Difference between revisions of "Ball bearing" - New World Encyclopedia

From New World Encyclopedia
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==See also==
 
==See also==
  
*[[Ball screw]]  
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* [[Bicycle]]
*[[Bearing (mechanical)]]
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* [[Friction]]
*[[Thrust bearing]]
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* [[Gear]]
*[[Linear bearing]]  
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* [[Wheel]]
*[[Rolling-element bearing]]
 
*[[Brinell scale]], a material hardness scale that can help determine the failure mode of ball bearings
 
  
 
== Notes ==
 
== Notes ==
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==References==
 
==References==
 +
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* Brändlein, J., et al. 1999. ''Ball and Roller Bearings: Theory, Design, and Application'', 3rd ed. Chichester: Wiley. ISBN 0471984523
 +
 +
* Harris, Tedric A., and Michael N. Kotzalas. 2006. ''Essential Concepts of Bearing Technology.'' Rolling Bearing Analysis, v. 1 (5th ed.). Boca Raton, FL: Taylor & Francis. ISBN 978-0849371837
  
  

Revision as of 01:00, 22 November 2008

Working principle for a ball bearing.
A four-point, angular contact ball bearing.

A ball bearing is an engineering term referring to a type of rolling-element bearing which uses balls to maintain the separation between the moving parts of the bearing.

The purpose of a ball bearing is to reduce rotational friction and support radial and axial loads. It achieves this by using at least two races to contain the balls and transmit the loads through the balls. Usually one of the races is held fixed. As one of the bearing races rotates it causes the balls to rotate as well. Because the balls are rolling they have a much lower coefficient of friction than if two flat surfaces were rotating on each other.

Ball bearings tend to have lower load capacity for their size than other kinds of rolling-element bearings due to the smaller contact area between the balls and races. However, they can tolerate some misalignment of the inner and outer races.

Compared to other bearing types, the ball bearing is the least expensive, primarily because of the low cost of producing the balls used in the bearing.

History

Leonardo da Vinci has been credited with the discovery of the principle behind the mechanics of ball bearings.

The first patent was awarded to Jules Suriray, a Parisian bicycle mechanic, on August 3, 1869.[1] The bearings were then fitted to the winning bicycle ridden by James Moore in the world's first bicycle road race, Paris-Rouen, in November 1869.[2]

The modern, self-aligning design of ball bearing is attributed to Sven Wingquist of the SKF ball-bearing manufacturer in 1907.

Ball bearings were found on the Roman Nemi ships constructed in about 40 C.E.[3]

Common designs

There are several common designs of ball bearings, each offering various tradeoffs. They can be made from many different materials, including: stainless steel, chrome steel, and ceramic (silicon nitride (Si3N4)). A hybrid ball bearing is a bearing with ceramic balls and races of metal.

Angular contact

An angular contact ball bearing uses axially asymmetric races. An axial load passes in a straight line through the bearing, whereas a radial load takes an oblique path that tends to want to separate the races axially. So the angle of contact on the inner race is the same as that on the outer race. Angular contact bearings better support "combined loads" (loading in both the radial and axial directions) and the contact angle of the bearing should be matched to the relative proportions of each. The larger the contact angle (typically in the range 10 to 45 degrees), the higher the axial load supported, but the lower the radial load. In high speed applications, such as turbines, jet engines, dentistry equipment, the centrifugal forces generated by the balls will change the contact angle at the inner and outer race. Ceramics such as silicon nitride are now regularly used in such applications due to its low density (40% of steel - and so significantly reduced centrifugal force), its ability to function in high temperature environments, and the fact that it tends to wear in a similar way to bearing steel (rather than cracking or shattering like glass or porcelain).

Most bicycles use angular-contact bearings in the headsets because the forces on these bearings are in both the radial and axial direction.

Axial

An axial ball bearing uses side-by-side races. An axial load is transmitted directly through the bearing, while a radial load is poorly-supported, tends to separate the races, and anything other than a small radial load is likely to damage the bearing.

Deep-groove

A deep-groove radial bearing is one in which the race dimensions are close to the dimensions of the balls that run in it. Deep-groove bearings have higher load ratings for their size than shallow-groove , but are also less tolerant of misalignment of the inner and outer races. A misaligned shallow-groove bearing may support a larger load than a similar deep-groove bearing with similar misalignment.

Construction types

Conrad

A Conrad bearing is assembled by placing the inner and outer races radially offset, so the races touch at one point and have a large gap on the radially opposite side. The bearing is then filled by placing balls in to the large gap, then distributing them around the bearing assembly. The act of distributing the balls causes the inner and outer races to become concentric. If the balls were left free, the balls could resume their offset locations and the bearing could disassemble itself. Thus, a cage is inserted to hold the balls in their distributed positions. The cage supports no bearing load; it serves to keep the balls located. Conrad bearings have the advantage that they take both radial and axial loads, but the disadvantage they cannot be filled to a full complement and thus have reduced load-carrying capacity compared to a full-complement bearing. The Conrad bearing is named for its inventor, Robert Conrad, who got British patent 12,206 in 1903 and U.S. patent 822,723 in 1906. Probably the most familiar industrial ball bearing is the deep-groove Conrad style. The bearing is used in most of the mechanical industries.

