JP5343457B2 - Roller bearing cage - Google Patents

Description

  The present invention relates to a crown type rolling bearing cage.

As a rolling bearing cage, Patent Document 1 discloses a pocket-shaped rolling bearing cage in which a plurality of pockets for accommodating rolling elements are provided at predetermined intervals on one side surface of an annular body, and pockets adjacent in the circumferential direction. There is disclosed a column having a back opening that opens on the back side opposite to the opening of the pocket and a through hole for a lubricant that communicates the back opening and the pocket.
JP-A-7-217659

  According to the rolling bearing cage of Patent Document 1 described above, the lubrication performance is improved by providing a through hole for the lubricant that communicates the back strip and the pocket. In this type of cage, Improvement of lubrication performance remains an important issue. If the lubrication performance is insufficient, cage noise is generated, and there is a problem that bearing vibration increases.

  Further, in the conventional resin cage, there is a problem that the clearance of the cage pocket changes due to a large deformation due to centrifugal force during high-speed rotation, making it difficult to secure grease.

  One of the objects of the present invention is to provide a rolling bearing cage in which the lubrication performance is greatly improved by considering the flow of the lubricant.

  Another object of the present invention is to provide a rolling bearing retainer in which displacement due to centrifugal force is reduced by paying attention to and reviewing the mass of the conventional claw tip shape.

A rolling bearing cage according to the present invention is a crown type rolling bearing cage in which a plurality of pockets for accommodating rolling elements are provided at predetermined intervals on one side surface of an annular body.
The outer diameter of the annular body is tapered so that the diameter decreases toward the opening of the pocket, and a lubricant reservoir that opens radially inward is provided on the back surface of the column portion formed between adjacent pockets. In addition, a through-hole that communicates between the lubricant reservoir and the pocket surface is provided, and a notch that enters the lubricant reservoir is provided on the opening surface side of the inner diameter of the annular body. The lubricant sealed in flows into the through hole from the lubricant reservoir, reaches the pocket through the through hole, is supplied to the rolling elements, and flows out from the lubricant reservoir to the inner diameter side, and It is characterized in that it is supplied to the rolling element even in the notch .

  Conventionally, the outer diameter of the annular body is a circumferential surface, and by making it tapered toward the opening of the pocket, the mass of the claw portion constituting the pocket is reduced. Thereby, the deformation | transformation and displacement of a nail | claw part by the centrifugal force at the time of high speed rotation reduce.

  Lubricant (for example, grease) is sealed in the lubricant reservoir in the initial state. The lubricant in the lubricant reservoir is prevented from moving radially outward by the surface on the outer diameter side of the column portion. Since the lubricant reservoir is opened inward in the radial direction, scattering of grease due to centrifugal force is suppressed, and the lubricant can easily move. In addition, since the through-hole that communicates the lubricant reservoir and the pocket surface is provided, the lubricant moves from the inside in the radial direction into the pocket and is easily supplied to the rolling part. .

  In addition to being encapsulated in the lubricant reservoir, the lubricant may be encapsulated in the same place as in the past, for example, between the claw portions of adjacent pockets, or may not be encapsulated in this portion. By encapsulating the lubricant in the same place as before, both sides are encapsulated from the back side and the front side (side where the pockets are open) of the cage, and the lubrication performance is further improved.

  Synthetic resin materials constituting the cage include polyamide resins such as nylon 66 and nylon 46, fluorine resins such as polytetrafluoroethylene (PTFE) and ethylene tetrafluoroethylene (ETFE), and polyether ether ketone (PEEK). ), Polyphenylene sulfide (PPS), polyethersulfone (PES), and the like. Reinforcing fibers such as glass fibers are added to these resins. In addition to the synthetic resin material, it is possible to use a metal material such as JIS standard SUS304 or brass.

  The inner / outer rings and rolling elements are appropriately made of JIS standard SUJ-2, SUS440C, SUS630, SAE standard 5120, or the like.

  In the rolling bearing retainer according to the present invention, it is preferable that a rib is formed at the rear end (surface opposite to the opening surface of the pocket) of the annular body outer diameter. The lubricant subjected to the centrifugal force moves to the rear side (radially outward) of the cage while being guided by the outer diameter of the annular body. Movement is prevented.

