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| {{pp-move-indef}}
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| {{Classical mechanics|cTopic=Core topics}}
| |
| '''Friction''' is the [[force]] resisting the relative motion of solid surfaces, fluid layers, and material elements sliding against each other. There are several types of friction: like fluid friction, dry friction, and sliding friction.
| |
| | |
| *'''Dry friction''' resists relative lateral motion of two solid [[surface]]s in contact. Dry friction is subdivided into ''static friction'' ("[[stiction]]") between non-moving surfaces, and ''kinetic friction'' between moving surfaces.
| |
| | |
| *'''Fluid friction''' describes the friction between layers of a [[viscous]] fluid that are moving relative to each other.<ref name="Beer">{{cite book
| |
| | title = Vector Mechanics for Engineers
| |
| | edition = Sixth
| |
| | last = Beer
| |
| | first = Ferdinand P.
| |
| | authorlink = Ferdinand Beer
| |
| | coauthor = E. Russel Johnston, Jr.
| |
| | page = 397
| |
| | year = 1996
| |
| | publisher = McGraw-Hill
| |
| | isbn = 0-07-297688-8}}</ref><ref name="Meriam">{{cite book
| |
| | title = Engineering Mechanics
| |
| | edition = fifth
| |
| | last = Meriam
| |
| | first = J. L.
| |
| | coauthor = L. G. Kraige
| |
| | page = 328
| |
| | year = 2002
| |
| | publisher = John Wiley & Sons
| |
| | isbn = 0-471-60293-0}}</ref>
| |
| | |
| *'''Lubricated friction''' is a case of fluid friction where a fluid separates two solid surfaces.<ref name="Ruina">{{cite book
| |
| | title = Introduction to Statics and Dynamics
| |
| | last = Ruina
| |
| | first = Andy
| |
| | coauthors = Rudra Pratap
| |
| | year = 2002
| |
| | publisher = Oxford University Press
| |
| | url = http://ruina.tam.cornell.edu/Book/RuinaPratapNoProblems.pdf
| |
| | page = 713}}</ref><ref name="Hibbeler">{{cite book
| |
| | title = Engineering Mechanics
| |
| | edition = Eleventh
| |
| | last = Hibbeler
| |
| | first = R. C.
| |
| | page = 393
| |
| | year = 2007
| |
| | publisher = Pearson, Prentice Hall
| |
| | isbn = 0-13-127146-6}}</ref><ref name="Soutas-Little">{{cite book
| |
| | title = Engineering Mechanics
| |
| | last = Soutas-Little
| |
| | first = Robert W.
| |
| | coauthors = Inman, Balint
| |
| | page = 329
| |
| | year = 2008
| |
| | publisher = Thomson
| |
| | isbn = 0-495-29610-4}}</ref>
| |
| | |
| *'''Skin friction''' is a component of [[Drag (physics)|drag]], the force resisting the motion of a fluid across the surface of a body.
| |
| | |
| *'''Internal friction''' is the force resisting motion between the elements making up a solid material while it undergoes [[Deformation (mechanics)|deformation]].<ref name="Meriam"/>
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| | |
| When surfaces in contact move relative to each other, the friction between the two surfaces converts [[kinetic energy]] into [[heat]]. This property can have dramatic consequences, as illustrated by the use of friction created by rubbing pieces of wood together to start a fire. Kinetic energy is converted to heat whenever motion with friction occurs, for example when a [[Viscous flow|viscous]] fluid is stirred. Another important consequence of many types of friction can be [[wear]], which may lead to performance degradation and/or damage to components. Friction is a component of the science of [[tribology]].
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|
| |
| Friction is not itself a [[fundamental force]] but arises from fundamental [[electromagnetic force]]s between the charged particles constituting the two contacting surfaces. The complexity of these interactions makes the calculation of friction from [[first principle]]s impractical and necessitates the use of [[empirical method]]s for analysis and the development of theory.
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| | |
| ==History==
| |
| {{Expand section|date=July 2010}}
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| | |
| The classic rules of sliding friction were discovered by [[Leonardo da Vinci]] (1452–1519), but remained unpublished in his notebooks.<ref name="Dowson" >{{cite book
| |
| | last = Dowson
| |
| | first = Duncan
| |
| | title = History of Tribology, 2nd Edition
| |
| | publisher = Professional Engineering Publishing
| |
| | year = 1997
| |
| | isbn = 1-86058-070-X}}</ref><ref name="Armstrong" >{{cite book
| |
| | last = Armstrong-Hélouvry
| |
| | first = Brian
| |
| | title = Control of machines with friction
| |
| | publisher = Springer
| |
| | year = 1991
| |
| | location = USA
| |
| | pages = 10
| |
| | url = http://books.google.com/?id=0zk_zI3xACgC&pg=PA10
| |
| | isbn = 0-7923-9133-0}}</ref><ref name="VanBeek">{{cite web
| |
| | last = van Beek
| |
| | first = Anton
| |
| | title = History of Science Friction
| |
| | publisher = tribology-abc.com
| |
| | url = http://www.tribology-abc.com/abc/history.htm
| |
| | accessdate = 2011-03-24}}</ref> They were rediscovered by [[Guillaume Amontons]] (1699). Amontons presented the nature of friction in terms of surface irregularities and the force required to raise the weight pressing the surfaces together. This view was further elaborated by Belidor (representation of rough surfaces with spherical asperities, 1737)<ref name="Dowson" /> and [[Leonhard Euler]] (1750), who derived the [[angle of repose]] of a weight on an inclined plane and first distinguished between static and kinetic friction.<ref>{{cite web
| |
| | title = Leonhard Euler
| |
| | work = Friction Module
| |
| | publisher = [http://www.nano-world.org/ Nano World website]
| |
| | year = 2002
| |
| | url = http://www.nano-world.org/frictionmodule/content/0200makroreibung/0400historisch/0300euler/?lang=en
| |
| | accessdate = 2011-03-25}}</ref>
| |
| A different explanation was provided by Desaguliers (1725), who demonstrated the strong cohesion forces between lead spheres of which a small cap is cut off and which were then brought into contact with each other.
