JP2017133648A - Rotation shaft structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rotation shaft structure which eliminates strength poverty in a portion where a lock nut is screwed, and can reduce an outer diameter.SOLUTION: On a secondary shaft 14, a piston 18 and a stopper 21 are externally fitted, and a lock nut 23 is screwed in a right side of the piston 18 and the stopper 21. Tightening the lock nut 23 makes the piston 18 and the stopper 21 be fixed to the secondary shaft 14. In the secondary shaft 14, a hollow section 39 is partially formed. The lock nut 23 is screwed at a position offset toward a rotation axis direction from the hollow section 39.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a rotating shaft structure applied to a vehicle transmission.

  In vehicles such as automobiles, power from a drive source is input to a transmission (transmission), and power shifted by the transmission is transmitted to drive wheels via a transfer, a differential, or the like.

  The transmission is provided with a plurality of rotating shafts, and an annular member surrounding the rotating shaft is externally fitted and fixed to the rotating shafts. For example, a belt-type continuously variable transmission (CVT) has a configuration in which an endless belt is wound between an input-side primary pulley and an output-side secondary pulley. A fixed sheave of the secondary pulley is integrally formed on the secondary shaft that supports the secondary pulley. The movable sheave of the secondary pulley is externally fitted to the secondary shaft, is opposed to the fixed sheave with the belt interposed therebetween, and is movable in the facing direction. A piston is provided on the opposite side of the movable sheave to the fixed sheave, and a piston chamber (oil chamber) to which hydraulic pressure acting on the movable sheave is supplied is formed between the movable sheave and the piston. The piston is formed in an annular shape and is externally fitted to the secondary shaft. A lock nut is screwed to the secondary shaft on the side opposite to the movable sheave side with respect to the piston, and the piston is fixed to the secondary shaft by tightening the lock nut.

Japanese Patent Laying-Open No. 2015-145682

  A rotating shaft such as a secondary shaft is often formed in a hollow structure having an axial center oil passage extending on the rotating axis. In the rotary shaft having a hollow structure, there is a problem that the outer diameter becomes large in order to secure the strength of the portion to which the lock nut is screwed.

  The objective of this invention is providing the rotating shaft structure which can aim at the reduction | decrease in an outer diameter avoiding the intensity | strength shortage of the part into which a lock nut is screwed.

  In order to achieve the above object, a rotating shaft structure according to the present invention is a rotating shaft structure applied to a transmission of a vehicle, and in the rotating shaft structure, a rotation partly having a hollow portion along the rotating axis. An outer fitting member is fitted on the shaft, and a lock nut is screwed to a position displaced in the rotation axis direction with respect to the hollow portion, and the outer fitting member is fixed to the rotation shaft by tightening the lock nut.

  According to this configuration, the external fitting member is externally fitted to the rotation shaft, and the lock nut is screwed to one side in the rotation axis direction with respect to the external fitting member. By tightening the lock nut, the outer fitting member is fixed to the rotating shaft. The rotation shaft is partially formed with a hollow portion along the rotation axis, and the lock nut is screwed at a position shifted in the rotation axis direction with respect to the hollow portion. Therefore, the strength of the portion of the rotating shaft to which the lock nut is screwed is avoided, and the outer diameter of the rotating shaft (at least the screw diameter of the screw formed on the outer peripheral surface of the rotating shaft for screwing the lock nut) ) Can be reduced.

  ADVANTAGE OF THE INVENTION According to this invention, the strength shortage of the part in which the lock nut in the rotating shaft is screwed can be avoided, and the outer diameter of the rotating shaft can be reduced.

It is sectional drawing which shows the rotating shaft structure which concerns on one Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

<Configuration>

  FIG. 1 is a cross-sectional view showing a rotating shaft structure 1 according to an embodiment of the present invention. In FIG. 1, the hatching indicating the cross section is omitted.

  The rotating shaft structure 1 is applied to a vehicle transmission. A belt-type continuously variable transmission (CVT) 11 is an example of a vehicle transmission, and an endless belt 13 is wound between an input-side primary pulley and an output-side secondary pulley 12. It has a configuration. FIG. 1 shows the configuration of the output side of the continuously variable transmission 11.

  The continuously variable transmission 11 includes a secondary shaft 14 that supports the secondary pulley 12 and an output shaft 15 that outputs power transmitted to the secondary shaft 14. The secondary shaft 14 and the output shaft 15 are arranged on the same axis, and their rotation axes coincide with each other.

  A fixed sheave 16 of the secondary pulley 12 is formed integrally with the secondary shaft 14. The movable sheave 17 of the secondary pulley 12 is externally fitted to the secondary shaft 14 on one side in the rotation axis direction with respect to the fixed sheave 16 (the right side in FIG. 1, hereinafter referred to as “right side”), and extends in the rotation axis direction. It is provided to be movable. The sheave surface of the movable sheave 17 is opposed to the sheave surface of the fixed sheave 16 with the belt 13 interposed therebetween.

  A piston 18 is provided on the right side of the movable sheave 17. A piston chamber (oil chamber) 19 to which hydraulic pressure acting on the movable sheave 17 is supplied is formed between the movable sheave 17 and the piston 18. The piston 18 is fitted on the secondary shaft 14. The portion of the secondary shaft 14 where the piston 18 is externally fitted is formed with a smaller diameter than the portion where the movable sheave 17 is externally fitted, and the portion of the secondary shaft 14 where the movable sheave 17 is externally fitted. And a step where the piston 18 is externally fitted.

