JP2007298068A - Bearing structure and rocking rotation electric equipment using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bearing structure having a long life without the need for an oiling device and for frequent maintenance, and to provide rocking rotation electric equipment using the same. <P>SOLUTION: A plurality of predetermined-shape holding spaces 19 are formed in a cage 18 which holds balls 15. Depending on the arrangement of the balls 15 in the holding spaces 19, the balls 15 are arranged in proper rolling raceway positions or moved from the proper rolling raceway positions, thereby restricting the rotating direction of a rolling bearing 11A. Furthermore, the two rolling bearings are incorporated in double so that the two rolling bearings has opposite rotation allowable directions, to form the rockable bearing structure and the rocking rotation electric equipment using the same. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a bearing structure that supports a shaft that continuously swings at a rotation angle of ± 180 degrees or less, and a swinging rotary electric machine that uses the bearing structure.

  In general, the bearing structure of a rotating electrical machine is mostly a slide bearing or a rolling bearing. For lubrication in the bearing structure, forced lubrication is used when the peripheral speed and operating frequency are high, and grease is used when the bearing structure is low. Further, as shown in FIG. 1, a similar bearing structure is also used in a swing rotating electrical machine (hereinafter referred to as a swing motor) that continuously swings with a shaft rotation angle of ± 180 degrees or less. Yes.

JP 2000-18243 A Japanese Patent Laid-Open No. 11-153133 Japanese Patent Laid-Open No. 10-242199 JP-A-5-231424 JP-A-11-132228 JP-A-58-13222

In a swing motor, there are many swing operations at the same position (angle), and the bearing structure receives a force partially.
For example, in the case of the slide bearing shown in FIG. 2 (a), the swing angle of the shaft is limited to a predetermined range, so that a portion of the bearing portion that supports the shaft, in particular, on the lower side of the inner surface of the bearing portion, The load on the shaft will work.
Further, even in the case of the rolling bearing shown in FIG. 2 (b), since the swing angle of the shaft is limited to a predetermined range, a portion in a predetermined range of the bearing portion (inner ring, ball, outer ring) for supporting the shaft, The load applied to the shaft acts on the inner ring, ball, and outer ring on the lower side of the bearing portion.

Therefore, in the case of a swing motor, both in the case of a sliding bearing and a rolling bearing, there is a problem that the life of the bearing portion is short and frequent maintenance is required due to the following factors.
(1) Since a force is always received at a specific position, fatigue fracture and wear partially progress, resulting in increased vibration and noise.
(2) In the case of grease lubrication, since the grease is not agitated, the oil film is cut in a short time, resulting in fretting and seizure.

  In addition, when performing forced oil supply, it is possible to extend the lifetime of a bearing part by supplying oil intensively to the part which force acts. However, there has been a problem that the structure of the oscillating motor becomes complicated, such as the installation of a fueling device and the collection of waste oil, which increases the cost and the risk of oil leakage.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a bearing structure having a long life and an oscillating rotating electric machine using the bearing structure without requiring a lubrication device or frequent maintenance. .

A bearing structure according to a first invention for solving the above-described problems is
A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a first outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. A plurality of inserted first balls, a first holding member inserted between an outer peripheral surface of the first inner ring and an inner peripheral surface of the first outer ring, and holding the first ball in a rollable manner; A first rolling bearing comprising:
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls inserted between the second inner ring outer peripheral track and the second outer ring inner peripheral track, and inserted between the outer peripheral surface of the second inner ring and the inner peripheral surface of the second outer ring. A bearing structure comprising a second rolling bearing provided with a second holding member that holds the second ball in a rollable manner;
The first holding member rolls the first ball so as to allow rotation of the first rolling bearing only in one circumferential direction,
The second holding member rolls the second ball so as to allow rotation of the second rolling bearing only in a circumferential direction opposite to the one circumferential direction.

A bearing structure according to a second invention for solving the above problem is as follows:
A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a first outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. A plurality of first balls that are inserted between a plurality of inserted first balls, and an outer peripheral surface of the first inner ring and an inner peripheral surface of the first outer ring, and hold the first ball in a rollable manner. A first rolling bearing comprising a first holding member having a space;
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls inserted between the second inner ring outer peripheral track and the second outer ring inner peripheral track, and inserted between the outer peripheral surface of the second inner ring and the inner peripheral surface of the second outer ring. And a second rolling bearing provided with a second holding member having a plurality of second holding spaces for holding the second balls in a rollable manner,
When the first ball rolls in one circumferential direction of the bearing, the first holding space moves the first ball to an appropriate first position of the first inner ring outer circumferential track and the first outer ring inner circumferential track. When the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first allowing portion that allows rotation of the first rolling bearing and the first rolling bearing from the first position is provided. A first stop portion that separates the balls and stops the rotation of the first rolling bearing;
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is disposed at an appropriate second position of the second inner ring outer circumferential track and the second outer ring inner circumferential track. And when the second ball rolls in the one circumferential direction, the second ball is separated from the second position, and the second ball is allowed to rotate. And a second stop portion for stopping the rotation of the second rolling bearing.

A bearing structure according to a third invention for solving the above-described problem is
In the bearing structure according to the second invention,
The first permissible portion is formed adjacent to the first vertical surface perpendicular to the circumferential direction of the bearing and the first vertical surface, and is parallel to the circumferential direction of the bearing. A first parallel surface disposed at a radial distance of the first ball from the center of one ball, and when the first ball rolls in the one circumferential direction, the first ball is the first ball The first ball is arranged at the first position by contacting a vertical plane and the first parallel plane,
The first restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the first ball in the axial direction of the bearing, and faces the first vertical surface in the opposite circumferential direction. The first small vertical surface disposed on the side, the first parallel surface and the first small vertical surface are formed adjacent to each other and have an acute inclination angle with respect to the circumferential direction of the bearing. When the first ball rolls in the opposite circumferential direction, the first ball comes into contact with the first small vertical surface and the first inclined surface, so that the first ball moves from the first position. To separate the first ball,
The second permissible part is formed adjacent to the second vertical surface perpendicular to the circumferential direction of the bearing and the second vertical surface, and is parallel to the circumferential direction of the bearing. A second parallel surface arranged at a radial distance of the second ball from the center of the two balls, and when the second ball rolls in the opposite circumferential direction, the second ball is the second ball The second ball is arranged at the second position by contacting a vertical plane and the second parallel plane,
The second restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the second vertical surface to the one circumferential direction. A second small vertical surface disposed on the side, adjacent to the second parallel surface and the second small vertical surface, and having an acute inclination angle with respect to the circumferential direction of the bearing. When the second ball rolls in the one circumferential direction, the second ball comes into contact with the second small vertical surface and the second inclined surface, so that the second ball moves from the second position. The second ball is separated.

A bearing structure according to a fourth invention for solving the above-described problem is
In the bearing structure according to the third invention,
In the first holding space, the first parallel surface, the first inclined surface, and the first small vertical surface in the adjacent first holding spaces are the outer peripheral surface of the first inner ring and the inner periphery of the first outer ring. It is formed so as to be opposite to each other with respect to the center line with the surface,
In the second holding space, the second parallel surface, the second inclined surface, and the second small vertical surface in the adjacent second holding spaces are the outer peripheral surface of the second inner ring and the inner periphery of the second outer ring. It is characterized by being formed so as to be opposite to each other with respect to the center line with the surface.

A bearing structure according to a fifth invention for solving the above-described problem is
A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a second outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. A plurality of first balls that are inserted between a plurality of inserted first balls, and an outer peripheral surface of the first inner ring and an inner peripheral surface of the first outer ring, and hold the first ball in a rollable manner. A first rolling bearing comprising: a first holding member having a space; and a first sealing member that encloses grease between an outer peripheral surface of the first inner ring and an inner peripheral surface of the first outer ring;
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls inserted between the second inner ring outer peripheral track and the second outer ring inner peripheral track, and inserted between the outer peripheral surface of the second inner ring and the inner peripheral surface of the second outer ring. In addition, grease is enclosed between a second holding member having a plurality of second holding spaces for holding the second ball in a rollable manner, and an outer peripheral surface of the second inner ring and an inner peripheral surface of the second outer ring. A second rolling bearing provided with a second enclosing member that comprises:
The first holding member has a first locked protrusion that protrudes from the opposite surface of the first holding space and has a first locked surface that is parallel to the diameter direction of the bearing,
The first enclosing member protrudes from the surface of the first enclosing member on the side of the first locked protrusion, and has a first locking surface facing the first locked surface. Having a protrusion,
When the first ball rolls in one circumferential direction of the bearing, the first holding space moves the first ball to an appropriate first position of the first inner ring outer circumferential track and the first outer ring inner circumferential track. When the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first allowing portion that allows rotation of the first rolling bearing and the first rolling bearing from the first position is provided. The ball is separated, the first holding member is moved to the first enclosing member side by the first ball, the first locked protrusion is locked to the first locking protrusion, and the A first stop portion for stopping the rotation of the first rolling bearing,
The second holding member has a second locked protrusion protruding from the opposite surface of the second holding space and having a second locked surface parallel to the diameter direction of the bearing,
The second enclosing member protrudes from the surface of the second enclosing member on the side of the second locked protrusion, and has a second locking surface facing the second locked surface. Having a protrusion,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is disposed at an appropriate second position of the second inner ring outer circumferential track and the second outer ring inner circumferential track. And when the second ball rolls in the one circumferential direction, the second ball is separated from the second position, and the second ball is allowed to rotate. The second holding member is moved to the second enclosing member side by the second ball, the second locked protrusion is locked to the second locking protrusion, and the second rolling bearing is rotated. It consists of the 2nd stop part which stops.

A bearing structure according to a sixth invention for solving the above-described problems is as follows.
In the bearing structure according to the fifth aspect,
The first permissible portion is formed adjacent to the first vertical surface perpendicular to the circumferential direction of the bearing and the first vertical surface, and is parallel to the circumferential direction of the bearing. A first parallel surface disposed at a radial distance of the first ball from the center of one ball, and when the first ball rolls in the one circumferential direction, the first ball is the first ball The first ball is arranged at the first position by contacting a vertical plane and the first parallel plane,
The first restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the first vertical surface in the opposite circumferential direction. The first small vertical surface disposed on the side, the first parallel surface and the first small vertical surface are formed adjacent to each other and have an acute inclination angle with respect to the circumferential direction of the bearing. When the first ball rolls in the opposite circumferential direction, the first ball comes into contact with the first small vertical surface and the first inclined surface, so that the first ball moves from the first position. The first ball is separated, the first holding member is pressed by the first ball, and the first locked protrusion is moved together with the first holding member to the first enclosing member side,
The second permissible part is formed adjacent to the second vertical surface perpendicular to the circumferential direction of the bearing and the second vertical surface, and is parallel to the circumferential direction of the bearing. A second parallel surface arranged at a radial distance of the second ball from the center of the two balls, and when the second ball rolls in the opposite circumferential direction, the second ball is the second ball The second ball is arranged at the second position by contacting a vertical plane and the second parallel plane,
The second restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the second vertical surface to the one circumferential direction. A second small vertical surface disposed on the side, adjacent to the second parallel surface and the second small vertical surface, and having an acute inclination angle with respect to the circumferential direction of the bearing. When the second ball rolls in the one circumferential direction, the second ball comes into contact with the second small vertical surface and the second inclined surface, so that the second ball moves from the second position. The second ball is separated, the second holding member is pressed by the second ball, and the second locked protrusion is moved to the second enclosing member side together with the second holding member. It is characterized by.

A bearing structure according to a seventh invention for solving the above-described problem is
A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a second outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. It has a plurality of first balls inserted and a plurality of first partition members supported on the inner peripheral surface of the first outer ring, and the first balls can roll between the first partition members. A first rolling bearing comprising a first holding member that forms a plurality of first holding spaces to be held;
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls inserted between the second inner ring outer peripheral track and the second outer ring inner track, and a plurality of second partition members supported by the inner peripheral surface of the second outer ring, A bearing structure comprising a second rolling bearing provided with a second holding member that forms a plurality of second holding spaces that hold the second balls in a rollable manner between the second partition members,
When the first ball rolls in one circumferential direction of the bearing, the first holding space moves the first inner space to a first position in contact with both the first inner ring outer circumferential track and the first outer ring inner circumferential track. A first allowing portion for allowing the ball to be arranged and allowing the rotation of the first rolling bearing; and when the first ball rolls in a circumferential direction opposite to the one circumferential direction, A first stop portion that presses a ball toward the outer circumference track side of the first inner ring and stops the rotation of the first rolling bearing;
When the second ball rolls in the opposite circumferential direction, the second holding space moves the second ball to a second position in contact with both the second inner ring outer circumferential track and the second outer ring inner circumferential track. A second allowing portion for allowing the second rolling bearing to rotate, and an outer periphery of the second inner ring when the second ball rolls in the one circumferential direction. It comprises a second stop portion that presses against the raceway side and stops the rotation of the second rolling bearing.