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|
| |
| The understanding of friction was further developed by [[Charles-Augustin de Coulomb]] (1785). Coulomb investigated the influence of four main factors on friction: the nature of the materials in contact and their surface coatings; the extent of the surface area; the normal pressure (or load); and the length of time that the surfaces remained in contact (time of repose).<ref name="Dowson" /> Coulomb further considered the influence of sliding velocity, temperature and humidity, in order to decide between the different explanations on the nature of friction that had been proposed. The distinction between static and dynamic friction is made in Coulomb's friction law (see below), although this distinction was already drawn by Johann Andreas von Segner in 1758.<ref name="Dowson" />
| |
| The effect of the time of repose was explained by Musschenbroek (1762) by considering the surfaces of fibrous materials, with fibers meshing together, which takes a finite time in which the friction increases.
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| | |
| John Leslie (1766–1832) noted a weakness in the views of Amontons and Coulomb. If friction arises from a weight being drawn up the inclined plane of successive asperities, why isn't it balanced then through descending the opposite slope? Leslie was equally skeptical about the role of adhesion proposed by Desaguliers, which should on the whole have the same tendency to accelerate as to retard the motion.<ref name="Dowson" /> In his view friction should be seen as a time-dependent process of flattening, pressing down asperities, which creates new obstacles in what were cavities before.
| |
| | |
| Arthur Morrin (1833) developed the concept of sliding versus rolling friction. [[Osborne Reynolds]] (1866) derived the equation of viscous flow. This completed the classic empirical model of friction (static, kinetic, and fluid) commonly used today in engineering.<ref name="Armstrong" />
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| | |
| The focus of research during the last century has been to understand the physical mechanisms behind friction. F. Phillip Bowden and [[David Tabor]] (1950) showed that at a microscopic level, the actual area of contact between surfaces is a very small fraction of the apparent area.<ref name="VanBeek" /> This actual area of contact, caused by "[[Asperity (materials science)|asperities]]" (roughness) increases with pressure, explaining the proportionality between normal force and frictional force. The development of the [[atomic force microscope]] (1986) has recently enabled scientists to study friction at the atomic scale.<ref name="Armstrong" />
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| | |
| ==Laws of dry friction==
| |
| The elementary property of sliding (kinetic) friction were discovered by experiment in the 15th to 18th centuries and were expressed as three empirical laws:
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| *'''[[Guillaume Amontons#Amontons' Laws of Friction|Amontons' First Law]]''': The force of friction is directly proportional to the applied load.
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| *'''Amontons' Second Law''': The force of friction is independent of the apparent area of contact.
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| *'''Coulomb's Law of Friction''': Kinetic friction is independent of the sliding velocity.
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| | |
| ==Dry friction<!--Charles-Augustin de Coulomb links here-->==
| |
| Dry friction resists relative lateral motion of two solid surfaces in contact. The two regimes of dry friction are 'static friction' ("[[stiction]]") between non-moving surfaces, and ''kinetic friction'' (sometimes called sliding friction or dynamic friction) between moving surfaces.
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| | |
| Coulomb friction, named after [[Charles-Augustin de Coulomb]], is an approximate model used to calculate the force of dry friction. It is governed by the model:
| |
| | |
| :<math>F_\mathrm{f} \leq \mu F_\mathrm{n}</math>
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| where
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| *<math>F_\mathrm{f}\,</math> is the force of friction exerted by each surface on the other. It is parallel to the surface, in a direction opposite to the net applied force.
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| *<math>\mu\,</math> is the coefficient of friction, which is an empirical property of the contacting materials,
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| *<math>F_\mathrm{n}\,</math> is the [[normal force]] exerted by each surface on the other, directed perpendicular (normal) to the surface.
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| | |
| The Coulomb friction <math>F_\mathrm{f}\,</math> may take any value from zero up to <math>\mu F_\mathrm{n}\,</math>, and the direction of the frictional force against a surface is opposite to the motion that surface would experience in the absence of friction. Thus, in the static case, the frictional force is exactly what it must be in order to prevent motion between the surfaces; it balances the net force tending to cause such motion. In this case, rather than providing an estimate of the actual frictional force, the Coulomb approximation provides a threshold value for this force, above which motion would commence. This maximum force is known as [[Traction (engineering)|traction]].
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| | |
| The force of friction is always exerted in a direction that opposes movement (for kinetic friction) or potential movement (for static friction) between the two surfaces. For example, a [[curling]] stone sliding along the ice experiences a kinetic force slowing it down. For an example of potential movement, the drive wheels of an accelerating car experience a frictional force pointing forward; if they did not, the wheels would spin, and the rubber would slide backwards along the pavement. Note that it is not the direction of movement of the vehicle they oppose, it is the direction of (potential) sliding between tire and road.
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| | |
| ===Normal force===
| |
| [[Image:Free Body Diagram.png|right|thumb|[[Free-body diagram]] for a block on a ramp. Arrows are [[Euclidean vector|vectors]] indicating directions and magnitudes of forces. ''N'' is the normal force, ''mg'' is the force of [[gravity]], and ''F<sub>f</sub>'' is the force of friction.]]
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| | |
| {{Main|Normal force}}
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| | |
| The normal force is defined as the net force compressing two parallel surfaces together; and its direction is perpendicular to the surfaces. In the simple case of a mass resting on a horizontal surface, the only component of the normal force is the force due to gravity, where <math>N=mg\,</math>. In this case, the magnitude of the friction force is the product of the mass of the object, the acceleration due to gravity, and the coefficient of friction. However, the coefficient of friction is not a function of mass or volume; it depends only on the material. For instance, a large aluminum block has the same coefficient of friction as a small aluminum block. However, the magnitude of the friction force itself depends on the normal force, and hence on the mass of the block.
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| | |
| If an '''object is on a level surface''' and the force tending to cause it to slide is horizontal, the normal force <math>N\,</math> between the object and the surface is just its weight, which is equal to its [[mass]] multiplied by the [[acceleration]] due to earth's gravity, ''[[standard gravity|g]]''. If the '''object is on a tilted surface''' such as an inclined plane, the normal force is less, because less of the force of gravity is perpendicular to the face of the plane. Therefore, the normal force, and ultimately the frictional force, is determined using [[Vector (geometric)|vector]] analysis, usually via a [[free body diagram]]. Depending on the situation, the calculation of the normal force may include forces other than gravity.
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| | |
| ===Coefficient of friction===
| |
| The '''coefficient of friction''' (COF), often symbolized by the Greek letter [[Mu (letter)|µ]], is a [[Dimensionless quantity|dimensionless]] [[scalar (physics)|scalar]] value which describes the ratio of the force of friction between two bodies and the force pressing them together. The coefficient of friction depends on the materials used; for example, ice on steel has a low coefficient of friction, while rubber on pavement has a high coefficient of friction. Coefficients of friction range from near zero to greater than one.