  In the rolling bearing retainer according to the present invention, it is preferable that a protrusion is formed on the inner diameter portion of the pocket. By forming a protrusion shape on the inner diameter surface of the pocket, the contact state between the ball and the inner diameter surface changes from line contact to point contact, a clearance is formed on the ball guide surface, and the flow of lubricant to the pocket surface is improved. .

  Furthermore, a notch extending from the opening of the pocket into the lubricant reservoir may be provided on the inner diameter of the annular body. In this way, in addition to the route passing through the through-hole, the lubricant can easily move from the radially inner side into the pocket along the surface of the annular body, and the radially inward direction to the rolling part of the lubricating oil. The supply from can be increased.

  According to the rolling bearing cage of the present invention, the outer diameter of the annular body is formed in a tapered shape with the diameter decreasing toward the opening of the pocket, thereby reducing the mass of the claw portion. Thereby, the deformation | transformation and displacement of a nail | claw part by the centrifugal force at the time of high speed rotation reduce. In addition, by enclosing the grease on the back side, scattering of the grease due to rotation is suppressed, and furthermore, by creating a flow of the lubricant that moves from the lubricant reservoir into the pocket through the through hole, the cage-rolling element The lubrication state in between is improved.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 shows a rolling bearing using a rolling bearing retainer according to the present invention. FIGS. 2 to 4 show a first embodiment of the rolling bearing retainer according to the present invention, and FIGS. FIG. 8 shows a second embodiment of a rolling bearing cage according to the present invention, and FIG. 8 shows a conventional rolling bearing cage. In the following description, the left and right refer to the left and right in FIG. The left is the opening side of the pocket, and the right is the opposite side (referred to as the back side).

  The rolling bearing (1) is a ball bearing and, as shown in FIG. 1, is made of, for example, nylon 66 disposed between the outer ring (2), the inner ring (3), and both the inner and outer rings (3) and (2). A crown type cage (4), a plurality of balls (rolling elements) (5) disposed between the inner and outer wheels (3) and (2) held by the cage (4), and both inner and outer wheels (3) ( 2) and a seal (6) disposed between the respective end portions.

  The cage (4) is an annular synthetic resin injection-molded product, and is provided with a plurality of predetermined intervals on one side of the annular body (11) and opens into one pocket (12) for accommodating balls (5). And a column part (13) formed between adjacent pockets (12), and a pocket (12) that protrudes in the axial direction of the annular body at both circumferential edges of each pocket (12) 1 A pair of claws (14).

  Each pocket (12) has a concave spherical pocket surface that is similar in shape to the ball (5) and has a slightly larger radius of curvature than the radius of curvature of the ball (5).

  The outer diameter (11a) of the annular body (11) is formed in a tapered shape whose diameter decreases toward the opening of the pocket (12). A rib (15) protruding outward in the radial direction is formed at the right end (back end) of the outer diameter (11a).

  On the back surface of each column portion (13), there is provided a lubricant reservoir (16) that opens radially inward and encloses a lubricant such as grease. The lubricant reservoir (16) is formed by removing a wall on the inner diameter side of a portion used as a back strip in the column portion in the conventional one. The wall on the outer diameter side remains, and the lubricant is difficult to move to the outer diameter side. The lubricant reservoir (16) and the pocket surface of the pocket (12) are communicated with each other through the through hole (20).

  In addition, a single projection (18) projecting inward from the pocket (12) is integrally formed at the inner diameter portion (the innermost portion of the inner ring (3) side edge) of the pocket surface of each pocket (12). ing. The protrusion (18) has a triangular shape with the inner ring (3) side as the bottom when viewed from the opening side of the pocket (12), and the height of the protrusion (18) is from the inner ring (3) side to the outer ring (2) side. Gradually lower. Further, the surface of the protrusion (18) is conical.

  FIG. 8 shows a cage (60) that is currently in common use. This retainer (60) is an annular synthetic resin injection-molded product, and a plurality of pockets (62) that are provided at predetermined intervals on one side of the annular body (61) and open to one side to receive balls, A pair of pillars (63) formed between adjacent pockets (62) and a pair of pockets (62) projecting in the axial direction of the annular body at both circumferential edges of each pocket (62) A claw portion (64) and a spine (65) formed in the column portion (63) so as to open to the right are provided.

