JP3223376U - Non-rotating bearing - Google Patents

Abstract

[PROBLEMS] To stabilize a bearing over a long period of time by providing excellent assemblability (mountability) when fitting a stationary ring (outer ring) to a housing, and preventing early deterioration of a detent structure. In addition, the present invention provides a bearing with a detent that makes it possible to continue rotating with high accuracy. A rotation preventing structure for preventing relative rotation between a stationary wheel and a housing facing the rotating wheel is provided such that one of the peripheral surfaces of the stationary wheel and the housing is aligned along the central axis Ax of the stationary wheel. A convex portion P that protrudes in parallel with each other, and a concave portion G that accommodates the convex portion by engaging one of the peripheral surfaces of the stationary ring and the housing so as to be opposed to the convex portion and engage with each other. The concave portion has a concave side surface Gs on both sides in the circumferential direction, and the concave side surface is configured and arranged as an inclined surface inclined in a divergent form at a predetermined angle θ from the base point T on the central axis side toward the radially outer side. The base point is separated from the central axis along the radial direction by a predetermined distance, and the convex portion side surface and the concave portion side surface are in plane contact with each other. [Selection] Figure 1

Description

The present invention is, for example, in a state in which a rolling bearing is incorporated between a rotating body and a housing,
The present invention relates to a bearing with a detent having a detent structure for preventing relative rotation between a stationary wheel and a housing.

Conventionally, various rotation preventing structures for preventing relative rotation between the stationary wheel and the housing are applied to the bearing incorporated between the rotating body and the housing (see, for example, Patent Document 1). . As an example, the rotation prevention structure includes a convex portion formed on the inner periphery of the housing,
It is known to prevent relative rotation between a stationary wheel and a housing by engaging recesses formed on the outer periphery of the stationary wheel with each other.

More specifically, as shown in FIG. 4 (a), the bearing having a detent structure is a rotating body R.
A rotating wheel 2 (for example, an inner ring) that is fitted to a rotating shaft (also referred to as a rotating shaft) and a stationary wheel 4 that is disposed opposite to the outer periphery of the rotating wheel 2 and that is fitted and fixed to a housing H ( For example, a plurality of rolling elements 6 incorporated so as to roll along the outer ring) and between the rotating wheel 2 and the stationary ring 4 (between the inner and outer rings 2 and 4), and a cage for holding these rolling elements 6. 8 and. In addition, as a rolling element 6, "ball" or "roller" can be applied.

In the rotation preventing structure, the inner peripheral surface of the housing H extends along the center axis Ax (also referred to as a bearing or a rotating shaft of the rotating body R) of the above-described bearing (specifically, the stationary ring 4 (outer ring)). The convex part P formed by projecting partly in parallel and the outer peripheral surface of the stationary ring 4 (outer ring) are formed by partially denting the convex part P so as to face the convex part P. And the recessed part G which can be mutually engaged is provided. In this case, convex side surfaces Ps are formed on both sides in the circumferential direction of the convex portion P (both sides in the direction along the central axis Ax), and both circumferential sides of the concave portion G (direction along the central axis Ax). Concave side surface Gs is formed on both sides.

In such a configuration, a pair of convex side surfaces P formed on both sides of the convex portion P of the housing H.
s is a positional relationship parallel to each other along the direction orthogonal to the central axis Ax (specifically, the central axis A
x are orthogonal to each other and arranged in parallel with each other with respect to a virtual plane S extending in parallel along the central axis Ax. Further, the pair of recess side surfaces Gs formed on both sides of the recess G of the stationary wheel 4 (outer ring) are parallel to each other along the direction orthogonal to the central axis Ax (specifically, the above-described virtual plane S). With respect to each other). Thus, the convex side surface Ps and the concave side surface Gs are arranged to face each other in a parallel positional relationship.