A bearing structure according to an eighth invention for solving the above-described problems is
In the bearing structure according to the seventh invention,
The first permissible portion has a first vertical surface perpendicular to the circumferential direction of the bearing on a surface on the opposite circumferential direction side of the first partition member, and the first ball extends in the one circumferential direction. When rolling, by allowing the first ball to contact the first vertical surface, the first ball is allowed to be placed in the first position;
The first restraining portion is perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the first partition member, and has a width smaller than the diameter of the first ball in the diameter direction of the bearing. A first small vertical surface, and an inclined angle that protrudes from the first small vertical surface to the one circumferential direction side and to the inner peripheral surface side of the first outer ring and is acute with respect to the inner peripheral surface of the first outer ring And when the first ball rolls in the opposite circumferential direction, the first ball is brought into contact with the first small vertical surface and the first inclined surface, Pressing the first ball toward the outer circumference of the first inner ring,
The second permissible portion has a second vertical surface perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the second partition member, and the second ball is in the opposite circumferential direction. When rolling, by allowing the second ball to contact the second vertical surface, the second ball is allowed to be placed in the second position;
The second stop portion is perpendicular to the circumferential direction of the bearing on the opposite circumferential surface of the second partition member, and has a width smaller than the diameter of the second ball in the diameter direction of the bearing. A second small vertical surface, and an inclined angle that is projected from the second small vertical surface to the opposite circumferential direction side and the inner peripheral surface side of the second outer ring, and is acute with respect to the inner peripheral surface of the second outer ring And when the second ball rolls in the one circumferential direction, by bringing the second ball into contact with the second small vertical surface and the second inclined surface, The second ball is configured to press the second inner ring outer periphery raceway side.

A bearing structure according to a ninth invention for solving the above-described problems is
A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a second outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. It has a plurality of first balls inserted and a plurality of first partition members supported on the outer peripheral surface of the first inner ring, and holds the first balls between the first partition members so that they can roll. A first rolling bearing provided with a first holding member that forms a plurality of first holding spaces.
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls interposed between the second inner ring outer circumferential track and the second outer ring inner circumferential track, and a plurality of second partition members supported on the outer circumferential surface of the second inner ring, A bearing structure comprising a second rolling bearing provided with a second holding member that forms a plurality of second holding spaces that hold the second balls in a rollable manner between the second partition members,
When the first ball rolls in one circumferential direction of the bearing, the first holding space moves the first inner space to a first position in contact with both the first inner ring outer circumferential track and the first outer ring inner circumferential track. A first allowing portion for allowing the ball to be arranged and allowing the rotation of the first rolling bearing; and when the first ball rolls in a circumferential direction opposite to the one circumferential direction, A first stopping portion that presses the ball toward the inner raceway side of the first outer ring and stops the rotation of the first rolling bearing;
When the second ball rolls in the opposite circumferential direction, the second holding space moves the second ball to a second position in contact with both the second inner ring outer circumferential track and the second outer ring inner circumferential track. A second allowing portion for allowing the second rolling bearing to rotate, and the second ball in the second outer ring when the second ball rolls in the one circumferential direction. It is characterized by comprising a second stop portion that presses against the circumferential track side and stops the rotation of the second rolling bearing.

A bearing structure according to a tenth invention for solving the above-described problems is
In the bearing structure according to the ninth aspect,
The first permissible portion has a first vertical surface perpendicular to the circumferential direction of the bearing on a surface on the opposite circumferential direction side of the first partition member, and the first ball extends in the one circumferential direction. When rolling, by allowing the first ball to contact the first vertical surface, the first ball is allowed to be placed in the first position;
The first restraining portion is perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the first partition member, and has a width smaller than the diameter of the first ball in the diameter direction of the bearing. A first small vertical surface; and a first inclined surface extending from the first small vertical surface toward the one circumferential direction side and the outer peripheral surface side of the first inner ring, and has an acute inclination angle with respect to the outer peripheral surface of the first inner ring. A first inclined surface, and when the first ball rolls in the opposite circumferential direction, the first ball is brought into contact with the first small vertical surface and the first inclined surface. One ball is pressed toward the inner circumference track of the first outer ring,
The second permissible portion has a second vertical surface perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the second partition member, and the second ball is in the opposite circumferential direction. When rolling, the second ball is brought into contact with the second vertical surface, and the second ball is allowed to be arranged at the second position;
The second stop portion is perpendicular to the circumferential direction of the bearing on the opposite circumferential surface of the second partition member and has a width smaller than the diameter of the second ball in the diameter direction of the bearing. A second small vertical surface, and projects from the second small vertical surface to the opposite circumferential direction side and the outer peripheral surface side of the second inner ring, and has an acute inclination angle with respect to the outer peripheral surface of the second inner ring. A second inclined surface, and when the second ball rolls in the opposite circumferential direction, the second ball is brought into contact with the second small vertical surface and the second inclined surface. Two balls are pressed against the inner circumferential track side of the second outer ring.

A bearing structure according to an eleventh invention for solving the above problem is as follows:
An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A first holding member that is inserted between an outer peripheral surface of the inner ring and an inner peripheral surface of the middle ring, and holds the first ball in a rollable manner; an outer peripheral surface of the intermediate ring; and an inner periphery of the outer ring A bearing structure comprising a rolling bearing provided with a second holding member inserted between the second holding member and capable of rolling the second ball,
The first holding member rolls the first ball so as to allow rotation of the inner ring only in one circumferential direction,
The second holding member rolls the second ball so as to allow rotation of the middle wheel only in a circumferential direction opposite to the one circumferential direction.

A bearing structure according to a twelfth invention for solving the above-described problems is
An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A first holding member that is inserted between an outer peripheral surface of the inner ring and an inner peripheral surface of the middle ring and has a plurality of first holding spaces that hold the first ball in a rollable manner; A rolling bearing comprising a second holding member inserted between an outer peripheral surface and an inner peripheral surface of the outer ring and having a plurality of second holding spaces for holding the second balls in a rollable manner;
When the first ball rolls in one circumferential direction of the bearing, the first holding space allows the first ball to be disposed at an appropriate first position of the inner ring outer circumferential track and the middle ring inner circumferential track. When the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first ball is separated from the first position. And a first stop portion for stopping the rotation of the first rolling bearing,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is arranged at an appropriate second position of the middle ring outer circumferential track and the outer ring inner circumferential track, A second permissible portion allowing rotation of the second rolling bearing; and when the second ball rolls in the one circumferential direction, the second ball is separated from the second position, and the second rolling It is characterized by comprising a second restraining portion that restrains the rotation of the bearing.

A bearing structure according to a thirteenth invention for solving the above-described problems is
In the bearing structure according to the twelfth invention,
The first permissible portion is formed adjacent to the first vertical surface perpendicular to the circumferential direction of the bearing and the first vertical surface, and is parallel to the circumferential direction of the bearing. A first parallel surface disposed at a radial distance of the first ball from the center of one ball, and when the first ball rolls in the one circumferential direction, the first ball is the first ball The first ball is arranged at the first position by contacting a vertical plane and the first parallel plane,
The first restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the first ball in the axial direction of the bearing, and faces the first vertical surface in the opposite circumferential direction. The first small vertical surface disposed on the side, the first parallel surface and the first small vertical surface are formed adjacent to each other and have an acute inclination angle with respect to the circumferential direction of the bearing. When the first ball rolls in the opposite circumferential direction, the first ball comes into contact with the first small vertical surface and the first inclined surface, so that the first ball moves from the first position. To separate the first ball,
The second permissible part is formed adjacent to the second vertical surface perpendicular to the circumferential direction of the bearing and the second vertical surface, and is parallel to the circumferential direction of the bearing. A second parallel surface arranged at a radial distance of the second ball from the center of the two balls, and when the second ball rolls in the opposite circumferential direction, the second ball is the second ball The second ball is arranged at the second position by contacting a vertical plane and the second parallel plane,
The second restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the second vertical surface to the one circumferential direction. A second small vertical surface disposed on the side, adjacent to the second parallel surface and the second small vertical surface, and having an acute inclination angle with respect to the circumferential direction of the bearing. When the second ball rolls in the one circumferential direction, the second ball comes into contact with the second small vertical surface and the second inclined surface, so that the second ball moves from the second position. The second ball is separated.

A bearing structure according to a fourteenth aspect of the present invention for solving the above problems is
In the bearing structure according to the thirteenth aspect,
In the first holding space, the first parallel surface, the first inclined surface, and the first small vertical surface in the adjacent first holding spaces are an outer peripheral surface of the inner ring and an inner peripheral surface of the middle wheel. It is formed to be opposite to each other with respect to the center line,
In the second holding space, the second parallel surface, the second inclined surface, and the second small vertical surface in the adjacent second holding spaces are formed between the outer peripheral surface of the middle wheel and the inner peripheral surface of the outer ring. The center line is formed so as to be opposite to each other.

A bearing structure according to a fifteenth aspect of the present invention for solving the above problem is
An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A first holding member that is inserted between an outer peripheral surface of the inner ring and an inner peripheral surface of the middle ring and has a plurality of first holding spaces that hold the first ball in a rollable manner; A second holding member inserted between an outer peripheral surface and an inner peripheral surface of the outer ring and having a plurality of second holding spaces for holding the second ball in a rollable manner; an outer peripheral surface of the inner ring; A first enclosing member that encloses grease between the inner peripheral surface of the ring and a second enclosing member that encloses grease between the outer peripheral surface of the middle wheel and the inner peripheral surface of the outer ring; A rolling bearing,
The first holding member has a first locked protrusion that protrudes from the opposite surface of the first holding space and has a first locked surface that is parallel to the diameter direction of the bearing,
The first enclosing member protrudes from the surface of the first enclosing member on the side of the first locked protrusion, and has a first locking surface facing the first locked surface. Having a protrusion,
When the first ball rolls in one circumferential direction of the bearing, the first holding space allows the first ball to be disposed at an appropriate first position of the inner ring outer circumferential track and the middle ring inner circumferential track. When the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first ball is separated from the first position. And the first ball is moved to the first enclosing member side by the first ball, and the first locking projection is locked to the first locking projection, so that the first rolling is performed. Comprising a first stop to stop the rotation of the bearing,
The second holding member has a second locked protrusion protruding from the opposite surface of the second holding space and having a second locked surface parallel to the diameter direction of the bearing,
The second enclosing member protrudes from the surface of the second enclosing member on the side of the second locked protrusion, and has a second locking surface facing the second locked surface. Having a protrusion,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is arranged at an appropriate second position of the middle ring outer circumferential track and the outer ring inner circumferential track, A second permissible portion allowing rotation of the second rolling bearing; and when the second ball rolls in the one circumferential direction, the second ball is separated from the second position, and the second ball The second holding member is moved to the second enclosing member side by the step, the second locked protrusion is locked to the second locking protrusion, and the rotation of the second rolling bearing is stopped. It consists of two stopping parts.

A bearing structure according to a sixteenth aspect of the present invention for solving the above problems is
In the bearing structure according to the fifteenth aspect,
The first permissible portion is formed adjacent to the first vertical surface perpendicular to the circumferential direction of the bearing and the first vertical surface, and is parallel to the circumferential direction of the bearing. A first parallel surface disposed at a radial distance of the first ball from the center of one ball, and when the first ball rolls in the one circumferential direction, the first ball is the first ball The first ball is arranged at the first position by contacting a vertical plane and the first parallel plane,
The first restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the first vertical surface in the opposite circumferential direction. The first small vertical surface disposed on the side, the first parallel surface and the first small vertical surface are formed adjacent to each other and have an acute inclination angle with respect to the circumferential direction of the bearing. When the first ball rolls in the opposite circumferential direction, the first ball comes into contact with the first small vertical surface and the first inclined surface, so that the first ball moves from the first position. The first ball is separated, the first holding member is pressed by the first ball, and the first locked protrusion is moved together with the first holding member to the first enclosing member side,
The second permissible part is formed adjacent to the second vertical surface perpendicular to the circumferential direction of the bearing and the second vertical surface, and is parallel to the circumferential direction of the bearing. A second parallel surface arranged at a radial distance of the second ball from the center of the two balls, and when the second ball rolls in the opposite circumferential direction, the second ball is the second ball The second ball is arranged at the second position by contacting a vertical plane and the second parallel plane,
The second restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the second vertical surface to the one circumferential direction. A second small vertical surface disposed on the side, adjacent to the second parallel surface and the second small vertical surface, and having an acute inclination angle with respect to the circumferential direction of the bearing. When the second ball rolls in the one circumferential direction, the second ball comes into contact with the second small vertical surface and the second inclined surface, so that the second ball moves from the second position. The second ball is separated, the second holding member is pressed by the second ball, and the second locked protrusion is moved to the second enclosing member side together with the second holding member. It is characterized by.

A bearing structure according to a seventeenth invention for solving the above problems is as follows:
An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A plurality of first partitioning members supported on the inner peripheral surface of the middle wheel, and a plurality of first holding spaces for holding the first balls in a rollable manner between the first partitioning members; A plurality of second holding members and a plurality of second partition members supported on the inner peripheral surface of the outer ring, and a plurality of second members which hold the second balls between the second partition members so as to roll. A rolling bearing provided with a second holding member that forms a holding space;
In the first holding space, when the first ball rolls in one circumferential direction of the bearing, the first ball is arranged at a first position in contact with both the inner ring outer circumferential track and the middle ring inner circumferential track. A first allowing portion for allowing the inner ring to rotate, and when the first ball rolls in a circumferential direction opposite to the one circumferential direction, A first stop portion that presses the inner ring and stops the rotation of the inner ring,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is arranged at a second position in contact with both the middle wheel outer circumferential track and the outer ring inner circumferential track. And when the second ball rolls in the one circumferential direction, the second ball is pressed toward the outer circumferential track side of the middle wheel. And a second restraining portion for restraining the rotation of the middle wheel.

