BALL BEARING

Abstract

A ball bearing includes rivets each including a columnar rivet shaft; a pre-formed head formed beforehand at one end of the rivet shaft; and a crimped head formed by crimping the other end of the rivet shaft. The crimped head of each rivet is formed to satisfy the following formula: 1.25V.sub.o<V<2.43V.sub.o, where V is the volume of the crimped head, and V.sub.o is the volume of the portion of the rivet shaft in the interiors of a first rivet hole and a second rivet hole.

Claims

1. A ball bearing comprising: an inner ring; an outer ring arranged radially outward of, and coaxially with, the inner ring a plurality of balls disposed between the inner ring and the outer ring; and a wave-shaped iron plate cage retaining the balls, wherein the wave-shaped iron plate cage includes: a first annular member formed of a steel plate; a second annular member formed of a steel plate, and axially opposed to the first annular member; and a plurality of rivets coupling the first annular member and the second annular member together, wherein the first annular member includes: first pocket wall portions for receiving the respective balls; and first flat plate portions that have respective first rivet holes axially extending through the first annular member, and that circumferentially alternate with the first pocket wall portions, wherein the second annular member includes: second pocket wall portions for receiving the respective balls; and second flat plate portions that have respective second rivet holes axially extending through the second annular member, and that circumferentially alternate with the second pocket wall portions, and wherein each of the rivets includes: a columnar rivet shaft inserted through one of the first rivet holes and a corresponding one of the second rivet holes; a pre-formed head formed at one end of the rivet shaft; and axially engaging with one of the first flat plate portions; and a crimped head formed at the other end of the rivet shaft, and axially engaging with one of the second plate portions, wherein the crimped head of each of the rivets is formed to satisfy the following formula: 1.25V.sub.o<V<2.43V.sub.o, where V is a volume of the crimped head, and V.sub.o is a volume of a portion of the rivet shaft in interiors of the one of the first rivet holes and the corresponding one of the second rivet holes.

1. The ball bearing according to claim 1, wherein the crimped head of each of the rivets is formed to satisfy the following formula: 1.25Tr.sup.2<V<2.43Tr.sup.2, where T is an axial thickness of a corresponding one of the first flat plate portions and a corresponding one of the second flat plate portion that are superposed on each other, and r is a radius of the rivet shaft.

3. The ball bearing according to claim 1, wherein nitrided layers are formed on a surface of the first annular member and a surface of the second annular member, respectively, wherein the nitrided layer of the second annular member is formed on an entire inner periphery of each of the second rivet holes, and wherein an inner periphery of each of the first rivet holes has a non-nitrided surface that is not formed with the nitrided layer of the first annular member.

4. The ball bearing according to claim 1, wherein the first annular member and the second annular member are formed of one of a carbon steel for machine structure, a carbon steel for cold heading and a stainless steel.

5. The ball bearing according to claim 1, wherein the rivets are formed of one of a carbon steel for machine structure, a carbon steel for cold heading and a stainless steel.

6. The ball bearing according to claim 1, wherein the inner periphery of each of the first rivet holes is constituted by: a cylindrical shear surface having a constant inner diameter that does not axially change; and a tapered surface radially expanding from the shear surface toward a corresponding one of abutment surfaces of the first flat plate portions against the respective second flat plate portions, the tapered surface comprising a smooth surface formed by cutting.

7. The ball bearing according to claim 2, wherein nitrided layers are formed on a surface of the first annular member and a surface of the second annular member, respectively, wherein the nitrided layer of the second annular member is formed on an entire inner periphery of each of the second rivet holes, and wherein an inner periphery of each of the first rivet holes has a non-nitrided surface that is not formed with the nitrided layer of the first annular member.

8. The ball bearing according to claim 2, wherein the inner periphery of each of the first rivet holes is constituted by: a cylindrical shear surface having a constant inner diameter that does not axially change; and a tapered surface radially expanding from the shear surface toward a corresponding one of abutment surfaces of the first flat plate portions against the respective second flat plate portions, the tapered surface comprising a smooth surface formed by cutting.