JP 2007-92863 A

By the way, when the stationary wheel 4 (outer ring) is fitted into the housing H, an operation of assembling (attaching) the concave portion G formed in the stationary wheel 4 (outer ring) to the convex portion P formed in the housing H is performed. However, in order to improve the assemblability (attachability) at this time, the width dimension W2 of the recess G may be expanded (increased) in the circumferential direction rather than the width dimension W1 of the protrusion P. The width dimensions W1 and W2 are defined as values along the circumferential direction around the central axis Ax.

According to such a configuration, for example, as shown in FIG. 4B, the stationary wheel 4 (outer ring) and the housing H are connected while the bearing is rotating (that is, the rotating wheel 2 (inner ring) is rotating together with the rotating body R). When relatively rotated, both outer diameter ends Gt of the recess G of the stationary wheel 4 (outer ring) (also referred to as an edge or the tip of each recess side surface Gs) are formed on the protrusion side surface Ps of the protrusion P of the housing H. Contact (specifically, line contact,
Or, point contact). Depending on the degree of the contact pressure at this time, the contact surface pressure of the outer diameter end Gt of the concave portion G with respect to the convex side surface Ps increases locally, and as a result, the convex side surface Ps is damaged or damaged. There is a risk of doing.

Then, depending on the degree of damage and damage to the convex side surface Ps, the rotation preventing structure deteriorates early, and it is difficult to keep the stationary wheel 4 (outer ring) stably fitted and fixed to the housing H. As a result, there is a possibility that the bearing cannot be stably and accurately rotated over a long period of time.

The present invention has been made to solve such a problem, and its purpose is excellent in assembling (attachability) when a stationary ring (outer ring) is fitted to a housing, and an early stage of a rotation preventing structure. It is an object of the present invention to provide a bearing with a detent that makes it possible to stably rotate the bearing stably and accurately over a long period of time by preventing the deterioration of the bearing.

In order to achieve such an object, the present invention provides a rotating wheel that is fitted to a rotating body and rotates together, a stationary wheel that is disposed opposite to the rotating wheel and is fitted to a housing, and the stationary wheel. A bearing with a detent having a detent structure for preventing relative rotation between a ring and the housing, wherein the detent structure includes a peripheral surface of one of the stationary ring and the housing,
A convex part formed by projecting partly in parallel along the central axis of the stationary ring and a peripheral surface of one of the stationary ring and the housing facing the convex part and partially recessed. And is formed with a concave portion that accommodates the convex portion and that can be engaged with the convex portion with a gap in the circumferential direction. The convex portion extends around the central axis. Convex side surfaces are respectively configured on both sides in the circumferential direction, and the concave portions are respectively configured on both circumferential sides in the direction along the central axis, and the pair of concave side surfaces are the center. It is configured and arranged to form an inclined surface inclined in a divergent shape at a predetermined angle from one base point to the radially outer side, which is set on the shaft side, and the base point is the portion where the detent structure is configured It is set on the opposite side in the radial direction across the central axis, and the radial direction from the central axis Along the specified distance apart, if the said stationary ring and said housing is rotated relative the the convex portion side and the concave side surface, contacting the surface with each other.
In the present invention, the convex portions are configured such that the convex side surfaces are respectively formed on both sides in the circumferential direction along the central axis, and the pair of convex side surfaces are orthogonal to the central axis. When the stationary ring and the housing rotate relative to each other, the side surface of the convex portion and the side surface of the concave portion have a positional relationship parallel to each other. The predetermined angle is set so as to be maintained and in contact with each other in a planar shape.
In the present invention, the side surfaces of the pair of concave portions have a constant circumferential width of the concave portion, and when the predetermined distance is increased, the predetermined angle is decreased accordingly, and when the predetermined distance is decreased, The predetermined angle increases.
In the present invention, the stationary wheel projects a flange that is continuous in the circumferential direction along the radial direction from the outer periphery of the stationary wheel, and forms the concave portion and the pair of concave side surfaces on the flange.

According to the present invention, it is excellent in assembling (mounting property) when fitting a stationary wheel (outer ring) to a housing, and prevents the rotation preventing structure from being deteriorated at an early stage. It is possible to realize a bearing with a detent that makes it possible to continue rotating with high accuracy and stability.