  The cage (4) according to the present invention focuses on preventing deformation due to centrifugal force when optimizing the shape, and the displacement is reduced by reviewing the tip shape of the cage (4) and changing the shape. At the same time, focusing on the retention and flow of the lubricant, and changing the lubricant sealing position accordingly, the lubrication performance is improved. The cage (4) of the first embodiment has the following improvements over the conventional cage (60).

1. In order to reduce displacement due to centrifugal force, the outer diameter (11a) of the annular body (11), which was a conventional cylindrical surface, was cut into a taper shape to reduce the mass of the claw portion (14).

2. Lubricant reservoir (16) on the back of each column (13) so that lubricant can be sealed from the back side (enclosed on both sides) that could be sealed only from the opening side of the pocket (62). Was provided.

3. A rib (15) is provided on a part of the outer diameter (11a) of the cage (4), which has been a smooth surface in the past, so that the lubricant is not scattered radially outward by centrifugal force.

4). In order to make it easier for the lubricant to be supplied to the surface of the ball (5), a through-hole (20) for communicating the lubricant reservoir and the pocket surface was provided.

5. With the guide surface of the ball (5) as the inner diameter side, a protrusion (18) was provided on the inner diameter portion of the pocket (12) to suppress the clearance on the outer diameter side of the pocket (12).

  FIG. 4 shows the flow of the lubricant when the cage (4) thus obtained is used.

  In the figure, grease as a lubricant is sealed in a lubricant reservoir (16) on the back side. The grease sealed in the lubricant reservoir (16) is prevented from moving to the outer diameter side, and the pocket surface of the pocket (12) and the lubricant reservoir (16) communicate with each other through the through hole (20). First, as indicated by an arrow A, the lubricant flows from the lubricant reservoir (16) into the through hole (20) and reaches the pocket surface of the pocket (12) through the through hole (20). , Supplied to the ball (5). Next, as indicated by an arrow C, in the pocket (12), it is guided by the tapered outer diameter (11a) of the annular body (11) and axially outward along this (in the pocket, the radial direction due to the tapered shape). Move outward). Since the rib (15) is formed at the rear side end of the outer diameter (11a), the grease is prevented from moving outward in the axial direction by the rib 15) as shown by an arrow D. It can continue to contribute to the lubrication of the rolling part.

  Thus, with regard to the method of encapsulating the lubricant, the initial encapsulating position is changed to the lubricant reservoir (16), so that the lubricant can be easily supplied from the inside in the radial direction and can be easily held in the pocket (12). In addition, the cage (4) has a shape of the rib (15), the through-hole (20), etc., so that the lubricant is not easily scattered and the lubricant is between the ball (5) and the cage (4). Therefore, the flow of the lubricant can be optimized. Of course, in addition to the lubricant reservoir (16), the lubricant may also be enclosed between the claw portion (14) on the front side of the column portion (13) and the claw portion (14). It is.

  According to the protrusion (18) provided on the inner diameter part of the pocket (12), when the inner ring (3) of the ball bearing (1) rotates, the pocket (12) The outer ring (2) side edge of the ball contacts the ball (5), and the gap between the pocket (12) and the ball (5) gradually increases from the outer ring (2) side toward the inner ring (3) side. growing. Therefore, the lubricant adhering to the ball (5) enters the gap and is held in the gap. Thus, the scattering of the lubricant is also suppressed by the protrusion (18) in the inner diameter portion of the pocket (12).

  When FEM analysis was performed on the cage (4) of the first embodiment according to the present invention and the cage (60) shown in FIG. 8, the cage (60) shown in FIG. Due to the force, the claw part (64) is greatly deformed radially outward and in the direction in which the opening of the pocket (62) is enlarged, and the displacement due to centrifugal force is the tip shape (claw part) (64 It was confirmed that the degradation of the lubrication performance due to the scattering of the lubricant was great. On the other hand, according to the cage (4) of the present invention, it was confirmed that the displacement due to the centrifugal force during high-speed rotation is greatly reduced, and the lubrication performance inside the rolling bearing (1) is improved. Specifically, for example, when comparing the displacement at a rotational speed of 15000 r / min and a temperature of 150 ° C., the cage (4) according to the present invention is reduced by 27% compared to the current cage (60), When the stress was compared under the same conditions, it was confirmed that the cage (4) according to the present invention was reduced by 33% compared to the current cage (60).