A bearing structure according to an eighteenth invention for solving the above-described problems is
In the bearing structure according to the seventeenth aspect of the present invention,
The first permissible portion has a first vertical surface perpendicular to the circumferential direction of the bearing on a surface on the opposite circumferential direction side of the first partition member, and the first ball extends in the one circumferential direction. When rolling, by allowing the first ball to contact the first vertical surface, the first ball is allowed to be placed in the first position;
The first restraining portion is perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the first partition member, and has a width smaller than the diameter of the first ball in the diameter direction of the bearing. A first small vertical surface; and a first inclined surface projecting from the first small vertical surface toward the one circumferential direction side and the inner peripheral surface side of the middle wheel, and has an acute inclination angle with respect to the inner peripheral surface of the middle wheel. A first inclined surface, and when the first ball rolls in the opposite circumferential direction, the first ball is brought into contact with the first small vertical surface and the first inclined surface. 1 ball is pressed against the inner ring outer circumference track side,
The second permissible portion has a second vertical surface perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the second partition member, and the second ball is in the opposite circumferential direction. When rolling, by allowing the second ball to contact the second vertical surface, the second ball is allowed to be placed in the second position;
The second stop portion is perpendicular to the circumferential direction of the bearing on the opposite circumferential surface of the second partition member, and has a width smaller than the diameter of the second ball in the diameter direction of the bearing. A second small vertical surface and a second small vertical surface projecting from the second small vertical surface to the opposite circumferential direction side and the inner circumferential surface side of the outer ring and having an acute inclination angle with respect to the inner circumferential surface of the outer ring. The second ball is brought into contact with the second small vertical surface and the second inclined surface when the second ball rolls in the one circumferential direction. Is pressed to the outer peripheral track side of the middle wheel.

A bearing structure according to a nineteenth aspect of the present invention for solving the above problem is
An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A plurality of first partition members supported on the outer peripheral surface of the inner ring, and a plurality of first holding spaces that hold the first balls in a rollable manner between the first partition members; A plurality of second holding spaces that have a holding member and a plurality of second partition members supported on the outer peripheral surface of the middle wheel, and hold the second ball between the second partition members so as to allow rolling. A rolling bearing provided with a second holding member forming
In the first holding space, when the first ball rolls in one circumferential direction of the bearing, the first ball is arranged at a first position in contact with both the inner ring outer circumferential track and the middle ring inner circumferential track. A first allowing portion that allows the inner ring to rotate, and when the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first ball is moved into the middle ring. It consists of a first stop portion that presses against the circumferential track and stops the rotation of the inner ring,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is arranged at a second position in contact with both the middle wheel outer circumferential track and the outer ring inner circumferential track. And when the second ball rolls in the one circumferential direction, the second ball is pressed toward the inner raceway side of the outer ring. And a second restraining portion for restraining the rotation of the middle wheel.

A bearing structure according to a twentieth invention for solving the above problems is as follows:
In the bearing structure according to the nineteenth aspect,
The first permissible portion has a first vertical surface perpendicular to the circumferential direction of the bearing on a surface on the opposite circumferential direction side of the first partition member, and the first ball extends in the one circumferential direction. When rolling, by allowing the first ball to contact the first vertical surface, the first ball is allowed to be placed in the first position;
The first restraining portion is perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the first partition member, and has a width smaller than the diameter of the first ball in the diameter direction of the bearing. A first small vertical surface and a first inclined surface projecting from the first small vertical surface toward the one circumferential direction side and the outer peripheral surface side of the inner ring and having an acute inclination angle with respect to the outer peripheral surface of the inner ring When the first ball rolls in the opposite circumferential direction, the first ball is brought into contact with the first small vertical surface and the first inclined surface, whereby the first ball is It is to be pressed to the inner ring inner track side,
The second permissible portion has a second vertical surface perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the second partition member, and the second ball is in the opposite circumferential direction. When rolling, the second ball is brought into contact with the second vertical surface, and the second ball is allowed to be arranged at the second position;
The second stop portion is perpendicular to the circumferential direction of the bearing on the opposite circumferential surface of the second partition member and has a width smaller than the diameter of the second ball in the diameter direction of the bearing. A second small vertical surface and a second small vertical surface projecting from the second small vertical surface to the opposite circumferential direction side and the outer peripheral surface side of the middle wheel and having an acute inclination angle with respect to the outer peripheral surface of the middle wheel The second ball is brought into contact with the second small vertical surface and the second inclined surface when the second ball rolls in the opposite circumferential direction. Is pressed to the inner ring side of the outer ring.

An oscillating rotating electrical machine according to a twenty-first invention for solving the above-described problems is
An oscillating rotating electric machine that oscillates a rotating shaft,
In the bearing structure according to any one of the first to twentieth inventions, at least one side of the rotating shaft is held on the inner peripheral surface of the first inner ring or the inner ring.

  According to the first to twentieth inventions, on the inner diameter side of the bearing (first rolling bearing or inner ring-middle ring), rotation in one circumferential direction is achieved by the configuration of the first holding member holding the first ball. Permitting and restricting rotation in the opposite circumferential direction, and on the outer diameter side of the bearing (second rolling bearing or middle ring-outer ring), the configuration of the second holding member that holds the second ball makes it possible to Since the rotation in the direction is restrained and the rotation in the opposite circumferential direction is allowed, even when the shaft is swung, the bearing portion on the inner diameter side rotates when rotating in one circumferential direction, When rotating in the opposite circumferential direction, the bearing portion on the outer diameter side rotates, and each bearing portion rotates over the entire circumference while repeatedly rotating / stopping in one direction or the opposite direction. . As a result, the place that receives the load always moves, so that partial wear and fatigue failure can be prevented. Further, since each bearing portion rotates over the entire circumference, grease can be agitated by the bearing itself, and grease lubrication failure can be prevented, and operation reliability can be improved.

  Further, according to the 11th to 20th inventions, since the two rolling bearings described in the 1st to 10th inventions are integrated, the number of parts is reduced and the assembling work becomes unnecessary. The cost can be reduced, and the bearing structure can be made more compact.

  According to the twenty-first aspect, in the oscillating rotating electrical machine, the bearing structure described in the first to twentieth aspects is used. Therefore, in addition to the effects of the first to twentieth aspects, forced lubrication for grease lubrication is performed. An oil supply device and an oil recovery device are not required, and the cost of the oscillating rotating electrical machine itself can be reduced.

The bearing structure according to the present invention is a bearing structure in which two rolling bearings are incorporated on the inner diameter side and the outer diameter side, or a bearing structure in which these rolling bearings are integrated. By devising the structure, on the inner diameter side, the rotation in one circumferential direction is allowed, the rotation in the opposite circumferential direction is restricted, the rotation direction is limited to one circumferential direction, and on the outer diameter side The rotation in the opposite circumferential direction is allowed, the rotation in one circumferential direction is stopped, and the rotation direction is limited to the opposite circumferential direction. The swing motor according to the present invention uses the bearing structure having the above structure.
Hereinafter, with reference to FIG. 3 to FIG. 10, some of the embodiments of the bearing structure according to the present invention and the swing rotating electric machine using the bearing structure will be described.

<First Embodiment>
The bearing structure of the present embodiment forms a plurality of holding spaces of a predetermined shape in the holding member that holds the balls, and in the holding space, the balls are arranged at appropriate rolling track positions or the appropriate rolling tracks. By moving the ball in the axial direction from the position, the rotation direction of the rolling bearing is limited, and furthermore, by using two of the rolling bearings, the allowable rotation directions of the two rolling bearings are reversed. By doubling in the diametrical direction, it can be swung.
Hereinafter, some examples of the present embodiment will be described with reference to FIGS.

FIG. 3 is a schematic configuration diagram of a swing motor using the bearing structure according to the present invention.
As shown in FIG. 3, the oscillating motor 1 of this embodiment includes a shaft 2 that serves as a rotation shaft, a rotor 3 that is supported coaxially with the shaft 2, and a stator that is disposed around the rotor 3. 4, the stator 4 is supported on the inner side of a frame 5 that is a housing of the swing motor 1, and the shaft 2 is framed via a bearing 6 that supports the shaft 2. 5 are supported by brackets 7 disposed at both ends of the plate.

  The bearing 6 includes a rolling bearing 11A on the inner diameter side that directly supports the shaft 2 on the inner peripheral side, and a rolling bearing 11B on the outer diameter side supported by the bracket 7, and between the rolling bearing 11A and the rolling bearing 11B. The rolling bearing 11B indirectly supports the rolling bearing 11A via the intermediate ring 12 provided in the inner ring 12, and the rolling bearings 11A and 11B are incorporated so as to have the same rotating shaft. The double rolling bearings 11A and 11B are arranged on both the direct connection side (right side in FIG. 3) and the anti-direct connection side (right side in FIG. 3) of the shaft 2.

Next, referring to FIGS. 4A to 4C and FIGS. 5A to 5B, the structures and operations of the rolling bearings 11A and 11B constituting the bearing structure of the present embodiment will be described. This will be described in detail.
Here, FIG. 4A is a plan view of the rolling bearing, FIGS. 4B and 4C are diagrams for explaining a rotation allowable state, and FIG. 4B is a diagram illustrating FIG. XX line development view of FIG. 4C and FIG. 4C are cross-sectional views of FIG. 4A and FIG. 4B ZZ line. 5 (a) and 5 (b) are diagrams for explaining the rotation-stopped state. FIG. 5 (a) is an XX line development view of FIG. 4 (a) and FIG. 5 (b). FIG. 6 is a sectional view taken along line ZZ in FIGS. 4 (a) and 5 (a).
The rolling bearings 11A and 11B differ only in size and direction of formation of the holding space 19 to be described later, and the other configurations are the same. In FIGS. 4 and 5, only the structure of the rolling bearing 11A on one inner diameter side is shown. This is illustrated and described.

  As shown in FIG. 4A, the inner diameter side rolling bearing 11A (first rolling bearing) in the present embodiment supports the shaft 2 on the inner peripheral surface and the inner ring 13 (first ring) having the inner ring outer peripheral track on the outer peripheral surface. 1 inner ring), an outer ring 14 whose outer peripheral surface is supported by the intermediate ring 12 and has an outer ring inner peripheral track on the inner peripheral surface (first outer ring), an inner ring outer peripheral track on the outer peripheral surface of the inner ring 13, and an inner peripheral surface of the outer ring 14 And a plurality of balls 15 inserted so as to be able to roll. Although not shown, the flat shield plate for enclosing the grease is also disposed on both side edges of the space formed by the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14. It is held on the surface side. Further, the inner ring outer peripheral track on the outer peripheral surface of the inner ring 13 and the outer ring inner peripheral track on the inner peripheral surface of the outer ring 14 are usually formed as arc-shaped grooves having a diameter slightly larger than the radius of the ball 15.

  The configuration of the outer diameter side rolling bearing 11B (second rolling bearing) will be described. An inner ring 13 (second inner ring) having an intermediate ring 12 supported on the inner peripheral surface and an inner ring outer peripheral track on the outer peripheral surface, and an outer periphery An outer ring 14 (second outer ring) having a surface fitted to the bracket 7 and having an outer ring inner circumferential track on the inner circumferential surface, an inner ring outer circumferential track on the outer circumferential surface of the inner ring 13 and an outer ring inner circumferential track on the inner circumferential surface of the outer ring 14 It becomes the structure which has the some ball | bowl 15 (2nd ball | bowl) inserted so that rolling was possible. Since the rolling bearing 11B is arranged on the outer diameter side of the inner diameter side rolling bearing 11A, the size is different, but the basic configuration is the same. Further, the outer peripheral surface of the outer ring 14 of the inner diameter side rolling bearing 11A may be directly supported on the inner peripheral surface by the outer diameter side rolling bearing 11B.

  In the present embodiment, the cage 18 (first holding member) is inserted between the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14 as shown in FIGS. Yes. More specifically, the retainer 18 has a plurality of unique-shaped retaining spaces 19 (first retaining spaces) formed in the retainer 18, and the balls 15 are retained in the retaining space 19 in a rollable manner. The holding space 19 is configured to limit the rolling of the balls 15, that is, the rotation direction of the rolling bearing 11 </ b> A to one circumferential direction, and each of the cages 18 having such holding spaces 19 is formed. The shaft 2 can be swung by combining the rolling bearing 11 </ b> A and the rolling bearing 11 </ b> B that are doubled in the diametrical direction.