(a) is a side view showing a configuration of a bearing with a rotation stopper according to an embodiment of the present invention, (b) is a bearing with a rotation stopper shown in FIG. The side view which shows the state which the housing rotated relatively. (a) is a perspective view which shows the structure of the stationary ring (outer ring) with which the bearing with a rotation prevention concerning one Embodiment of this invention was equipped, (b) is with the rotation prevention shown by the figure (a). In a bearing, the perspective view which shows the other structure of the stationary ring (outer ring) with which the bearing with a rotation stopper which concerns on one Embodiment of this invention was equipped. (a) is a side view showing the structure of a bearing with a rotation stopper according to a modification of the present invention, and (b) is a bearing with a rotation stopper shown in FIG. The side view which shows the state which rotated relatively. (a) is a side view showing a configuration of a conventional bearing with a rotation stopper, (b) is a bearing with a rotation stopper shown in FIG. (a), in which a stationary ring (outer ring) and a housing are relatively The side view which shows the state which rotated.

Hereinafter, a bearing with a detent according to an embodiment of the present invention will be described with reference to the accompanying drawings.
In addition, since this embodiment is an improvement of the bearing with a detent shown in FIG.
Only the improvements are explained. In this case, with respect to the same configuration as the bearing with the detent (FIG. 4 (a)), by adding the same reference numerals as the reference numerals attached to the configuration on the drawing used in this embodiment, The description is omitted (simplified).

As shown in FIGS. 1 (a), 1 (b) and 2 (a), in the bearing with a detent of this embodiment,
The non-rotating structure is such that one of the peripheral surfaces of the stationary wheel 4 and the housing H protrudes in parallel along the central axis Ax of the stationary wheel 4 (also referred to as a bearing or the rotating shaft of the rotating body R). The formed convex part P and the other peripheral surface of the stationary wheel 4 and the housing H are formed by partially indenting the convex part P so as to accommodate the convex part P and to engage with each other. And a concave portion G that can be mated.

In the present embodiment, as an example, the stationary wheel 4 is an outer ring, and is disposed opposite to the inner periphery of the stationary wheel 4 (outer ring) and is fitted to a rotating body R (also referred to as a rotating shaft) to rotate together. A rotation-preventing bearing is assumed in which the rotating wheel 2 is an inner ring. In addition, about the other structure in the said bearing, since it is the same as that of Fig.4 (a), the description is abbreviate | omitted.

In this case, the convex portion P is formed on the inner peripheral surface of the housing H by the above-described bearing (specifically, the stationary wheel 4
(Outer ring)) along the central axis Ax. On the other hand, the concave portion G is formed by partially denting the outer peripheral surface of the stationary ring 4 (outer ring) so as to face the convex portion P.
The convex part P is accommodated and it is comprised so that engagement with each other is possible. In addition, since the protrusion amount (protrusion length) of the convex portion P and the concave amount (depression depth) of the concave portion G are set according to the radial width (thickness) of the stationary ring 4 (outer ring), Here, numerical values are not particularly limited.

Further, the convex portion P is formed with convex side surfaces Ps on both sides in the circumferential direction around the central axis Ax, and the pair of convex side surfaces Ps are in a direction orthogonal to the central axis Ax. And a parallel positional relationship (specifically, a positional relationship that is orthogonal to the central axis Ax and parallel to the virtual plane S extending in parallel along the central axis Ax). Are arranged.

On the other hand, the concave portion G is formed with concave side surfaces Gs on both sides in the circumferential direction around the central axis Ax, and the pair of concave side surfaces Gs is one base point set on the central axis Ax side. It is configured and arranged to form an inclined surface inclined in a divergent shape at a predetermined angle θ from T toward the radially outer side. In other words, the pair of concave side surfaces Gs form inclined surfaces inclined in a divergent form at a predetermined inclination angle θ from the base point T toward the radially outer side on both sides of the virtual plane S described above. And arranged.