  5 to 7 show a second embodiment of the rolling bearing retainer according to the present invention according to the present invention, FIG. 5 being FIG. 2, FIG. 6 being FIG. 3 and FIG. It corresponds. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  The cage (4) of this embodiment is obtained by adding a notch (17) on the opening surface side of the inner diameter of the annular body (11) to the one of the first embodiment.

  The notch (17) is a part in which the inner diameter of the cage (4), which has been a smooth cylindrical surface in the past, is partially cut, and enters the lubricant reservoir (16).

  Therefore, in the cage (4) of this embodiment, as shown in FIG. 7, the grease sealed in the lubricant reservoir (16) is prevented from moving to the outer diameter side, and the pocket (12 ) Pocket surface and the lubricant reservoir (16) communicate with each other through the through hole (20). First, as indicated by the arrow A, the lubricant flows into the through hole (20) from the lubricant reservoir (16). Then, it reaches the pocket surface of the pocket (12) through the through hole (20) and is supplied to the ball (5) (same as in the first embodiment). On the other hand, as shown by the arrow B, the grease sealed in the lubricant reservoir (16) flows out from the lubricant reservoir (16) to the inner diameter side, and also in the notch (17) of the column portion (13). (5) is supplied (difference from the first embodiment). The grease supplied to the balls (5) by these two routes is then guided to the tapered outer diameter (11a) of the annular body (11) in the pocket (12) as shown by the arrow C. Then, it moves axially outward (radially outward due to the taper shape) along this. Since the rib (15) is formed at the rear side end of the outer diameter (11a), the grease is prevented from moving outward in the axial direction by the rib 15) as shown by an arrow D. It can continue to contribute to the lubrication of the rolling part.

  According to the cage (4) of the second embodiment, it has all the improvements that the first embodiment has, and the notch (17) makes it easier than the first embodiment. Thus, the displacement is further reduced by the centrifugal force, and the lubricant is more easily supplied to the surface of the ball (5).

FIG. 1 is a partial longitudinal sectional view of a rolling bearing using a rolling bearing cage according to the present invention. FIG. 2 is a perspective view showing a first embodiment of a rolling bearing retainer according to the present invention. FIG. 3 is a partial longitudinal sectional view of the same. FIG. 4 is a partial cross-sectional view showing the flow of lubricant in the rolling bearing cage of the first embodiment. FIG. 5 is a perspective view showing a second embodiment of the rolling bearing retainer according to the present invention. FIG. 6 is a partial longitudinal sectional view of the same. FIG. 7 is a partial cross-sectional view showing the flow of the lubricant in the rolling bearing cage of the second embodiment. FIG. 8 is a partial longitudinal sectional view showing a conventional rolling bearing cage.

Explanation of symbols

(1) Ball bearing (rolling bearing)
(4) Cage
(5) Ball (rolling element)
(11) Toroid
(11a) Tapered outer diameter
(12) Pocket
(13) Column
(15) Rib
(16) Lubricant reservoir
(17) Notch
(20) Through hole

Claims (3)

In a crown-type rolling bearing retainer in which a plurality of pockets for accommodating rolling elements are provided at predetermined intervals on one side surface of an annular body,
The outer diameter of the annular body is tapered so that the diameter decreases toward the opening of the pocket, and a lubricant reservoir that opens radially inward is provided on the back surface of the column portion formed between adjacent pockets. In addition, a through-hole that communicates the lubricant reservoir and the pocket surface is provided, and a notch that enters the lubricant reservoir is provided on the opening surface side of the inner diameter of the annular body,
The lubricant sealed in the lubricant reservoir flows into the through hole from the lubricant reservoir, reaches the pocket through the through hole, is supplied to the rolling element, and flows out from the lubricant reservoir to the inner diameter side. A rolling bearing retainer which is supplied to a rolling element even in a notch in a column portion .   The rolling bearing retainer according to claim 1, wherein a rib is formed at a rear side end portion of the outer diameter of the annular body.   The rolling bearing retainer according to claim 1 or 2, wherein a protrusion is formed on an inner diameter portion of the pocket.

Images