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As used in [[mechanical engineering]], the term '''tractive force''' can either refer to the total [[traction]] a vehicle exerts on a surface, or the amount of the total traction that is parallel to the direction of [[motion (physics)|motion]].<ref>SAE J2047, Tire Performance Technology, dated February 1998.</ref>
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In railway engineering, the term '''tractive effort''' is often used [[synonym]]ously with tractive force to describe the pulling or pushing capability of a [[locomotive]].  In automotive engineering, the terms are distinctive:  [[tractive effort]] is generally higher than tractive force by the amount of [[rolling resistance]] present, and both terms are higher than the amount of [[drawbar pull]] by the total resistance present (including [[drag (physics)|air resistance]] and [[grade (slope)|grade]]).  The published tractive force value for any vehicle may be theoretical&mdash;that is, calculated from known or implied mechanical properties&mdash;or obtained via testing under controlled conditions.  The discussion herein covers the term's usage in mechanical applications in which the final stage of the power transmission system is one or more [[wheel]]s in [[friction]]al contact with a [[roadway]] or [[railroad track]].
 
==Defining tractive effort==
The term '''tractive effort''' is often qualified as '''starting tractive effort''', '''continuous tractive effort''' and '''maximum tractive effort'''.  These terms apply to different operating conditions, but are related by common mechanical factors: [[torque|input torque]] to the driving wheels, the wheel diameter, [[coefficient of friction]] ('''μ''') between the driving wheels and supporting surface, and the weight applied to the driving wheels ('''m''').  The [[product (mathematics)|product]] of '''μ''' and '''m''' is the [[factor of adhesion]], which determines the maximum torque that can be applied before the onset of [[wheelspin]] or [[locomotive wheelslip|wheelslip]].
 
*'''Starting tractive effort''': Starting tractive effort is the tractive force that can be generated at a standstill.  This figure is important on railways because it determines the maximum train weight that a locomotive can set into motion.
 
*'''Maximum tractive effort''': Maximum tractive effort is defined as the highest tractive force that can be generated under any condition that is not injurious to the vehicle or machine.  In most cases, maximum tractive effort is developed at low speed and may be the same as the starting tractive effort.
 
*'''Continuous tractive effort''': Continuous tractive effort is the tractive force that can be maintained indefinitely, as distinct from the higher tractive effort that can be maintained for a limited period of time before the power transmission system overheats. Due to the relationship between [[power (physics)|power]] (''P''), velocity (''v'') and force (''F''), described as:
 
:''P'' = ''vF''  or  ''P''/''v'' = ''F''
 
: tractive effort inversely varies with speed at any given level of available power.  Continuous tractive effort is often shown in graph form at a range of speeds as part of a '''tractive effort curve'''.<ref name=dynamics/>
 
Vehicles having a [[fluid coupling|hydrodynamic coupling]], [[torque converter|hydrodynamic torque multiplier]] or [[electric motor]] as part of the power transmission system may also have a '''maximum continuous tractive effort''' rating, which is the highest tractive force that can be produced for a short period of time without causing component harm. The period of time for which the maximum continuous tractive effort may be safely generated is usually limited by thermal considerations. such as temperature rise in a [[traction motor]].
 
==Tractive effort curves==
 
Specifications of locomotives often include '''''tractive effort curves''''',<ref name=railpage/><ref name=voith/><ref name=vossloh/><ref name=siemens/> showing the relationship between tractive effort and velocity.
 
[[File:Schematic tractive effort curve.JPG|thumb|500px|Diagram of tractive effort vs. speed for a hypothetical locomotive with power at rail of ~7000 kW]]
 
The shape of the graph is shown at right. The line AB shows operation at the maximum tractive effort, the line BC shows continuous tractive effort that is inversely proportional to speed (constant power).<ref name=marks/>
 
Tractive effort curves often have graphs of [[rolling resistance]] superimposed on them—the intersection of the rolling resistance graph<ref group="note">The graphs typically show rolling resistance for standard train lengths or weights, on the level or on an uphill gradient</ref> and tractive effort graph gives the maximum velocity (i.e. when net tractive effort is zero).
 
==Rail vehicles==
 
In order to start a train and accelerate it to a given speed, the locomotive(s) must develop sufficient tractive force to overcome the train's drag (resistance to motion), which is a combination of [[inertia]], [[axle]] [[bearing (mechanical)|bearing]] [[friction]], the friction of the wheels on the rails (which is substantially greater on curved track than on tangent track), and the force of [[gravity]] if on a [[grade (slope)|grade]].  Once in motion, the train will develop additional drag as it accelerates due to [[aerodynamic force]]s, which increase with the square of the speed.  Drag may also be produced at speed due to [[hunting oscillation|truck (bogie) hunting]], which will increase the rolling friction between wheels and rails.  If acceleration continues, the train will eventually attain a speed at which the available tractive force of the locomotive(s) will exactly offset the total drag, causing acceleration to cease.  This top speed will be increased on a downgrade due to gravity assisting the motive power, and will be decreased on an upgrade due to gravity opposing the motive power.
 