Here, one base point T set on the center axis Ax side is set on the opposite side in the radial direction across the center axis Ax from the portion where the rotation preventing structure is configured, and the base point T is the center axis Ax. And a predetermined distance δ along the radial direction. More specifically, a portion where the anti-rotation structure is formed (that is, a portion where the convex portion P and the concave portion G are formed) and the base point T are the virtual plane S described above.
, The portion where the convex portion P and the concave portion G are configured, and the base point T,
In this positional relationship, the base point T is placed opposite to both sides across the central axis Ax.
Is separated from the central axis Ax by a predetermined distance δ along the radial direction.

In this case, when the circumferential width of the recess G is set to a constant value and the distance δ from the central axis Ax to the base point T is increased, the inclination angle θ of the pair of recess side surfaces Gs can be reduced accordingly.
On the other hand, when the circumferential width of the recess G is set to a constant value and the distance δ from the central axis Ax to the base point T is decreased, the inclination angle θ of the pair of recess side surfaces Gs can be increased accordingly. In addition, since the magnitude change of the inclination angle θ of the pair of concave side surfaces Gs is set according to the size of the convex portion P, the width in the circumferential direction, etc., for example, the numerical value is not particularly limited here.

Here, assuming that the inclination angle θ of the pair of concave side surfaces Gs is set in accordance with, for example, the size and the circumferential width of the convex portion P, the rotating wheel 2 (inner ring) is fitted to the rotating body R. At the same time, by fitting the stationary ring 4 (outer ring) to the housing H, the stationary ring 4 (outer ring) and the housing H are relatively relative to each other in a state in which the bearing with a detent is assembled between the rotating body R and the housing H. When the rotation is performed, the convex portion P and the concave portion G are in contact with each other in a planar shape.

That is, when the stationary wheel 4 (outer ring) and the housing H rotate relatively, the convex side surface Ps formed in the convex portion P and the concave side surface Gs configured in the concave portion G are in a positional relationship parallel to each other. And in contact with each other in a planar manner. In this case, “contact in a planar shape” means the convex side surface P
s and the side surface Gs of a recessed part point to contacting each other without a line contact or a point contact, and without a gap.

As described above, according to the present embodiment, when the stationary wheel 4 (outer ring) is fitted into the housing H, the concave portion G formed in the stationary wheel 4 (outer ring) is assembled to the convex portion P formed in the housing H (see FIG. In order to improve the assembling property (attachability) of the work, the concave portion G is larger than the width dimension W1 of the convex portion P.
Even when the width dimension W2 is expanded (enlarged) along the circumferential direction (see FIG. 4A), the concave portion G
Each concave portion side surface Gs is directed radially outward from one base point T set on the central axis Ax side,
By forming and arranging the inclined surface inclined in a divergent shape at a predetermined angle θ, it is possible to realize an excellent effect that cannot be obtained from a conventional bearing with a rotation stopper.

That is, for example, as shown in FIG. 1B, when the stationary wheel 4 (outer ring) and the housing H rotate relatively while the bearing is rotating (the rotating wheel 2 (inner ring) is rotating together with the rotating body R). Since the convex side surface Ps formed in the convex portion P and the concave side surface Gs configured in the concave portion G maintain a parallel positional relationship with each other and contact each other in a planar shape, the convex side surface Ps However, the local contact pressure does not act on the surface, and as a result, it is possible to prevent the occurrence of the problem that the convex side surface Ps is broken or damaged.

Accordingly, it is possible to completely prevent a situation in which the rotation prevention structure is deteriorated at an early stage as in the prior art, so that the stationary wheel 4 (outer ring) can be stably fitted and fixed to the housing H. As a result, the bearing can be rotated stably and accurately over a long period of time.