9. The ball bearing according to claim 3, wherein the inner periphery of each of the first rivet holes is constituted by: a cylindrical shear surface having a constant inner diameter that does not axially change; and a tapered surface radially expanding from the shear surface toward a corresponding one of abutment surfaces of the first flat plate portions against the respective second flat plate portions, the tapered surface comprising a smooth surface formed by cutting.

10. The ball bearing according to claim 4, wherein the inner periphery of each of the first rivet holes is constituted by: a cylindrical shear surface having a constant inner diameter that does not axially change; and a tapered surface radially expanding from the shear surface toward a corresponding one of abutment surfaces of the first flat plate portions against the respective second flat plate portions, the tapered surface comprising a smooth surface formed by cutting.

11. The ball bearing according to claim 5, wherein the inner periphery of each of the first rivet holes is constituted by: a cylindrical shear surface having a constant inner diameter that does not axially change; and a tapered surface radially expanding from the shear surface toward a corresponding one of abutment surfaces of the first flat plate portions against the respective second flat plate portions, the tapered surface comprising a smooth surface formed by cutting.

12. The ball bearing according to claim 7, wherein the inner periphery of each of the first rivet holes is constituted by: a cylindrical shear surface having a constant inner diameter that does not axially change; and a tapered surface radially expanding from the shear surface toward a corresponding one of abutment surfaces of the first flat plate portions against the respective second flat plate portions, the tapered surface comprising a smooth surface formed by cutting.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] FIG. 1 is a sectional view of a ball bearing embodying the present invention.

[0028] FIG. 2 is a view illustrating a production step of a wave-shaped iron plate cage in FIG. 1; and a state in which a rivet is press-fitted in a first rivet hole formed in each first flat plate portion of a first annular member, and a second annular member is axially opposed to the first annular member.

[0029] FIG. 3 is a view illustrating a state in which the first annular member of FIG. 2 is superposed on the second annular member.

[0030] FIG. 4 is a view illustrating a state in which the first and second annular members are coupled together by crimping the portions of rivet shafts protruding beyond second rivet holes in FIG. 3.

[0031] FIG. 5A is an enlarged view of each rivet in FIG. 2.

[0032] FIG. 5B is a view illustrating a different example of the river in FIG. 5A.

[0033] FIG. 5C is a view illustrating a still different example of the river in FIG. 5A.

[0034] FIG. 6 is a view illustrating a step of crimping the portion of the rivet shaft of each rivet protruding beyond the second rivet hole in FIG. 3.

[0035] FIG. 7 is a view illustrating, as a comparative example, a rivet whose rivet shaft has a length longer than that of the rivet shaft in FIG. 6.

[0036] FIG. 8 is a view illustrating, as a comparative example, a rivet whose rivet shaft has a length shorter than that of the rivet shaft in FIG. 6.

[0037] FIG. 9 is an enlarged sectional view illustrating the first and second rivet holes and the vicinities thereof; and a state in which a soft nitriding treatment has been conducted to the first and second annular members in FIG. 2.

[0038] FIG. 10 is an enlarged sectional view illustrating the first and second rivet holes and the vicinities thereof; and a state in which the first and second annular members in FIG. 9 have been coupled together.

[0039] FIG. 11 is an enlarged sectional view illustrating each first rivet hole and the vicinity thereof; and a step of cutting and removing a fracture surface of the first rivet hole on its inner periphery.

[0040] FIG. 12 is a perspective view of the wave-shaped iron plate cage in FIG. 1.

BEST MODE FOR CARRYING OUT THE INVENTION

[0041] FIG. 1 illustrates a ball bearing according to an embodiment of the present invention. This ball bearing includes an inner ring 1; an outer ring 2 arranged radially outward of, and coaxially with, the inner ring 1; a plurality of balls 3 disposed between the inner ring 1 and the outer ring 2 so as to be circumferentially spaced apart from each other; and a wave-shaped iron plate cage 4 (hereinafter simply referred to as the cage 4) that keeps the circumferential distances between the balls 3.