Tractive effort can be theoretically calculated from a locomotive's mechanical characteristics (e.g., steam pressure, weight, etc.), or by actual testing with [[drawbar (haulage)|drawbar]] [[strain gauge|strain sensor]]s and a [[dynamometer car]].  '''''Power at rail''''' is a railway term for the available power for traction, that is, the power that is available to propel the train.
 
===Steam locomotives===
An estimate for the tractive effort of a single cylinder steam locomotive can be obtained from the cylinder pressure, cylinder area, [[stroke (engines)|stroke]] of the piston<ref group="note">Half the stroke distance is about the same as the radial distance from the coupling of the driving rod to the centre of the driven wheel</ref> and the diameter of the wheel. The torque developed by the linear motion of the piston depends on the angle that the driving rod makes with the tangent of the radius on the driving wheel.<ref group="note">The relationship is: Torque = Force<sub>piston</sub> x ''R'' (the radial distance to the point of connection of the driving rod) x cos(''A''), where ''A'' is the angle the driving rod makes with the tangent to the radius from wheel centre to driving rod attachment</ref> For a more useful value an average value over the rotation of the wheel is used. The driving force is the torque divided by the wheel radius.
 
As an approximation, the following formula can be used (for a 2 cylinder locomotive):<ref group="note">As with any physical formula, [[units of measurement]] must be consistent: pressure in psi and lengths in inches give tractive effort in lbf, while pressure in Pa and lengths in metres give tractive effort in N.</ref>
 
:<math>t = \frac {cPd^2s} {D}</math>
 
where
* ''t'' is ''tractive effort''
* ''c'' is a constant representing losses in pressure and friction; normally 0.85 is used<ref group="note">For a 'perfect' locomotive with cylinder piston pressure equal to boiler pressure (independent of stroke) and with no frictional losses the constant ''c'' can be taken as 1</ref>
* ''P'' is the [[boiler]] pressure<ref group="note">note that the boiler pressure may be greater than the cylinder pressure</ref>
* ''d'' is the [[piston]] diameter ([[bore (engine)|bore]])
* ''s'' is the piston stroke
* ''D'' is the [[driving wheel]] diameter
 
The constant 0.85 was the [[Association of American Railroads]] (AAR) standard for such calculations, and overestimated the efficiency of some locomotives and underestimated that of others. Modern locomotives with roller bearings were probably underestimated.
 
European designers used a constant of 0.6 instead of 0.85, so the two cannot be compared without a conversion factor.  In Britain main-line railways generally used a constant of 0.85 but builders of industrial locomotives often used a lower figure, typically 0.75.
 
The constant ''c'' also depends on the cylinder dimensions and the time at which the steam inlet valves are open; if the steam inlet valves are closed immediately after obtaining full cylinder pressure the piston force can be expected to have dropped to less than half the initial force.<ref group="note">See [[Gas laws]] for an explanation.</ref> giving a low ''c'' value. If the cylinder valves are left open for longer the value of ''c'' will rise nearer to 1.
 
;Three or four cylinders (simple)
The result should be multiplied by 1.5 for a 3 cylinder locomotive and by 2 for a 4 cylinder locomotive.<ref>''Ian Allan ABC of British Railways Locomotives'', winter 1960/61 edition, part 1, page 3</ref>
 
;Multiple cylinders (compound)
For other numbers and combinations of cylinders, including double and triple expansion engines the tractive effort can be estimated by adding the tractive efforts due to the individual cylinders at their respective pressures and cylinder strokes.<ref group="note">The value of the constant ''c'' for a low-pressure cylinder is taken to be 0.80 when the value for a high pressure cylinder is taken to be 0.85</ref>
 
====Values and comparisons for steam locomotives====
 
Tractive effort is the figure often quoted when comparing the powers of steam locomotives, but it's misleading because tractive effort shows the ability to start a train, not the ability to haul it. Possibly the highest tractive effort ever claimed was for the [[Virginian Railway]]'s 2-8-8-8-4 Triplex locomotive, which in [[Steam engine#Simple expansion|simple expansion]] mode had a calculated starting T.E. of 199,560&nbsp;lbf (887.7&nbsp;kN) &mdash; but the boiler could not produce enough steam to haul at speeds over 5&nbsp;mph (8&nbsp;km/h).
 
Of more successful steam locomotives, those with the highest rated starting tractive effort were the Virginian Railway AE-class [[2-10-10-2]]s, at 176,000&nbsp;lbf (783&nbsp;kN) in simple-expansion mode (or 162,200&nbsp;lb if calculated by the usual formula). The [[Union Pacific]] [[Union Pacific Big Boy|Big Boys]] had a starting T.E. of 135,375&nbsp;lbf (602&nbsp;kN); the [[Norfolk & Western]]'s Y5, Y6, Y6a, and Y6b class  [[2-8-8-2]]s had a starting T.E. of 152,206&nbsp;lbf (677&nbsp;kN) in simple expansion mode (later modified to 170,000&nbsp;lbf (756&nbsp;kN), claim some enthusiasts); and the [[Pennsylvania Railroad]]'s freight [[Duplex (locomotive)|Duplex]] [[PRR Q2|Q2]] attained 114,860&nbsp;lbf (510.9&nbsp;kN, including booster) &mdash; the highest for a rigid framed locomotive. Later two cylinder passenger locomotives were generally 40,000 to 80,000&nbsp;lbf (170 to 350&nbsp;kN) of T.E.
 
