Difference between revisions of "Overhead cam"

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'''Overhead cam''' (OHC) [[piston engine]]s place the [[camshaft]] above the [[cylinder head]]s and drive the [[poppet valve|valves]] or [[lifter]]s directly instead of using [[pushrod]]s.  This arrangement is more complex, and relies on a [[timing belt]] or chain, but allows for greater valvetrain flexibility.  Currently, engines have used [[single overhead camshaft]]s (SOHC) or [[dual overhead camshaft]]s (DOHC), which refers to the number of camshafts per cylinder bank.
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{{Refimprove|date=September 2007}}
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[[Image:DOHC-Zylinderkopf-Schnitt.jpg|thumb|right|250px|A [[cylinder head]] sliced in half shows two overhead camshafts—one above each of the two [[poppet valve|valves]].]]
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'''Overhead camshaft''', commonly abbreviated to '''OHC''', [[valvetrain]] configurations place the engine [[camshaft]] within the [[cylinder head]]s, above the [[combustion chamber]]s, and drive the [[poppet valve|valves]] or [[lifter]]s in a more direct manner, when compared with [[Overhead valve]]s (OHV) and [[pushrod]]s.
  
Many OHC engines today employ [[Variable Valve Timing]] and [[multi-valve|multiple valves]] to improve efficiency and powerOHC also allows for greater RPM, though pushrod designs have closed the gap somewhat.   
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When compared directly with OHV pushrod (or I-Head) systems with the same number of valves, the reciprocating components of the OHC system are fewer and in total will have less massThough the system that drives the cams may become more complex, most engine manufacturers easily accept the added complexity in trade for better engine performance and greater design flexibility.  Another performance advantage is gained as a result of the better optimized port configurations made possible with overhead camshaft designs.  With no intrusive pushrods , the overhead camshaft cylinder head design can use straighter ports, of more advantageous crossection and length.   
  
The highest-revving automobile piston-engine currently available from a large-scale manufacturer is a DOHC design found in the [[Honda S2000]] with a 9,000 RPM limit.  Most production car engines with an OHC-controlled valvetrain have limits between 6000 and 7000 RPM.  Honda achieves this unusually high rev-limit by use of lightweight components and techniques learned from their design of motorcycle engines.
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The OHC system can be driven using the same methods as an OHV system, these methods may include using a rubber/kevlar toothed [[timing belt]], [[Roller chain|chain]], or in less common cases, [[gears]].
  
In addition, purpose-built small-volume engines like the [[Powertec RPA]] [[V8]] engine from [[Radical Motorsport]] can be built to higher specifications than mass-produced enginesThe 2.6 L version has a 10,500 RPM limit and there is a de-stroked 2.0 L version planned that is said to have a 12,500 RPM limit.
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Many OHC engines today employ [[Variable Valve Timing]] and [[multi-valve|multiple valves]] to improve efficiency and powerOHC also inherently allows for greater engine speeds over comparable cam-in-block designs.
  
[[Category:Engine technology]]
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There are two overhead camshaft layouts:
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* '''Single overhead camshaft''' - or '''SOHC'''
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* '''Double overhead camshaft''' - or '''DOHC'''
  
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==Single overhead camshaft==<!-- This section is linked from [[Straight-4]] -->
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[[Image:Head D15A3.JPG|thumb|right|250px|A single overhead camshaft cylinder head from a [[1987]] [[Honda]] [[Honda CRX|CRX]] Si.]]
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Single overhead camshaft (SOHC) is a design in which one camshaft is placed within the [[cylinder head]].  In an inline engine this means there is one camshaft in the head, while in a [[V engine]] or a horizontally-opposed engine (boxer; [[Flat engine]]) there are two camshafts: one per cylinder bank.
  
