JPH0647127Y2 - Spring key - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a spring key used, for example, when attaching a hollow work to a mandrel.

<Prior Art> The raceway surfaces 51, 52 of the double-row eccentric bearing inner ring 50 shown in FIGS. 5 and 6 are processed by using a mandrel (not shown), and the double-row eccentric bearing inner ring 50 is attached to the mandrel at that time. Is
It is performed as follows. That is, the key submerged in the axial key groove provided on the outer peripheral surface of the mandrel is provided with the axial key groove 50b provided on the inner peripheral surface of the hole 50a of the double row eccentric bearing inner ring 50.
While fitting, the double-row eccentric bearing inner ring 50 is tightly fitted onto the mandrel, and the double-row eccentric bearing inner ring 50 is positioned in the radial direction and the circumferential direction with respect to the mandrel. And
For machining each of the eccentric raceway surfaces 51, 52 of the double row eccentric bearing inner ring 50 into a cylindrical surface whose center (see O ₁ and O _{2 in} FIG. 6) is precisely located at a predetermined position. That is, in order to process the double-row eccentric bearing inner ring 50 with high accuracy, the above positioning, particularly the circumferential positioning, is particularly important.

Conventionally, as a key used for positioning and mounting such a work on a mandrel, there is a so-called "pull" square bar-shaped key.

<Problems to be Solved by the Invention> However, since the above-mentioned conventional key is simply a “pulled” square bar shape, as shown in FIG. 7, the width dimension of the key groove 50b on the workpiece 50 side and the key 54 If there is an error δ as shown in the figure with respect to the width of the mandrel 53, the key 54 is closely fitted in the key groove 53a on the mandrel 53 side in the circumferential direction, and even if the key 50 is sunk, the work 50 is rotated relative to the mandrel 53. There is a problem in that the workpiece 50 is rattled in the direction, in other words, the workpiece 50 cannot be accurately positioned in the circumferential direction with respect to the mandrel 53, and a highly accurate machining result cannot be obtained. Further, if the above-mentioned error δ is made as small as possible in order to eliminate rattling, high accuracy is required for processing the key groove 50b on the work 50 side, and a great deal of labor is required. Also, work 50 mandrel 53
When the key 54 was repeatedly attached to the work and the part of the key 54 projecting toward the work 50 was worn, a new key 54 had to be prepared and replaced.

Therefore, the object of the present invention is to make it possible to absorb these errors by elastic expansion and contraction even if there is an error in the width dimension of the key groove on the work side or the width dimension of the key groove on the jig side. It is to provide a key that can be positioned and supported without rattling against a tool.

<Means for Solving the Problems> In order to achieve the above-mentioned object, the spring key of the present invention is a substantially elliptical ring having a hollow portion, and includes two longitudinal portions extending in the longitudinal direction of the ellipse. On one side, a slit that communicates with the hollow portion and extends in the longitudinal direction of the ellipse is formed, and one portion and the other portion that extend in the longitudinal direction of the ellipse sandwiching the slit are independent of each other. It is characterized by being elastically deformable in the width direction intersecting the longitudinal direction.

<Operation> One of the two longitudinal portions of the spring key having a substantially elliptical annular shape communicates with the hollow portion, and one of the two longitudinal portions extends in the longitudinal direction of the ellipse with a slit extending in the longitudinal direction of the ellipse interposed therebetween. It has a part and the other part. The one part and the other part sandwiching the slit can be elastically deformed independently of each other with respect to the longitudinal part on the side where the slit is not provided.

When positioning and attaching a work to a jig, this spring key compresses one of the above parts and the remaining part corresponding thereto into the key groove on the jig side, while the other part and this And the remaining part corresponding to is compressed into the key groove on the work side. At the time of the compression, the one portion and the other portion are elastically deformed as much as necessary to press the inner surfaces of the jig-side key groove and the work-side key groove. In this way, the spring key is fitted in the space formed by the key groove on the jig side and the key groove on the work side.

This spring key can be mounted without elastically deforming one of the parts sandwiching the slit according to the width dimension of the key groove on the jig side without rattling the key groove on the jig side. Further, even if there is an error in the width dimension of the key groove of the work to be attached to the jig, the other part sandwiching the slit of the spring key is elastically deformed to absorb the above dimensional error. It can be installed without rattling.

Further, since the longitudinal portion is fitted in the key groove in a state of being displaced in the width direction and facing the inner surface of the key groove substantially in parallel, the fitting in the key groove is stable.

Further, when the spring key is fitted in the space formed by the key groove of the jig and the key groove of the work, the portion where the slit is not provided is one side surface of the key groove of the jig. The side surface corresponding to the above-mentioned side surface of the work key groove is pressed at the same time and positioned in the same plane. Therefore,
The work can be accurately positioned with respect to the jig.

<Embodiment> Hereinafter, the present invention will be described in detail with reference to an illustrated embodiment.