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| | |
| For surfaces at rest relative to each other <math>\mu = \mu_\mathrm{s}\,</math>, where <math>\mu_\mathrm{s}\,</math> is the ''coefficient of static friction''. This is usually larger than its kinetic counterpart.
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| | |
| For surfaces in relative motion <math>\mu = \mu_\mathrm{k}\,</math>, where <math>\mu_\mathrm{k}\,</math> is the ''coefficient of kinetic friction''. The Coulomb friction is equal to <math>F_\mathrm{f}\,</math>, and the frictional force on each surface is exerted in the direction opposite to its motion relative to the other surface.
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| | |
| [[Arthur Morin]] introduced the term and demonstrated the utility of the coefficient of friction.<ref name="Dowson" /> The coefficient of friction is an [[empirical]] [[measurement]] – it has to be measured [[experiment]]ally, and cannot be found through calculations.{{Citation needed|date=June 2013}} Rougher surfaces tend to have higher effective values. Both static and kinetic coefficients of friction depend on the pair of surfaces in contact; for a given pair of surfaces, the coefficient of static friction is ''usually'' larger than that of kinetic friction; in some sets the two coefficients are equal, such as teflon-on-teflon.
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| | |
| Most dry materials in combination have friction coefficient values between 0.3 and 0.6. Values outside this range are rarer, but [[polytetrafluoroethylene|teflon]], for example, can have a coefficient as low as 0.04. A value of zero would mean no friction at all, an elusive property – even [[magnetic levitation]] [[Maglev train|vehicles]] have drag. Rubber in contact with other surfaces can yield friction coefficients from 1 to 2. Occasionally it is maintained that µ is always < 1, but this is not true. While in most relevant applications µ < 1, a value above 1 merely implies that the force required to slide an object along the surface is greater than the normal force of the surface on the object. For example, [[silicone rubber]] or [[acrylic rubber]]-coated surfaces have a coefficient of friction that can be substantially larger than 1.
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| | |
| While it is often stated that the COF is a "material property," it is better categorized as a "system property." Unlike true material properties (such as conductivity, dielectric constant, yield strength), the COF for any two materials depends on system variables like [[temperature]], [[velocity]], [[atmosphere]] and also what are now popularly described as aging and deaging times; as well as on geometric properties of the interface between the materials. For example, a [[copper]] pin sliding against a thick copper plate can have a COF that varies from 0.6 at low speeds (metal sliding against metal) to below 0.2 at high speeds when the copper surface begins to melt due to frictional heating. The latter speed, of course, does not determine the COF uniquely; if the pin diameter is increased so that the frictional heating is removed rapidly, the temperature drops, the pin remains solid and the COF rises to that of a 'low speed' test.{{Citation needed|date=December 2008}}
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| | |
| ====Negative coefficient of friction====
| |
| {{As of|2012}}, a single study has demonstrated the potential for a negative coefficient of friction, meaning that a decrease in force leads to an increase in friction. This contradicts the everyday experience that an increase of normal force improves friction.<ref name=deng2012/> This was reported in the journal ''Nature'' in October 2012 and involved the friction encountered by an atomic force microscope stylus when dragged across a graphene sheet in the presence of graphene-adsorbed oxygen.<ref name=deng2012>{{Citation
| |
| |last=Deng |first=Zhao |coauthors=et al. |publication-date=October 14, 2012 |title=Adhesion-dependent negative friction coefficient on chemically modified graphite at the nanoscale |journal=[[Nature (journal)|Nature]] |doi=10.1038/nmat3452 |url=http://www.nature.com/nmat/journal/vaop/ncurrent/full/nmat3452.html |accessdate=November 18, 2012 |laysummary=http://www.rdmag.com/news/2012/10/nanoscale-graphite-can-turn-friction-upside-down |laysource=[[R&D Magazine]] |laydate=October 17, 2012 |bibcode = 2012NatMa..11.1032D }}</ref>
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| | |
| ====Approximate coefficients of friction====
| |
| {| class="wikitable" border="1"
| |
| |-
| |
| ! colspan="2" rowspan="2"|Materials !! colspan="2"|Static friction, <math>\mu_s\,</math>
| |
| |-
| |
| ! Dry and clean !! Lubricated
| |
| |-
| |
| ! Aluminium
| |
| ! Steel
| |
| | 0.61
| |
| |
| |
| |-
| |
| ! Copper
| |
| ! Steel
| |
| | 0.53
| |
| |
| |
| |-
| |
| ! Brass
| |
| ! Steel
| |
| | 0.51
| |
| |
| |
| |-
| |
| ! Cast iron
| |
| ! Copper
| |
| | 1.05
| |
| |
| |
| |-
| |
| ! Cast iron
| |
| ! Zinc
| |
| | 0.85
| |
| |
| |
| |-
| |
| ! Concrete
| |
| ! Rubber
| |
| | 1.0
| |
| | 0.30 (wet)
| |
| |-
| |
| ! Concrete
| |
| ! Wood
| |
| | 0.62<ref name=engHandbook/>
| |
| |
| |
| |-
| |
| ! Copper
| |
| ! Glass
| |
| | 0.68
| |
| |
| |
| |-
| |
| ! Glass
| |
| ! Glass
| |
| | 0.94
| |
| |
| |
| |-
| |
| ! Metal
| |
| ! Wood
| |
| | 0.2–0.6<ref name=engHandbook/>
| |
| | 0.2 (wet)<ref name=engHandbook/>
| |
| |-
| |
| ! [[Polyethene]]
| |
| ! Steel
| |
| | 0.2<ref name=eng/>
| |
| | 0.2<ref name=eng/>
| |
| |-
| |
| ! Steel
| |
| ! Steel
| |
| | 0.80<ref name=eng/>
| |
| | 0.16<ref name=eng/>
| |
| |-
| |
| ! Steel
| |
| ! [[PTFE]] (Teflon)
| |
| | 0.04<ref name=eng/>
| |
| | 0.04<ref name=eng/>
