KR20220110167A - A Cap For Pinion Shaft - Google Patents

Abstract

The present invention relates to a cap (120) for a pinion shaft (110), which is firmly inserted into an opening and prevents the leakage of lubricating oil. The cap (120) for the pinion shaft (110) is inserted into an open insertion portion (117) of a connection hole (111) of the pinion shaft (110), the pinion shaft (110) comprising the connection hole (111) that extends in an axial direction and is opened to one end in the axial direction, a first hole (113) that extends outward in a radial direction from the connection hole (111) and is opened to the outer surface, and a second hole (115) that is away in the axial direction from the first hole (113) and extends outward in the radial direction to be opened to the outer surface. The cap (120) for the pinion shaft (110) includes a cap body portion (121) that is a hollow body opened on both sides, and a cap bottom portion (123) that is connected to one open end of the cap body portion (121). On an outer surface of the cap body portion (121), formed are cap protrusion portions (125) that have a shape opened to the opposite side of the cap bottom portion (123) and protrude outward to come in contact with the inner surface of the opened insertion portion (117) of the connection hole (111).

Description

Cap for Pinion Shaft {A Cap For Pinion Shaft}

The present invention relates to a cap for a pinion shaft, and to a cap for a pinion shaft that is coupled to a pinion shaft used for a planetary gear to prevent oil from leaking.

A planetary gear installed in a transmission or the like of a vehicle includes a sun gear 1 , a sun gear 1 , a ring gear 2 , and a carrier 4 . These configurations are arranged concentrically around an output shaft (not shown). The pinion (3, Planet Gear) meshing with the sun gear (1) and the ring gear (2) is rotatably supported by a roller (not shown) on the pinion shaft (5) fixed to the carrier (4). . An oil supply passage 10 for supplying lubricating oil between the outer peripheral surface 5a of the pinion shaft 5 used in such a planetary gear and the roller is formed in the pinion shaft 5 .

The pinion shaft 5 has a first hole 13 extending outward in the radial direction from the connection hole 11 and opening near the axial end of the outer circumferential surface 5a, and extending radially outward from the connection hole 11 and extending outward from the outer circumferential surface. A second hole 12, which opens approximately in the center in the axial direction of (5a), and three holes that are connection holes 11 extending in the axial direction of the pinion shaft 5 are formed, and two radially extending holes are formed. The holes 12 and 13 communicate with the connection hole 11 .

The lubricating oil introduced into the opening 13a of the first hole 13 reaches the second hole 12 through the inside of the connection hole 11, and the second hole ( 12) through the opening 12a. The discharged lubricant is provided as a lubricant between the outer peripheral surface 5a of the pinion shaft 5 and the roller. The first hole 13 and the second hole 12 connection hole 11 are machined using a tool such as a drill. In order to form the connection hole 11, since the machining starts from one end of the pinion shaft 5 and proceeds in the axial direction, the opening 11a is formed in the cross section of one end.

If there is an opening 11a in the connection hole 11, a part of the lubricant in the connection hole 11 leaks from the opening 11a, so the amount of lubricant discharged from the opening 12a of the second hole 12 is lubrication becomes insufficient. Therefore, since it is necessary to close the opening 11a of the cross section, the cap 20 having a cross section of a substantially "U" shape in cross section was press-fitted into the opening 11a. In general, the cap 20 is made of low-carbon steel such as SPCC material, but since the strength can be increased by heat treatment such as carburization and nitriding treatment or quenching, the cap 20 is difficult to separate from the opening 11a. . That is, by heat treatment, the force (release load) required for the cap 20 to slip off from the opening 11a is improved.

The cylindrical portion of the cap 20 does not uniformly contact the opening 11a, which is a cylindrical surface, in the circumferential and axial directions, and only the outer end of the cap 20 has an opening ( 11a), causing leakage of lubricating oil, and causing the cap 20 to be easily separated from the opening 11a. And in order to solve this problem, the manufacturing cost is reduced by precisely processing the outer diameter surface of the cap 20 and the opening 11a, undergoing a process such as heat treatment as described above, and strictly managing the interference. There was an increasing problem.