[0042] The outer ring 2 has, on its inner periphery, an outer ring raceway groove 5 with which the balls 3 come into rolling contact. The outer ring raceway groove 5 extends circumferentially at the axial central portion of the inner periphery of the outer ring 2. The inner ring 1 also has, on its outer periphery, an inner ring raceway groove 6 with which the balls 3 come into rolling contact. The inner ring raceway groove 6 extends circumferentially at the axial central portion of the outer periphery of the inner ring 1.

[0043] The balls 3 are radially sandwiched between the outer ring raceway groove 5 and the inner ring raceway groove 6. This ball bearing is a deep groove ball bearing. That is, the outer ring raceway groove 5 is a circular arc-shaped groove having a concave circular arc-shaped cross section symmetrical with respect to the axial center of the outer ring 2, and the inner ring raceway groove 6 is also a circular arc-shaped groove having a concave circular arc-shaped cross section symmetrical with respect to the axial center of the inner ring 1. The outer ring raceway groove 5 has an axial width dimension larger than half of the diameter of each ball 3, and the inner ring raceway groove 6 also has an axial width dimension larger than half of the diameter of each ball 3.

[0044] The cage 4 includes a first annular member 7a formed of a steel plate; a second annular member 7b formed of a steel plate, and axially opposed to the first annular member 7a; and a plurality of rivets 8 coupling the first annular member 7a and the second annular member 7b together.

[0045] As illustrated in FIGS. 2 and 12, the first annular member 7a includes circular arc-shaped first pocket wall portions 9a that receive the balls 3; and flat plate-shaped first flat plate portions 10a that are orthogonal to the axial direction (vertical direction in the relevant drawings), and that circumferentially alternate with the first pocket wall portions 9a. Similarly, the second annular member 7b also includes circular arc-shaped second pocket wall portions 9b that receive the balls 3; and flat plate-shaped second flat plate portions 10b that are orthogonal to the axial direction, and that circumferentially alternate with the second pocket wall portions 9b. The first annular member 7a has the same shape and dimensions as the second annular member 7b.

[0046] As illustrated in FIG. 2, a first rivet hole 11a is formed in each first flat plate portion 10a of the first annular member 7a so as to axially extend through the first annular member 7a; a second rivet hole 11b is formed in each second flat plate portion 10b of the second annular member 7b so as to axially extend through the second annular member 7b; and a common rivet 8 is inserted in the first and second rivet holes 11a and 11b. The second flat plate portion 10b has an axial thickness tb equal to the axial thickness ta of the first flat plate portion 10a. The axial thickness tb equal to the axial thickness ta does not necessarily require that the axial thicknesses ta and tb should be strictly equal to each other in the mathematical sense, and means that the axial thicknesses ta and tb may be substantially equal to each other to such an extent that manufacturing errors are allowed.

[0047] The first annular member 7a is formed by pressing a plate material formed of one of a carbon steel for machine structure (such as SC material or S45C), a carbon steel for cold heading and a stainless steel. The first rivet holes 11a are formed by punching the first flat plate portions 10a using a punch. Similarly, the second annular member 7b is also formed by pressing a plate material formed of one of a carbon steel for machine structure, a carbon steel for cold heading and a stainless steel. The second rivet holes 11b are formed by punching the second flat plate portions 10b using a punch. The rivets 8 are formed of a wire rod of one of a carbon steel for machine structure, a carbon steel for cold heading and a stainless steel.

[0048] A nitrided layer is formed on the surface of the first annular member 7a by conducting a soft nitriding treatment, and a nitrided layer is also formed on the surface of the second annular member 7b by conducting a soft nitriding treatment. The nitrided layer is a surface-hardened layer having a hardness of 400 HV or more, and is an extremely thin chemical compound layer (compound layer comprising iron and nitrogen) having a thickness of 20 m or less. As illustrated in FIGS. 9 and 10, a nitrided layer is formed on the entire inner periphery of each second rivet hole 11b, whereas the inner periphery of each first rivet hole 11a has a non-nitrided surface formed with no nitrided layer.