| |
| |-
| |
| ! PTFE (Teflon)
| |
| ! PTFE (Teflon)
| |
| | 0.04<ref name=eng>{{cite web
| |
| | url = http://www.engineeringtoolbox.com/friction-coefficients-d_778.html
| |
| | title = The Engineering Toolbox: Friction and Coefficients of Friction
| |
| | accessdate = 2008-11-23}}</ref>
| |
| | 0.04<ref name=eng/>
| |
| |-
| |
| ! Wood
| |
| ! Wood
| |
| | 0.25–0.5<ref name=engHandbook>[http://www.engineershandbook.com/Tables/frictioncoefficients.htm Coefficient of Friction]. EngineersHandbook.com</ref>
| |
| | 0.2 (wet)<ref name=engHandbook/>
| |
| |}
| |
| | |
| An AlMgB<sub>14</sub>-TiB<sub>2</sub> composite has an approximate coefficient of friction of 0.02 in water-[[glycol]]-based lubricants,<ref>{{cite web
| |
| | url = http://www.newscientist.com/article/dn16102-material-slicker-than-teflon-discovered-by-accident.html
| |
| | title = Material slicker than Teflon discovered by accident
| |
| | author = Kleiner, Kurt
| |
| | date = 2008-11-21
| |
| | accessdate = 2008-12-25}}</ref><ref>{{cite journal|doi=10.1016/j.wear.2010.11.044|title=Friction and wear mechanisms in AlMgB14-TiB2 nanocoatings|year=2011|last1=Higdon|first1=C.|last2=Cook|first2=B.|last3=Harringa|first3=J.|last4=Russell|first4=A.|last5=Goldsmith|first5=J.|last6=Qu|first6=J.|last7=Blau|first7=P.|journal=Wear|volume=271|issue=9–10|pages=2111}}</ref> and 0.04–0.05 when dry.<ref>{{cite journal|doi=10.1063/1.1615677|title=Superhard self-lubricating AlMgB[sub 14] films for microelectromechanical devices|year=2003|last1=Tian|first1=Y.|last2=Bastawros|first2=A. F.|last3=Lo|first3=C. C. H.|last4=Constant|first4=A. P.|last5=Russell|first5=A. M.|last6=Cook|first6=B. A.|journal=Applied Physics Letters|volume=83|issue=14|pages=2781|bibcode = 2003ApPhL..83.2781T }}</ref> Under certain conditions, some materials have even lower friction coefficients. An example is (highly ordered pyrolytic) graphite, which can have a friction coefficient below 0.01.<ref>{{cite journal|title=Superlubricity of Graphite|author= Dienwiebel, Martin ''et al.'' |journal=Phys. Rev. Lett.|volume=92|page=126101 |year=2004|doi=10.1103/PhysRevLett.92.126101|url=http://www.physics.leidenuniv.nl/sections/cm/ip/group/PDF/Phys.rev.lett/2004/92(2004)12601.pdf|issue=12|bibcode = 2004PhRvL..92l6101D }}</ref>
| |
| This ultralow-friction regime is called [[superlubricity]].
| |
| | |
| ===Static friction===<!-- Traction (engineering) links here -->
| |
| Static friction is friction between two or more solid objects that are not moving relative to each other. For example, static friction can prevent an object from sliding down a sloped surface. The coefficient of static friction, typically denoted as ''μ''<sub>s</sub>, is usually higher than the coefficient of kinetic friction.
| |
| | |
| The static friction force must be overcome by an applied force before an object can move. The maximum possible friction force between two surfaces before sliding begins is the product of the coefficient of static friction and the normal force: <math>F_{max} = \mu_s F_{n}\,</math>. When there is no sliding occurring, the friction force can have any value from zero up to <math>F_{max}\,</math>. Any force smaller than <math>F_{max}\,</math> attempting to slide one surface over the other is opposed by a frictional force of equal magnitude and opposite direction. Any force larger than <math>F_{max}\,</math> overcomes the force of static friction and causes sliding to occur. The instant sliding occurs, static friction is no longer applicable—the friction between the two surfaces is then called kinetic friction.
| |
|
| |
| An example of static friction is the force that prevents a car wheel from slipping as it rolls on the ground. Even though the wheel is in motion, the patch of the tire in contact with the ground is stationary relative to the ground, so it is static rather than kinetic friction.
| |
|
| |
| The maximum value of static friction, when motion is impending, is sometimes referred to as '''limiting friction''',<ref name="Bhavikatti">{{cite book
| |
| | url = http://books.google.com/?id=4wkLl4NvmWAC&pg=PA112&lpg=PA112
| |
| | title = Engineering Mechanics
| |
| | last = Bhavikatti
| |
| | first = S. S.
| |
| | coauthor = K. G. Rajashekarappa
| |
| | page = 112
| |
| | accessdate = 2007-10-21
| |
| | publisher = New Age International
| |
| | isbn = 978-81-224-0617-7
| |
| | year = 1994}}</ref>
| |
| although this term is not used universally.<ref name="Beer">{{cite book
| |
| | title = Vector Mechanics for Engineers
| |
| | edition = Sixth
| |
| | last = Beer and Johnston
| |
| | year = 1996
| |
| | publisher = McGraw-Hill
| |
| | isbn = 0-07-005367-7
| |
| | pages = 397–400}}</ref> It is also known as traction.{{Citation needed|date=November 2013}}
| |
| | |
| ===Kinetic friction===
| |
| Kinetic (or dynamic) friction occurs when two objects are moving relative to each other and rub together (like a sled on the ground). The coefficient of kinetic friction is typically denoted as ''μ''<sub>k</sub>, and is usually less than the coefficient of static friction for the same materials.<ref>{{cite book
| |
| | title = Statics: Analysis and Design of Systems in Equilibrium
| |
| | author=Sheppard, Sheri; Tongue, Benson H. and Anagnos, Thalia
| |
| | publisher = Wiley and Sons
| |
| | year = 2005
| |
| | page = 618
| |
| | quote = In general, for given contacting surfaces, ''μ''<sub>k</sub> < ''μ''<sub>s</sub>
| |
| | isbn = 0-471-37299-4}}
| |
| </ref><ref>
| |
| {{cite book
| |
| | title = Engineering Mechanics: Statics
| |
| | last = Meriam, James L.; Kraige, L. Glenn and Palm, William John
| |
| | publisher = Wiley and Sons
| |
| | year = 2002
| |
| | page= 330
| |
| | quote = Kinetic friction force is usually somewhat less than the maximum static friction force.