Further, according to the present embodiment, the change in the inclination angle θ of the pair of recess side surfaces Gs described above is performed while the bearing is rotating (the rotating wheel 2 (inner ring) is rotating together with the rotating body R) and the stationary wheel 4 ( Outer ring)
When the housing H and the housing H rotate relatively, the convex side surface Ps of the convex portion P and the concave side surface Gs of the concave portion G
Since it is only necessary to set the inclination angle θ of each recess side surface Gs so that they are in surface contact with each other, the manufacturing process of the anti-rotation structure becomes extremely simple. As a result, the bearing having the anti-rotation structure The overall manufacturing cost can be greatly reduced.

Furthermore, according to the present embodiment, the width dimension W2 of the concave portion G of the conventional anti-rotation structure (FIG. 4A) is simply changed by changing the inclination angle θ of the pair of concave portion side surfaces Gs. The width dimension of the recess G (FIG. 1 (a)) of the anti-rotation structure of this embodiment can be expanded (enlarged) along the circumferential direction. Thus, when the stationary wheel 4 (outer ring) is fitted into the housing H, the stationary wheel 4
The assembling property (mounting property) for assembling (attaching) the concave portion G formed in the (outer ring) to the convex portion P formed in the housing H can be dramatically improved as compared with the conventional case.

Note that the present invention is not limited to the above-described embodiment, and technical ideas related to the following configurations and modifications are also included in the technical scope of the present invention.
For example, as shown in FIG. 2B, as another configuration of the stationary ring 4 (outer ring) provided in the bearing with the rotation stopper, continuous from the outer periphery of the stationary ring 4 (outer ring) in the circumferential direction along the radial direction. The flange 4f may be protruded, and the recess 4f and the pair of recess side surfaces Gs similar to those of the above-described embodiment may be formed on the flange 4f. Note that the protrusion amount (protrusion length) and width (thickness) of the flange 4f are set according to the purpose of use and the use environment of the bearing with the rotation stopper, and are not specifically limited here. In short, the flange 4 can be secured to ensure the necessary strength for rotation prevention.
What is necessary is just to set the protrusion amount (protrusion length) and width (wall thickness) of f.

In the above-described embodiment, the description has been given assuming that the convex portion P is formed on the inner peripheral surface of the housing H and the concave portion G is formed on the outer peripheral surface of the stationary wheel 4 (outer ring). For example, as shown in FIGS. 3 (a) and 3 (b), as a bearing with a detent according to a modification of the present invention, a convex portion P is formed on the outer peripheral surface of the stationary ring 4 (outer ring), and a concave portion G is formed. May be formed on the inner peripheral surface of the housing H.

In this case, the convex part P projects the outer peripheral surface of the stationary ring 4 (outer ring) partially in parallel along the center axis Ax of the above-described bearing (specifically, the stationary ring 4 (outer ring)). Is formed. On the other hand, the concave portion G is formed by partially denting the inner peripheral surface of the housing H so as to face the convex portion P.
The convex part P is accommodated and it is comprised so that engagement with each other is possible. In addition, about the protrusion amount (protrusion length) of the convex part P and the recessed amount (recessed depth) of the recessed part G, the radial direction width | variety (thickness) of the housing H
Therefore, the numerical value is not particularly limited here.

Further, the convex portion P is formed with convex side surfaces Ps on both sides in the circumferential direction around the central axis Ax, and the pair of convex side surfaces Ps are in a direction orthogonal to the central axis Ax. And a parallel positional relationship (specifically, a positional relationship that is orthogonal to the central axis Ax and parallel to the virtual plane S extending in parallel along the central axis Ax). Are arranged.

On the other hand, the concave portion G is formed with concave side surfaces Gs on both sides in the circumferential direction around the central axis Ax, and the pair of concave side surfaces Gs is one base point set on the central axis Ax side. It is configured and arranged to form an inclined surface inclined in a divergent shape at a predetermined angle θ from T toward the radially outer side. In other words, the pair of concave side surfaces Gs form inclined surfaces inclined in a divergent form at a predetermined inclination angle θ from the base point T toward the radially outer side on both sides of the virtual plane S described above. And arranged.

