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Debris particle contamination in lubricants has been identified as a major cause of premature bearing and gear failure, with accompanying costs in equipment downtime, warranty, and lost productivity. Various experimental and predictive methods have been developed to assist the design engineer in analysis and development of equipment that is less sensititive to such contamination. This paper provides an overview and new data comparing bearing life test results and predictive analysis methods for various tapered roller bearings operating under debris-contaminated conditions. As a baseline, some past work in these areas is briefly summarized and referenced. Recent work has refined one analytical method (using a surface characterization technique), correlated this method with bearing test lives in debris conditions, and pointed to design and manufacturing modifications in the bearings themselves, making the bearings live longer in debris-contaminated environments.

Improved fuel economy translates into significant savings over the life of a fleet vehicle. Aside from fuel cost savings, tighter emissions regulations require truck Original Equipment Manufacturers (OEMs) to improve the fuel economy of the products they bring to market. OEMs are dependent on Tier 1 suppliers for many systems which have a direct impact on vehicle fuel efficiency. Tier 1 suppliers are then dependent on sub-suppliers for components which affect the fuel efficiency of the system. Improvements in tapered roller bearing design and technology can significantly improve the fuel efficiency of driveline systems. This paper summarizes the improvement in bearing efficiency by applying advanced design and technology solutions. Analysis was used to predict the affect of design changes, leading to an optimized solution. Testing was performed to verify the improvement in bearing efficiency.

Environmental effects on fatigue and non-fatigue modes of tapered roller bearing damage are discussed. Primary emphasis is placed on the influence of load, speed, lubricant and temperature on the fatigue modes of damage. Effects of dissolved water in oil, traction fluids and fire resistant hydraulic fluids are included.

Increased size, payload and horsepower requirements are the trend in today's off-highway industry. This paper discusses the role of new anti-friction roller bearing technology in avoiding problems created by changing design considerations and the performance/cost/EPA triad currently squeezing designers and manufacturers of rubber tired earthmoving machinery. A comparison is made of bearing fatigue life determined by several methods including those derived from vehicle instrumentation and purely empirical criteria. Some common problems relating to the mounting and set up of large wheel bearings are also reviewed together with corresponding remedies.

Building quality into products requires the dedication of a total team that includes the product designer, process engineer, production personnel, process maintenance personnel, and a total process control system. Operating a process to a known state of capability and sustaining it must be recognized as a multiple functional task as technological changes occur. The understanding of how to manage with changed capability requires a team to understand the characteristics of both the process and the product which need to be monitored to assure that quality is built in. With the increased usage of computers into a manufacturing environment, the task of real time, preemptive management of a process can be achieved. Competitive advantage is a result of the improved capability of the total process that provides maximum yield, process up-time, and sustainability of results.