| |
| | isbn = 0-471-40646-5}}</ref> However, [[Richard Feynman]] comments that "with dry metals it is very hard to show any difference."<ref>{{cite web
| |
| | url = http://hyperphysics.phy-astr.gsu.edu/hbase/frict2.html
| |
| | title = The Feynman Lectures on Physics, Vol. I, p. 12-5
| |
| | publisher = Addison-Wesley
| |
| | year = 1964
| |
| | last = Feynman, Richard P.; Leighton, Robert B. and Sands, Matthew
| |
| | accessdate = 2009-10-16}}</ref>
| |
| | |
| New models are beginning to show how kinetic friction can be greater than static friction.<ref name="PerssonVolokitin" >{{cite journal
| |
| | url = http://juwel.fz-juelich.de:8080/dspace/bitstream/2128/1343/1/17249.pdf
| |
| | title = Theory of rubber friction: Nonstationary sliding
| |
| |journal= Physical Review B| volume= 65|pages=134106|doi=10.1103/PhysRevB.65.134106
| |
| | author = Persson, B. N.; Volokitin, A. I
| |
| | year = 2002|bibcode = 2002PhRvB..65m4106P
| |
| | issue = 13 }}
| |
| </ref> Kinetic friction is now understood, in many cases, to be primarily caused by chemical bonding between the surfaces, rather than interlocking asperities;<ref>
| |
| {{cite web
| |
| | last = Beatty
| |
| | first = William J.
| |
| | url = http://amasci.com/miscon/miscon4.html#fric
| |
| | title = Recurring science misconceptions in K-6 textbooks
| |
| | accessdate = 2007-06-08}}</ref> however, in many other cases roughness effects are dominant, for example in rubber to road friction.<ref name="PerssonVolokitin" /> Surface roughness and contact area, however, do affect kinetic friction for micro- and nano-scale objects where surface area forces dominate inertial forces.<ref>{{cite book|author=Persson, B. N. J. |title=Sliding friction: physical principles and applications|url=http://books.google.com/books?id=1jb-nZMnRGYC|accessdate=12 December 2011|year=2000|publisher=Springer|isbn=978-3-540-67192-3}}</ref>
| |
| | |
| [[File:Free body.svg|thumb|Angle of friction, ''θ'', when block just starts to slide.]]
| |
| | |
| ===Angle of friction===
| |
| {{For|the maximum angle of static friction between granular materials|Angle of repose}}
| |
| For certain applications it is more useful to define static friction in terms of the maximum angle before which one of the items will begin sliding. This is called the ''angle of friction'' or ''friction angle''. It is defined as:
| |
| | |
| :<math>\tan{\theta} = \mu_s\,</math>
| |
| | |
| where ''θ'' is the angle from horizontal and ''µ<sub>s</sub>'' is the static coefficient of friction between the objects.<ref>{{cite book
| |
| | last = Nichols
| |
| | first = Edward Leamington
| |
| | last2 = Franklin
| |
| | first2 = William Suddards
| |
| | title = The Elements of Physics
| |
| | publisher = Macmillan
| |
| | page = 101
| |
| | year = 1898
| |
| | volume = 1
| |
| | url = http://books.google.com/?id=8IlCAAAAIAAJ}}</ref> This formula can also be used to calculate ''µ<sub>s</sub>'' from empirical measurements of the friction angle.
| |
| | |
| ===Friction at the atomic level===
| |
| Determining the forces required to move atoms past each other is a challenge in designing [[nanomachines]]. In 2008 scientists for the first time were able to move a single atom across a surface, and measure the forces required. Using ultrahigh vacuum and nearly zero temperature (5 K), a modified atomic force microscope was used to drag a [[cobalt]] atom, and a [[carbon monoxide]] molecule, across surfaces of copper and [[platinum]].<ref>{{Cite journal|last = Ternes|first = Markus|last2 = Lutz|first2 = Christopher P.|last3 = Hirjibehedin|first3 = Cyrus F.|last4 = Giessibl|first4 = Franz J.|last5 = Heinrich|first5 = Andreas J.|title = The Force Needed to Move an Atom on a Surface|journal = [[Science (magazine)|Science]]|volume = 319|issue = 5866|pages = 1066–1069|date = 2008-02-22|doi = 10.1126/science.1150288|pmid = 18292336|bibcode = 2008Sci...319.1066T }}</ref>
| |
| | |
| ===Limitations of the Coulomb model===
| |
| The Coulomb approximation mathematically follows from the assumptions that surfaces are in atomically close contact only over a small fraction of their overall area, that this [[contact area]] is proportional to the normal force (until [[Saturated model|saturation]], which takes place when all area is in atomic contact), and that the frictional force is proportional to the applied normal force, independently of the contact area (you can see the experiments on friction from Leonardo da Vinci). Such reasoning aside, however, the approximation is fundamentally an empirical construct. It is a rule of thumb describing the approximate outcome of an extremely complicated physical interaction. The strength of the approximation is its simplicity and versatility – though in general the relationship between normal force and frictional force is not exactly linear (and so the frictional force is not entirely independent of the contact area of the surfaces), the Coulomb approximation is an adequate representation of friction for the analysis of many physical systems.
| |
| | |
| When the surfaces are conjoined, Coulomb friction becomes a very poor approximation (for example, [[adhesive tape]] resists sliding even when there is no normal force, or a negative normal force). In this case, the frictional force may depend strongly on the area of contact. Some [[drag racing]] tires are adhesive for this reason. However, despite the complexity of the fundamental physics behind friction, the relationships are accurate enough to be useful in many applications.