FIG. 1 is a plan view of an embodiment of the spring key of the present invention. The spring key 10 is an elliptical ring having parallel portions 11 and 12 as longitudinal portions and is perpendicular to the plane of the drawing as shown. It has a cylindrical shape having a height H (see FIG. 2) in the direction. And, it has a hollow portion 13 penetrating in a direction perpendicular to the paper surface. The spring key 10 has a constant width W in a natural state where no external force acts. Further, since it has an annular shape, it can elastically bend, and in particular, because it has an oval annular shape, it can smoothly elastically deform in the width W direction. A boundary portion between the parallel portion 11 on the left side of the figure and the semi-cylindrical curved portions 14 and 15 is formed as a notch, and the parallel portion 11 projects to the left side of the figure by a certain dimension.

As shown in FIG. 2, a slit which extends in the width W direction and communicates with the hollow portion 13 is formed substantially at the center in the height H direction on the parallel portion 11 side.
16 are provided. This slit 16 has a cutting depth equal to approximately half the width W. The slit 16 divides the one parallel portion 11 side into approximately two equal parts in the height H direction. The parallel portions 11a, 11b formed by being divided into two and sandwiching the slit 16 and the parallel portions 11a, 1b.
The semi-elliptical portion (see FIG. 1) formed by the slits 16 of the curved portions 14 and 15 connected to 1b is a slit.
On the other parallel part 12 side where 16 is not provided, they are provided independently of each other and elastically deformable. Therefore, the two parallel portions 11a and 11b can be elastically displaced in the width W direction independently of each other with respect to the parallel portion 12. When the parallel portions 11a and 11b are displaced in the width W direction, the curved portions 14 and 15 bend so that the radii of curvature change, thereby contributing to the elastic displacement of the parallel portions 11a and 11b with respect to the respective parallel portions 12. .

As shown in FIG. 3, the spring key 10 having the above structure is
When the work 21 is externally fitted and positioned on the mandrel 20, it is provided on the outer periphery of the mandrel 20, and the spring key 10
The parallel portion 11b side on one side in the height H direction is contracted to the key groove 20a having a width W ₁ which is narrower than the width W in the natural state by the work 21 on the other side. The width W of the spring key 10 in the natural state is also provided on the inner peripheral surface of the
The key groove 21a having a width W ₂ (W ₂ = W _{1 in} FIG. 4) narrower by a certain size than that of the key groove 21a is used by being compressed. As mentioned above, parallel part 1
Since the respective 1a and 11b can be elastically displaced in the width W direction with respect to the parallel portion 12 independently of each other, the parallel portion 11b of the spring key 10 in the state shown in the drawing can be moved relative to the parallel portion 12 with respect to the mandrel 20. depending on the width W ₁ of the side of the keyway 20a spread resiliently width W ₁ cup of the groove, it is pressed by the parallel portion 11b and the parallel portion 12 on both sides of the keyway 20a. Further, without being affected by the pressure of the mandrel 20, the parallel portion 11a of the opposite side, the width W of the key groove 21a according to the width W ₂ of the workpiece 21 side of the keyway 21a relative to the parallel portion 12 ₂ It spreads elastically as much as possible, and is pressed against both side surfaces of this key groove 21a at parallel portions 11a and 12 respectively. Therefore, the work 21 is supported by the spring key 10 on the mandrel 20 without rattling in the circumferential direction. In addition to this, as shown in the drawing, the key groove 20a on the mandrel 20 side, the side surface 20b on the left side in the figure, and the key groove on the work 21 side.
The left side surface 21b in the figure of 21a is the two side surfaces 20b, 21b.
The parallel positions 12 of the spring keys 10 that are pressed against the same time are aligned with each other in the circumferential direction so as to form one surface. Therefore, the work 21 is accurately positioned by the spring key 10 in the circumferential direction on the mandrel 20 with the side surface 20b of the key groove 20a as a reference surface for positioning. Then, as shown in FIG. 4, even if a work having an error δ in the width dimension of the key groove 21a is mounted on the mandrel, the spring key 10
The error δ is absorbed by the elastic displacement of the parallel portion 11a in the width W direction with respect to the parallel portion 12 (see the arrow in the figure), and the work 21 is supported on the mandrel 20 without rattling in the circumferential direction. And at the same time, the side surface 2 of the keyway 20a on the mandrel 20 side
0b and the side surface 20b of the key groove 21a on the side of the work 21 with the key groove 21a.
The same as in FIG. 3, regardless of the error δ in the width dimension of
The work 21 is accurately positioned with respect to the mandrel 20 in the circumferential direction. Of course, contrary to Fig. 4, the keyway on the workpiece 21 side
Even if there is an error in the direction in which the width dimension is narrowed in 21a (not shown), this error can be absorbed, and the work 21 can be accurately positioned and supported on the mandrel 20 in the circumferential direction without rattling. The keyway on the mandrel 20 side
Even if there is an error in 20a (not shown), of course work 2
This error can be absorbed like the 1st side.

