This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2016-64793 filed on Mar. 29, 2016, the entire contents of which are incorporated herein by reference.
The present invention relates to a rocker arm and a method of manufacturing the rocker arm.
Japanese Patent Application Publication No. JP-A-2011-196240 discloses a rocker arm including an arm body formed by pressing a metal plate. The arm body has an engagement portion which a rocking fulcrum member slidably engages, a sliding portion on which an end of a valve stem is slid, and a pair of sidewalls opposed to each other between the engagement portion and the sliding portion. A hollow potion is defined between both sidewalls, and a roller which is brought into contact with a cam is rotatably housed in the hollow portion. The sidewalls have respective shaft holes into which a rotating shaft of the roller is to be mounted.
In the meantime, a modification in a vehicle or the like increases load input from a cam to the rocker arm. In this case, the rocker arm sometimes requires a large load resistant performance. In order that this problem may be coped with, for example, a thickness of the arm body may be increased so that the rigidity of the rocker arm can be improved. However, since the increase in the thickness of the arm body results in an increase in inertial mass, there is a concern that the responsiveness during rocking would be reduced. Furthermore, a biasing force of a valve spring needs to be increased, and thus, the increase in the thickness of the arm body has a large influence on the design of the entire valve gear.
The present invention was made in view of the foregoing circumstances and an object thereof is to provide a rocker arm which can ensure sufficient rigidity against input load and which can reduce the inertial mass.
In one aspect, the present invention provides a rocker arm including a pair of sidewalls disposed along a heightwise direction so as to be opposed to each other. The sidewalls define a space to house a roller and have opposed portions extending in the heightwise direction relative to adjacent portions which are adjacent to the opposed portions. The opposed portions have thinner portions having smaller thicknesses than the adjacent portions.
According to the above-described rocker arm, since the thinner portions are rendered thinner, an inertial mass of the rocker arm can be reduced accordingly. In particular, since the opposed portions largely extending in the heightwise direction, the thinner portions can easily be formed utilizing the height of the opposed portions. Furthermore, since the adjacent portions of the sidewalls which are adjacent to opposed portions can be formed with the usual thicknesses, the rocker arm can ensure rigidity sufficient to withstand input load.
In another aspect, the invention provides a method of manufacturing a rocker arm, which includes stamping a plate material to form a developed body having a through hole, applying pressure to parts of the developed body located at both sides of the through hole to stretch the parts of the developed body, thereby forming thinner portions, and folding the developed body via a pair of folding portions parallel to each other thereby to raise portions with the thinner portions in a heightwise direction, so that a pair of sidewalls are formed which are opposed to each other with a space for housing a roller being interposed therebetween.
According to the above-described method, the above-described rocker arm can easily be manufactured by pressing. Particularly in the step of forming the thinner portions, pressure is applied to the parts of the developed body located at both sides of the through hole so that the parts are stretched. This can render the surface area of the developed body at the time of stamping the plate material smaller by an amount of stretch. Consequently, the yield of the plate material can be improved.
In the accompanying drawings:
A first embodiment will be described with reference to
Referring to
The supporting member 96 may be a lash adjuster for example, and has a plunger 97 having an upper end against which a support receiving portion 22 of the rocker arm 10 abuts, and a cylindrical body 98 for housing a plunger 97. The support receiving portion 22 will be described later. The body 98 is inserted into a mounting hole 99 of the cylinder head 91. The plunger 97 is reciprocable in the up-down direction with respect to the body 98 depending on variations in hydraulic pressure. Upon reciprocation of the plunger 97, the valve abutting portion 18 is adjusted so that no clearance is produced between the valve abutting portion 18 and the valve 94.
The rocker arm 10 includes an arm body 11 comprising a metal plate material. The arm body 11 is integrally formed by bending the plate material and comprises a pair of sidewalls 12, a valve side connecting portion 13 and a support side connecting portion 14, as illustrated in
The paired sidewalls 12 are disposed substantially in parallel to each other and shaped to extend in an axial direction (in a direction of line X-X in
A housing space 16 for housing a roller 30 is defined between both opposed portions 15. The opposed portions 15 have respective central parts through which circular shaft holes 17 are coaxially formed. Furthermore, the opposed portions 15 are formed so as to have substantially constant widths in a radial direction around the shaft holes 17.