  The holding space 19 is formed perpendicular to the circumferential direction XX of the rolling bearing 11A (parallel to the diameter direction of the rolling bearing 11A), and is disposed on one circumferential side (CCW direction side) in the holding space 19. The vertical surface 18a is formed perpendicular to the circumferential direction XX, and has a width smaller than the diameter of the ball 15 in the axial direction Y. In the holding space 19, the opposite circumferential direction (CW) is opposed to the vertical surface 18a. Small vertical surface 18b disposed at a predetermined distance on the direction side) and adjacent to the vertical surface 18a, and parallel to the circumferential direction XX, the inner ring outer peripheral track of the inner ring 13 and the outer ring 14 Between the parallel surface 18c disposed at the radial distance of the ball 15 from the center c of the ball 15 at the appropriate position WW of the inner ring on the inner ring, and between the parallel surface 18c and the small vertical surface 18b. Formed adjacent to each other in the circumferential direction XX, Those having an inclined surface 18d having a sharp inclination angle constant.

  The holding space 19 having a specific shape formed by the surfaces 18a, 18b, 18c, and 18d is adjacent to the center line XX between the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14 in the opening direction. The opposite holding spaces 19 have opposite directions, that is, the small vertical surfaces 18b, the parallel surfaces 18c, and the inclined surfaces 18d in the adjacent holding spaces 19 are opposite to each other with respect to the center line XX. The ball 15 is arranged in such a holding space 19 so as to be able to roll.

  In the holding space 19, when the ball 15 is located in a rectangular space (left side of the holding space 19 in the figure) formed by the vertical surface 18a and the parallel surface 18c (first permissible portion), in other words, the ball 15 However, when rolling in the counterclockwise (CCW) direction, which is one of the circumferential directions, and abutting on the vertical surface 18a and the parallel surface 18c, the ball 15 The center c is arranged on the appropriate position WW. In this case, as the widths of the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14 with respect to the ball 15, a predetermined width that allows the ball 15 to freely roll is ensured, so that the ball 15 can roll freely. The rotation of the rolling bearing 11A in that direction is allowed (unlocked) (see FIGS. 4B and 4C).

  Conversely, when the ball 15 is located in the trapezoidal space (the right side of the holding space 19 in the figure) formed by the small vertical surface 18b and the inclined surface 18d (first stop portion) in the holding space 19, in other words, Then, when the ball 15 rolls in the clockwise (CW) direction which is the opposite circumferential direction and comes into contact with the small vertical surface 18b and the inclined surface 18d, it comes into contact with the small vertical surface 18b and the inclined surface 18d. Thus, the ball 15 moves in the axial direction Y of the rolling bearing 11A, and the center c of the ball 15 is separated from the appropriate position WW. In this case, the width of the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14 becomes narrower with respect to the ball 15, so that the ball 15 cannot freely roll and the rolling bearing 11A rotates in that direction. Is stopped (locked) (see FIGS. 5A and 5B).

  In addition, as described above, since the adjacent holding spaces 19 are arranged so that the opening direction of the holding spaces 19 is opposite, the balls 15 held in the adjacent holding spaces 19 are also mutually, As a result, the adjacent balls 15 are separated from each other in the direction of both side edges of the space formed by the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14. Thus, the rotation of the rolling bearing 11A can be reliably controlled in a balanced manner.

  The stop portion may be formed by a single inclined surface instead of the small vertical surface 18b and the inclined surface 18d. However, when the ball 15 rolls in the CW direction, the outer peripheral surface of the inner ring 13 and the outer ring In consideration of limiting the force acting between the inner peripheral surface of the ball 14 and the ball 15, it is desirable to form the stop portion from the small vertical surface 18b and the inclined surface 18d as in this embodiment. Further, if the inclination angle of the inclined surface 18d is gentle, the change in the force acting between the outer peripheral surface of the wheel 13 and the inner peripheral surface of the outer ring 14 and the ball 15 becomes gentle. The moving distance also becomes longer. If the inclination angle is close to a right angle, the force acting between the outer peripheral surface of the wheel 13 and the inner peripheral surface of the outer ring 14 and the ball 15 becomes abrupt, but the rolling distance becomes shorter. Therefore, it is desirable to select the inclination angle of the inclined surface 18d as appropriate according to the load on the bearing.

  Here, simply referring to the configuration of the cage 18 in the outer diameter side rolling bearing 11B, the holding space 19 of the cage 18 in the rolling bearing 11B is the holding space 19 of the cage 18 in the inner diameter side rolling bearing 11A. On the other hand, in the circumferential direction XX, it is formed so as to be arranged in the opposite direction. Therefore, also in the rolling bearing 11B, the ball 15 freely rolls when rolling in the opposite circumferential direction, contrary to the case of the rolling bearing 11A, due to the action of the holding space 19 of the cage 18 described above. And the rotation of the rolling bearing 11B in that direction is allowed (unlocked), and when rolling in one circumferential direction, the ball 15 cannot freely roll and roll in that direction. The rotation of the bearing 11B is stopped (locked).

  Thus, in the rolling bearing 11A of the present embodiment, the holding space 19 in the cage 18 is configured as described above, thereby controlling the rolling state of the balls 15 and allowing the rotation only in one circumferential direction. It is possible to prevent rotation in the opposite circumferential direction. Then, in the rolling bearing 11A on the inner diameter side and the rolling bearing 11B on the outer diameter side, the installation direction of the holding space 19 in the cage 18 is reversed, for example, one circumferential direction is the CCW direction, and the opposite circumferential direction is In the CW direction, the inner diameter side rolling bearing 11A can rotate only in the CCW direction, and the outer diameter side rolling bearing 11B can rotate only in the CW direction. Therefore, even if one of the rolling bearings is restrained, the other rolling bearing side rotates, so that the rotation of one of the rolling bearings can be reliably restrained without applying a load.

  When the shaft 2 is swung, only when the shaft 2 is rotated in one circumferential direction, the rolling bearing 11A on the inner diameter side sequentially rotates in one direction, so that a load is applied only to a specific portion. And the occurrence of partial wear and fatigue failure can be suppressed. Further, since the rolling bearing 11A on the inner diameter side sequentially rotates in one direction, the rolling bearing 11A on the inner diameter side rotates around the entire circumference in one direction. The grease lubrication at the rolling bearing 11A is maintained.

  Similarly, when the shaft 2 is swung, the rolling bearing 11B on the outer diameter side sequentially rotates in the reverse direction only when the shaft 2 is rotated in the reverse circumferential direction. Does not work, and partial wear and fatigue failure can be suppressed. Further, since the outer diameter side rolling bearing 11B rotates sequentially in the reverse direction, the outer diameter side rolling bearing 11B rotates around the entire circumference in the reverse direction, so that the grease is stirred. The grease lubrication at the outer diameter side rolling bearing 11B is maintained.

6 and 7 are diagrams for explaining the bearing structure of the present embodiment. FIG. 6A is a plan view of the rolling bearing, and FIGS. 6B and 6C are rotation allowable states. FIG. 6B is a developed view taken along line XX in FIG. 6A, and FIG. 6C is a cross-sectional view taken along line ZZ in FIGS. 6A and 6B. FIG. 7 (a) and 7 (b) are diagrams for explaining the rotation restrained state. FIG. 7 (a) is a developed view of line XX in FIG. 6 (a), and FIG. 7 (b). FIG. 8 is a sectional view taken along the line ZZ in FIGS. 6 (a) and 7 (a).
In this case as well, the inner diameter side rolling bearing 21A and the outer diameter side rolling bearing 21B (not shown) differ only in the size and the structure of the retainer 22 and shield plate 23 described later, and the other structures are the same. Therefore, in FIGS. 6 and 7, only the structure of the rolling bearing 21A on one inner diameter side is shown. Moreover, the same code | symbol is attached | subjected to the structure equivalent to the rolling bearing in Example 1, and the detailed description is abbreviate | omitted.

  As shown in FIG. 6A, the inner diameter side rolling bearing 21 </ b> A (first rolling bearing) in this embodiment has an inner ring 13, an outer ring 14, and balls 15, as in the first embodiment. Although only one side is illustrated, a flat shield plate enclosing grease is disposed on both side edges of the space formed by the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14. It is hold | maintained at the inner peripheral surface side.

  In the present embodiment, the cage 22 (first holding member) is inserted between the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14 as shown in FIGS. 6 (b) and 6 (c). Yes. More specifically, the retainer 22 has a plurality of unique shaped retaining spaces 24 (first retaining spaces) formed in the retainer 22, and the balls 15 are retained in the retaining space 24 so that they can roll. . In addition, the retainer 22 is formed with a locked projection 22e having a locked surface on the surface opposite to the holding space 24, and the locked projection is formed on the shield plate 23 (first enclosure member). A locking projection 23a having a locking surface is formed facing the locked surface of the portion 22e. As described above, the present embodiment is different from the first embodiment in the configuration of the holding space 24, the locked protrusion 22e, and the locking protrusion 23a. In the same manner as described above, the rolling of the balls 15, that is, the rotational direction of the rolling bearing 21A is limited to one circumferential direction. Thus, the rocking | fluctuation operation | movement of the axis | shaft 2 is enabled by combining twice in the diameter direction.

  The holding space 24 is formed perpendicular to the circumferential direction XX of the rolling bearing 21 </ b> A (parallel to the diameter direction of the rolling bearing 21 </ b> A), and the holding space 24 is arranged vertically on one circumferential side (CCW) side. The surface 22a is formed perpendicular to the circumferential direction XX, has a width smaller than the diameter of the ball 15 in the axial direction Y, and faces the vertical surface 22a in the holding space 24 so as to face the opposite circumferential direction (CW direction). A small vertical surface 22b disposed at a predetermined distance from the inner surface of the inner ring 13 and the inner surface of the inner ring 13 and the outer ring 14 of the inner ring 13. The parallel surface 22c disposed at the radial distance of the ball 15 from the center c of the ball 15 at an appropriate position WW of the inner ring orbit of the outer ring on the peripheral surface, and adjacent between the parallel surface 22c and the small vertical surface 22b. Formed with respect to the circumferential direction XX. Those having an inclined surface 22d having a sharp inclination.

  The holding space 24 having a specific shape formed by the surfaces 22a, 22b, 22c, and 22d is such that the direction of the opening side is only one direction in the axial direction Y with respect to the center line XX. The ball 15 is arranged in such a holding space 24 so as to be able to roll. Thus, the opening direction of the holding space 24 is different from the holding space 19 in the first embodiment.

  In addition, as described above, the cage 22 protrudes from the surface opposite to the opening direction of the holding space 24, is parallel to the diameter direction of the rolling bearing 21A, and is in the CW direction in the circumferential direction XX. A locked projection 22e having a locked surface facing the side and having a triangular shape in side view is provided. Further, the shield plate 23 projects from the surface of the shield plate 23 on the locked projection 22e side and faces the locked surface, and is locked in the circumferential direction XX toward the CCW direction. A locking projection 23a having a surface and a triangular shape in side view is provided.

  In the holding space 24, when the ball 15 is located in a rectangular space (the left side of the holding space 24 in the figure) formed by the vertical surface 22a and the parallel surface 22c (first allowable portion), in other words, the ball 15 However, when rolling in the counterclockwise (CCW) direction, which is one circumferential direction, and abutting on the vertical surface 22a and the parallel surface 22c, the ball 15 The center c is arranged at an appropriate position WW of the inner ring outer peripheral track on the outer peripheral surface of the inner ring 13 and the outer ring inner peripheral track on the inner peripheral surface of the outer ring 14. In this case, as the widths of the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14 with respect to the ball 15, a predetermined width that allows the ball 15 to roll freely is secured. The bowl 22 is not moved to the shield plate 23 side, the protrusions 22e and 23a are not caught with each other, and the ball 15 can freely roll, and the rolling bearing 21A in that direction can be moved. The rotation is allowed (unlocked) (see FIGS. 6B and 6C).

  Conversely, when the ball 15 is located in the trapezoidal space (the right side of the holding space 24 in the figure) formed by the small vertical surface 22b and the inclined surface 22d (first stop portion) in the holding space 24, in other words, Then, when the ball 15 rolls in the clockwise (CW) direction which is the opposite circumferential direction and comes into contact with the small vertical surface 22b and the inclined surface 22d, it comes into contact with the small vertical surface 22b and the inclined surface 22d. As a result, the ball 15 moves in the axial direction Y of the rolling bearing 21A, the center c of the ball 15 is separated from the appropriate position WW, and the inclined surface 22d is pressed in the axial direction Y and held. The container 22 moves to the shield plate 23 side. In this case, the width of the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14 becomes narrower with respect to the ball 15, and the protrusion 22e of the cage 22 also moves toward the shield plate 23, so that the protrusion 22e is shielded. Since the protrusions 23a of the plate 23 are caught with each other, the balls 15 cannot freely roll and the cage 22 itself cannot freely rotate, and the rolling bearing 11A rotates in that direction. Is restrained (locked) (see FIGS. 7A and 7B).

  Here, simply referring to the configuration of the cage 22 of the outer diameter side rolling bearing 21B, the holding space 24 of the cage 22 in the rolling bearing 21B is the holding space 24 of the cage 22 in the inner diameter side rolling bearing 21A. On the other hand, in the circumferential direction XX, it is formed so as to be arranged in the opposite direction, and the locked projection 22e and the locking projection 23a are also arranged in the opposite direction. It is formed as follows. Therefore, also in the rolling bearing 21B on the outer diameter side, the reverse of the case of the rolling bearing 21A due to the action of the holding space 24 of the retainer 22 and the locked protrusion 22e and the locking protrusion 23a described above. When rolling in the circumferential direction, the balls 15 and the cage 22 can freely roll, allowing the rolling bearing to rotate in that direction (unlocking) and rolling in one circumferential direction. At this time, the balls 15 and the cage 22 cannot freely roll, and the rotation of the rolling bearing in that direction is stopped (locked).

