JPH09254007A - Large roller made of ceramics - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the weight of a large roller made of ceramics while securing its rigidity by forming an outer peripheral part made of ceramics into a hollow cylinder and providing a reinforcing means. SOLUTION: An outer peripheral part 2 made of ceramics is formed into a hollow cylinder by using alumina, zirconia, etc., and a reinforcing member 8 is provided inside the outer peripheral part 2. The reinforcing member 8 is a reinforcing means for reinforcing the rigidity of the outer peripheral part made of ceramics and is a disc-shaped body which is formed into an integral structure with the outer peripheral part 2 and has the same core as that of the outer peripheral part. One or a plurality of holes 9 for reducing weight are provided in the reinforcing member 8 to reduce its weight. Moreover, a material having substantially equal coefficient of thermal expansion to that of the material of the outer peripheral part 2, for example, titanium, a titanium material, is used. As for a material of a shaft 3, titanium or titanium alloy having substantially equal expansion coefficient to that of the material of the outer peripheral part 2 made of ceramics is used. Consequently, since the outer peripheral part 2 and the shaft 3 are expanded and shrunk simultaneously at the same rate when temperature of a large roller LR made of ceramics is changed, the peeling and deviation of a joint part 4 do not occur.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a large-sized ceramic roller which constitutes a part of a processing device such as a wire saw and a roll crusher and has an outer peripheral portion made of ceramics.

[0002]

[Prior art]

2. Description of the Related Art As shown in FIG. 13, in a roll crusher, two crushing rollers 1 are arranged in close proximity to each other, and the two rollers 1 are rotated in opposite directions to rotate the rollers. When the crushed object M is inserted from the winding side U, the crushed object M is crushed and discharged from the discharge side D by the two crushing rollers 1. As shown in FIG. 14, the crushing roller 1 is
It is composed of an outer peripheral portion 2 and a shaft 3 made of ceramics, and the outer peripheral portion 2 and the shaft 3 are usually adhered to each other by an adhesive S or the like at a joint portion 4 and attached to the crusher main body by the metal shaft 3.

[0003]

2. Description of the Related Art As shown in FIG. 15, a wire saw has a plurality of multi-groove rollers 6 on which the wires 5 are stretched. By rotating the rollers 6, the wire 5 moves linearly in the direction of arrow A5. Then, the abrasive grains are pressed against the work piece 7 with a wire to cut the work piece 7 such as a magnetic body, crystal, ceramics, or silicon. When the multi-groove roller 6 is a large roller having a diameter of 70 mm or more and a length of more than 150 mm, the roller 6 has an outer peripheral portion 2 as shown in FIG.
Is made of, for example, 66 nylon, and is made of a metal shaft 3
Is bonded to the processing apparatus main body (not shown) by an adhesive agent S or the like via the bonding portion 4.

In recent years, the size of the work piece has been increased, and for example, in the case of silicon, the ingot of silicon has been increased from 8 inches to 12 inches as the diameter of the wafer is increased. As a result, the wire saw has been increased in size, and so-called large rollers having a diameter of 200 mm, a length of 600 mm and a weight of 60 kg have been used as the multi-groove roller.

[0005]

In a large roller having a diameter of 70 mm or more and a length of more than 150 mm, which is attached to a processing apparatus, such as a roll crusher roller or a wire saw multi-groove roller, the outer peripheral portion and the outer peripheral portion are supported. Different kinds of materials are used for the shaft, which is a member, for example,
When ceramics is used for the outer circumference and metal such as iron or aluminum is used for the shaft, there are the following problems. (1) Since the roller is heavy, a mounting device with high rigidity is required, and it takes a lot of time and cost to detach the roller from the processing apparatus when replacing the roller.