A shaft member 40 is mounted to extend through the shaft holes 17 while crossing the housing space 16. The shaft member 40 has two ends swaged thereby to be fixed to the opposed portions 15. Furthermore, the roller 30 is rotatably supported at a middle part of the shaft member 40 via a bearing 41 such as a needle bearing.
The valve side connecting portion 13 is disposed in a width direction of the arm body 11 (a direction in which both sidewalls 12 are opposed to each other) between upper ends of axial ends 19 of both sidewalls 12, thereby defining and closing an axial one end of the housing space 16. The valve abutting portion 18 is formed to have a gate-shaped cross-section by the axial ends 19 of the sidewalls 12 and the valve side connecting portion 13. The valve 94 has a stem upper end which abuts against an underside of the valve side connecting portion 13 and is configured to be guided so as to be prevented from falling-out by the axial ends 19 of the respective sidewalls 12.
The support side connecting portion 14 is disposed between upper ends of the other axial ends of the sidewalls 12 in the width direction of the arm body 11, thereby defining and closing the other axial end of the housing space 16. The support receiving portion 22 is formed to have a gate-shaped cross-section by the other axial ends 21 of the sidewalls 12 and the support side connecting portion 14. The support side connecting portion 14 has a middle part provided with a substantially semi-spherical bulging portion 23 bulging upward. The plunger 97 serving as a supporting member 96 has a top which is slidable on a semispherically recessed underside of the bulging portion 23.
The opposed portions 15 have upper and lower ends (both heightwise ends) provided with respective thinner portions 24. The thinner portions 24 are formed to be thinner than surrounding portions (a portion near the shaft holes 17 of the opposed portions 15 and both axial ends 19 and 21 of the sidewalls 12). More specifically, the thinner portions 24 extend along the upper and lower ends of the opposed portions 15, and as illustrated in
Parts of the sidewalls 12 except for the thinner portions 24 are formed so as to have a substantially constant thickness. Furthermore, the sidewalls 12 have inner surfaces formed into wall surfaces continuously rising steeply in the heightwise direction without unevenness inclusive of upper and lower ends which are opposed to the thinner portions 24 in the thickness direction.
Next, the working of the rocker arm 10 will be described with reference to
The developed body 60 has a through hole 61 which is formed through a substantially central portion thereof and corresponds to the housing space 16 for the roller 30. The through hole 61 has an opening generally rectangular in shape with rounded corners. The developed body 60 includes two widthwise sides sandwiching the through hole 61 (upper and lower sides as viewed in
Subsequently, a press die (not illustrated) is pressed against both widthwise ends of each original-shape portion 62 (including the straight portion 63 and the gentle arc-shaped portion 64) from outside. In this pressing process, the inner surfaces of both widthwise ends of the original-shape portions 62 are supported by dies (not illustrated), and outer surfaces of both widthwise ends of the original-shape portions 62 are pressed by dies (not illustrated) thereby to be crushed. As a result, the pair of straight portions 63 are curved to jut out in such a manner that the straight portions 63 come close to each other inward of the through hole 61 thereby to be stretched inward, and the gentle arc-shaped portions 64 are stretched outward so as to depart from the through hole 61. Consequently, both widthwise ends of the respective original-shape portions 62 are deformed so as to be stretched to both widthwise sides (both heightwise sides after forming), whereby the thinner portions 24 are formed as illustrated in
Next, the developed body 60 is folded via a pair of folding portions 65 which are located at both sides with the through hole 61 being interposed therebetween and are parallel to the axial direction. In this folding process, the developed body 60 is held by a plurality of molding dies (not illustrated), and both sidewalls 12 are formed to be perpendicular to and to be continuous with the valve side connecting portion 13 and the support side connecting portion 14. Furthermore, the housing space 16 for the roller 30 is defined between the valve side connecting portion 13 and the support side connecting portion 14 and between both sidewalls 12, as illustrated in
Next, a mold pin (not illustrated) is caused to penetrate through the central parts of the opposed portions 15 of both sidewalls 12 from the widthwise outside, so that the shaft holes 17 are bored. As a result, the arm body 11 is formed. The roller 30 is subsequently disposed in the housing space 16 of the arm body 11. The shaft member 40 is then caused to extend through the roller 30 with the bearing 41 being interposed therebetween, and both ends of the shaft member 40 are inserted through the shaft holes 17 of the opposed portions 15 and then swaged thereby to be fixed.