  Thus, in the rolling bearing 21A of the present embodiment, the cage 22 and the shield plate 23 are configured as described above, so that the rolling state of the ball 15 and the operating state of the cage 22 are controlled, and It is possible to allow rotation only in the direction and not to rotate in the opposite circumferential direction. Then, in the inner diameter side rolling bearing 21 </ b> A and the outer diameter side rolling bearing 21 </ b> B, the installation directions of the holding space 24 in the cage 22, the locked protrusion 22 e, and the locking protrusion 23 a in the shield plate 23 are reversed. For example, if one circumferential direction is the CCW direction and the opposite circumferential direction is the CW direction, the inner diameter side rolling bearing 21A can rotate only in the CCW direction, and the outer diameter side rolling bearing 21B can rotate only in the CW direction. can do.

  When the shaft 2 is swung, only when the shaft 2 is rotated in one circumferential direction, the rolling bearing 21A on the inner diameter side sequentially rotates in one direction, so that a load acts only on a specific portion. And the occurrence of partial wear and fatigue failure can be suppressed. Further, since the rolling bearing 21A on the inner diameter side sequentially rotates in one direction, the rolling bearing 21A on the inner diameter side rotates around the entire circumference in one direction. The grease lubrication at the rolling bearing 21A is maintained.

  Similarly, when the shaft 2 is swung, only when the shaft 2 is rotated in the reverse circumferential direction, the rolling bearing 21B on the outer diameter side sequentially rotates in the reverse direction, so that a load acts only on a specific portion. There is nothing, and the occurrence of partial wear and fatigue failure can be suppressed. Further, since the outer diameter side rolling bearing 21B sequentially rotates in the reverse direction, the outer diameter side rolling bearing 21B rotates around the entire circumference in the reverse direction, so that the grease is stirred. The grease lubrication at the outer diameter side rolling bearing 21B is maintained.

Second Embodiment
In the first and second embodiments, a plurality of holding spaces having a predetermined shape are formed in the cage, and balls are arranged in the holding spaces to limit the rotation direction of the rolling bearing. In the embodiment, a plurality of partition members constituting the cage are formed in a predetermined shape, a holding space of a specific shape is formed between the partition members, and balls are placed at appropriate rolling track positions in the holding space. The rotation direction of the rolling bearing is limited by arranging or moving the ball in the diametrical direction from an appropriate rolling track position. Furthermore, using two of the rolling bearings, two rolling bearings By doubling in the diametrical direction so that the allowable rotation direction is reversed, it can be swung.
Hereinafter, some of the embodiments will be described with reference to FIGS.

FIG. 8 is a view for explaining the bearing structure of the present embodiment, and is a plan view of the rolling bearing. Hereinafter, the structure and operation of the rolling bearing will be described in detail with reference to FIG.
In this case as well, the inner diameter side rolling bearing 31A and the outer diameter side rolling bearing 31B (not shown) are different in size and only in the structure of a cage 32 described later, and other structures are the same. Then, only the structure of the rolling bearing 31A on one inner diameter side is illustrated. Moreover, the same code | symbol is attached | subjected to the structure equivalent to the rolling bearing in Example 1, and the detailed description is abbreviate | omitted.

  As shown in FIG. 8, the inner diameter side rolling bearing 31 </ b> A (first rolling bearing) in the present embodiment has an inner ring 13, an outer ring 14, and balls 15 similarly to the first embodiment, and includes a shield plate (not shown). ) Is also arranged.

  In this embodiment, as shown in FIG. 8, the cage 32 (first holding member) is inserted between the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14. More specifically, the retainer 32 has a plurality of partition members 33 (first partition members) that are supported on the inner peripheral surface of the outer ring 14 and formed in a specific shape, and between the adjacent partition members 33. A plurality of holding spaces 34 (first holding spaces) are formed, and the balls 15 are held in the holding space 34 in a rollable manner. As described above, the present embodiment differs from the first embodiment in the configuration of the holding space 34. With these configurations, as in the first embodiment, the balls 15 roll, that is, the rolling bearing 31A. The rotation direction is limited to one circumferential direction, and the rolling bearings having such a configuration are combined in a diametrical direction so that the rotation permissible directions are opposite to each other. Swing operation is possible.

  The partition member 33 has a vertical surface 33a formed on the surface on the CW direction side of the partition member 33 so as to be perpendicular to the circumferential direction of the rolling bearing 31A (parallel to the diameter direction of the rolling bearing 31A). A small vertical surface 33b that is perpendicular to the circumferential direction of the rolling bearing 31A and is smaller than the diameter of the ball 15 in the diameter direction of the rolling bearing 31A on the CCW direction side surface, that is, the surface opposite to the vertical surface 33a. And an inclined surface 33 c that protrudes from the small vertical surface 33 b toward the CCW direction side and the inner peripheral surface side of the outer ring 14 and has an acute inclination angle with respect to the inner peripheral surface of the outer ring 14. And the partition member 33 which has each surface 33a, 33b, 33c is arrange | positioned at intervals larger than the diameter of the ball | bowl 15, and the holding space 34 of a specific shape is formed between the partition members 33. The ball 15 is arranged in such a holding space 34 so as to be able to roll. The surface on the inner ring 13 side of the partition member 33 is formed in a curved shape, for example, in accordance with the shape of the inner ring 13 with a predetermined distance from the inner ring 13 so that the inner ring 13 side can freely rotate.

  In the holding space 34, when the ball 15 is positioned on the right side of the holding space 34 in FIG. 8, in other words, the ball 15 rolls in the CCW direction, and the vertical surface 33a (first allowable value) of the partition member 33 is obtained. The center position of the ball 15 is arranged on the center line between the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14 by contacting the vertical surface 33a. . In this case, the ball 15 is disposed at a position where the ball 15 is appropriately in contact with the inner ring outer circumferential track of the inner ring 13 and the outer ring inner circumferential track of the outer ring 14, so that the ball 15 can freely roll. Since the width is secured, the ball 15 can freely roll, and the rotation of the rolling bearing 31A in that direction is allowed (unlocked).

  Conversely, when the ball 15 is located on the left side of the holding space 34 in FIG. 8 in the holding space 34, in other words, the ball 15 rolls in the CW direction, and the small vertical surface 33b and the inclined surface 33c. When abutting on the (first restraining portion), the ball 15 rides on the inclined surface 33c by moving to the small vertical surface 33b and the inclined surface 33c, and moves to the inner ring 13 side in the diameter direction of the rolling bearing 31A. Thus, the center position of the ball 15 is arranged at a position shifted from the center line. In this case, the ball 15 is no longer in contact with the outer ring inner circumference track of the outer ring 14 and is pressed to the inner ring outer circumference track side of the outer ring surface of the inner ring 13. Since there is no appropriate gap, the ball 15 cannot freely roll and stops (locks) the rotation of the rolling bearing 31A in that direction.

  Thus, in the rolling bearing 31A of the present embodiment, by configuring the cage 32 as described above, the rolling state of the ball 15 is controlled, and the rotation is allowed only in one circumferential direction. It can be prevented from rotating in the direction. Then, in the rolling bearing 31A on the inner diameter side and the rolling bearing 31B on the outer diameter side, by incorporating the installation direction of the cage 32 in reverse, for example, if one circumferential direction is the CCW direction and the opposite circumferential direction is the CW direction, The inner diameter side rolling bearing 31A can be rotated only in the CCW direction, and the outer diameter side rolling bearing 31B can be rotated only in the CW direction.

  When the shaft 2 is swung, only when the shaft 2 is rotated in one circumferential direction, the rolling bearing 31A on the inner diameter side sequentially rotates in one direction, so that a load is applied only to a specific portion. And the occurrence of partial wear and fatigue failure can be suppressed. Further, since the rolling bearing 31A on the inner diameter side sequentially rotates in one direction, the rolling bearing 31A on the inner diameter side rotates around the entire circumference in one direction. The grease lubrication at the rolling bearing 31A is maintained.

  Similarly, when the shaft 2 is swung, only when the shaft 2 is rotated in the opposite circumferential direction, the rolling bearing 31B on the outer diameter side sequentially rotates in the opposite direction, so that a load acts only on a specific portion. There is nothing, and the occurrence of partial wear and fatigue failure can be suppressed. Moreover, since the outer diameter side rolling bearing 31B is rotated in the reverse direction sequentially, the outer diameter side rolling bearing 31B rotates around the entire circumference in the reverse direction, so that the grease is stirred. The grease lubrication at the outer diameter side rolling bearing 31B is maintained.

FIG. 9 is a view for explaining the bearing structure of the present embodiment, and is a plan view of the rolling bearing. Hereinafter, the structure and the like of the rolling bearing will be described in detail with reference to FIG.
In this case as well, the inner diameter side rolling bearing 41A and the outer diameter side rolling bearing 41B (not shown) are different only in size and in the structure of a cage 42 described later, and other structures are the same. Then, only the structure of one inner diameter side rolling bearing 41A is illustrated. Moreover, the same code | symbol is attached | subjected to the structure equivalent to the rolling bearing in Example 1, and the detailed description is abbreviate | omitted.

  As shown in FIG. 9, the configuration of the rolling bearing 41A on the inner diameter side in the present embodiment is substantially the same as the rolling bearing 31A shown in the third embodiment. However, the cage 42 is configured and formed into a specific shape. The support directions of the plurality of partition members 43 are different. Specifically, the retainer 42 is supported on the outer peripheral surface of the inner ring 13, has a plurality of partition members 43 (first partition members) formed in a specific shape, and a plurality of partitions between adjacent partition members 43. The holding space 44 (first holding space) is formed, and the ball 15 is held in the holding space 44 in a rollable manner. As described above, the present embodiment differs from the first embodiment in the support structure of the holding space 34. With these structures, as in the first embodiment, the balls 15 roll, that is, the rolling bearing 41A. The rotation direction is limited to one circumferential direction, and further, the rolling bearings having such a configuration are swung in a diametrical direction so that the rotation allowable directions are opposite to each other. In the motor 3, the shaft 2 can swing.

  The partition member 43 has a vertical surface 43a formed on the surface of the partition member 43 on the CW direction side so as to be perpendicular to the circumferential direction of the rolling bearing 41A (parallel to the diameter direction of the rolling bearing 41A). A small vertical surface 43b that is perpendicular to the circumferential direction of the rolling bearing 41A on the CCW direction side surface, that is, the surface opposite to the vertical surface 43a, and has a width smaller than the diameter of the ball 15 in the diameter direction of the rolling bearing 41A. And an inclined surface 43 c that protrudes from the small vertical surface 43 b toward the CCW direction side and the outer peripheral surface side of the inner ring 13 and has an acute inclination angle with respect to the outer peripheral surface of the inner ring 13. And the partition member 43 which has each surface 43a, 43b, 43c is arrange | positioned with the space | interval larger than the diameter of the ball | bowl 15, and the holding space 44 of a specific shape is formed between the partition members 43. The ball 15 is arranged in such a holding space 44 so as to be able to roll. The surface on the outer ring 14 side of the partition member 43 is formed in a curved shape, for example, in accordance with the shape of the outer ring 14 with a predetermined interval from the outer ring 14 so that the inner ring 13 side can freely rotate.

  In the holding space 44, when the ball 15 is located on the right side of the holding space 44 in FIG. 9, in other words, the ball 15 rolls in the CCW direction, and the vertical surface 43a (first allowable value) of the partition member 43 is obtained. The center position of the ball 15 is arranged on the center line between the outer peripheral surface of the inner ring 13 and the inner peripheral surface of the outer ring 14 by contacting the vertical surface 43a. . In this case, the ball 15 is disposed at a position where the ball 15 is appropriately in contact with the inner ring outer circumferential track of the inner ring 13 and the outer ring inner circumferential track of the outer ring 14, and the ball 15 can roll freely. Since the width is secured, the ball 15 can freely roll and allow (unlock) rotation of the rolling bearing 41A in that direction.

  Conversely, when the ball 15 is located on the left side of the holding space 44 in FIG. 9 in the holding space 44, in other words, the ball 15 rolls in the CW direction, and the small vertical surface 43b and the inclined surface 43c. When abutting on the (first restraining portion), the ball 15 rides on the inclined surface 43c and contacts the small vertical surface 43b and the inclined surface 43c, and moves to the outer ring 14 side in the diameter direction of the rolling bearing 41A. Thus, the center position of the ball 15 is arranged at a position shifted from the center line. In this case, the ball 15 loses contact with the inner ring outer peripheral track of the inner ring 13 and is pressed toward the outer ring inner track side of the inner ring of the outer ring 14. Accordingly, the ball 15 cannot freely roll and stops (locks) the rotation of the rolling bearing 41A in that direction.

  As described above, in the rolling bearing 41A of the present embodiment, the cage 42 is configured as described above, thereby controlling the rolling state of the ball 15, allowing the rotation only in one circumferential direction, It can be prevented from rotating in the direction. Then, in the rolling bearing 41A on the inner diameter side and the rolling bearing 41B on the outer diameter side, by installing the installation direction of the cage 42 in reverse, for example, if one circumferential direction is the CCW direction and the opposite circumferential direction is the CW direction, The inner diameter side rolling bearing 41A can be rotated only in the CCW direction, and the outer diameter side rolling bearing 41B can be rotated only in the CC direction.