===Diesel and electric locomotives===
 
For an [[electric locomotive]] or a [[Diesel-electric locomotive]], starting tractive effort can be calculated from the amount of weight on the driving wheels (which may be less than the total locomotive weight in some cases), combined [[stall torque]] of the [[traction motor]]s, the [[gear#Spur|gear ratio]] between the traction motors and axles, and driving wheel [[diameter]].  For a [[Diesel-hydraulic locomotive]], the starting tractive effort is affected by the stall torque of the [[torque converter]], as well as gearing, wheel diameter and locomotive weight.
 
Freight locomotives are designed to produce higher maximum tractive effort than passenger units of equivalent power, necessitated by the much higher weight that is typical of a freight train.  In modern locomotives, the gearing between the traction motors and axles is selected to suit the type of service in which the unit will be operated.  As traction motors have a maximum speed at which they can rotate without incurring damage, gearing for higher tractive effort is at the expense of top speed.  Conversely, the gearing used with passenger locomotives favors speed over maximum tractive effort.
 
Electric locomotives with [[monomotor]] [[bogie]]s are sometimes fitted with two-speed gearing.  This allows higher tractive effort for hauling freight trains but at reduced speed. Examples include [[SNCF Class BB 8500]] and [[SNCF Class BB 25500]].
 
==See also==
* [[Factor of adhesion]], which is simply the weight on the locomotive's driving wheels divided by the starting tractive effort
* [[Tractor pulling]], [[bollard pull]] - articles relating to tractive effort for other forms of vehicle
* [[Rail adhesion]]
* [[Power classification]] - [[British Railways]] and [[London, Midland and Scottish railway]] classification scheme
* [[Drag equation]]
 
==References and notes==
 
===Notes===
<references group="note"/>
 
===References===
{{reflist
|refs=
 
<ref name="dynamics">{{cite book|title=Handbook of railway vehicle dynamics|editor=Simon Iwnicki|publisher=CRC Press: Taylor & Francis|location=Boca Raton|year=2006|page=256|url=http://books.google.com/books?id=Im0ZjhI3a-cC&printsec=frontcover#PPA256,M1 | isbn=978-0-8493-3321-7}}</ref>
 
<ref name=marks>{{cite book|title=Marks Standard Handbook for Mechanical Engineers|editor=Eugene A. Avallone, Theodore Baumeister, Ali Sadegh|edition=11th|page=166|url=http://books.google.com/books?id=QrQQTTmr3sQC&pg=RA4-PA166&lpg=RA4-PA166&dq=continuous+tractive+effort | isbn=978-0-07-142867-5 | year=2006 | publisher=McGraw-Hill}}</ref>
 
<ref name=railpage>[http://www.railpage.org.au/xpt/delivery.html XPT: Delivery, test runs and demonstration runs railpage.au.org ''see graph'']</ref>
 
<ref name=siemens>[http://www.siemens.dk/ccmi/bu/ts/download/pdf/tog/lokomotiver1/EuroRunner_ER20_eng.pdf Eurorunner ER20 BF and ER20 BU, Diesel electric platform locomotives for Europe siemens.dk (page 3)]</ref>
 
<!-- <ref name="tonywoof">{{cite web|url=http://www.twoof.freeserve.co.uk/motion1.htm|title=Kilo Newtons, kilo Watts, kilometres per Hour|last=Woof|first=Tony|year=2001|accessdate=5 March 2010}}</ref> -->
 
<ref name=voith>[http://www.voithturbo.de/applications/documents/document_files/1581_e_g_1974_gravita_e_2008-10_singlepage.pdf The Gravita Locomotive Family voithturbo.de (page 2)]</ref>
 
<ref name=vossloh>[http://www.vossloh-espana.com/cms/media/downloads/pdfs/flyer/Vossloh_Espana_EURO4000_freight_us.pdf EURO 4000 Freight Diesel-Electric Locomotives vossloh-espana.com (page 2)]</ref>
 
}}
 
===Additional references and further reading===
* [http://www.twoof.freeserve.co.uk/motion1.htm A simple guide to train physics]
* [http://www.brightlemon.com/ma/what_use/TractiveEffortAccelerationAndBraking.doc Tractive effort, acceleration and braking]
 
[[Category:Rolling stock]]
[[Category:Force]]

Latest revision as of 02:11, 2 December 2014

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Lovely to be a part of wmflabs.org.
I really hope I am useful in one way .

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