Patent Literature (0001) Japanese Patent No. 4911062 Patent Publication Patent Literature (0002) Korean Patent No. 10-1675792 Registered Patent Publication Patent Literature (0003) Republic of Korea Patent No. 10-0941713 Patent Publication

The present invention has been proposed to solve the problems of the prior art as described above, and an object of the present invention is to provide a cap for a pinion shaft which is firmly inserted into an opening and prevents leakage of lubricating oil.

For the above purpose, the present invention provides a connection hole extending in the axial direction and opened to one end in the axial direction, a first hole extending outward in the radial direction from the connection hole and opened to the outside, and the shaft from the first hole A cap for a pinion shaft spaced apart in the direction and extending radially outwardly from the connection hole, the second hole being opened to the outer surface is formed, and inserted into the insertion part of the pinion shaft having an insertion part at the opened end of the connection hole; It consists of a cap body part which is a hollow body opened on both sides, and a cap bottom part connected to an open end of one side of the cap body part, and is formed to be opened opposite to the cap bottom part. Provided is a cap for a pinion shaft provided with a cap protrusion in contact with an inner surface of an insertion part.

In the above, the inner surface of the insertion part is formed in a cylindrical surface, the cross section of the cap body part is formed in a circular ring shape, and the cap protrusion part is formed along the circumferential direction on the outer surface of the cap body part to form a ring shape, and the cap protrusion part is characterized in that it is in contact with the inner surface of the insertion part along the circumferential direction.

In the above, it is characterized in that the cap protrusion is provided in plurality and spaced apart in the axial direction.

In the above, at least one of the cap protrusions is characterized in that the inclination angle of the inward-facing surface is formed to be greater than the inclination angle of the outward-facing surface.

In the above, the cap protrusion is pressed outwardly from the inside to protrude outward in the radial direction, and the inner surface of the cap body part is characterized in that a concave groove is formed along the circumferential direction at the portion where the cap protrusion is formed.

In the above, the cap bottom portion is characterized in that the central portion is formed in a protruding conical shape.

According to the cap 120 for the pinion shaft of the present invention, the cap protrusion 125 extending in the circumferential direction and protruding outward in the radial direction is provided on the outer surface of the cap body part 121, and the cap 120 for the pinion shaft is connected to the connection hole. It is inserted into the insertion part 117 provided in the 111, and it is possible for the cap protrusion part 125 to contact the inner surface of the insertion part 117 along the circumferential direction, and to suppress the occurrence of a portion spaced apart along the circumferential direction. The lubricating oil leakage is prevented, and a plurality of cap protrusions 125 are spaced apart in the axial direction to maintain a stable insertion state, and it is possible to increase the amount of interference between the cap protrusion 125 and the inner surface of the insert 117. Detachment after assembly can be prevented.

1 is a schematic exploded perspective view of a planetary gear having a pinion shaft;
2 is a cross-sectional view of a conventional pinion shaft and a cap supporting the pinion (planet gear) of the planetary gear shown in FIG. 1;
3 is a cross-sectional view of the pinion shaft and the pinion shaft cap of the present invention,
Figure 4 is a partial cross-sectional view of the cap showing an enlarged rectangular display portion of Figure 3,
5 is a view for explaining the manufacturing process of the cap for the pinion shaft of the present invention,
6 is a partial cross-sectional view of a cap for a pinion shaft of the present invention.

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

Figure 3 is a cross-sectional view of the pinion shaft and the cap for the pinion shaft of the present invention, Figure 4 is a partial cross-sectional view of the cap showing an enlarged rectangular portion of Figure 3, Figure 5 is a cap for the pinion shaft of the present invention In order to explain the manufacturing process of the present invention 6 is a partial cross-sectional view of the cap for the pinion shaft of the present invention.

The pinion shaft cap 120 according to the present invention is installed by being inserted into the pinion shaft 110 (100, pinion shaft cap assembly). The pinion shaft 110 into which the cap 120 for the pinion shaft of the present invention is inserted is coupled to the carrier and is inserted into the inner diameter of the pinion (Planet Gear) to rotatably support the pinion through a roller (not shown). The roller is a cylindrical needle roller and is arranged along the circumferential direction between the outer surface of the pinion shaft 110 and the inner diameter of the pinion (Planet Gear) (the details of this are omitted since it is a known technology).