  When the shaft 2 is swung, only when the shaft 2 is rotated in one circumferential direction, the rolling bearing 41A on the inner diameter side sequentially rotates in one direction, so that a load acts only on a specific portion. And the occurrence of partial wear and fatigue failure can be suppressed. Further, the rolling bearing 41A on the inner diameter side sequentially rotates in one direction, so that the rolling bearing 41A on the inner diameter side circulates all around in one direction. The grease lubrication at the rolling bearing 41A is maintained.

  Similarly, when the shaft 2 is swung, the outer diameter side rolling bearing 41B sequentially rotates in the reverse direction only when the shaft 2 is rotated in the reverse circumferential direction, so that a load acts only on a specific portion. There is nothing, and the occurrence of partial wear and fatigue failure can be suppressed. Moreover, since the outer diameter side rolling bearing 41B is rotated in the reverse direction sequentially, the outer diameter side rolling bearing 41B rotates around the entire circumference in the reverse direction, so that the grease is stirred. The grease lubrication at the outer diameter side rolling bearing 41B is maintained.

<Third Embodiment>
In Examples 1 to 4 above, the inner diameter side rolling bearing and the outer diameter side rolling bearing are formed independently and are combined in a diametrical direction so that their rotatable directions are opposite to each other. It is a thing. On the other hand, in the fifth embodiment shown below, the inner diameter side rolling bearing and the outer diameter side rolling bearing in the first to fourth embodiments are integrated, and the inner ring side rotation allowable direction and the outer ring side rotation are integrated. In this configuration, the permissible directions are opposite to each other.
Hereinafter, the present embodiment will be described with reference to FIG.

  10A and 10B are diagrams for explaining the bearing structure of the present embodiment. FIG. 10A is a plan view of the rolling bearing, and FIG. 10B is a cross-sectional view taken along the line ZZ in FIG. is there. Here, the structure and operation of the rolling bearing 51 will be described in detail with reference to FIGS. 10 (a) to 10 (b).

  In this embodiment, as shown in FIG. 10A, the rolling bearing 51 includes an inner ring 52 that supports the shaft 2 on the inner peripheral surface and has an inner ring outer peripheral track on the outer peripheral surface, and an inner ring inner periphery on the inner peripheral surface. A middle ring 53 having a raceway and having an outer peripheral raceway on the outer peripheral surface; an outer ring 54 fitted to the frame and having an inner peripheral raceway on the inner ring; Rollable between the inner ring inner track of the inner ring 53 and between the outer ring track of the outer ring of the inner ring 53 and the outer ring track of the outer ring 54 inner ring. It has a plurality of balls 15 inserted.

  In the present embodiment, as shown in FIG. 10B, between the outer peripheral surface of the inner ring 52 and the inner peripheral surface of the middle ring 53, and between the outer peripheral surface of the middle ring 53 and the inner peripheral surface of the outer ring 54. A cage 18 having a plurality of holding spaces formed in a specific shape and a flat shield plate (not shown) enclosing grease is inserted between the balls 15 so as to be able to roll. . Each cage 18 is the same as that of the first embodiment, and is arranged so that the rolling directions of the balls 15 that are held are opposite to each other. In this structure, the direction and the rotation allowable direction of the middle wheel 53 are opposite to each other. That is, the rolling bearing 51 in the present embodiment is obtained by integrating the inner diameter side rolling bearing 11A and the outer diameter side rolling bearing 11B described in the first embodiment into one rolling bearing. Accordingly, the detailed structure and operation of the cage 18 are the same as those in the first embodiment, and thus detailed description thereof is omitted here.

  In the rolling bearing 51 having the above-described configuration, the rolling state of the ball 15 is controlled by using the two cages 18 in which the rolling possible direction of the ball 15 is opposite, and the shaft 2 rotates in one direction. When either the inner ring 52 or the middle ring 53 is rotatable, and when the shaft 2 rotates in the reverse direction, only the other one of the inner ring 52 or the middle ring 53 is allowed to rotate. Can do. Accordingly, when the shaft 2 is swung, only one of the inner ring 52 and the middle wheel 53 is sequentially rotated in one direction (or the reverse direction) only when the shaft 2 is rotated in one direction (or the reverse direction). As a result, a load is not applied only to a specific portion, and the occurrence of partial wear and fatigue failure can be suppressed. Further, only one of the inner ring 52 and the middle ring 53 is sequentially rotated in one direction (or the reverse direction), so that only one of the inner ring 52 and the middle ring 53 is in one direction (or the reverse direction). ), The grease is agitated and the grease lubrication in the rolling bearing is maintained.

<Other embodiments>
In the fifth embodiment, the rolling bearing 51 in which the two rolling bearings 11A and 11B in the first embodiment are integrated is shown. Of course, in this embodiment, the two rolling bearings shown in the second, third, and fourth embodiments are naturally used. It is good also as a rolling bearing which integrated the bearing. Similarly to the rolling bearing 51 shown in FIG. 10A, the rolling bearing in this case also includes an inner ring 52, an intermediate ring 53, an outer ring 54, and a plurality of balls 15 inserted so as to be able to roll therebetween. Furthermore, the retainer 22 and the shield plate 23 or the retainer 32 shown in the second, third, and fourth embodiments so that the rollable directions of the balls 15 to be held are opposite to each other. Or the holder | retainer 42 should just be arrange | positioned.

  Even in the integrated rolling bearing of the above configuration, by using the two cages 22 and the shield plate 23 (or the cage 32 or the cage 42) in which the rolling direction of the balls 15 is opposite, When the rolling state of the ball 15 is controlled and the shaft 2 rotates in one direction, only one of the inner ring 52 and the middle ring 53 can rotate, and the shaft 2 rotates in the reverse direction. Only one of the inner ring 52 and the middle ring 53 can be rotated. Accordingly, when the shaft 2 is swung, only one of the inner ring 52 and the middle wheel 53 is sequentially rotated in one direction (or the reverse direction) only when the shaft 2 is rotated in one direction (or the reverse direction). As a result, a load is not applied only to a specific portion, and the occurrence of partial wear and fatigue failure can be suppressed. Further, only one of the inner ring 52 and the middle ring 53 is sequentially rotated in one direction (or the reverse direction), so that only one of the inner ring 52 and the middle ring 53 is in one direction (or the reverse direction). ), The grease is agitated and the grease lubrication in the rolling bearing is maintained.

<Fourth embodiment>
In FIG. 3, as an example, the configuration of the swing motor is illustrated on the assumption that the bearing 6 (the rolling bearing 11 </ b> A and the rolling bearing 11 </ b> B) illustrated in the first embodiment is applied. By applying the bearing structures shown in the other embodiments, a swing motor using these bearing structures can be configured.
Hereinafter, the structure and operation of the swing motor using these bearing structures, including the case of the first embodiment, will be described.

  As described in the first embodiment, the swing motor 1 shown in FIG. 3 has the shaft 2 supported by the bearing structure described above. For example, in the case of the bearing structure shown in Examples 1 to 4, as shown in FIG. 3, the inner diameter side rolling bearing and the outer diameter side rolling bearing are doubled in the diametrical direction via the intermediate ring 12. It is built and the shaft 2 is supported. Further, in the case of the bearing structure shown in Example 5 and the like, the shaft 2 is supported by using one rolling bearing. These bearing structures are preferably arranged on both the direct connection side (right side in FIG. 3) and the anti-direct connection side (right side in FIG. 3) of the shaft 2, but either the direct connection side or the anti-direct connection side of the shaft 2 It is good also as a structure arrange | positioned.

  In the oscillating motor 1 having the above-described bearing structure, as described in the above embodiment, the inner diameter side rolling bearing or inner ring allows the rotation of the shaft 2 only in one circumferential direction, and the outer diameter side rolling bearing. Alternatively, the middle wheel allows rotation of the shaft 2 only in the reverse circumferential direction. Therefore, when the shaft 2 is swung, when the shaft 2 is rotated in one circumferential direction, only the inner diameter side rolling bearing or inner ring rotates, and when the shaft 2 is rotated in the opposite circumferential direction. Only the rolling bearing or the middle ring 4 on the outer diameter side rotates.

  When the shaft 2 is swung, the rolling bearing or inner ring on the inner diameter side sequentially rotates in one direction only when the shaft 2 is rotated in one circumferential direction, so that a load acts only on a specific portion. No, it is possible to suppress the occurrence of partial wear and fatigue failure. In addition, when the rolling bearing or inner ring on the inner diameter side sequentially rotates in one direction, the rolling bearing or inner ring on the inner diameter side rotates around the entire circumference in one direction. Even if not provided, the grease is agitated and the grease lubrication at the inner diameter side rolling bearing or inner ring is maintained.

  Similarly, when the shaft 2 is swung, only when the shaft 2 is rotated counterclockwise in the reverse circumferential direction, the rolling bearing or the middle wheel on the outer diameter side sequentially rotates in the reverse direction. Only the load does not work, and the occurrence of partial wear and fatigue failure can be suppressed. In addition, since the outer diameter side rolling bearing or the middle ring rotates sequentially in the reverse direction, the outer diameter side rolling bearing or the middle ring rotates around the entire circumference in the opposite direction. Even if a forced oiling device or the like is not separately provided, the grease is agitated and the grease lubrication at the outer diameter side rolling bearing is maintained.

  The bearing structure according to the present invention is suitable for a swing motor, but can be applied not only to a swing motor but also to other devices as long as it supports a shaft that performs a swing motion. Is.

It is a perspective view of an oscillating rotating electrical machine. It is a figure which shows the bearing structure of a rocking | swiveling rotary electric machine, (a) is a slide bearing, (b) is a rolling bearing. It is a schematic block diagram of the rocking | swiveling rotary electric machine which concerns on this invention. It is a figure which shows an example (Example 1) of the bearing structure which concerns on this invention. It is a figure explaining operation | movement of the bearing structure shown in FIG. It is a figure which shows another example (Example 2) of the bearing structure which concerns on this invention. It is a figure explaining operation | movement of the bearing structure shown in FIG. It is a figure which shows another example (Example 3) of the bearing structure which concerns on this invention. It is a figure which shows another example (Example 4) of the bearing structure which concerns on this invention. It is a figure which shows another example (Example 5) of the bearing structure which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Swing motor 2 Shaft 3 Rotor 4 Stator 5 Frame 6 Bearing structure 7 Bracket 11A Rolling bearing 11B Rolling bearing 12 Intermediate ring 13 Inner ring 14 Outer ring 15 Ball 18 Cage 21A Rolling bearing 22 Cage 23 Shield plate 31A Rolling bearing 32 Cage 33 Partition member 41A Rolling bearing 42 Cage 43 Partition member 51 Rolling bearing 52 Inner ring 53 Middle ring 54 Outer ring

Claims (21)