  An annular plate-like stopper 21 for restricting the movement of the movable sheave 17 is interposed between the surface 20 formed by the step and the inner peripheral end of the piston 18.

  Further, a screw 22 is cut in a portion adjacent to the right side of the portion where the piston 18 is fitted on the outer peripheral surface of the secondary shaft 14. A lock nut 23 is screwed into a portion where the screw 22 is cut. By tightening the lock nut 23, the inner peripheral ends of the piston 18 and the stopper 21 are pressed against each other between the surface 20 and the lock nut 23, and the piston 18 and the stopper 21 are fixed to the secondary shaft 14.

  A shaft center oil passage 24 extending along the rotation axis is formed in the secondary shaft 14. The shaft center oil passage 24 is opened at the end surface on the other side (left side in FIG. 1, hereinafter referred to as “left side”) of the secondary shaft 14 in the rotation axis direction.

  The left end 25 of the secondary shaft 14 protrudes from the fixed sheave 16 to the left. An inner ring (inner race) 32 of the bearing 31 is fitted on the end portion 25. An outer ring (outer race) 33 of the bearing 31 is held by a case 34 of the continuously variable transmission 11.

  Further, the piston 18 extends from the outer peripheral surface of the secondary shaft 14 in the rotational radial direction, and a midway portion is bent and extends to the left side. An inner ring 36 of the bearing 35 is fitted on a portion extending to the left side. An outer ring 37 of the bearing 35 is held by the case 34.

  Accordingly, the secondary shaft 14 is supported by the case 34 via the two bearings 31 and 35.

  The right end 38 of the secondary shaft 14 extends further to the right from the portion where the screw 22 is cut. The end portion 38 is formed with a hollow portion 39 opened at the end surface. The hollow portion 39 has a cylindrical inner peripheral surface 40 centering on the rotation axis of the secondary shaft 14. The inner peripheral surface 40 overlaps with the right end of the screw 22 cut on the outer peripheral surface of the secondary shaft 14 with a minute width in the rotation axis direction. As a result, the lock nut 23 is screwed to the hollow portion 39 at a position displaced in the rotational axis direction.

  The left end portion 41 of the output shaft 15 is formed in a columnar shape having an outer diameter smaller than the inner diameter of the inner peripheral surface 40 of the hollow portion 39 of the secondary shaft 14. The end portion 41 is inserted into the hollow portion 39. A bearing 43 is interposed between the inner peripheral surface 40 of the hollow portion 39 and the outer peripheral surface 42 of the end portion 41. The bearing 43 is a cage and roller needle bearing having a configuration in which a plurality of rolling elements are held by a cage.

  A bearing 45 is fitted on the right end 44 of the output shaft 15. The bearing 45 is a needle roller bearing that does not have an inner ring. The outer ring 46 of the bearing 45 is held by the case 34.

  As a result, the output shaft 15 is supported by the case 34 such that the end portion 41 is supported by the secondary shaft 14 via the bearing 43 and the end portion 44 is supported by the case 34 via the bearing 45. Has been.

  A parking gear 47 is fitted on the output shaft 15 on the left side of the bearing 45. The parking gear 47 is spline-fitted to the outer peripheral surface of the output shaft 15.

<Effect>

  As described above, the piston 18 and the stopper 21 are fitted on the secondary shaft 14, and the lock nut 23 is screwed to the right side of the piston 18 and the stopper 21. By tightening the lock nut 23, the piston 18 and the stopper 21 are fixed to the secondary shaft 14. The secondary shaft 14 is partially formed with a hollow portion 39, and the lock nut 23 is screwed at a position shifted in the rotational axis direction with respect to the hollow portion 39. Therefore, the strength of the portion of the secondary shaft 14 to which the lock nut 23 is screwed is avoided, and the outer diameter of the secondary shaft 14 (at least formed on the outer peripheral surface of the secondary shaft 14 for screwing the lock nut 23 is formed. The screw diameter of the screw 22 can be reduced.

<Modification>

  Although one embodiment of the present invention has been described above, the present invention can be implemented in other forms.

  For example, the piston 18 and the stopper 21 are given as examples of the external fitting member that is externally fitted to the secondary shaft 14 that is an example of the rotating shaft, but the external fitting member may be a bearing, a gear, or the like.

  Further, in the above-described embodiment, the case where the rotation shaft to which the rotation shaft structure 1 is applied is the secondary shaft 14, but another rotation shaft of the continuously variable transmission 11, for example, a primary pulley is supported. The primary shaft may be an application target of the rotating shaft structure according to the present invention.

  In addition, various design changes can be made to the above-described configuration within the scope of the matters described in the claims.

1 Rotating shaft structure 11 Continuously variable transmission (transmission)
14 Secondary shaft (rotary shaft)
18 Piston (External fitting member)
21 Stopper (external fitting member)
23 Lock nut

Claims (1)

A rotating shaft structure applied to a vehicle transmission,
In the rotating shaft partially having a hollow portion along the rotating axis,
The external fitting member is externally fitted,
A rotary shaft structure in which a lock nut is screwed at a position shifted in the rotation axis direction with respect to the hollow portion, and the outer fitting member is fixed to the rotary shaft by tightening the lock nut.

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