(2) The outer peripheral portion is fixed to the shaft by an adhesive or the like at the joint, but there is a large difference in the coefficient of linear expansion between the ceramic outer peripheral portion and the metal shaft. Therefore, when the product expands or contracts due to a temperature change caused by heat generation during operation, the positional relationship between the two in the axial direction is displaced, and not only the processed product may not be processed accurately, but also the adhesive or the like may be peeled off. . Then,
The ability to fix the outer periphery and the shaft is lost, and the processing machine itself does not function. Further, as the length of the roller becomes longer and the joint portion becomes longer, the influence becomes more remarkable. Therefore, in a wire saw or the like in which the pitch accuracy between the wires extended to the plurality of multi-groove rollers is important, the processing accuracy is reduced due to the positional deviation between the outer peripheral portion and the shaft.

(3) Since the roller has a large inertial force, a large drive source is required at the time of starting, reversing, stopping and rotating at high speed, which is economically disadvantageous.
In addition, the processing apparatus as a whole becomes large in size and weight, and a large installation space is required.

In view of the above circumstances, an object of the present invention is to reduce the weight of a large ceramic roller while ensuring its rigidity. Another object is to prevent the ceramic outer peripheral portion and the supporting member from being displaced from each other and from being separated from each other.

[0009]

SUMMARY OF THE INVENTION The present invention relates to a large-sized ceramic roller having a ceramic outer peripheral portion and mounted on a processing apparatus or the like; the ceramic outer peripheral portion having a hollow cylindrical shape. A ceramic large-sized roller characterized by comprising a reinforcing means.

According to the present invention, there is provided a large-sized ceramic roller which has a ceramic outer peripheral portion and is mounted on a processing device or the like through a support member; the ceramic outer peripheral portion is formed into a hollow cylindrical shape, and the support is provided. The member is a shaft that penetrates the outer peripheral portion made of ceramics and is joined to the outer peripheral portion, and the shaft is formed of a material having an expansion coefficient substantially equal to that of the outer peripheral portion made of ceramics. A large roller made of ceramics.

The present invention relates to a large-sized ceramic roller provided with a ceramic outer peripheral portion and mounted on a processing device or the like via a supporting member; the ceramic outer peripheral portion being formed into a hollow cylindrical shape, and supporting the same. A large-sized ceramic roller characterized in that the member is an end supporting member joined to both ends of a ceramic outer peripheral portion.

According to the present invention, there is provided a large-sized ceramic roller having a ceramic outer peripheral portion and mounted on a processing device or the like through a supporting member; the ceramic outer peripheral portion being formed into a hollow cylindrical shape, and A material having a reinforcing means, wherein the supporting member is a shaft that penetrates the outer peripheral portion made of ceramics and is joined to the outer peripheral portion, and the shaft has a coefficient of expansion substantially equal to that of the outer peripheral portion made of ceramics. A large roller made of ceramics, characterized in that it is formed of.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION A processing apparatus or the like, for example, a large-sized roller such as a wire saw or a roll crusher is formed with a ceramic hollow cylindrical outer peripheral portion, and reinforcing means for increasing the strength of the outer peripheral portion is provided. This roller
For example, it is a large roller having a diameter of 200 mm and a length of 600 mm.

As the reinforcing means, for example, a reinforcing member or a reinforced thick portion is adopted. The reinforcing member material is, for example, a disk-shaped body that is concentrically formed in the hollow portion of the ceramic outer peripheral portion, and is formed integrally with the ceramic.
The reinforced thick portion is formed thick enough to have a sufficient thickness of the outer peripheral portion made of ceramics, and the thickness is formed uniformly, but it is not always necessary to form such a thickness. A mesh-like protrusion may be formed on the inner surface of the outer peripheral portion. Further, a hollow insert may be inserted and joined inside the outer peripheral portion to strengthen the ceramic outer peripheral portion. By providing the reinforcing means in this manner, it is possible to obtain a large ceramic roller which is rigid and lightweight.

The ceramic roller is mounted on a processing device or the like by a supporting member, and as the supporting member, for example, a shaft or an end supporting material is used. This shaft is inserted and joined to the outer peripheral portion made of ceramics, and the material of the shaft is one having an expansion coefficient substantially equal to that of the outer peripheral portion made of ceramics such as titanium or titanium alloy. By using such a metal supporting member, the ceramics and the supporting member are strongly fixed to each other without causing positional displacement due to temperature change.