According to the above-described rocker arm 10 of the first embodiment, since the thinner portions 24 are thinner than the portions of sidewalls 12 adjacent to the respective thinner portions 24, an inertia mass of the arm body 11 can be reduced accordingly, in particular, the thinner portions 24 are thinned utilizing the up-down dimensions of the opposed portions 15, the freedom in the design of the thinner portions 24 can be improved.
Furthermore, since the part of the arm body 11 other than the thinner portions 24 has a usual thickness, the valve abutting portion 18, the support receiving portion 22 and the like can be formed to have respective rigidities enough to withstand the input load.
Furthermore, the shaft member 40 rotatably supporting the roller 30 is held in the shaft holes 17 of the respective opposed portions 15. The thinner portions 24 are formed on the outer surfaces of the opposed portions 15 so as to have shapes such that the thinner portions 24 are recessed. The inner surface of each opposed portion 15 is continuous overall, without unevenness. Accordingly, the bearing 41 such as needle bearing is prevented from being caught by the inner surfaces of the opposed portions 15, with the result that the bearing 41 can be provided without any difficulty.
Furthermore, the thinner portions 24 are provided only on the upper and lower ends (both heightwise ends) of the opposed portions 15. This can reduce influences of the thinner portions 24 on the shaft holes 17 formed in the central parts of the opposed portions 15.
According to the above-described method of manufacturing the rocker arm 10 of the first embodiment, the rocker arm 10 can easily be manufactured from a single plate material by the pressing process. Particularly in the process of forming the thinner portions 24, pressure is applied to the portions of the developed body 60 located at both sides of the through hole 61 so that the portions are stretched. Accordingly, the surface area of the developed body 60 at the time of the punching of the plate material can be rendered smaller by an amount of stretch. As a result, the yield of plate material can be improved. Particularly in the pressure applying process, the paired straight portions 63 are curved to jut out in such a manner that the straight portions 63 come close to each other inward of the through hole 61. Consequently, the space inside the through hole 61 can effectively be used with the result of further improvement of the yield.
Furthermore, since pressure is applied to the developed body 60 so that the thinner portions 24 are formed, the inner tissues of the thinner portions 24 are rendered denser with the result that the strength of the thinner portions 24 can be ensured.
The thinner portions 24A are formed on entire outer surfaces of the opposed portions 15 of both sidewalls 12 over entire heights of the opposed portions 15. In manufacture of the thinner portions 24A, entire outer surfaces of parts of the developed body 60 to be formed into the opposed portions 15 later are pressed and stretched by a press die. Accordingly, the opposed portions 15 are rendered thinner in their entirety than both axial ends 19 and 21, so that the outer surfaces of the opposed portions 15 are disposed one level lower than the outer surfaces of both axial ends 19 and 20 of the sidewalls 12. The second embodiment is identical with the first embodiment in the other respect.
According to the second embodiment, the structure of the press die used to form the thinner portions 24A can be simplified, and the thinner portions 24A can be manufactured in a relatively rougher manner.
The thinner portions 24B are formed on circumferential edges of the shaft holes 17 in the opposed portions 15 of both sidewalls 12 over entire circumferences of the shaft holes 17. However, no thinner portions 24B are formed on the parts of the opposed portions 15 other than the circumferential edges of the shaft holes 17. As shown in
According to the third embodiment, since the circumferential edges of the shaft holes 17 of the opposed portion 15 are rendered thinner by the thinner portions 24B, the mold pin used to form the shaft holes 17 can be rendered smaller. This can contribute to reduction in size of the rocker arm 10.
Furthermore, the central parts of the thinner portions 24B are removed from the arm body 11B as the result of the boring of the shaft holes 17 through the centers of the thinner portions 24B. Thus, the forming ranges of the thinner portions 24B remaining in the arm body 11B can be narrowed. Accordingly, reduction in the rigidity of the rocker arm 10 can effectively be suppressed while the improvement of the yield is realized by the stretch of the developed body 60.
Other embodiments will briefly be described in the following.
Number | Date | Country | Kind |
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2016-064793 | Mar 2016 | JP | national |