This invention generally relates to a driveline yoke with a stiffness ring that more evenly distributes load forces.
Vehicle drivelines typically include a series of driveshafts that are connected to each other at connection interfaces. Various connection interfaces can be used to connect these driveshafts, such as flanges or universal joint yokes for example. Flanges and universal joint yokes each include a hub portion with a bore that receives one end of a driveshaft. A flange includes a substantially flat connection interface that connects to another flange component. A yoke is connected to another yoke with a cross member to form a universal joint. The cross member includes four trunnions. One yoke includes a pair of yoke arms that are coupled to two trunnions of the cross member. The remaining pair of trunnions are coupled to another pair of yoke arms on a second yoke to form the universal joint.
One advantage with a flange connection is that torque loads are evenly distributed across the body of the flange such that torque levels are at an acceptable level when they reach a reduced diameter area at the hub portion. When a flange connection is replaced by a universal joint yoke, due to the opposing connection point interfaces of the yoke arms, stress levels are significantly increased at the hub portion, which can result in premature wear or failure.
A driveline yoke includes a body with a pair of yoke arms that are adapted to receive a cross member. The body includes a stiffness ring that comprises an increased diameter portion that extends radially outwardly from the body at least in regions of the yoke arms.
In one example, the increased diameter portion extends about a substantial portion of an outer periphery of the body. In another example, the increased diameter portion extends entirely about the outer periphery of the body.
The body includes a hub portion on one side and the yoke arms extend outwardly from the body on an opposite side. The hub portion receives one end of a driveshaft that is rotatable about an axis. The increased diameter portion extends radially outwardly from the body at least in regions of each of the arms such that the arms are located radially closer to the axis than an outer peripheral edge of the increased diameter portion.
These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.
A heavy-duty vehicle 10 includes a powertrain assembly, shown generally at 12, that transfers driving power from a vehicle power source 14 to a plurality of wheels 16. The power source 14 can comprise an engine or electric motor, for example, and can be operably coupled to a transmission 18 in a known manner. A driveline assembly 20, including at least one driveshaft 22, is used to transfer driving power from the transmission 18 to a drive axle assembly 24 that supports the wheels 16. In the example shown, the drive axle assembly 24 is a tandem drive axle; however, other types of axles could also be utilized. The tandem drive axle includes a forward-rear axle 24a and a rear-rear axle 24b that are interconnected to each other.
U-joints allow two adjoining driveline components to be positioned at different angles relative to each other to accommodate relative movement and angular misalignment. Misalignment and relative movement can be caused by adjoining driveline components not being mounted within a common plane, or can be caused by a driveline component, such as a drive axle assembly 24, moving relative to adjoining driveline component, such as a driveshaft 22, in response to interaction with a vehicle suspension.
The cross member 28 is shown in greater detail in
The yoke 26 is shown in greater detail in
The hub portion 46 is defined by a first outer diameter D1 as shown in
The hub portion 46 includes a bore 58 that includes a splined surface 60 as shown in
The body 40 includes a generally flat surface area 62 in regions near the first 48 and second 50 yokes arms as shown in
The distal ends 66 comprise a generally flat surface that includes a pair of fastening holes 68. Between the fastening holes 68, the distal ends 66 each include a recessed area 70 that is to receive one trunnion 34 of the cross member 28 (
The stiffness ring 52 comprises an increased diameter portion that is integrally formed as part of the body 40, i.e. the body 40 and stiffness ring 52 comprise a monolithic structure. This allows torque to be more evenly distributed throughout the body before reaching the reduced diameter area at the hub portion 46. Analysis indicates that the use of the stiffness ring reduces torque levels at the hub portion of the yoke by 50% compared to a traditional yoke without the stiffness ring.
In the example shown in
Although a preferred embodiment of this invention has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.
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Wagner et al, “Driveshaft Attachment Methods,” Universal Joint and Driveshaft Design Manual, AE-7, Society of Automotive Engineers, Inc., Warrendale, PA, pp. 209-211, TJ1079.S62 1979. |
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20120034983 A1 | Feb 2012 | US |