Further, when the end supporting member is used as the supporting member, the length of the joint between the two becomes extremely shorter than the length of the roller, so that there is a difference in the expansion coefficient and the displacement at the joint. Is almost negligible, and the displacement of the joint due to temperature change does not occur. Therefore, it is not always necessary to use a material having an expansion coefficient substantially equal to that of the ceramic outer peripheral portion for the end portion supporting member.

[0017]

First Embodiment A first embodiment of the present invention will be described with reference to FIGS. In the ceramic large roller LR, the ceramic outer peripheral portion 2 is formed in a hollow cylindrical shape. As this ceramic, for example, alumina, zirconia or the like is used.

A reinforcing member 8 is provided inside the ceramic outer peripheral portion 2. The reinforcing member 8 is a reinforcing means for strengthening the rigidity of the ceramic outer peripheral portion, and is a concentric disc-shaped body formed integrally with the ceramic outer peripheral portion 2. The number, spacing, thickness, material, etc. of the reinforcing member 8 are appropriately determined by the length of the roller and the load applied to the roller.

As a reinforcing means, instead of using the disk-shaped body 8, a hollow ceramic outer peripheral portion 2 may be thickened to be a reinforced thick portion for holding necessary strength. There are various types of this reinforced thick portion, for example, those having a uniform thickness, those having a honeycomb structure on the inner surface of the outer peripheral portion, and the like.

The reinforcing member 8 is provided with one or a plurality of weight reducing holes 9 for weight reduction. Lightening hole 9
In some cases, it may not be possible to open the holes, and the shape, number, through-holes or stop holes shall be decided appropriately.

The ceramic outer peripheral portion 2 and the reinforcing member 8
May be an integral sintered body or may be adhered. Therefore, the ceramic outer peripheral portion 2 and the reinforcing member 8 do not necessarily have to be made of the same material, but when they are adhered by using different materials, the material of the reinforcing member 8 is substantially the same as that of the outer peripheral portion 2. A material having an equal thermal expansion coefficient, for example, titanium or a titanium material is used. It is both 2, 8
This is to prevent the displacement of the adhesive portion due to the difference in the amount of displacement when the sheet expands and contracts due to temperature changes.

The reinforcing member 8 includes a ceramic outer peripheral portion 2
A through hole 10 through which the shaft 3, which is a support member of the above, passes is provided. Normally, this portion becomes a joint 4 between the ceramic outer peripheral portion 2 and the shaft 3 and is joined by an adhesive or the like.
However, this does not limit the fixing method.

The shaft 3 is made of titanium or titanium alloy having substantially the same expansion coefficient as the ceramic outer peripheral portion 2. Therefore, when the temperature of the large ceramics roller LR changes due to the operation of the processing device, the ceramics outer peripheral portion 2 and the shaft 3 simultaneously expand and contract at substantially the same rate, so that the joining portion 4 does not peel off or shift.

As a means for preventing the displacement of the joint portion due to the temperature change in this way, by using a material having a coefficient of thermal expansion substantially equal to that of the ceramic outer peripheral portion for the shaft, the original performance of the processing apparatus is improved. It can be put out and the function of ceramics can be fully exhibited. The linear expansion coefficient (× 10 ⁻⁶ ° C., 20 ° C.) of each material is as follows, for example. Iron = 11.8 Aluminum = 23.1 Titanium = 8.6 Titanium alloy (Ti-6Al-4V) = 8.8 Alumina = 7.1 Zirconia = 9.0 66 Nylon = 90

On one end side of the shaft 3, there is provided a step which is a positioning part 13 integrally formed on the outer peripheral part, and by making contact with the reinforcing member 8, the outer peripheral part 2 made of ceramics and the shaft 3 in the longitudinal direction. Perform positioning. As a result, the positional relationship between the device for mounting the large ceramic roller and the ceramic outer peripheral portion 2 can be easily and accurately mounted. However, this does not limit the positioning method.