Slot-fill

A slot-fill radial bearing is one in which the inner and outer races are notched so that when they are aligned, balls can be slipped in the slot in order to fill the bearing. A slot-fill bearing has the advantage that the entire groove is filled with balls, called a full complement. A slot-fill bearing has the disadvantages that it handles axial loads poorly, and the notches weaken the races. Note that an angular contact bearing can be disassembled axially and so can easily be filled with a full complement.

Split-race

The outer race may be split axially or radially, or a hole drilled in it for filling. These approaches allow a full complement to be used, but also limit the orientation of loads or the amount of misalignment the bearing can tolerate. Thus, these designs find much less use.

Single-row versus double-row

Most ball bearings are single-row designs. Some double-row designs are available but they need better alignment than single-row bearings.

Caged

Caged bearings typically have fewer balls than a full complement, and thus have reduced load capacity. However, cages keep balls from scuffing directly against each other and so can reduce the drag of a loaded bearing. Caged roller bearings were invented by John Harrison in the mid 1700s as part of his work on chronographs.[4] Caged bearings were used more frequently during wartime steel shortages for bicycle wheel bearings married to replaceable cups.

Ceramic hybrid ball bearings using ceramic balls

Ceramic bearing balls weigh up to 40 percent less than steel bearing balls, depending on size. This reduces centrifugal loading and skidding, so hybrid ceramic bearings can operate 20 to 40 percent faster than conventional bearings. This means that the outer race groove exerts less force inward against the ball as the bearing spins. This reduction in force reduces the friction and rolling resistance. The lighter ball allows the bearing to spin faster, and uses less energy to maintain its speed.

Ceramic hybrid ball bearings use these ceramic balls in place of steel balls. They are constructed with steel inner and outer rings, but ceramic balls; hence the hybrid designation.

Self-aligning ball bearings

Self-aligning ball bearings are constructed with the inner ring and ball assembly contained within an outer ring that has a spherical raceway. This construction allows the bearing to tolerate a small angular misalignment resulting from deflection or improper mounting.

Modern Applications

Today the ball bearing is used in numerous applications which affect the functionality of everyday life. One interesting application for ball bearings has been implemented at the San Francisco International Airport. In the airport there are 267 columns which are used to bear the weight of the airport. Each column is placed on a steel ball bearing with a diameter of 5 feet. The ball sits in a concave foundation. If an Earthquake occurs, the ground can move up to 20 inches in any direction, as the columns roll on their bases. This is an effective way to separate the building from the movement of the ground. After the earthquake has ended, the columns are re-centered on their bases by the force of gravity.[5]

Ball bearings are also used for dental and medical instruments. In dental and medical hand pieces, it is necessary for the pieces to withstand sterilization and corrosion. Because of this requirement, dental and medical hand pieces are made from 440C stainless steel, which allows for smooth rotations at fast speeds.[6]

  • Hard drive bearings used to be highly spherical, and were said to be the best spherical manufactured shapes, but this is no longer true, and more and more are being replaced with fluid bearings.
  • German ball bearing factories were often a target of allied aerial bombings during World War II; such was the importance of the ball bearing to the German war industry.[7]

See also

Notes

  1. 1869 en science. French Wiki. Retrieved November 22, 2008.
  2. Mozer, David. Bicycle History: Chronology of the Growth of Bicycling and the Development of Bicycle Technology. Retrieved November 22, 2008.
  3. Purtell, John 1999/2001. http://nemiship.multiservers.com/nemi.htm Project Diana, Section 10]. Retrieved November 22, 2008.
  4. Sobel, Dava. 1995. Longitude: The Story of a Lone Genius Who Solved the Greatest Scientific Problem of His Time. London: Fourth Estate. p. 103. ISBN 0007214464. Quote: "A novel antifriction device that Harrison developed for H-3 survives to the present day - ...caged ball bearings."
  5. How Bearings Work. HowStuffWorks. Retrieved November 22, 2008.
  6. Dental and Medical Bearings. PKB. Retrieved November 22, 2008.
  7. Speer, Albert. 1970. Inside the Third Reich: Memoirs. New York: Macmillan. pp. 331-347. OCLC 87656.

References
ISBN links support NWE through referral fees

  • Brändlein, J., et al. 1999. Ball and Roller Bearings: Theory, Design, and Application, 3rd ed. Chichester: Wiley. ISBN 0471984523
  • Harris, Tedric A., and Michael N. Kotzalas. 2006. Essential Concepts of Bearing Technology. Rolling Bearing Analysis, v. 1 (5th ed.). Boca Raton, FL: Taylor & Francis. ISBN 978-0849371837


External links

  • Ball Bearing. Madlix. (Animated 3D-model of ball bearing, explaining rotation.) Retrieved November 22, 2008.

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