| |
| | |
| ===Numerical simulation of the Coulomb model===
| |
| Despite being a simplified model of friction, the Coulomb model is useful in many [[Computer simulation|numerical simulation]] applications such as [[multibody system]]s and [[granular material]]. Even its most simple expression encapsulates the fundamental effects of sticking and sliding which are required in many applied cases, although specific algorithms have to be designed in order to efficiently [[Numerical integration|numerically integrate]] mechanical systems with Coulomb friction and bilateral and/or unilateral contact.<ref>{{cite journal|last = Haslinger|first = J. |title=Approximation of the Signorini problem with friction, obeying the Coulomb law | journal = Mathematical Methods in the Applied Sciences |volume=5|pages=422–437|year=1983|bibcode = 1983MMAS....5..422H |doi = 10.1002/mma.1670050127|last2 = Nedlec|first2 = J.C. }}</ref><ref>{{cite journal|last1 = Alart|first1 = P.|last2=Curnier |first2=A. |title= A mixed formulation for frictional contact problems prone to Newton like solution method | journal = Computer Methods in Applied Mechanics and Engineering |volume= 92 |pages=353–375|year=1991|bibcode = 1991CMAME..92..353A |doi = 10.1016/0045-7825(91)90022-X|issue = 3 }}</ref><ref>{{cite journal | last1 = Acary |first1= V. |last2= Cadoux | first2 = F.| last3 =Lemaréchal|first3=C. | last4=Malick | first4=J.| title= A formulation of the linear discrete Coulomb friction problem via convex optimization | journal = Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik | volume= 91 | issue = 2 |pages = 155–175 |year = 2011 | doi = 10.1002/zamm.201000073|bibcode = 2011ZaMM...91..155A }}</ref><ref>{{cite journal | last1=De Saxcé|first1= G.|last2= Feng|first2= Z.-Q.|title=The bipotential method: A constructive approach to design the complete contact law with friction and improved numerical algorithms | journal= Mathematical and Computer Modelling | volume= 28 |issue=4 | pages =225–245|year= 1998 | doi=10.1016/S0895-7177(98)00119-8}}</ref><ref>{{cite journal| last1= Simo |first1=J.C.|last2=Laursen | first2= T.A.| title= An augmented lagrangian treatment of contact problems involving friction |journal = Computers and Structures | volume = 42 | issue=2 | pages= 97–116| year=1992| doi= 10.1016/0045-7949(92)90540-G}}</ref> Some quite [[Nonlinear_system#Types_of_nonlinear_behaviors|nonlinear effects]], such as the so-called [[Painlevé paradox]]es, may be encountered with Coulomb friction.<ref>{{cite book|last = Acary|first= V.|last2 = Brogliato|first2 = B.|title=Numerical Methods for Nonsmooth Dynamical Systems. Applications in Mechanics and Electronics|publisher=[[Springer Science+Business Media|Springer Verlag Heidelberg]]|volume=35|year = 2008}}</ref>
| |
| | |
| ===Dry friction and instabilities===
| |
| [[Image:animation flutter.gif|right|thumb|250px|A physical model of the so-called '[[Ziegler column]]', a two-degree-of-freedom system, exhibiting flutter instability as induced by dry friction. Watch the complete [http://www.ing.unitn.it/~bigoni/flutter.html movie] for more details.]]
| |
| Dry friction can induce several types of instabilities in mechanical systems which display a stable behaviour in the absence of friction.<ref>{{cite book
| |
| |author=Bigoni, D.|title=Nonlinear Solid Mechanics: Bifurcation Theory and Material Instability|publisher= Cambridge University Press, 2012|isbn= 9781107025417}}</ref> For instance, friction-related dynamical instabilities are thought to be responsible for [[Brake#Noise|brake squeal]] and the 'song' of a [[glass harp]],<ref>{{cite journal
| |
| | author = Flint, J. and Hultén, J.
| |
| | title = Lining-deformation-induced modal coupling as squeal generator in a distributed parameter disk brake model|doi=10.1006/jsvi.2001.4052|bibcode=2002JSV...254....1F
| |
| | journal = J. Sound and Vibration
| |
| | year = 2002
| |
| | volume = 254
| |
| | pages = 1–21}}</ref><ref>{{cite journal
| |
| | author = Kröger, M.; Neubauer, M. and Popp, K.
| |
| | title = Experimental investigation on the avoidance of self-excited vibrations
| |
| | journal = Phil. Trans. R. Soc. A|doi=10.1098/rsta.2007.2127
| |
| | year = 2008
| |
| | pages = 785–810
| |
| | volume = 366
| |
| | issue = 1866
| |
| | pmid = 17947204|bibcode = 2008RSPTA.366..785K }}</ref> phenomena which involve stick and slip, modelled as a drop of friction coefficient with velocity.<ref>{{cite journal
| |
| | author = Rice, J. R. and Ruina, A. L.
| |
| | title = Stability of Steady Frictional Slipping
| |
| | journal = Journal of Applied Mechanics
| |
| | volume = 50
| |
| | year = 1983
| |
| | pages = 343–349
| |
| | url = http://ruina.tam.cornell.edu/research/topics/friction_and_fracture/stability_steady.pdf
| |
| | doi = 10.1115/1.3167042
| |
| | issue = 2|bibcode = 1983JAM....50..343R }}</ref>
| |
| | |
| A practically important case is the [[self-oscillation]] of the strings of [[bowed instruments]] such as the [[violin]], [[cello]], [[hurdy-gurdy]], [[erhu]] etc.
| |
| | |
| A connection between dry friction and [[Aeroelastic_flutter#Flutter|flutter]] instability in a simple mechanical system has been discovered.<ref>{{cite journal
| |
| | url = http://www.ing.unitn.it/~bigoni
| |
| | author = Bigoni, D. and Noselli, G.
| |
| | title = Experimental evidence of flutter and divergence instabilities induced by dry friction
| |
| | journal = Journal of the Mechanics and Physics of Solids
| |
| | year = 2011
| |
| | volume = 59
| |
| | pages = 2208–2226
| |
| | doi = 10.1016/j.jmps.2011.05.007
| |
| | issue = 10|bibcode = 2011JMPSo..59.2208B }}</ref>
| |
| | |
| Frictional instabilities can lead to the formation of new self-organized patterns (or "secondary structures") at the sliding interface, such as in-situ formed tribofilms which are utilized for the reduction of friction and wear in so-called self-lubricating materials.<ref>{{cite book
| |
| | title = Friction-Induced Vibrations and Self-Organization: Mechanics and Non-Equilibrium Thermodynamics of Sliding Contact
| |
| | first = Michael
| |
| | last = Nosonovsky
| |
| | year = 2013
| |
| | publisher = CRC Press
| |
| | isbn = 978-1466504011
| |
| | url = http://www.crcpress.com/product/isbn/9781466504011
| |
| | page = 333}}</ref>
| |
| | |
| ==Fluid friction==
| |
| {{Main|Viscosity}}
| |
| | |
| Fluid friction occurs between layers within a [[fluid]] that are moving relative to each other. This internal resistance to flow is described as ''[[viscosity]]''. In everyday terms viscosity of a fluid is said to have "thickness". Thus, water is "thin", having a lower viscosity, while honey is "thick", having a higher viscosity. The less viscous the fluid, the greater its ease of movement.