[0026]

Second Embodiment A second embodiment of the present invention will be described with reference to FIGS. The ceramic outer peripheral portion 2 of the ceramic large roller LR is formed in a hollow cylindrical shape. As this ceramic, for example, alumina, zirconia, or the like is used.

A reinforcing member 28 is provided inside the ceramic outer peripheral portion 2. The reinforcing member 28 is a reinforcing means for strengthening the rigidity of the ceramic outer peripheral portion 2, and has a concentric disk shape integrally formed with the ceramic outer peripheral portion 2. Number of reinforcing members 28, spacing,
The thickness, material, etc. are appropriately determined by the length L of the roller and the load applied to the roller.

The ceramic outer peripheral portion 2 and the reinforcing member 2
8 may be an integral sintered body or may be adhered. Therefore, the ceramic outer peripheral portion 2 and the reinforcing member 28 do not necessarily have to be made of the same material, but when they are adhered using different materials, the material of the reinforcing member 28 is substantially the same as that of the outer peripheral portion 2. A material having a coefficient of thermal expansion, for example, titanium or a titanium material is used. It is both 2, 2
This is to prevent the displacement of the adhesive portion due to the difference in the displacement amount when 8 expands and contracts due to the temperature change.

The reinforcing member 8 is provided with one or a plurality of weight-reducing holes 9 for reducing the weight. The holes may not be formed in some cases, and the shape, the number, the through holes, or the stop holes are appropriately determined.

At both ends 2a of the ceramic outer peripheral portion 2, end supporting members 11 which are supporting members for the outer peripheral portion 2 are provided.
Both end support members 11 are formed to have the same diameter, and a step portion 11A having a length L2 is provided on the inner peripheral portion of the inner surface thereof. The end portion 2a of the outer peripheral portion 2 is fitted into the step portion 11A to form the joint portion 24. The length L2 of the stepped portion 11A is appropriately selected as needed. In addition, the shaft portion 1 is provided at the center of the outer surface of the end support member 11.
1B is projected. Like the reinforcing member 28, the end supporting member 11 may be provided with the hole 9 for reducing the weight.

The end supporting member 11 is in contact only with the ceramic outer peripheral portion 2 and the end portion 2a, and the length L of the joint portion 24 is L.
Since 2 is much shorter than the length L of the roller LR, even if the ceramic outer peripheral portion 2 expands or contracts due to the temperature change generated by the operation of the processing device, it is not affected. As described above, by shortening the length of the joint portion between the two and 11 as the positional deviation preventing means, it is possible to deal with various materials having different expansion rates. Of course, the end support member 11 may be formed of titanium or titanium alloy having a thermal expansion coefficient substantially equal to that of the ceramic outer peripheral portion 2.

When the positioning portion 23 of the end support member 11 is fitted into the end surface 2a of the ceramic outer peripheral portion 2, the ceramic outer peripheral portion 2 and the shaft 3 can be automatically positioned in the longitudinal direction. As a result, a device for mounting a large ceramic roller and a ceramic outer peripheral portion 2
The positional relationship of can be easily and accurately attached. However, this does not limit the positioning method.

[0033]

Third Embodiment A third embodiment of the present invention will be described with reference to FIGS. In the ceramic large roller LR, the ceramic outer peripheral portion 2 is formed in a hollow cylindrical shape. As this ceramic, for example, alumina, zirconia, or the like is used.

A concentric hollow insert 32 is provided inside the ceramic outer peripheral portion 2. The hollow insert 32 is a reinforcing means for strengthening the rigidity of the ceramic outer peripheral portion 2, is formed in a hollow cylindrical shape, and is bonded to the ceramic outer peripheral portion 2 via an outer joint portion 35 thereof by an adhesive or the like. It is joined.