A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a first outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. A plurality of inserted first balls, a first holding member inserted between an outer peripheral surface of the first inner ring and an inner peripheral surface of the first outer ring, and holding the first ball in a rollable manner; A first rolling bearing comprising:
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls inserted between the second inner ring outer peripheral track and the second outer ring inner peripheral track, and inserted between the outer peripheral surface of the second inner ring and the inner peripheral surface of the second outer ring. A bearing structure comprising a second rolling bearing provided with a second holding member that holds the second ball in a rollable manner;
The first holding member rolls the first ball so as to allow rotation of the first rolling bearing only in one circumferential direction,
The second holding member rolls the second ball so as to allow rotation of the second rolling bearing only in a circumferential direction opposite to the one circumferential direction. . A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a first outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. A plurality of first balls that are inserted between a plurality of inserted first balls, and an outer peripheral surface of the first inner ring and an inner peripheral surface of the first outer ring, and hold the first ball in a rollable manner. A first rolling bearing comprising a first holding member having a space;
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls inserted between the second inner ring outer peripheral track and the second outer ring inner peripheral track, and inserted between the outer peripheral surface of the second inner ring and the inner peripheral surface of the second outer ring. And a second rolling bearing provided with a second holding member having a plurality of second holding spaces for holding the second balls in a rollable manner,
When the first ball rolls in one circumferential direction of the bearing, the first holding space moves the first ball to an appropriate first position of the first inner ring outer circumferential track and the first outer ring inner circumferential track. When the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first allowing portion that allows rotation of the first rolling bearing and the first rolling bearing from the first position is provided. A first stop portion that separates the balls and stops the rotation of the first rolling bearing;
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is disposed at an appropriate second position of the second inner ring outer circumferential track and the second outer ring inner circumferential track. And when the second ball rolls in the one circumferential direction, the second ball is separated from the second position, and the second ball is allowed to rotate. A bearing structure comprising: a second stopping portion for stopping rotation of the second rolling bearing. The bearing structure according to claim 2,
The first permissible portion is formed adjacent to the first vertical surface perpendicular to the circumferential direction of the bearing and the first vertical surface, and is parallel to the circumferential direction of the bearing. A first parallel surface disposed at a radial distance of the first ball from the center of one ball, and when the first ball rolls in the one circumferential direction, the first ball is the first ball The first ball is arranged at the first position by contacting a vertical plane and the first parallel plane,
The first restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the first ball in the axial direction of the bearing, and faces the first vertical surface in the opposite circumferential direction. The first small vertical surface disposed on the side, the first parallel surface and the first small vertical surface are formed adjacent to each other and have an acute inclination angle with respect to the circumferential direction of the bearing. When the first ball rolls in the opposite circumferential direction, the first ball comes into contact with the first small vertical surface and the first inclined surface, so that the first ball moves from the first position. To separate the first ball,
The second permissible part is formed adjacent to the second vertical surface perpendicular to the circumferential direction of the bearing and the second vertical surface, and is parallel to the circumferential direction of the bearing. A second parallel surface arranged at a radial distance of the second ball from the center of the two balls, and when the second ball rolls in the opposite circumferential direction, the second ball is the second ball The second ball is arranged at the second position by contacting a vertical plane and the second parallel plane,
The second restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the second vertical surface to the one circumferential direction. A second small vertical surface disposed on the side, adjacent to the second parallel surface and the second small vertical surface, and having an acute inclination angle with respect to the circumferential direction of the bearing. When the second ball rolls in the one circumferential direction, the second ball comes into contact with the second small vertical surface and the second inclined surface, so that the second ball moves from the second position. A bearing structure that separates the second balls. The bearing structure according to claim 3,
In the first holding space, the first parallel surface, the first inclined surface, and the first small vertical surface in the adjacent first holding spaces are the outer peripheral surface of the first inner ring and the inner periphery of the first outer ring. It is formed so as to be opposite to each other with respect to the center line with the surface,
In the second holding space, the second parallel surface, the second inclined surface, and the second small vertical surface in the adjacent second holding spaces are the outer peripheral surface of the second inner ring and the inner periphery of the second outer ring. A bearing structure, wherein the bearing structure is formed so as to be opposite to each other with respect to the center line with the surface. A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a second outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. A plurality of first balls that are inserted between a plurality of inserted first balls, and an outer peripheral surface of the first inner ring and an inner peripheral surface of the first outer ring, and hold the first ball in a rollable manner. A first rolling bearing comprising: a first holding member having a space; and a first sealing member that encloses grease between an outer peripheral surface of the first inner ring and an inner peripheral surface of the first outer ring;
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls inserted between the second inner ring outer peripheral track and the second outer ring inner peripheral track, and inserted between the outer peripheral surface of the second inner ring and the inner peripheral surface of the second outer ring. In addition, grease is enclosed between a second holding member having a plurality of second holding spaces for holding the second ball in a rollable manner, and an outer peripheral surface of the second inner ring and an inner peripheral surface of the second outer ring. A second rolling bearing provided with a second enclosing member that comprises:
The first holding member has a first locked protrusion that protrudes from the opposite surface of the first holding space and has a first locked surface that is parallel to the diameter direction of the bearing,
The first enclosing member protrudes from the surface of the first enclosing member on the side of the first locked protrusion, and has a first locking surface facing the first locked surface. Having a protrusion,
When the first ball rolls in one circumferential direction of the bearing, the first holding space moves the first ball to an appropriate first position of the first inner ring outer circumferential track and the first outer ring inner circumferential track. When the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first allowing portion that allows rotation of the first rolling bearing and the first rolling bearing from the first position is provided. The ball is separated, the first holding member is moved to the first enclosing member side by the first ball, the first locked protrusion is locked to the first locking protrusion, and the A first stop portion for stopping the rotation of the first rolling bearing,
The second holding member has a second locked protrusion protruding from the opposite surface of the second holding space and having a second locked surface parallel to the diameter direction of the bearing,
The second enclosing member protrudes from the surface of the second enclosing member on the side of the second locked protrusion, and has a second locking surface facing the second locked surface. Having a protrusion,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is disposed at an appropriate second position of the second inner ring outer circumferential track and the second outer ring inner circumferential track. And when the second ball rolls in the one circumferential direction, the second ball is separated from the second position, and the second ball is allowed to rotate. The second holding member is moved to the second enclosing member side by the second ball, the second locked protrusion is locked to the second locking protrusion, and the second rolling bearing is rotated. A bearing structure comprising: a second stopping portion for stopping. The bearing structure according to claim 5,
The first permissible portion is formed adjacent to the first vertical surface perpendicular to the circumferential direction of the bearing and the first vertical surface, and is parallel to the circumferential direction of the bearing. A first parallel surface disposed at a radial distance of the first ball from the center of one ball, and when the first ball rolls in the one circumferential direction, the first ball is the first ball The first ball is arranged at the first position by contacting a vertical plane and the first parallel plane,
The first restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the first vertical surface in the opposite circumferential direction. The first small vertical surface disposed on the side, the first parallel surface and the first small vertical surface are formed adjacent to each other and have an acute inclination angle with respect to the circumferential direction of the bearing. When the first ball rolls in the opposite circumferential direction, the first ball comes into contact with the first small vertical surface and the first inclined surface, so that the first ball moves from the first position. The first ball is separated, the first holding member is pressed by the first ball, and the first locked protrusion is moved together with the first holding member to the first enclosing member side,
The second allowing portion is formed adjacent to the second vertical surface perpendicular to the circumferential direction of the bearing and the second vertical surface, and is parallel to the circumferential direction of the bearing. A second parallel surface arranged at a radial distance of the second ball from the center of the two balls, and when the second ball rolls in the opposite circumferential direction, the second ball is the second ball The second ball is arranged at the second position by contacting a vertical plane and the second parallel plane,
The second restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the second vertical surface to the one circumferential direction. A second small vertical surface disposed on the side, adjacent to the second parallel surface and the second small vertical surface, and having an acute inclination angle with respect to the circumferential direction of the bearing. When the second ball rolls in the one circumferential direction, the second ball comes into contact with the second small vertical surface and the second inclined surface, so that the second ball moves from the second position. The second ball is separated, the second holding member is pressed by the second ball, and the second locked protrusion is moved to the second enclosing member side together with the second holding member. Bearing structure characterized by. A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a second outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. It has a plurality of first balls inserted and a plurality of first partition members supported on the inner peripheral surface of the first outer ring, and the first balls can roll between the first partition members. A first rolling bearing comprising a first holding member that forms a plurality of first holding spaces to be held;
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls inserted between the second inner ring outer peripheral track and the second outer ring inner track, and a plurality of second partition members supported by the inner peripheral surface of the second outer ring, A bearing structure comprising a second rolling bearing provided with a second holding member that forms a plurality of second holding spaces that hold the second balls in a rollable manner between the second partition members,
When the first ball rolls in one circumferential direction of the bearing, the first holding space moves the first inner space to a first position in contact with both the first inner ring outer circumferential track and the first outer ring inner circumferential track. A first allowing portion for allowing the ball to be arranged and allowing the rotation of the first rolling bearing; and when the first ball rolls in a circumferential direction opposite to the one circumferential direction, A first stop portion that presses a ball toward the outer circumference track side of the first inner ring and stops the rotation of the first rolling bearing;
When the second ball rolls in the opposite circumferential direction, the second holding space moves the second ball to a second position in contact with both the second inner ring outer circumferential track and the second outer ring inner circumferential track. A second allowing portion for allowing the second rolling bearing to rotate, and an outer periphery of the second inner ring when the second ball rolls in the one circumferential direction. A bearing structure comprising: a second stop portion that presses against the raceway side to stop the rotation of the second rolling bearing. The bearing structure according to claim 7,
The first permissible portion has a first vertical surface perpendicular to the circumferential direction of the bearing on a surface on the opposite circumferential direction side of the first partition member, and the first ball extends in the one circumferential direction. When rolling, by allowing the first ball to contact the first vertical surface, the first ball is allowed to be placed in the first position;
The first restraining portion is perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the first partition member, and has a width smaller than the diameter of the first ball in the diameter direction of the bearing. A first small vertical surface, and an inclined angle that protrudes from the first small vertical surface to the one circumferential direction side and to the inner peripheral surface side of the first outer ring and is acute with respect to the inner peripheral surface of the first outer ring And when the first ball rolls in the opposite circumferential direction, the first ball is brought into contact with the first small vertical surface and the first inclined surface, Pressing the first ball toward the outer circumference of the first inner ring,
The second permissible portion has a second vertical surface perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the second partition member, and the second ball is in the opposite circumferential direction. When rolling, by allowing the second ball to contact the second vertical surface, the second ball is allowed to be placed in the second position;
The second stop portion is perpendicular to the circumferential direction of the bearing on the opposite circumferential surface of the second partition member, and has a width smaller than the diameter of the second ball in the diameter direction of the bearing. A second small vertical surface, and an inclined angle that is projected from the second small vertical surface to the opposite circumferential direction side and the inner peripheral surface side of the second outer ring, and is acute with respect to the inner peripheral surface of the second outer ring And when the second ball rolls in the one circumferential direction, by bringing the second ball into contact with the second small vertical surface and the second inclined surface, A bearing structure characterized in that the second ball is pressed toward the outer circumference raceway side of the second inner ring. A first inner ring having a first inner ring outer peripheral track on the outer peripheral surface, a first outer ring having a second outer ring inner peripheral track on the inner peripheral surface, and an intermediate between the first inner ring outer peripheral track and the first outer ring inner peripheral track. It has a plurality of first balls inserted and a plurality of first partition members supported on the outer peripheral surface of the first inner ring, and holds the first balls between the first partition members so that they can roll. A first rolling bearing provided with a first holding member that forms a plurality of first holding spaces.
Holding the first outer ring directly or indirectly on the inner peripheral surface, a second inner ring having a second inner ring outer peripheral track on the outer peripheral surface, and a second outer ring having a second outer ring inner peripheral track on the inner peripheral surface; A plurality of second balls interposed between the second inner ring outer circumferential track and the second outer ring inner circumferential track, and a plurality of second partition members supported on the outer circumferential surface of the second inner ring, A bearing structure comprising a second rolling bearing provided with a second holding member that forms a plurality of second holding spaces that hold the second balls in a rollable manner between the second partition members,
When the first ball rolls in one circumferential direction of the bearing, the first holding space moves the first inner space to a first position in contact with both the first inner ring outer circumferential track and the first outer ring inner circumferential track. A first allowing portion for allowing the ball to be arranged and allowing the rotation of the first rolling bearing; and when the first ball rolls in a circumferential direction opposite to the one circumferential direction, A first stopping portion that presses the ball toward the inner raceway side of the first outer ring and stops the rotation of the first rolling bearing;
When the second ball rolls in the opposite circumferential direction, the second holding space moves the second ball to a second position in contact with both the second inner ring outer circumferential track and the second outer ring inner circumferential track. A second allowing portion for allowing the second rolling bearing to rotate, and the second ball in the second outer ring when the second ball rolls in the one circumferential direction. A bearing structure comprising: a second stopping portion that presses against a circumferential track side and stops the rotation of the second rolling bearing. The bearing structure according to claim 9,
The first permissible portion has a first vertical surface perpendicular to the circumferential direction of the bearing on a surface on the opposite circumferential direction side of the first partition member, and the first ball extends in the one circumferential direction. When rolling, by allowing the first ball to contact the first vertical surface, the first ball is allowed to be placed in the first position;
The first restraining portion is perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the first partition member, and has a width smaller than the diameter of the first ball in the diameter direction of the bearing. A first small vertical surface; and a first inclined surface extending from the first small vertical surface toward the one circumferential direction side and the outer peripheral surface side of the first inner ring, and has an acute inclination angle with respect to the outer peripheral surface of the first inner ring. A first inclined surface, and when the first ball rolls in the opposite circumferential direction, the first ball is brought into contact with the first small vertical surface and the first inclined surface. One ball is pressed toward the inner circumference track of the first outer ring,
The second permissible portion has a second vertical surface perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the second partition member, and the second ball is in the opposite circumferential direction. When rolling, the second ball is brought into contact with the second vertical surface, and the second ball is allowed to be arranged at the second position;