Here, one base point T set on the center axis Ax side is set on the opposite side in the radial direction across the center axis Ax from the portion where the rotation preventing structure is configured, and the base point T is the center axis Ax. And a predetermined distance δ along the radial direction. More specifically, a portion where the anti-rotation structure is formed (that is, a portion where the convex portion P and the concave portion G are formed) and the base point T are the virtual plane S described above.
, The portion where the convex portion P and the concave portion G are configured, and the base point T,
In this positional relationship, the base point T is placed opposite to both sides across the central axis Ax.
Is separated from the central axis Ax by a predetermined distance δ along the radial direction.

In this case, when the circumferential width of the recess G is set to a constant value and the distance δ from the central axis Ax to the base point T is increased, the inclination angle θ of the pair of recess side surfaces Gs can be reduced accordingly.
On the other hand, when the circumferential width of the recess G is set to a constant value and the distance δ from the central axis Ax to the base point T is decreased, the inclination angle θ of the pair of recess side surfaces Gs can be increased accordingly. In addition, since the magnitude change of the inclination angle θ of the pair of concave side surfaces Gs is set according to the size of the convex portion P, the width in the circumferential direction, etc., for example, the numerical value is not particularly limited here.

Here, assuming that the inclination angle θ of the pair of concave side surfaces Gs is set in accordance with, for example, the size and the circumferential width of the convex portion P, the rotating wheel 2 (inner ring) is fitted to the rotating body R. At the same time, by fitting the stationary ring 4 (outer ring) to the housing H, the stationary ring 4 (outer ring) and the housing H are relatively relative to each other in a state in which the bearing with a detent is assembled between the rotating body R and the housing H. When the rotation is performed, the convex portion P and the concave portion G are in contact with each other in a planar shape.

That is, when the stationary wheel 4 (outer ring) and the housing H rotate relatively, the convex side surface Ps formed in the convex portion P and the concave side surface Gs configured in the concave portion G are in a positional relationship parallel to each other. And in contact with each other in a planar manner. In this case, “contact in a planar shape” means the convex side surface P
s and the side surface Gs of a recessed part point to contacting each other without a line contact or a point contact, and without a gap.
In addition, since the effect of this modified example having the above-described configuration is the same as that of the above-described embodiment, the description thereof is omitted.
In the above-described embodiment, the rotating wheel 2 is described as an inner ring and the stationary wheel 4 is described as an outer ring. However, the same effect can be obtained when the rotating wheel 2 is an outer ring and the stationary wheel 4 is an inner ring. .

2 Rotating wheel (inner ring)
4 stationary wheel (outer ring)
Ax Center axis G Concave Gs Concave side H Housing T Base point θ Inclination angle of concavity side

Claims (1)

A rotating wheel fitted into a rotating body and rotating together;
A stationary wheel disposed opposite the rotating wheel and fitted into a housing;
A bearing with a detent having a detent structure for preventing relative rotation between the stationary wheel and the housing,
The detent structure is
A convex portion formed by projecting a peripheral surface of either one of the stationary ring and the housing partially in parallel along a central axis of the stationary ring;
The other peripheral surface of the stationary ring or the housing is formed by recessing a part thereof so as to face the convex portion, accommodates the convex portion, and has a gap in the circumferential direction with the convex portion. And a recess that can be engaged.
The convex portions are respectively configured with convex side surfaces on both sides in the circumferential direction along the central axis.
The concave portions are respectively configured with concave side surfaces on both sides in the circumferential direction around the central axis.
The pair of recess side surfaces are set on the central axis side and radially outward from one base point,
It is constructed and arranged to form an inclined surface inclined in a divergent shape at a predetermined angle,
The base point is set on the opposite side in the radial direction across the central axis from the portion where the anti-rotation structure is configured, and is separated from the central axis by a predetermined distance along the radial direction,
When the stationary wheel and the housing rotate relatively, the convex side surface and the concave side surface contact each other in a planar shape.