The hollow portion 32a of the hollow insert 32 is provided with a reinforcing member, for example, a disc-shaped body 38, which is integral with the hollow insert 32. This reinforcing member 3
Reference numeral 8 serves as a reinforcing means together with the hollow insert 32. The number, spacing, thickness, material and the like of the reinforcing member 38 are appropriately determined by the length of the roller and the load applied to the roller. The hollow insert 32 and the reinforcing member 38 are
It may be cut out from the same member, or may be integrally structured by means such as welding, adhesion, and screwing. Further, the hollow insert 32 and the reinforcing member 38 do not necessarily have to be made of the same material.

The reinforcing member 38 is provided with one or a plurality of weight reducing holes 9 for weight reduction. Lightening hole 9
May not be opened, and the shape, number, through-holes or stop-holes shall be properly determined.

The hollow insert 32 is made of titanium or a titanium alloy whose coefficient of expansion is substantially equal to that of the ceramic outer peripheral portion 2. Therefore, although the temperature of the ceramic large roller LR changes due to the operation of the processing device and the like, the ceramic outer peripheral portion 2 and the hollow insert 32 expand and contract at the same rate at the same time, so that the joining portion is not peeled and the displacement does not occur.

The reinforcing member 38 is provided with a through hole 10 through which the shaft 3 passes. Normally, this portion serves as a joint portion 34 with the shaft 3 and is joined by an adhesive material, a screw or the like. However, this does not limit the fixing method.

The shaft 3 has a roller L having a length L4 at the joint 34 with the ceramic outer peripheral portion 2 and the hollow insert 32.
Since the length R is much shorter than the length L, even if the ceramic outer peripheral portion 2 expands or contracts due to the temperature change generated by the operation of the processing device, it is less likely to be affected. Therefore, various materials having different expansion rates can be used for the shaft 3. Further, the expansion and contraction of the mounting portion of the device for mounting the ceramic large roller due to the heat change, the shaft 3 becomes an interference material for thermal expansion by absorbing the expansion and contraction of the device mounting portion by selecting an appropriate material for the shaft 3. Is also possible.

The shaft 3 is provided with a step which is a positioning portion 33 formed as an integral structure, and by contacting with the reinforcing member 38, the ceramic outer peripheral portion 2 and the shaft 3 are provided.
And position in the length direction. This makes it possible to easily and accurately attach the positional relationship between the device for mounting the large ceramic roller and the ceramic outer peripheral portion 2. However, this does not limit the positioning method.

[0041]

Fourth Embodiment A fourth embodiment of the present invention will be described with reference to FIGS. In the large ceramic roller LR, the ceramic outer peripheral portion 2 is formed in a hollow cylindrical shape. Alumina, zirconia, or the like is used as this ceramic.

Inside the ceramic outer peripheral portion 2, a hollow insert 42 having a length L4 and formed in a hollow cylindrical shape is provided. The hollow insert 42 is a reinforcing means for strengthening the rigidity of the outer peripheral portion 2, and is joined to the outer peripheral portion 2 made of ceramics with an adhesive or the like via an outer joint portion 44.

The hollow portion 42a of the hollow insert 42 is provided with a reinforcing member formed integrally with the hollow insert 42, for example, a disk-shaped body 48. The reinforcing member 48 forms a reinforcing means together with the hollow insert 42. The number, spacing, thickness, etc. of the disk-shaped bodies 48 are appropriately determined by the length of the roller and the load applied to the roller. The hollow insert 42 and the reinforcing member 48 are
It may be cut out from the same member, or may be integrally structured by means such as welding, adhesion, and screwing. Further, the hollow insert 42 and the reinforcing member 48 do not necessarily have to be made of the same material.

The disc-shaped body 48 is provided with a plurality of weight-reducing holes 9 for reducing the weight in a circumferential shape. Lightening hole 9
May not be opened, and the shape, number, through-holes or stop-holes shall be properly determined.