In addition, the width W of the spring key 10 shown in FIG.
Is the width dimension W ₂ of the key groove 21a on the work 21 side when the maximum error δmax exists, that is, the key groove 2 as shown in FIG.
It is provided with a predetermined dimension larger than the maximum width dimension W ₂ max of 1a. Of course, the width W is the keyway on the mandrel 20 side.
Larger than the maximum width dimension of 20a. Further, the spring property of the spring key 10 is largely determined by the material and thickness of the annular member. The resilience is further adjusted by changing the dimensions indicated by c and d in FIG. The spring key 10 of this embodiment is mainly for positioning.
So by this spring key 10 the mandrel
The work 21 positioned in the circumferential direction with respect to 20 is then fixed to the mandrel 20 so as not to rotate together by a fixing member (not shown), if necessary.

Thus, according to this spring key 10, the work 21
Width W ₂ and the mandrel 20 side of the keyway 20a on the side of the keyway 21a
Even if there is an error in the width dimension W ₁ of
The error of the key groove 21a on the work 21 side is caused by the elastic displacement of the parallel portion 11a with respect to the parallel portion 12, and the error of the key groove 20a on the mandrel 20 side is caused by the elastic displacement of the parallel portion 11b with respect to the parallel portion 12. Can be absorbed independently of each other and always work 21
Can be supported on the mandrel 20 without rattling in the circumferential direction. At the same time, the work 21 is mandreled.
20 can be accurately positioned in the circumferential direction.
Further, since the parallel portions 11 and 12 fitted in the key grooves 20a, 21a are in surface contact with both side surfaces of the key grooves 20a, 21a by the rectangular surfaces extending in the longitudinal direction, the work 21 and the mandrel 20 are stably supported. it can. Therefore, if the work 21 is positioned on the mandrel 20 by using the spring key 10, the work 21 can be processed with higher accuracy as compared with the case of using the conventional square bar-shaped key.

In the above embodiment, the spring key 10 has an oval annular shape having the parallel portions 11 and 12, but it goes without saying that the shape is not limited to the oval annular shape having the parallel portions.

Further, in the above embodiment, the spring key 10 is the mandrel.
The work 20 is used to support the work 21 in the circumferential direction, but the application is not limited to this, and for example, two members that abut on each other in a plane may be supported in the width direction of the key by using this spring key. it can.

<Effect of the Invention> As is apparent from the above, the spring key of the present invention is a substantially elliptical ring having a hollow portion, and one of two longitudinal portions extending in the longitudinal direction of the ellipse, A slit communicating with the hollow portion and extending in the longitudinal direction of the ellipse is formed, and one portion and the other portion extending in the longitudinal direction of the ellipse sandwiching the slit are independent of each other in the longitudinal direction. It is elastically deformable in the width direction intersecting the direction.

Therefore, according to the spring key of this invention, one portion and the other portion extending in the longitudinal direction of the ellipse across the slit can be elastically deformed independently of each other in the width direction intersecting the longitudinal direction. Even if there is an error in the width dimension of the key groove or the width dimension of the key groove on the work side, these dimension errors can be absorbed and the key groove can be mounted without rattling.

Further, one part and the other part of the one longitudinal part are displaced in the width direction, and the two longitudinal parts are in surface contact with each other in a state of being substantially parallel to the inner side surface of the key groove and fitted into the key groove. Since they fit together, the fitting in the key groove is stable.

Further, while the one portion and the other portion independently press one side surface of the key groove of the jig and one side surface of the work at the same time, while the slit of the spring key is not formed, Since the portion simultaneously presses the other side surface of the key groove of the jig and the other side surface of the key groove of the work, the two other side surfaces can be positioned in the same plane, and the work can be placed against the jig. Can be positioned accurately.

[Brief description of drawings]

FIG. 1 is a plan view of an embodiment of the spring key of the present invention, FIG. 2 is a view taken in the direction of arrow II in FIG. 1, and FIGS. 3 and 4 are spring keys of FIG. And a cross-sectional view perpendicular to the shaft when fitted in the key groove on the work side at the same time,
5 and 6 are explanatory views of the inner race of the double-row eccentric bearing, and FIG. 7 is an explanatory view of the conventional key. 10 …… Spring key, 13 …… Hollow part, 16 …… Slit.

Claims (1)

[Scope of utility model registration request] 1. A substantially elliptical ring having a hollow portion, wherein one of two longitudinal portions extending in the longitudinal direction of the ellipse communicates with the hollow portion and extends in the longitudinal direction of the ellipse. An extending slit is formed, and one portion and the other portion extending in the longitudinal direction of the ellipse with the slit interposed therebetween are elastically deformable independently of each other in a width direction intersecting the longitudinal direction. Spring key that is characterized.