[0049] As illustrated in FIGS. 6 and 10, each rivet 8 includes a columnar rivet shaft 12; a pre-formed head 13 formed beforehand at one end (upper end in the relevant drawings) of the rivet shaft 12; and a crimped head 14 formed by crimping the other end (lower end in the relevant drawings) of the rivet shaft 12. As illustrated in FIG. 6, the rivet shaft 12 is inserted through the first and second rivet holes 11a and 11b with the first and second flat plate portions 10a and 10b superposed on each other. The pre-formed head 13 and the crimped head 14 are disposed such that the first and second flat plate portions 10a and 10b are axially sandwiched therebetween. The pre-formed head 13 is axially engaged with the first flat plate portion 10a, and the crimped head 14 is axially engaged with the second flat plate portion 10b. The crimped head 14 has a hemispherical shape having a diameter larger than the diameter of the rivet shaft 12.

[0050] The cage 4 can be manufactured as follows:

[0051] First, as illustrated in FIG. 2, a first annular member 7a including the first pocket wall portions 9a and the first flat plate portions 10a is formed by pressing a steel plate. Next, each first rivet hole 11a is formed in the first flat plate portion 10a of the first annular member 7a by punching with a punch. At this time, the first rivet holed 11a is formed by punching, with a punch, the first flat plate portion 10a from the side opposite from an abutment surface 15a of the first flat plate portion 10a (that abuts) against the second flat plate portion 10b toward the abutment surface 15a of the first flat plate portion 10a (from the upper side toward the lower side in FIG. 2). Due to this, as illustrated on the left side of FIG. 11, the first rivet hole 11a has an inner periphery formed with a cylindrical shear surface 16 having a constant inner diameter that does not change in the axial direction; and a tapered fracture surface 17 radially expanding from the shear surface 16 toward the abutment surface 15a. The cylindrical shear surface 16 is first formed and then the tapered fracture surface 17 is formed from the side opposite from the abutment surface 15a toward the abutment surface 15a (from the upper side toward the lower side in FIG. 11). The shear surface 16 is a smooth surface having an axially extending striated pattern. On the other hand, the fracture surface 17 is an irregular uneven surface created by tearing off the material of the first flat plate portion 10a. The fracture surface 17 has a surface roughness larger than that of the shear surface 16. Thereafter, as illustrated on the right side of FIG. 11, the inner periphery of the first rivet hole 11a at its end portion closer to the abutment surface 15a (end portion on the lower side in FIG. 11) is cut with a chamfering drill, thereby removing the fracture surface 17 of the first rivet hole 11a on its inner periphery. Due to this, a tapered surface 18 radially expanding toward the abutment surface 15a is formed on the inner periphery of the first rivet hole 11a. The tapered surface 18 is a smooth surface formed by cutting. The second annular member 7b is also formed in the same manner as described above.

[0052] Next, as illustrated in FIG. 2, the rivets 8 are press-fitted into the respective first rivet holes 11a in the first flat plate portions 10a of the first annular member 7a. At this time, each rivet 8 press-fitted in the first rivet hole 11a is retained at the first annular member 7a by the interference between its rivet shaft 12 and the first rivet hole 11a. Also, the rivet shaft 12 of each rivet 8 partially protrudes beyond the abutment surface 15a of the first flat plate portion 10a against the second flat plate portion 10b.

[0053] Thereafter, a soft nitriding treatment is conducted to the rivets 8 and the first annular member 7a that are now integrally combined together by press fitting. The soft nitriding treatment is a treatment for forming a nitrided layer (surface-hardened layer) on the surface of a steel, and for example, by heating a steel at a temperature lower than the transformation point (within the temperature range of about 400 C. to 590 C.) in a mixed gas atmosphere of ammonia gas and endothermic denaturing gas, nitrogen infiltrates into the surface of the steel, thereby forming a nitrided layer. By conducting a soft nitriding treatment to the cage 4, it is possible to improve the durability of the cage 4 without substantially changing the dimensions of the cage 4. By conducting a soft nitriding treatment, a nitrided layer is formed on the surface of the first annular member 7a, but as illustrated in FIG. 9, the inner periphery of each first rivet hole 11a (fitting surface thereof to which the rivet shaft 12 is fitted) is masked by the rivet shaft 12, and thus has a non-nitrided surface formed with no nitrided layer. Similarly, the portion of the outer periphery of each river shaft 12 fitted to the inner periphery of the first rivet hole 11a also has a non-nitrided surface formed with no nitrided layer.