When the hollow insert 42 has a high rigidity, it functions sufficiently as a reinforcing means, and therefore, as shown in FIGS.
The second reinforcing member 48 can be omitted. in this case,
The hollow insert 42 is made thick with titanium or a titanium alloy having a density of 4.4 to 4.5 g / cm ³ . In this way, while increasing the rigidity by thickening the wall thickness than usual,
The weight can be reduced.

Since the hollow insert 42 is made of titanium or titanium alloy whose expansion coefficient is substantially equal to that of the ceramic outer peripheral portion 2, the temperature of the large ceramic roller changes due to the operation of the processing device, etc. Since the outer peripheral portion 2 and the hollow insert 42 simultaneously expand and contract at substantially the same rate, the outer joint portion 44a does not peel off and shift.

At both ends of the ceramic outer peripheral portion 2 and the hollow insert 42, end supporting members 41, which are support members for the ceramic outer peripheral portion 2 and the hollow insert 42, are provided. The end supporting member 41 is formed to have a thickness L5, and the diameters of the end supporting members are different from each other. The large-diameter end supporting member 41 is bonded to the hollow insert 42 and one end surface 42n, 2a of the ceramic outer peripheral portion 2, and the other small-diameter end supporting member 41 is the other end of the outer peripheral portion 2. And is joined to the other end surface 42m of the hollow insert 42. The end support member 41 may also be provided with a hole for weight reduction like the disk-shaped body (reinforcing member) 48. Of course, support materials of the same shape may be used on both sides.

Since the end support member 41 has a very short length of the joint 44 in contact with the outer peripheral portion 2 made of ceramics and the hollow insert 42, the outer peripheral portion 2 made of ceramics and the hollow portion due to temperature change caused by the operation of the processing apparatus. Even if the insert 42 expands and contracts, it is not affected by it. Therefore, it can support various materials with different expansion rates. Of course, titanium or titanium alloy may be used for the end support member 41.

The positioning portion 43 of the end supporting member 41 is joined to the ceramic outer peripheral portion 2 and the end portion of the hollow insert 42 to form the ceramic outer peripheral portion 2 and the hollow insert 4.
2 and the shaft portion 11B are positioned in the longitudinal direction. This makes it possible to easily and accurately attach the positional relationship between the device for mounting the large ceramic roller, the ceramic outer peripheral portion 2 and the hollow insert. However, this does not limit the positioning method.

[0050]

Fifth Embodiment A fifth embodiment of the present invention will be described with reference to FIGS. In the large ceramic roller LR,
The ceramic outer peripheral portion 2 is formed in a hollow cylindrical shape. Alumina, zirconia, or the like is used as this ceramic.

A reinforcing member 58 is provided inside the ceramic outer peripheral portion 2. The reinforcing member 58 is a concentric disk-shaped body formed integrally with the shaft 53. The number, spacing, thickness, etc. of the reinforcing members 58 are appropriately determined by the length of the roller and the load applied to the roller. The shaft 53 and the reinforcing member 58 may be cut out from the same member, or may be integrally structured by means such as welding, bonding, and screwing. Further, the shaft 53 and the reinforcing member 58 do not necessarily have to be made of the same material.

The reinforcing member 58 is provided with one or a plurality of weight-reducing holes 9 for weight reduction. The weight-reducing holes 9 may not be opened in some cases, and the shape, number, through-holes or stop holes are appropriately determined.

The shaft 3 is made of titanium or a titanium alloy whose coefficient of expansion is substantially equal to that of the ceramic outer peripheral portion 2. Therefore, although the temperature of the large ceramics roller changes due to the operation of the processing device and the like, the ceramics outer peripheral portion 2 and the shaft 53 simultaneously expand and contract at substantially the same rate, so that the bonded portion is not peeled off and is not displaced. As a result, the original performance of the processing apparatus can be obtained, and the function of ceramics can be fully exhibited.

