Some 100 years after the ball bearing was invented and 50 years after the first needle roller bearing was produced, the Schaeffler Group has developed a new bearing concept, combining the best of both ball bearing and roller bearing technologies.
The prototype 'ball roller' bearing incorporates bearing elements that are spherical, but which have their sides cut off. While the design may sound simplistic, the research and development behind this radical breakthrough has been significant. The result is a range of ball roller elements that offer all the axial load handling capabilities of fully spherical balls, but more importantly, allow overall bearing width and mass to be decreased by around 20%, as well as a reduction in friction. Thus, in the same design space, it is possible to carry greater loads and provide a larger grease reservoir, or more space for improved sealing.
The novel bearings were unveiled at Schaeffler's 'Innovation Days', a customer open day held at the company's headquarters in Schweinfurt, Germany, in May this year. The 'ball roller' was demonstrated to more than 100 design and development managers attending the conference, who, if they wish, can now begin their own tests with product samples.
The 'ball roller', which was developed over a period of almost two years, represents a genuine breakthrough in new bearing technology and should generate huge interest from the automotive industry and other industrial sectors, particularly where compactness of bearings is a key design consideration. Manufacturers of wheel bearings and automotive transmission systems such as gearboxes, are potential beneficiaries of the new technology.
"The idea for the ball roller came from our development engineers, who were testing ball bearings and discovered that the spherical balls tended to roll about a single axis and made no use of those areas adjacent to this axis," recalls Schaeffler development engineer, Heinrich Hofmann.
In a typical ball bearing, only 70% of the ball width is utilised, so the outer 15% to the left and right of the ball diameter can be considered redundant. The company considered that cutting off this 'redundant' material from the sides of the balls might just be feasible. After six months of advanced 3D modelling, finite element analysis (FEA) simulation, and dynamic modelling using the firm's own proprietary bearing dynamic modelling software, the first prototypes were developed. Initially, these were based on single row bearings, then double row roller bearings, then four-row bearings, to be used as vehicle wheel bearings.
According to Hofmann, as the balls cannot be allowed to change their rotation axes to any great extent, cage design was crucial. The critical conditions occur during initial rotation. Once the bearings are moving under conditions of speed and load, they become self-locating, like a bicycle wheel.
The company's 'KXR' range of bearings was tested using the new concept in combination with a novel cage design. The pocket bases of the cage were designed so that, under load, the ball roller aligned itself freely as a function of the contact angle.
Aside from the obvious benefits from being able to manufacture thinner bearings - or maintaining the same thickness for a higher load carrying capacity - it is possible to get more bearing elements into the same size of bearing. The balls are loaded by positioning the inner race eccentrically with respect to the outer race. Because the ball rollers have their sides cut off, it is possible, for example, to get 11 ball roller elements into the company's '6207' basic bearing rather than nine fully round balls.
In addition, having moved away from a fully spherical shape, it is possible to give the roller a logarithmic profile, since the rotational axis is always perpendicular to the variable contact angle. Therefore, the oscillation conditions - the 'kiss' between the roller and the bearing groove - do not change. If the load ratio changes from axial to radial and the contact angle changes as a result, the oscillation 'creeps' in an optimum manner with the change in load.
All computer-based simulations and running tests at Schaeffler have demonstrated that the rollers rotate about their intended rotational axes. Due to their moments of inertia, the rollers are more quickly stabilised than fully spherical balls by 'gyroscopic effects' similar to those that make bicycle pedals more stable at higher speeds.
The new bearings already exist in a variety of designs depending on their intended application.