Patent Application
20050150111
The present invention is directed to a constant velocity joint (“CV joint”) and method of forming the same.
Two types of Rzeppa CV joints are commonly used in vehicles. The first type is a bell shaped CV joint and the second type is a disc shaped CV joint. The bell shaped CV joint is formed with a bell shaped outer bearing race having a bell shaft protruding from the crown of the bell. The bell and bell shaft are generally aligned symmetrically about a bell axis. Reference points may be forged on the bell and bell shaft for locating the bell axis during machining. The reference points allow precise and accurate machining of the bell shaped outer bearing race to provide a well balanced outer bearing race about the bell axis.
Disc shaped CV joints typically include a disc shaped outer bearing race, an inner bearing race, and stub shaft having a hub on one end. Alternatively, the disc shaped CV joint may be formed without the stub shaft and instead be flange mounted to a shaft. When assembled, the inner race fits within the outer disc race, with ball bearings located therebetween. A splined portion of the stub shaft then fits within the inner bearing race, specifically a splined hub on the inner bearing race. The CV joint provides articulation by the outer bearing race, connected to one shaft of the driveshaft, articulating relative to the inner bearing race and stub shaft, connected to the other shaft of the driveshaft. The outer bearing race and stub shaft are separately forged with each having their own axis. Therefore, during machining, the outer bearing race and stub shaft are machined about their respective axes, which may not be in alignment when assembled into a CV joint. To provide a CV joint with minimal noise, vibration, and harshness issues, the axes should be in alignment with one another when assembled and in alignment with the axis of the assembled CV joint. Another problem with disc shaped CV joints is that they are typically difficult to precisely and accurately manufacture, because each part is separately formed and machined. Other problems include finding the axis of each part during the machining process, especially the disc shaped outer bearing race. Each of the above problems makes it difficult to efficiently machine and assemble the CV joint so that the axes of each part are aligned and balanced to reduce or eliminate noise, vibration, and harshness issues. Another problem with disc type CV joints is that it currently is not possible to efficiently and repeatedly form the outer disc bearing race to near net shape tolerances so that the amount of machining is limited, especially machining of bearing races.
The present invention is directed to a constant velocity joint (“CV joint”) and, more particularly, to a Rzeppa CV joint and method of forming the same. The method generally includes the steps of forming a bell shaped outer bearing race and separating the bell shaped outer bearing race into a disc shaped outer bearing race and a stub shaft. The method may further include the step of machining the bell shaped outer bearing race to create the stub shaft integrally connected to the disc shaped outer bearing race, before separating the bell shaped outer bearing race into the disc shaped outer bearing race and the stub shaft.
The bell shaped outer bearing race may include a bell axis, an outer surface and a first face and the step of machining the bell shaped outer bearing race may further include the step of creating reference datums on at least one of the outer surface and first face of the integrally coupled stub shaft and disc shaped outer bearing race. The step of machining the bell shaped outer bearing race may also includes the step of using a reference point and an outer bearing recess and/or a cage track to determine the bell axis. Splines, snap ring grooves and boot grooves may also be formed on the stub shaft.
The method of forming a constant velocity joint may also include the steps of, forming a bell shaped outer bearing race having a housing defining a cavity, a crown, and a bell shaft extending from said crown, and separating the housing defining a cavity from the crown and the bell shaft. The bell shaped outer bearing race may further include a bell axis, a first reference point defined by at least one of the crown and the bell shaft, a cage track and an outer bearing recess, and wherein the method further includes the step of machining the bell shaped outer bearing race about the bell axis using the reference point and the outer bearing recess and/or the cage track as references. Reference datums may also be created on at least one of the said housing and stub shaft during the machining process for use later in locating the bell axis.
The method of the present invention may also be used to form a cross groove CV joint in place of a Rzeppa CV joint.
Further scope of applicability of the present invention will become apparent from the following detailed description, claims, and drawings. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art.
The present invention will become more fully understood from the detailed description given here below, the appended claims, and the accompanying drawings in which:
An illustrative embodiment of a CV joint 10 constructed and assembled in accordance with the present invention is shown in
The bell shaped outer bearing race 20 is formed (Step 102) in a generally conventional manner such as by forging. The bell shaped outer bearing race 20 includes a housing 21 defining a cavity 19, a crown 23, and a bell shaft 24 extending from the crown (
Next, the bell shaped outer bearing race 20 is machined using at least one of the reference points 26 to create an integrally connected stub shaft 30 and outer bearing race 40 (Step 104). To machine the outer surface 22 about the bell axis, at least one outer ball recess 48 or cage track may be used in conjunction with at least one reference point 26 to locate the bell axis 25. In the illustrated embodiment, a three prong chuck engages the outer bearing recesses 48 and at lest one reference point 26 during machining. During the machining process or after heat treating, the outer bearing recesses 48 may be further machined and polished to their final shape, and the first face 42 of the outer bearing race 40 may be created by machining the outer bell face 28. The second face 44 of the outer bearing race 40 is also partially created during the machining process of the outer bell surface 22 and further created as the stub shaft 30 is separated from the outer bearing race 40 as described below. Splines 32, snap ring grooves 34, and a boot clip groove 36 may also be machined while the stub shaft 30 is connected to the disc shaped outer bearing race 40. The majority of machining is generally done to the outer bell surface 22 to remove excess material in order to create the stub shaft 30, specifically the stub shaft hub 38 integrally connected to the outer disc bearing race 40. Performing the machining process while the stub shaft 30 is connected to the disc shaped outer bearing race 40 ensures that, when separated, the stub shaft axis 31 is in alignment with the outer bearing race axis 41. Because both the stub shaft 30 and disc shaped outer bearing race 40 are machined while connected, using the reference points 26 for locating the bell axis 25, they are balanced about aligned axes. Using the outer bearing recesses 44 or cage tracks 49 with at least one reference point allow the outer surface 22 to be machined to create reference datums used in the machining of the outer bearing recesses 48 or other operations. The reference datums may be the machined outer surface 22 shown in
The machined bell shaped outer bearing race 20 is then separated into the stub shaft 30 and the disc shaped outer bearing race 40 (Step 106). During separation, the second face 44 of the disc shaped outer bearing race 40 may be created (
The CV joint 10 is then assembled (Step 108) as shown in
Forming the disc shaped outer bearing race 40 and stub shaft 30 as a single integral piece allows for easier machining and a better balanced CV joint. Manufacturing costs are also reduced by eliminating complicated processes to determine the axis of the disc shaped outer bearing race 40 for machining. Reference datums may also be easily created for additional machining operations. As stated above, a typical bell shaped outer bearing race may be used as the bell shaped outer bearing race 20. The bell shaped outer bearing race 20 may also be formed by forging a shape close to the integrally connected outer bearing race and stub shaft. The bell shaped outer bearing race 20 is then machined and separated to provide the resulting stub shaft 30 and outer bearing race 40. The bell shaped outer bearing race 20 may also be near net formed to minimize the amount of machining in forming the outer disc bearing race 40.
The method of the present invention may also be used to form a cross groove CV joint in place of a Rzeppa CV joint.
The foregoing discussion discloses and describes an exemplary embodiment of the present invention. One skilled in the art will readily recognize from such discussion, and from the accompanying drawings and claims that various changes, modifications and variations can be made therein without departing from the true spirit and fair scope of the invention as defined by the following claims.