A step, which is a positioning portion 53B, is provided on the outer peripheral portion of the reinforcing member 58 formed integrally with the shaft 53, and the ceramic outer peripheral portion 2 and the shaft 53 are brought into contact with each other by making contact with the ceramic outer peripheral portion 2. Position in the length direction. This makes it possible to easily and accurately attach the positional relationship between the device for mounting the large ceramic roller and the ceramic outer peripheral portion 2. However, this is
The positioning method is not limited.

[0055]

As described above, the present invention has the following remarkable effects. (1) Since the ceramic outer peripheral portion is formed in a hollow cylindrical shape and is provided with the reinforcing means, it is possible to reduce the weight and enhance the rigidity. Therefore, the work of attaching and detaching the roller is facilitated, and the roller can be used as a roller for high speed rotation. Further, since the roller is lighter than the conventional example, the inertial force is small and the energy consumption of the drive source is significantly reduced.

(2) Since the roller supporting member joined to the ceramic outer peripheral portion is made of a material having an expansion coefficient substantially equal to that of the outer peripheral portion, even if both expand and contract due to temperature change, they are substantially the same. It expands and contracts simultaneously in proportion. Therefore, since the bonded portion can always maintain a strongly bonded state, problems such as peeling and displacement of the bonded portion do not occur.

(3) Since the end supporting member is joined to the end of the ceramic outer peripheral portion, the length of the joint portion in the axial direction of both is extremely short. Therefore, even if the two expand and contract due to temperature changes, the joint is hardly affected by the influence, and the strongly joined state can always be maintained. Therefore, problems such as peeling and displacement of the bonded portion do not occur.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of a large ceramic roller showing a first embodiment.

FIG. 2 is a right side view of FIG.

FIG. 3 is a sectional view of a large ceramic roller according to a second embodiment.

FIG. 4 is a right side view of FIG.

FIG. 5 is a sectional view of a large ceramic roller according to a third embodiment.

FIG. 6 is a right side view of FIG.

FIG. 7 is a sectional view of a large ceramic roller according to a fourth embodiment.

FIG. 8 is a right side view of FIG. 7;

FIG. 9 is a cross-sectional view showing a state in which the disk-shaped body is omitted.

FIG. 10 is a right side view of FIG.

FIG. 11 is a sectional view of a large ceramic roller according to a fifth embodiment.

FIG. 12 is a right side view of FIG.

FIG. 13 is a view showing a conventional example, and is a perspective view of an arrangement of rollers of a roll crusher.

14 is a sectional view taken along line XIV-XIV of FIG.

FIG. 15 is a view showing a conventional example, which is a conceptual diagram of a wire saw.

16 is a sectional view taken along line XVI-XVI of FIG.

[Explanation of symbols]

 2 Ceramics Outer Part 3 Shaft 4 Joint 8 Reinforcing Member 9 Lightening Hole 10 Through Hole 11 End Supporting Member 12 Hollow Insert 13 Positioning Part

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Norihisa Tanaka 6276 Onoda, Onoda City, Yamaguchi Prefecture Chichibu Onoda Co., Ltd. Onoda Works, Ceramics Division

Claims (25)