The second stop portion is perpendicular to the circumferential direction of the bearing on the opposite circumferential surface of the second partition member and has a width smaller than the diameter of the second ball in the diameter direction of the bearing. A second small vertical surface, and projects from the second small vertical surface to the opposite circumferential direction side and the outer peripheral surface side of the second inner ring, and has an acute inclination angle with respect to the outer peripheral surface of the second inner ring. A second inclined surface, and when the second ball rolls in the opposite circumferential direction, the second ball is brought into contact with the second small vertical surface and the second inclined surface. A bearing structure characterized in that two balls are pressed against the inner circumferential track side of the second outer ring. An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A first holding member that is inserted between an outer peripheral surface of the inner ring and an inner peripheral surface of the middle ring, and holds the first ball in a rollable manner; an outer peripheral surface of the intermediate ring; and an inner periphery of the outer ring A bearing structure comprising a rolling bearing provided with a second holding member inserted between the second holding member and capable of rolling the second ball,
The first holding member rolls the first ball so as to allow rotation of the inner ring only in one circumferential direction,
The bearing structure, wherein the second holding member rolls the second ball so as to allow rotation of the middle wheel only in a circumferential direction opposite to the one circumferential direction. An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A first holding member that is inserted between an outer peripheral surface of the inner ring and an inner peripheral surface of the middle ring and has a plurality of first holding spaces that hold the first ball in a rollable manner; A bearing structure comprising a rolling bearing provided with a second holding member inserted between an outer peripheral surface and an inner peripheral surface of the outer ring and having a plurality of second holding spaces for holding the second balls in a rollable manner. Because
When the first ball rolls in one circumferential direction of the bearing, the first holding space allows the first ball to be disposed at an appropriate first position of the inner ring outer circumferential track and the middle ring inner circumferential track. When the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first ball is separated from the first position. And a first stop portion for stopping the rotation of the first rolling bearing,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is arranged at an appropriate second position of the middle ring outer circumferential track and the outer ring inner circumferential track, A second permissible portion allowing rotation of the second rolling bearing; and when the second ball rolls in the one circumferential direction, the second ball is separated from the second position, and the second rolling A bearing structure comprising: a second restraining portion that restrains rotation of the bearing. The bearing structure according to claim 12,
The first permissible portion is formed adjacent to the first vertical surface perpendicular to the circumferential direction of the bearing and the first vertical surface, and is parallel to the circumferential direction of the bearing. A first parallel surface disposed at a radial distance of the first ball from the center of one ball, and when the first ball rolls in the one circumferential direction, the first ball is the first ball The first ball is arranged at the first position by contacting a vertical plane and the first parallel plane,
The first restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the first ball in the axial direction of the bearing, and faces the first vertical surface in the opposite circumferential direction. The first small vertical surface disposed on the side, the first parallel surface and the first small vertical surface are formed adjacent to each other and have an acute inclination angle with respect to the circumferential direction of the bearing. When the first ball rolls in the opposite circumferential direction, the first ball comes into contact with the first small vertical surface and the first inclined surface, so that the first ball moves from the first position. To separate the first ball,
The second permissible part is formed adjacent to the second vertical surface perpendicular to the circumferential direction of the bearing and the second vertical surface, and is parallel to the circumferential direction of the bearing. A second parallel surface arranged at a radial distance of the second ball from the center of the two balls, and when the second ball rolls in the opposite circumferential direction, the second ball is the second ball The second ball is arranged at the second position by contacting a vertical plane and the second parallel plane,
The second restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the second vertical surface to the one circumferential direction. A second small vertical surface disposed on the side, adjacent to the second parallel surface and the second small vertical surface, and having an acute inclination angle with respect to the circumferential direction of the bearing. When the second ball rolls in the one circumferential direction, the second ball comes into contact with the second small vertical surface and the second inclined surface, so that the second ball moves from the second position. A bearing structure that separates the second balls. The bearing structure according to claim 13,
In the first holding space, the first parallel surface, the first inclined surface, and the first small vertical surface in the adjacent first holding spaces are an outer peripheral surface of the inner ring and an inner peripheral surface of the middle wheel. It is formed to be opposite to each other with respect to the center line,
In the second holding space, the second parallel surface, the second inclined surface, and the second small vertical surface in the adjacent second holding spaces are formed between the outer peripheral surface of the middle wheel and the inner peripheral surface of the outer ring. A bearing structure formed so as to be opposite to each other with respect to a center line. An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A first holding member that is inserted between an outer peripheral surface of the inner ring and an inner peripheral surface of the middle ring and has a plurality of first holding spaces that hold the first ball in a rollable manner; A second holding member inserted between an outer peripheral surface and an inner peripheral surface of the outer ring and having a plurality of second holding spaces for holding the second ball in a rollable manner; an outer peripheral surface of the inner ring; A first enclosing member that encloses grease between the inner peripheral surface of the ring and a second enclosing member that encloses grease between the outer peripheral surface of the middle wheel and the inner peripheral surface of the outer ring; And a bearing structure formed by a rolling,
The first holding member has a first locked protrusion that protrudes from the opposite surface of the first holding space and has a first locked surface that is parallel to the diameter direction of the bearing,
The first enclosing member protrudes from the surface of the first enclosing member on the side of the first locked protrusion, and has a first locking surface facing the first locked surface. Having a protrusion,
When the first ball rolls in one circumferential direction of the bearing, the first holding space allows the first ball to be disposed at an appropriate first position of the inner ring outer circumferential track and the middle ring inner circumferential track. When the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first ball is separated from the first position. And the first ball is moved to the first enclosing member side by the first ball, and the first locking projection is locked to the first locking projection, so that the first rolling is performed. Comprising a first stop to stop the rotation of the bearing,
The second holding member has a second locked protrusion protruding from the opposite surface of the second holding space and having a second locked surface parallel to the diameter direction of the bearing,
The second enclosing member protrudes from the surface of the second enclosing member on the side of the second locked protrusion, and has a second locking surface facing the second locked surface. Having a protrusion,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is arranged at an appropriate second position of the middle ring outer circumferential track and the outer ring inner circumferential track, A second permissible portion allowing rotation of the second rolling bearing; and when the second ball rolls in the one circumferential direction, the second ball is separated from the second position, and the second ball The second holding member is moved to the second enclosing member side by the step, the second locked protrusion is locked to the second locking protrusion, and the rotation of the second rolling bearing is stopped. 2. A bearing structure comprising two stop portions. The bearing structure according to claim 15,
The first permissible portion is formed adjacent to the first vertical surface perpendicular to the circumferential direction of the bearing and the first vertical surface, and is parallel to the circumferential direction of the bearing. A first parallel surface disposed at a radial distance of the first ball from the center of one ball, and when the first ball rolls in the one circumferential direction, the first ball is the first ball The first ball is arranged at the first position by contacting a vertical plane and the first parallel plane,
The first restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the first vertical surface in the opposite circumferential direction. The first small vertical surface disposed on the side, the first parallel surface and the first small vertical surface are formed adjacent to each other and have an acute inclination angle with respect to the circumferential direction of the bearing. When the first ball rolls in the opposite circumferential direction, the first ball comes into contact with the first small vertical surface and the first inclined surface, so that the first ball moves from the first position. The first ball is separated, the first holding member is pressed by the first ball, and the first locked protrusion is moved together with the first holding member to the first enclosing member side,
The second permissible part is formed adjacent to the second vertical surface perpendicular to the circumferential direction of the bearing and the second vertical surface, and is parallel to the circumferential direction of the bearing. A second parallel surface arranged at a radial distance of the second ball from the center of the two balls, and when the second ball rolls in the opposite circumferential direction, the second ball is the second ball The second ball is arranged at the second position by contacting a vertical plane and the second parallel plane,
The second restraining portion is perpendicular to the circumferential direction of the bearing, has a width smaller than the diameter of the second ball in the axial direction of the bearing, and faces the second vertical surface to the one circumferential direction. A second small vertical surface disposed on the side, adjacent to the second parallel surface and the second small vertical surface, and having an acute inclination angle with respect to the circumferential direction of the bearing. When the second ball rolls in the one circumferential direction, the second ball comes into contact with the second small vertical surface and the second inclined surface, so that the second ball moves from the second position. The second ball is separated, the second holding member is pressed by the second ball, and the second locked protrusion is moved to the second enclosing member side together with the second holding member. Bearing structure characterized by. An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A plurality of first partitioning members supported on the inner peripheral surface of the middle wheel, and a plurality of first holding spaces for holding the first balls in a rollable manner between the first partitioning members; A plurality of second holding members and a plurality of second partition members supported on the inner peripheral surface of the outer ring, and a plurality of second members which hold the second balls between the second partition members so as to roll. A bearing structure comprising a rolling bearing provided with a second holding member forming a holding space,
In the first holding space, when the first ball rolls in one circumferential direction of the bearing, the first ball is arranged at a first position in contact with both the inner ring outer circumferential track and the middle ring inner circumferential track. A first allowing portion for allowing the inner ring to rotate, and when the first ball rolls in a circumferential direction opposite to the one circumferential direction, A first stop portion that presses the inner ring and stops the rotation of the inner ring,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is arranged at a second position in contact with both the middle wheel outer circumferential track and the outer ring inner circumferential track. And when the second ball rolls in the one circumferential direction, the second ball is pressed toward the outer circumferential track side of the middle wheel. A bearing structure comprising: a second stop portion for stopping rotation of the middle wheel. The bearing structure according to claim 17,
The first permissible portion has a first vertical surface perpendicular to the circumferential direction of the bearing on a surface on the opposite circumferential direction side of the first partition member, and the first ball extends in the one circumferential direction. When rolling, by allowing the first ball to contact the first vertical surface, the first ball is allowed to be placed in the first position;
The first restraining portion is perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the first partition member, and has a width smaller than the diameter of the first ball in the diameter direction of the bearing. A first small vertical surface; and a first inclined surface projecting from the first small vertical surface toward the one circumferential direction side and the inner peripheral surface side of the middle wheel, and has an acute inclination angle with respect to the inner peripheral surface of the middle wheel. A first inclined surface, and when the first ball rolls in the opposite circumferential direction, the first ball is brought into contact with the first small vertical surface and the first inclined surface. 1 ball is pressed against the inner ring outer circumference track side,
The second permissible portion has a second vertical surface perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the second partition member, and the second ball is in the opposite circumferential direction. When rolling, by allowing the second ball to contact the second vertical surface, the second ball is allowed to be placed in the second position;
The second stop portion is perpendicular to the circumferential direction of the bearing on the opposite circumferential surface of the second partition member, and has a width smaller than the diameter of the second ball in the diameter direction of the bearing. A second small vertical surface and a second small vertical surface projecting from the second small vertical surface to the opposite circumferential direction side and the inner circumferential surface side of the outer ring and having an acute inclination angle with respect to the inner circumferential surface of the outer ring. The second ball is brought into contact with the second small vertical surface and the second inclined surface when the second ball rolls in the one circumferential direction. Is pressed against the outer peripheral track side of the middle wheel. An inner ring having an inner ring outer peripheral track on the outer peripheral surface, an intermediate ring having an inner ring inner peripheral track on the inner peripheral surface, an intermediate ring outer peripheral track on the outer peripheral surface, and an outer ring having an outer ring inner peripheral track on the inner peripheral surface; A plurality of first balls inserted between the inner ring outer periphery track and the middle ring inner periphery track; a plurality of second balls inserted between the middle wheel outer periphery track and the outer ring inner periphery track; A plurality of first partition members supported on the outer peripheral surface of the inner ring, and a plurality of first holding spaces that hold the first balls in a rollable manner between the first partition members; A plurality of second holding spaces that have a holding member and a plurality of second partition members supported on the outer peripheral surface of the middle wheel, and hold the second ball between the second partition members so as to allow rolling. A bearing structure comprising a rolling bearing provided with a second holding member forming
In the first holding space, when the first ball rolls in one circumferential direction of the bearing, the first ball is arranged at a first position in contact with both the inner ring outer circumferential track and the middle ring inner circumferential track. A first allowing portion that allows the inner ring to rotate, and when the first ball rolls in a circumferential direction opposite to the one circumferential direction, the first ball is moved into the middle ring. It consists of a first stop portion that presses against the circumferential track and stops the rotation of the inner ring,
In the second holding space, when the second ball rolls in the opposite circumferential direction, the second ball is arranged at a second position in contact with both the middle wheel outer circumferential track and the outer ring inner circumferential track. And when the second ball rolls in the one circumferential direction, the second ball is pressed toward the inner raceway side of the outer ring. A bearing structure comprising: a second stop portion for stopping rotation of the middle wheel. The bearing structure according to claim 19,
The first permissible portion has a first vertical surface perpendicular to the circumferential direction of the bearing on a surface on the opposite circumferential direction side of the first partition member, and the first ball extends in the one circumferential direction. When rolling, by allowing the first ball to contact the first vertical surface, the first ball is allowed to be placed in the first position;
The first restraining portion is perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the first partition member, and has a width smaller than the diameter of the first ball in the diameter direction of the bearing. A first small vertical surface and a first inclined surface projecting from the first small vertical surface toward the one circumferential direction side and the outer peripheral surface side of the inner ring and having an acute inclination angle with respect to the outer peripheral surface of the inner ring When the first ball rolls in the opposite circumferential direction, the first ball is brought into contact with the first small vertical surface and the first inclined surface, whereby the first ball is It is to be pressed to the inner ring inner track side,
The second permissible portion has a second vertical surface perpendicular to the circumferential direction of the bearing on the surface on the one circumferential direction side of the second partition member, and the second ball is in the opposite circumferential direction. When rolling, the second ball is brought into contact with the second vertical surface, and the second ball is allowed to be arranged at the second position;
The second stop portion is perpendicular to the circumferential direction of the bearing on the opposite circumferential surface of the second partition member and has a width smaller than the diameter of the second ball in the diameter direction of the bearing. A second small vertical surface and a second small vertical surface projecting from the second small vertical surface to the opposite circumferential direction side and the outer peripheral surface side of the middle wheel and having an acute inclination angle with respect to the outer peripheral surface of the middle wheel The second ball is brought into contact with the second small vertical surface and the second inclined surface when the second ball rolls in the opposite circumferential direction. Is pressed against the inner ring raceway side of the outer ring. An oscillating rotating electric machine that oscillates a rotating shaft,
21. An oscillating rotating electrical machine, wherein at least one side of the rotating shaft is held on an inner peripheral surface of the first inner ring or the inner ring of the bearing structure according to any one of claims 1 to 20.

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