The pinion shaft 110 is in the shape of a rod having a circular cross section, and as shown in FIG. 3 , the pinion shaft 110 has a connection hole 111 extending in the axial direction and opened to one end in the axial direction, and the connection A first hole 113 extending outward in a radial direction from the hole 111 and opened to the outer surface, spaced apart from the first hole 113 in an axial direction, and extending radially outward from the connection hole 111 and opened to the outer surface A second hole 115 is formed. Lubricating oil flows into the first hole 113 , flows through the connection hole 111 , and is discharged through the open end of the second hole 115 . The connection hole 111 may be formed at the center of the pinion shaft 110 or may be formed eccentrically to one side as shown in FIG. 3 . The first hole 113 and the second hole 115 are opened in opposite directions in a radial direction.

The connection hole 111 forms a chin in the opening, and an insertion part 117 having an increased diameter is formed. The inner surface of the insertion part 117 is formed as a cylindrical surface. A portion of the outer end of the insertion part 117 is formed in an inclined shape by increasing the diameter so that the cap 120 for the pinion shaft is easily inserted. The cap 120 for the pinion shaft is slidingly inserted into the insertion part 117 and coupled thereto. The inner end of the pinion shaft cap 120 in the axial direction is in contact with the chin.

The cap 120 for the pinion shaft includes a hollow cap body part 121 opened on both sides, and a cap bottom part 123 connected to an open end of one side of the cap body part 121 . The cap 120 for the pinion shaft is formed in a cup shape that is opened opposite to the cap bottom part 123 .

The cap body part 121 is formed as a hollow cylindrical body having a circular cross section, and the cap bottom part 123 coupled to the inner end of the cap body part 121 in the axial direction is formed in a plate-shaped circular shape.

A cap protrusion 125 is provided on the outer surface of the cap body portion 121 to protrude outward and contact the inner surface of the insertion portion 117 . The cap protrusion part 125 extends along the circumferential direction on the outer surface of the cap body part 121 and is formed in a ring shape. The cap protrusion 125 is concentric with the cap body 121 .

The outer diameter of the cap protrusion 125 is formed to be larger than the inner diameter of the inner surface of the insertion portion 117 . When the cap 120 for the pinion shaft is inserted into the inner surface of the insertion portion 117, the cap protrusion 125 is press-fitted to the inner surface of the insertion portion 117 to contact without a gap along the circumferential direction. The cap 120 for the pinion shaft according to the present invention is provided with a cap protrusion 125 so that the cap protrusion 125 comes into contact with the inner surface of the insertion part 117, so that the amount of interference between the inner surface of the cap protrusion 125 and the insertion part 117 is greatly increased. it is possible to do Therefore, it is prevented that a gap is generated between the inner surface of the cap protrusion 125 and the insertion part 117 at any part along the circumferential direction.

The cap protrusion 125 is provided with a plurality of spaced apart in the axial direction. Since a plurality of the cap protrusions 125 are spaced apart from each other in the axial direction, the cap 120 for the pinion shaft is inserted into the inner surface of the insertion part 117 without being inclined to prevent leakage of lubricant in a stable state.

At least one of the cap protrusions 125 is formed so that the inclination angle of the inward-facing surface 120-2b1 is greater than the inclination angle of the outward-facing surface 120-2b2. Therefore, insertion into the inner surface of the insertion portion 117 is easy, and when it is separated, it acts like a wedge to prevent the cap 120 for the pinion shaft from being separated from the inner surface of the insertion portion 117 .

The cap protrusion 125 is pressed outwardly from the inside to protrude radially outward, and a concave groove is formed on the inner surface of the cap body 121 in the circumferential direction at the portion where the cap protrusion 125 is formed. Since the inner side of the cap protrusion 125 is formed concave, the deformation of the cap protrusion 125 is easy, and accordingly, it is possible to further increase the amount of interference between the cap protrusion 125 and the inner surface of the insertion part 117, and the leakage effect of the lubricant is reduced. it gets bigger

The material of the cap 120 for the pinion shaft according to the present invention is not limited, and it can be made of metal such as SPCC, and it can also be made of synthetic resin such as nylon 66.