[Claims] 1. A large-sized ceramic roller provided with a ceramic outer peripheral portion and mounted on a processing apparatus or the like; the ceramic outer peripheral portion being formed into a hollow cylindrical shape and provided with a reinforcing means. Large roller made of ceramics. 2. The large-sized ceramic roller according to claim 1, wherein the reinforcing means is a reinforced thick portion of the ceramic outer peripheral portion. 3. The large-sized ceramic roller according to claim 1, wherein the reinforcing means is a concentric disk-shaped body provided in the hollow portion of the outer peripheral portion. 4. The large roller made of ceramics according to claim 1, wherein the reinforcing means is a hollow insert inserted and joined to the inside of the outer peripheral portion made of ceramics. 5. The large-sized ceramics roller according to claim 4, wherein the hollow insert is provided with a disk-shaped body in its hollow portion. 6. The large-sized ceramic roller according to claim 3, wherein the disk-shaped body has a plurality of weight-reducing holes. 7. The large-sized ceramic roller according to claim 3, 5 or 6, wherein the disk-shaped body has a through hole that is joined to the shaft. 8. The large-sized ceramic roller according to claim 3, wherein the disk-shaped body is integrally formed with a ceramic outer peripheral portion. 9. A large-sized ceramic roller provided with a ceramic outer peripheral portion and mounted on a processing device or the like through a supporting member; the ceramic outer peripheral portion being formed into a hollow cylindrical shape, wherein the supporting member is A shaft which penetrates the outer peripheral portion of the ceramic and is joined to the outer peripheral portion, wherein the shaft is formed of a material having an expansion coefficient substantially equal to that of the outer peripheral portion of the ceramic. Large roller. 10. A ceramic outer peripheral portion, and
In a large-sized ceramic roller mounted on a processing device or the like through a supporting member; the ceramic outer peripheral portion is formed into a hollow cylindrical shape, and the supporting member is joined to both ends of the ceramic outer peripheral portion. A large ceramic roller characterized by being a member. 11. The large-sized ceramic roller according to claim 10, wherein the end supporting member is composed of a pair of disk-shaped members having the same diameter. 12. The large-sized ceramic roller according to claim 10, wherein the end support member has a stepped positioning portion that engages with the end of the ceramic outer peripheral portion. 13. The end supporting member is composed of a pair of disk-shaped members having different diameters.
Large ceramic roller described. 14. One end support member is joined to one end face of a ceramic outer peripheral portion, and the other end support member having a smaller diameter is inserted inside the other end portion of the ceramic outer peripheral portion. It is joined, It is characterized by the above-mentioned.
Large-sized ceramic roller described in 3. 15. The end support member includes a weight-reducing hole, as set forth in claim 10, 11, 12, and 13,
Alternatively, the large-sized ceramic roller described in 14 above. 16. The end supporting member is formed of a material having an expansion coefficient substantially equal to that of the ceramic outer peripheral portion, 10, 11, 12, 13, 14, or 1.
The large-sized ceramic roller described in 5. 17. A ceramic outer peripheral portion, and
In a large-sized ceramic roller mounted on a processing device or the like via a supporting member; the ceramic outer peripheral portion is formed into a hollow cylindrical shape, and is provided with a reinforcing means, and the supporting member is made of the ceramic material. A large-sized ceramic roller, which is a shaft that penetrates an outer peripheral portion and is joined to the outer peripheral portion, wherein the shaft is formed of a material having an expansion coefficient substantially equal to that of the outer peripheral portion made of ceramics. 18. A ceramic outer peripheral portion, and
In a large-sized ceramic roller mounted on a processing device or the like via a supporting member; the ceramic outer peripheral portion is formed into a hollow cylindrical shape, and is provided with a reinforcing means, and the supporting member is a ceramic outer periphery. A large roller made of ceramics, which is an end supporting member joined to both ends of the section. 19. The large-sized ceramic roller according to claim 17, wherein the reinforcing means is a reinforced thick portion of the ceramic outer peripheral portion. 20. The large-sized ceramic roller according to claim 17, wherein the reinforcing means is a concentric disk-shaped body provided in the hollow portion of the outer peripheral portion. 21. The large roller made of ceramics according to claim 17, wherein the reinforcing means is a hollow insert which is inserted and joined to the inside of the outer peripheral portion made of ceramics. 22. The large-sized ceramic roller according to claim 21, wherein the hollow insert is provided with a disk-shaped body in its hollow portion. 23. The ceramic large-sized roller according to claim 21, wherein the hollow insert is made of a material having an expansion coefficient substantially equal to that of the ceramic outer peripheral portion. 24. The large-sized ceramic roller according to claim 9, 17 or 23, wherein the material having an expansion coefficient substantially equal to that of the ceramic outer peripheral portion is titanium. 25. The large ceramic roller according to claim 9, 17 or 23, wherein the material having an expansion coefficient substantially equal to that of the ceramic outer peripheral portion is a titanium alloy.