| |
| | |
| All real fluids (except [[superfluid]]s) have some resistance to stress and therefore are viscous, but a fluid which has no resistance to shear stress is known as an [[ideal fluid]] or inviscid fluid.
| |
| | |
| ==Lubricated friction==
| |
| {{Main|Lubrication}}
| |
| | |
| Lubricated friction is a case of fluid friction where a fluid separates two solid surfaces. Lubrication is a technique employed to reduce wear of one or both surfaces in close proximity moving relative to each another by interposing a substance called a lubricant between the surfaces.
| |
| | |
| In most cases the applied load is carried by pressure generated within the fluid due to the frictional viscous resistance to motion of the lubricating fluid between the surfaces. Adequate lubrication allows smooth continuous operation of equipment, with only mild wear, and without excessive stresses or seizures at bearings. When lubrication breaks down, metal or other components can rub destructively over each other, causing heat and possibly damage or failure.
| |
| | |
| ==Skin friction==
| |
| {{Main|Parasitic drag}}
| |
| | |
| Skin friction arises from the friction of the fluid against the "skin" of the object that is moving through it. Skin friction arises from the interaction between the fluid and the skin of the body, and is directly related to the area of the surface of the body that is in contact with the fluid. Skin friction follows the [[drag equation]] and rises with the square of the velocity.
| |
| | |
| Skin friction is caused by viscous drag in the [[boundary layer]] around the object. There are two ways to decrease skin friction: the first is to shape the moving body so that smooth flow is possible, like an airfoil. The second method is to decrease the length and cross-section of the moving object as much as is practicable.
| |
| | |
| ==Internal friction==
| |
| {{Main|Plastic deformation of solids}}
| |
| {{See also|Deformation (engineering)}}
| |
| Internal friction is the force resisting motion between the elements making up a solid material while it undergoes plastic deformation.
| |
| | |
| Plastic deformation in solids is an irreversible change in the internal molecular structure of an object. This change may be due to either (or both) an applied force or a change in temperature. The change of an object's shape is called strain. The force causing it is called [[stress (mechanics)|stress]]. Stress does not necessarily cause permanent change. As deformation occurs, internal forces oppose the applied force. If the applied stress is not too large these opposing forces may completely resist the applied force, allowing the object to assume a new equilibrium state and to return to its original shape when the force is removed. This is what is known in the literature as [[elastic deformation]] (or elasticity). Larger forces in excess of the elastic limit may cause a permanent (irreversible) deformation of the object. This is what is known as plastic deformation.
| |
| | |
| ==Other types of friction==
| |
| | |
| ===Rolling resistance===
| |
| {{Main|Rolling resistance}}
| |
| | |
| Rolling resistance is the force that resists the rolling of a wheel or other circular object along a surface caused by deformations in the object and/or surface. Generally the force of rolling resistance is less than that associated with kinetic friction.<ref>Silliman, Benjamin (1871) ''Principles of Physics, Or Natural Philosophy'', Ivison, Blakeman, Taylor & company publishers</ref> Typical values for the coefficient of rolling resistance are 0.001.<ref>Butt, Hans-Jürgen; Graf, Karlheinz and Kappl, Michael (2006) ''Physics and Chemistry of Interfaces'', Wiley, ISBN 3-527-40413-9</ref>
| |
| One of the most common examples of rolling resistance is the movement of [[motor vehicle]] tires on a [[road]], a process which generates heat and [[roadway noise|sound]] as by-products.<ref>{{cite journal|last1=Hogan|first1=C. Michael|title=Analysis of highway noise|journal=Water, Air, and Soil Pollution|volume=2|pages=387|year=1973|doi=10.1007/BF00159677|issue=3}}</ref>
| |
| | |
| ===Triboelectric effect===
| |
| {{Main|Triboelectric effect}}
| |
| | |
| Rubbing dissimilar materials against one another can cause a build-up of [[electrostatic charge]], which can be hazardous if flammable gases or vapours are present. When the static build-up discharges, [[explosion]]s can be caused by ignition of the flammable mixture.
| |
| | |
| ===Belt friction===
| |
| | |
| {{Main|Belt friction}}
| |
| | |
| Belt friction is a physical property observed from the forces acting on a belt wrapped around a pulley, when one end is being pulled. The resulting tension, which acts on both ends of the belt, can be modeled by the belt friction equation.
| |
| | |
| In practice, the theoretical tension acting on the belt or rope calculated by the belt friction equation can be compared to the maximum tension the belt can support. This helps a designer of such a rig to know how many times the belt or rope must be wrapped around the pulley to prevent it from slipping. Mountain climbers and sailing crews demonstrate a standard knowledge of belt friction when accomplishing basic tasks.
| |
| | |
| ==Reducing friction==
| |
| | |
| ===Devices===
| |
| Devices such as wheels, [[ball bearing]]s, [[roller bearing]]s, and air cushion or other types of [[fluid bearing]]s can change sliding friction into a much smaller type of rolling friction.
| |
| | |
| Many [[thermoplastic]] materials such as [[nylon]], [[HDPE]] and PTFE are commonly used in low friction [[Bearing (mechanical)|bearings]]. They are especially useful because the coefficient of friction falls with increasing imposed load.{{Citation needed|date=August 2009}} For improved wear resistance, very high [[molecular weight]] grades are usually specified for heavy duty or critical bearings.
| |
| | |
| ===Lubricants===
| |
| A common way to reduce friction is by using a [[lubricant]], such as oil, water, or grease, which is placed between the two surfaces, often dramatically lessening the coefficient of friction. The science of friction and lubrication is called [[tribology]]. Lubricant technology is when lubricants are mixed with the application of science, especially to industrial or commercial objectives.
| |
| | |
| Superlubricity, a recently discovered effect, has been observed in [[graphite]]: it is the substantial decrease of friction between two sliding objects, approaching zero levels. A very small amount of frictional energy would still be dissipated.
| |
| | |
| Lubricants to overcome friction need not always be thin, turbulent fluids or powdery solids such as graphite and [[talc]]; [[acoustic lubrication]] actually uses sound as a lubricant.
| |
| | |
| Another way to reduce friction between two parts is to superimpose micro-scale vibration to one of the parts. This can be sinusoidal vibration as used in ultrasound-assisted cutting or vibration noise, known as dither.