[0054] Also, a soft nitriding treatment is conducted to the second annular member 7b which has not been coupled to the first annular member 7a yet as illustrated in FIG. 9. At this time, since each rivet 8 has not been inserted in the second rivet hole 11b of the second annular member 7b and the entire inner periphery of the second rivet hole 11b is exposed, a nitrided layer is formed on the entire inner periphery of the second rivet hole 11b.

[0055] Thereafter, a plurality of balls 3 are placed between the inner ring 1 and the outer ring 2 illustrated in FIG. 1 so as to be circumferentially equidistantly spaced apart from each other, and the first annular member 7a and the second annular member 7b are superposed on each other such that each ball 3 is sandwiched from both axial sides by the first pocket wall portion 9a of the first annular member 7a and the second pocket wall portion 9b of the second annular member 7b illustrated in FIG. 3. At this time, the rivet shafts 12 partially protruding beyond the first annular member 7a are inserted through the respective second rivet holes 11b of the second annular member 7b so as to partially protrude beyond the second rivet holes 11b toward the side of the second annular member 7b opposite from the first annular member 7a (toward the lower side in FIG. 3).

[0056] Thereafter, as illustrated in FIG. 4, the portions of the rivet shafts 12 protruding beyond the respective second rivet holes 11b of the second annular member 7b are axially crushed and crimped (plastically deformed) by a crimping die (not shown), so that crimped heads 14 are formed and the first annular member 7a and the second annular member 7b are coupled together.

[0057] When forming crimped heads 14 by crimping the portions of the rivet shafts 12 protruding beyond the respective second rivet holes 11b as illustrated in FIG. 6, if the portions of the rivet shafts 12 that are crimped to be the crimped heads 14 are shortened as illustrated in FIG. 8, the rivet shafts 12 will be plastically deformed to radially expand, and the expansion of the rivet shafts 12 is likely to cause tensile stress on the inner peripheries of the first rivet holes 11a. Due to the tensile stress generated on the inner peripheries of the first rivet holes 11a, the strength of the cage 4 may decrease.

[0058] Especially since, when conducting a soft nitriding treatment with the above method, the inner periphery of each first rivet hole 11a has a non-nitrided surface formed with no nitrided layer (no surface-hardened layer) as illustrated in FIG. 9, if tensile stress is generated on the inner periphery of the first rivet hole 11a, the strength of the cage 4 is likely to decrease.

[0059] On the other hand, when forming crimped heads 14 by crimping the portions of the rivet shafts 12 protruding beyond the respective second rivet holes 11b, if the portions of the rivet shafts 12 that are crimped to be the crimped heads 14 are lengthened as illustrated in FIG. 7, the rivets 8 could become axially unstable, thus preventing the first flat plate portions 10a from sufficiently coming into close contact with the second flat plate portions 10b. In order to prevent each rivet 8 from becoming unstable, it is considered to increase the crimping load on the rivet shaft 12, but if the crimping load on the rivet shaft 12 is increased, the rivet shaft 12 will expand, and due to the expansion of the rivet shaft 12, tensile stress is likely to occur on the inner periphery of the first rivet hole 11a.

[0060] In the above embodiment, in order to prevent tensile stress from occurring on the inner periphery of each first rivet hole 11a due to the expansion of the rivet shaft 12; and sufficiently bring the first flat plate portions 10a into close contact with the second flat plate portions 10b, the length L of the rivet shaft 12 shown in FIG. 5A is set to satisfy the following formula: 2.25T<L<3.43T, where T is the axial thickness (i.e., the total of the thicknesses) of the first and second flat plate portions 10a and 10b that are superposed on each other as illustrated in FIG. 3.

