Engineering:Flexure bearing
A flexure bearing is a category of flexure which is engineered to be compliant in one or more angular degrees of freedom. Flexure bearings are often part of compliant mechanisms. Flexure bearings serve much of the same function as conventional bearings or hinges in applications which require angular compliance. However, flexures require no lubrication and exhibit very low or no friction.[1]
Many flexure bearings are made of a single part: two rigid structures joined by a thin "hinge" area. A hinged door can be created by implementing a flexible element between a door and the door frame, such that the flexible element bends allowing the door to pivot open.
Flexure bearings have the advantage over most other bearings that they are simple and thus inexpensive. They are also often compact, lightweight, have very low friction, and are easier to repair without specialized equipment. Flexure bearings have the disadvantages that the range of motion is limited, and often very limited for bearings that support high loads.
A flexure bearing relies on the bearing element being made of a material which can be repeatedly flexed without disintegrating. However, most materials lose strength and eventually fail with repeated flexing and bending. For example, most metals will fatigue with repeated flexing, and will eventually snap. Thus, one part of flexure bearing design is the careful consideration of material properties to avoid fatigue with normal use.
Flexure bearings can give very low friction and also give very predictable friction. Many other bearings rely on sliding or rolling motions (rolling-element bearings), which are necessarily uneven because the bearing surfaces are never perfectly flat. A flexure bearing operates by bending of materials, which causes motion at microscopic level, so friction is very uniform. For this reason, flexure bearings are often used in sensitive precision measuring equipment.
Many types of flexure bearings are not limited to low loads, however. For example, the drive shafts of some sports cars replace cardan universal joints with an equivalent joint called a rag joint which works by bending rubberized fabric. The resulting joint is lighter yet is capable of carrying hundreds of kilowatts, with adequate durability for a sports car.
Because flexure bearings do not rely on sliding or rolling motions, they do not require lubrication. Consequently, they can be employed in abrasive environments and environments hostile to lubricants: underwater, in a vacuum and at elevated temperatures.
See also
References
- ↑ Malka, Ronit (18 Sep 2014). "Principles of Microscale Flexure Hinge Design for Enhanced Endurance". 2014 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS 2014). https://scholar.harvard.edu/yufengchen/publications/principles-microscale-flexure-hinge-design-enhanced-endurance.
External links
- NASA Tech Brief
- Awtar, Shorya; Slocum, Alexander H. (24 September 2006). Parasitic Error-free Symmetric Diaphragm Flexure, and a set of precision compliant mechanisms based it: Three and Five DOF flexible torque couplings, Five DOF motion stage, single DOF linear/axial bearing (Report). MIT. http://www-personal.umich.edu/~awtar/PHD/Diaphragm.pdf.
- Kinematic Models for Design Digital Library (KMODDL) - Movies and photos of hundreds of working mechanical-systems models at Cornell University. Also includes an e-book library of classic texts on mechanical design and engineering.
- Weinstein, Warren D., "Flexure-Pivot Bearings", Machine Design, Part 1, June 10, 1965, Part 2, July 8, 1965 - Spring rates, bearing types, single and multi-strip design, material types, hysteresis and fatigue
- Weinstein, Warren D., "Microperformance of Metals". Machine Design, September 11, 1969 - Material relaxation and rolamite
- The Bal-tec Flexural Encyclopedia
Original source: https://en.wikipedia.org/wiki/Flexure bearing.
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