5 schematically shows the manufacturing process of the cap 120 for the pinion shaft made of metal, and as shown in FIG. 5, a circular plate-shaped first member 120-1 is prepared by shearing from the plate-shaped base material, and , by pressing one side of the first member 120-1 to form a plurality of concentric portions 120-2a having different diameters to form a second member 120-2. A plurality of ring-shaped convex portions (not shown) forming concentric protrusions formed by the formation of the concave portion 120-2a are formed on the opposite surface where the concave portion 120-2a is formed.

The second member 120-2 is pressed downward with a punch having a circular cross section with the surface on which the concave portion 120-2a is formed as the upper surface, and the cylindrical cap body part 121 and the circular cap bottom on one side. It is molded into a cap 120 for a pinion shaft having a portion 123 (deep drawing).

In order to prevent the effect of the convex part from disappearing due to the reduction in the height of the convex part by the mold during deep drawing, the cylindrical cap body part 121 and It may be molded into a cap 120 for a pinion shaft having a circular cap bottom 123 on one side (deep drawing). In this case, the concave portions are formed outwardly, and the portion between the concave portions serves as the convex portion.

A plurality of convex portions formed on the opposite surface of the concave portion 120 - 2a becomes the ring-shaped cap protrusion 125 formed on the outer surface of the cap body portion 121 . The concave portion 120 - 2a is a concave groove formed on the inner surface of the cap body portion 121 .

The cap bottom portion 123 is a plate-shaped circular shape, and is preferably formed in a conical shape with the center portion protruding by pressing the center portion when it is inserted into the insertion portion 117 of the pinion shaft 110 . Since the cap bottom part 123 is formed in a conical shape, the flowing lubricating oil comes into contact with the inclined cap bottom part 123 to smoothly flow without stagnation. The inclination angle θ of the cap bottom 123 is in the range of 1 to 3°.

100: pinion shaft cap assembly 110: pinion shaft
120: cap for pinion shaft

Claims (6)

A connection hole 111 extending in the axial direction and opened to one end in the axial direction, a first hole 113 extending outward in a radial direction from the connection hole 111 and opened to the outside, and the first hole 113 A second hole 115 spaced apart from the axial direction and extending radially outwardly from the connection hole 111 and opened to the outside is formed, and an insertion part 117 is provided at the opened end of the connection hole 111 . As a pinion shaft cap 120 inserted into the insertion portion 117 of the pinion shaft 110;
It consists of a cap body part 121, which is a hollow body, opened on both sides, and a cap bottom part 123 connected to an open end of one side of the cap body part 121. The cap 120 for the pinion shaft is formed, and the cap protrusion 125 is provided on the outer surface of the cap body 121 to protrude outward and contact the inner surface of the opening insertion portion 117 of the connection hole 111 . ). According to claim 1, wherein the inner surface of the insertion portion 117 is formed in a cylindrical surface, the cap body portion 121 is formed in a cylindrical body, and the cap protrusion portion 125 is formed on the outer surface of the cap body portion (121). The cap 120 for a pinion shaft, characterized in that it is formed in a ring shape along the circumferential direction, and the cap protrusion 125 is in contact with the inner surface of the insertion part 117 along the circumferential direction. The cap 120 for a pinion shaft according to claim 2, wherein a plurality of the cap protrusions 125 are spaced apart from each other in the axial direction. [4] The pinion shaft according to claim 3, wherein at least one of the cap protrusions 125 has an inclination angle (120-2b1) of the inward-facing surface greater than the inclination angle of the outward-facing surface (120-2b2). cap (120). According to claim 3, wherein the cap protrusion 125 is pressed outwardly from the inside to form a radially outwardly protruding shape, the inner surface of the cap body 121, a concave groove at the portion where the cap protrusion 125 is formed is circumferential Cap 120 for the pinion shaft, characterized in that formed along the direction. [Claim 5] The cap 120 for the pinion shaft according to claim 3 or 4, wherein the cap bottom portion 123 is formed in a conical shape with a protruding center portion.

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