[0061] Since the length L of each rivet shaft 12 is set to satisfy the above formula, when forming a crimped head 14 by crimping the portion of the rivet shaft 12 protruding beyond the second rivet hole 11b as illustrated in FIG. 6, the volume V of the crimped head 14 satisfies the following formula: 1.25Tr.sup.2<V<2.43Tr.sup.2, where r is the radius of the rivet shaft 12 shown in FIGS. 6 to 8.

[0062] Also, the volume V of the crimped head 14 satisfies the following formula: 1.25V.sub.o<V<2.43V.sub.o, where V.sub.o is the volume of the portion of the rivet shaft 12 in the interiors of the first and second rive holes 11a and 11b after crimping the rivet shaft 12.

[0063] When producing a bearing, it is possible to detect a defect in the rivets 8 or a defect in the attachment of the rivets 8 by measuring the volumes V of the crimped heads 14 by image processing; and judging whether or not the volumes V are within the range of the above formulas/inequalities.

[0064] With respect to the ball bearing of this embodiment, when forming crimped heads 14 by crimping the portions of the rivet shafts 12 protruding beyond the second rivet holes 11b as illustrated in FIG. 6, since the portions of the rivet shafts 12 that are crimped to be the crimped heads 14 (portions of the rivet shafts 12 protruding beyond the second rivet holes 11b) are each longer than the length corresponding to 1.25T, the rivet shafts 12 are less likely to expand, and tensile stress due to the expansion of the rivet shafts 12 is less likely to occur on the inner peripheries of the first rivet holes 11a. Therefore, the strength of the cage 4 is less likely to decrease.

[0065] Also, with respect to this ball bearing, when forming crimped heads 14 by crimping the portions of the rivet shafts 12 protruding beyond the second rivet holes 11b as illustrated in FIG. 6, since the portions of the rivet shafts 12 that are crimped to be the crimped heads 14 (portions of the rivet shafts 12 protruding beyond the second rivet holes 11b) are each shorter than the length corresponding to 2.43T, the rivets 8 do not become axially unstable. Therefore, it is possible to sufficiently bring the first flat plate portions 10a of the first annular member 7a into close contact with the second flat plate portions 10b of the second annular member 7b, and to obtain a stable quality.

[0066] Also, with respect to this ball bearing, since, as illustrated in FIG. 10, the inner periphery of each first rivet hole 11a has a non-nitrided surface formed with no nitrided layer (no surface-hardened layer), if tensile stress occurs on the inner periphery of the first rivel hole 11a, the strength of the cage 4 is likely to decrease. However, as illustrated in FIG. 6, when forming crimped heads 14 by crimping the portions of the rivet shafts 12 protruding beyond the second rivet holes 11b, since the portions of the rivet shafts 12 that are to be crimped to be the crimped heads 14 (portions of the rivet shafts 12 protruding beyond the second rivet holes 11b) are each longer than the length corresponding to 1.25T, it is possible to effectively prevent tensile stress due to the expansion of the rivet shafts 12 from occurring on the inner peripheries of the first rivet holes 11a.

[0067] The following table shows analysis results of the relationship between the length L of the portion of each rivet shaft 12 that will be crimped later (see FIG. 5A), the radius r of the rivet shaft 12 (see FIGS. 6 to 8), the axial thickness T of each first flat plate portion 10a of the first annular member 7a and the corresponding second flat plate portion 10b of the second annular member 7b that are superposed on each other (see FIG. 3), a case in which a reduction in the strength of the cage 4 due to tensile stress on the inner peripheries of the first rivet holes 11a is seen or not seen, and the adhesiveness between the first and second plate portions 10a and 10b.

