first conventional example, the size of the fixing device can be largely suppressed as compared with the first conventional example. This dimension a3 also
It is substantially the same as the dimension a2 in the second conventional example. However, in the present invention, the bearing support flange portion 133A that supports the outer peripheral surface of the ball bearing B2 is a partial region of the outer peripheral edge of the main body 131, which is located radially outward with respect to the axial center O2 of the pressure roller 140. Body 13 to extend at a right angle to body 131
1, an arc-shaped inner peripheral surface 133a (arc-shaped curved drawing surface) that is formed integrally with the pressure roller 140 and that is concentric with the pressure roller 140 and that can be aligned with a partial area of the outer peripheral surface of the corresponding ball bearing B2. Since it has an arcuate shape, it has a strong structure in which the bending surface (arc-shaped inner peripheral surface 133a) generated by the reaction force received from the corresponding ball bearing B2 is hard to deform. Therefore, as compared with the second conventional example, the rigidity of the bearing support flange portion 133A that receives the ball bearing B2 becomes very high, so that the plate thickness of each of the bearing support plate members 130 is the same as that of the second conventional example. It is possible to make the bearing support plate member 50 thinner than each plate, and it is possible to reduce the cost. Further, unlike the second conventional example, it is not necessary to form a V notch at each bent base end of the bearing support flange 52 in order to secure bending rigidity, so the number of press working steps is also reduced, and in this aspect as well. The cost can be reduced. Further, in the above embodiment, the bearing support flange portion 133 is provided on the outer peripheral edge of the main body 131 in each of the bearing support plate members 130.
Since the reinforcing flange portion 133B which is continuous with A is formed, the rigidity of the entire bearing supporting plate member 130 together with the bearing supporting flange portion 133A is improved.

In the above embodiment according to the present invention, each bearing support flange portion 133A of the bearing support plate member 130.
Is composed of a so-called inferior arc whose arc length is shorter than a semicircle, but may be an embodiment which is composed of a so-called superior arc whose arc length is longer than a semicircle. Further, the outer peripheral edge 131a of each of the bearing support plate members 130 is formed with a flange 133 in which a bearing support flange portion 133A and a reinforcing flange portion 133B are continuous, but only the bearing support flange portion 133A is formed as the flange. There are also other embodiments of forming Furthermore, although the pressure roller 140 includes the heater 140H in the above embodiment, there is another embodiment in which the heater 140H is not included. Furthermore, the heating roller 120 having a built-in heater 120H as a heating rotator against which the pressure roller 140 is pressed.
However, in place of this, there is another embodiment in which a heating belt body (not shown) whose construction is known is used. The heating belt body is composed of a pair of rollers each having a built-in heater, and an endless belt wound between the rollers.

[0021]

According to the fixing device of the present invention, although the pressure roller is supported on each of the bearing supporting plate members through the rolling bearings larger than the slide bearings, each of the bearing supporting plate members is supported. It is possible to reduce costs while minimizing the increase in size and ensuring sufficient strength. As a result, the fixing device according to the present invention can be applied particularly to a color image forming machine.

[Brief description of drawings]

FIG. 1 is a cross-sectional view schematically showing a configuration of a fixing device configured according to the present invention, which is a cross-sectional view taken along the line AA of FIG.

FIG. 2 is a schematic vertical cross-sectional view of the fixing device shown in FIG.

3 is a perspective view of the bearing support plate member shown in FIG. 1. FIG.

FIG. 4 is a cross-sectional view schematically showing the configuration of an example of a conventional fixing device, which is a cross-sectional view corresponding to the cross-sectional view taken along the line AA of FIG.

5 is a perspective view of the bearing support plate member shown in FIG.

FIG. 6 is a cross-sectional view schematically showing the configuration of another example of a conventional fixing device, which is a cross-sectional view corresponding to the cross-sectional view taken along the line AA of FIG.

7 is a perspective view of the bearing support plate member shown in FIG.

[Explanation of symbols]

100 stationary frame 101 bottom wall 102 side wall 120 heating roller 120H heater 130 Bearing support plate member 131 body 133A bearing support flange 133a arc-shaped inner peripheral surface 140 pressure roller 140H heater B1 and B2 ball bearings S swivel axis

Claims (3)

[Claims] 1. A heating rotator rotatably supported between both side walls of a stationary frame and having a built-in heater, and a metal bearing support plate member rotatably supported by both side walls of the stationary frame. A pressure roller rotatably supported on each of the bearing support plate members via a rolling bearing, and each of the bearing support plate members is arranged in a direction of rotation by a spring means arranged between the bearing support plate member and the stationary frame body. In the fixing device in which the pressure roller is pressed against the heating rotator by being urged to one side, each of the bearing support plate members has a substantially flat plate-shaped main body and a pressure roller of the main body. A flange integrally formed with the main body so as to extend at a right angle to the main body from a partial region of an outer peripheral edge located radially outward with respect to the axis, the flange being at least concentric with the pressure roller. And one of the corresponding outer peripheral surface of the bearing A bearing support flange portion having an arcuate inner peripheral surface that can be aligned with the area is provided, and a partial area of each outer peripheral surface of the bearing of the pressure roller has an arcuate shape of the bearing support flange portion of the corresponding bearing support plate member. A fixing device, which is supported on an inner peripheral surface. 2. The fixing device according to claim 1, wherein the flange of the main body of each of the bearing support plate members includes a reinforcing flange portion continuous with the bearing support flange portion. 3. The fixing according to claim 1, wherein the arcuate inner peripheral surface of each of the bearing supporting flange portions of the bearing supporting plate member is formed by drawing and bending and has a superior arc or an inferior arc. apparatus.