| |
| | |
| ==Energy of friction==
| |
| According to the law of [[conservation of energy]], no energy is destroyed due to friction, though it may be lost to the system of concern. Energy is transformed from other forms into heat. A sliding hockey puck comes to rest because friction converts its kinetic energy into heat. Since heat quickly dissipates, many early philosophers, including [[Aristotle]], wrongly concluded that moving objects lose energy without a driving force.
| |
| | |
| When an object is pushed along a surface, the energy converted to heat is given by:
| |
|
| |
| :<math>E_{th} = \mu_\mathrm{k} \int F_\mathrm{n}(x) dx\,</math>
| |
| where
| |
| : <math>F_{n}\,</math> is the normal force,
| |
| : <math>\mu_\mathrm{k}\,</math> is the coefficient of kinetic friction,
| |
| : <math>x\,</math> is the coordinate along which the object transverses.
| |
| | |
| Energy lost to a system as a result of friction is a classic example of thermodynamic [[irreversibility]].
| |
| | |
| ===Work of friction===
| |
| In the reference frame of the interface between two surfaces, static friction does ''no'' [[mechanical work|work]], because there is never displacement between the surfaces. In the same reference frame, kinetic friction is always in the direction opposite the motion, and does ''negative'' work.<ref>{{Cite book
| |
| | last = Den Hartog
| |
| | first = J. P.
| |
| | title = Mechanics
| |
| | publisher = Courier Dover Publications
| |
| | page = 142
| |
| | year = 1961
| |
| | url = http://books.google.com/?id=WRXrtu44W9UC
| |
| | isbn = 0-486-60754-2}}</ref> However, friction can do ''positive'' work in certain [[frames of reference]]. One can see this by placing a heavy box on a rug, then pulling on the rug quickly. In this case, the box slides backwards relative to the rug, but moves forward relative to the frame of reference in which the floor is stationary. Thus, the kinetic friction between the box and rug accelerates the box in the same direction that the box moves, doing ''positive'' work.<ref>{{cite book
| |
| | title = Minds-on Physics
| |
| | first = William J
| |
| | last = Leonard
| |
| | year = 2000
| |
| | publisher = Kendall/Hunt
| |
| | isbn = 0-7872-3932-1
| |
| | url = http://books.google.com/?id=t_AKvmza5s8C&pg=PA603
| |
| | page = 603}}</ref>
| |
| | |
| The work done by friction can translate into deformation, wear, and heat that can affect the contact surface properties (even the coefficient of friction between the surfaces). This can be beneficial as in [[polishing]]. The work of friction is used to mix and join materials such as in the process of [[friction welding]]. Excessive erosion or wear of mating sliding surfaces occurs when work due frictional forces rise to unacceptable levels. [[hardness|Harder]] corrosion particles caught between mating surfaces in relative motion ([[fretting]]) exacerbates wear of frictional forces. Bearing seizure or failure may result from excessive wear due to work of friction. As surfaces are worn by work due to friction, [[tolerance (engineering)|fit]] and [[Surface roughness|surface finish]] of an object may degrade until it no longer functions properly.<ref name="Bayer">{{cite book|last = Bayer|first = Raymond George|title = Mechanical wear|publisher = CRC Press|year = 2004 |pages = 1, 2|url = http://books.google.com/?id=Q64Kq2HlyucC&pg=PA3&lpg=PA3&dq=Physical+wear+is+associated+with+friction|accessdate = 2008-07-07|isbn = 0-8247-4620-1}}</ref>
| |
| | |
| ==Applications==
| |
| Friction is an important factor in many [[engineering]] disciplines.
| |
| | |
| ===Transportation===
| |
| *[[Vehicle brake|Automobile brakes]] inherently rely on friction, slowing a vehicle by converting its kinetic energy into heat. Incidentally, dispersing this large amount of heat safely is one technical challenge in designing brake systems.
| |
| *[[Rail adhesion]] refers to the grip wheels of a train have on the rails, see [[Frictional contact mechanics]].
| |
| *[[Road slipperiness]] is an important design and safety factor for automobiles
| |
| **[[Split friction]] is a particularly dangerous condition arising due to varying friction on either side of a car.
| |
| **[[Texture (roads)|Road texture]] affects the interaction of tires and the driving surface.
| |
| | |
| ===Measurement===
| |
| *A [[tribometer]] is an instrument that measures friction on a surface.
| |
| *A [[profilograph]] is a device used to measure pavement surface roughness.
| |
| | |
| ===Household usage===
| |
| *Friction is used to heat and ignite [[matchsticks]] (friction between the head of a matchstick and the rubbing surface of the match box).
| |
| | |
| ==See also==
| |
| {{colbegin|3}}
| |
| *[[Contact dynamics]]
| |
| *[[Contact mechanics]]
| |
| *[[Factor of adhesion]]
| |
| *[[Frictionless plane]]
| |
| *[[Galling]]
| |
| *[[Non-smooth mechanics]]
| |
| *[[Stick-slip phenomenon]]
| |
| *[[Transient friction loading]]
| |
| *[[Triboelectric effect]]
| |
| *[[Unilateral contact]]
| |
| {{colend}}
| |
| | |
| ==References==
| |
| {{Reflist|35em}}
| |
| | |
| ==External links==
| |
| *[http://www.roymech.co.uk/Useful_Tables/Tribology/co_of_frict.htm Coefficients of Friction] – tables of coefficients, plus many links
| |
| *[http://www.physclips.unsw.edu.au/ Physclips: Mechanics with animations and video clips] from the University of New South Wales
| |
| *[http://books.google.com/books?id=WDll8hA006AC&pg=PT2503&lpg=PT2503 CRC Handbook of Chemistry & Physics – Values for Coefficient of Friction]
| |
| *[http://chain-guide.com/basics/2-3-1-coefficient-of-friction.html Characteristic Phenomena in Conveyor Chain]
| |
| *[http://nsfafresh.org Atomic-scale Friction Research and Education Synergy Hub (AFRESH)] an Engineering Virtual Organization for the atomic-scale friction community to share, archive, link, and discuss data, knowledge and tools related to atomic-scale friction.
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| | |
| [[Category:Friction| ]]
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| [[Category:Classical mechanics]]
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| [[Category:Force]]
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| [[Category:Tribology]]
| |