TABLE-US-00001 TABLE 1 Reduction in Adhesiveness the strength of the between the first cage due to and second flat L/T tensile stress plate portions 2.25 Seen Good 2.34 Not seen Good 2.70 Not seen Good 3.05 Not seen Good 3.43 Not seen Bad

[0068] The analysis results in the above table show that by setting the length L (see FIG. 5A) of the portion of the rivet shaft 12 that will be crimped later such that the ratio L/T of the length L to the axial thickness T (see FIG. 3) of the first and second flat plate portions 10a and 10b that are superposed on each other is larger than 2.25, it is possible to prevent a reduction in the strength of the cage 4, whereas by setting the length L such that the ratio L/T is smaller than 3.43, it is possible to prevent the adhesiveness between the first and second annular members 7a and 7b from deteriorating.

[0069] Also, with respect to this ball bearing, since the tapered surfaces 18 on the inner peripheries of the first rivet holes 11a are smooth surfaces formed by cutting, it is possible to particularly effectively prevent a reduction in the strength of the cage 4. That is, if, as illustrated on the left side of FIG. 11, in each first rivet hole 11a, which is formed by punching the first flat plate portion 10a, the fracture surface 17, which is an irregular uneven surface created by tearing off the material of the first flat plate portion 10a, is used as it is without removing the fracture surface 17 by additional machining, when tensile stress occurs on the inner periphery of the first rivet hole 11a due to the expansion of the rivet shaft 12 during formation of the crimped head 14, cracks or the like are likely to form starting from the fracture surface 17 (irregular uneven surface), so that the strength of the cage 4 could decrease. In contrast thereto, if the fracture surface 17 shown in FIG. 11 is removed by cutting as in the above embodiment, even when tensile stress occurs on the inner periphery of the first rivet hole 11a due to the expansion of the rivet shaft 12, cracks or the like are less likely to form on the inner periphery of the first rivet hole 11a, thus making it possible to prevent a reduction in the strength of the cage 4.

[0070] While, in the above embodiment, rivets 8 including a hemispherical pre-formed head 13 as illustrated in FIG. 5A are exemplified and described, rivets 8 including a spherical segment-shaped pre-formed head 13 as illustrated in FIG. 5B, or rivets 8 including a cylindrical pre-formed head 13 as illustrated in FIG. 5C may be used.

[0071] While, in the above embodiment, a hollow annular member having an inner ring raceway groove 6 in the outer periphery is exemplified and described as the inner ring 1, the inner ring 1 does not necessarily need to be a hollow annular member. For example, a solid member (shaft body) having an inner ring raceway groove 6 which is directly formed in the outer periphery and with which the balls 3 come into rolling contact may be used as the inner ring 1. In short, an inner member having, in the outer periphery, an annular inner ring raceway groove with which the balls come into rolling contact can be used as the inner ring.

[0072] While, in the above embodiment, a hollow annular member having an outer ring raceway groove 5 in the inner periphery is exemplified and described as the outer ring 2, the outer ring 2 does not necessarily need to be a hollow annular member. For example, a bearing housing having an outer ring raceway groove 5 which is directly formed in the inner periphery and with which the balls 3 come into rolling contact may be used as the outer ring 2. In short, an outer member having, in the inner periphery, an annular outer ring raceway groove with which the balls come into rolling contact can be used as the outer ring.

[0073] The above-described embodiment is a mere example in every respect, and the present invention is not limited thereto. The scope of the present invention is indicated not by the above description but by the claims, and should be understood to include all modifications within the meaning and scope equivalent to the scope of the claims.

DESCRIPTION OF REFERENCE NUMERALS

[0074] 1: Inner ring [0075] 2: Outer ring [0076] 3: Ball [0077] 4: Wave-shaped iron plate cage [0078] 7a: First annular member [0079] 7b: Second annular member [0080] 8: Rivet [0081] 9a: First pocket wall portion [0082] 9b: Second pocket wall portion [0083] 10a: First flat plate portion [0084] 10b: Second flat plate portion [0085] 11a: First rivet hole [0086] 11b: Second rivet hole [0087] 12: Rivet shaft [0088] 13: Pre-formed head [0089] 14: Crimped head [0090] 15a: Abutment surface [0091] 16: Shear surface [0092] 18: Tapered surface