{{tech-stub}}
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The SOHC design has less reciprocating mass than a comparable [[pushrod]] design.  This can allow for higher engine speeds, which in turn will increase power output for a given [[torque]].  The cam operates the valves directly or through a [[rocker arm]] as opposed to overhead valve [[pushrod]] engines, which have tappets, long pushrods and rocker arms to transfer the movement of the lobes on the camshaft in the engine block to the valves in the [[cylinder head]].
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SOHC designs offer reduced complexity compared to [[pushrod]] designs when used for [[multivalve]] heads, in which each cylinder has more than two valves.  An example of a SOHC design using [[shim]] and bucket valve adjustment was the engine installed in the [[Hillman Imp]] (4 cylinder, 8 valve), a small early [[1960s]] 2-door [[saloon car]] with a rear mounted alloy engine, based on the [[Coventry Climax|Coventry Climax FWMA]] race engines.  Exhaust and inlet manifolds were both on the same side of the engine block (thus not a [[crossflow cylinder head]] design).  However, this did offer excellent access to the spark plugs.
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In the early [[1980s]] [[Toyota]] and [[Volkswagen]] also used a directly actuated, SOHC parallel valve configuration with two valves for each cylinder.  The Toyota system used hydraulic [[tappet]]s while the Volkswagen system used bucket [[tappet]]s with shims for valve lash adjustment.  Of all valvetrain systems this is the least complex configuration possible.
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==Double overhead camshaft==
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[[Image:Suzuki-GS550-DOHC.jpg|thumb|right|250px|Overhead view of Suzuki [[Suzuki gs series|GS550]] head showing dual camshafts and drive sprockets.]]
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A double overhead camshaft (also called ''DOHC'', ''dual overhead cam'', or ''twin cam (TC)'') valve train layout is characterized by two camshafts being located within the cylinder head, where there are separate camshafts for inlet and exhaust valves.  Typical automotive engines equipped with dual overhead camshafts can have from two to four camshafts in total, depending on the engine configuration.<!-- for Vee and horizontally opposed engines --> The term Twin Cam doesnt tell the exact location of camshafts, but it is mostly used to describe DOHC structure.
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Double overhead camshafts are not required in order to have [[multivalve|multiple inlet or exhaust valves]], but are necessary for more than two valves that are directly actuated (though still usually via tappets).  Not all DOHC engines are multivalve engines—DOHC was common in two valve per cylinder heads for decades before multivalve heads appeared, however today DOHC is synonymous with multi-valve heads, since almost all DOHC engines have between three and five valves per cylinder.
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==History==
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[[Image:1933 Bugatti Type 59 Grand Prix engine.jpg|right|thumb|250px|[[DOHC]] [[straight-8]] in a 1933 [[Bugatti Type 59]] [[Grand Prix motor racing|Grand Prix]] racer]]
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Among the early pioneers of DOHC were [[Isotta Fraschini]]'s [[Giustino Cattaneo]], [[Austro-Daimler]]'s [[Ferdinand Porsche]] [[Stephen Tomczak]] (in the ''Prinz Heinrich''), and [[W. O. Bentley]] (in 1919); [[Sunbeam Car Company|Sunbeam]] built small numbers between 1921 and 1923. The first DOHC engines were two- or four-valve ''per'' cylinder designs from companies like [[Fiat]] (1912), [[Peugeot]] Grand Prix (1913, 4 valve), [[Alfa Romeo]] [[Alfa Romeo Grand Prix|GP]] (1914, 4 valve) and [[Alfa Romeo 6C|6C]] (1925), [[Maserati]] [[Maserati Tipo 26|Tipo 26]] (1926),  [[Bugatti]] [[Bugatti Type 51|Type 51]] (1931), and [[Audi]]. Most [[Ferrari]]s used two-valve DOHC engines as well.
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When DOHC technology was introduced in mainstream vehicles, it was common for it to be heavily advertised. While used at first in limited production and sports cars, [[FIAT]] is credited as the first car company to use a belt-driven DOHC engine across their complete product line, in the mid-1960s.{{Fact|date=April 2008}}
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==See also==
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* [[Valvetrain]]
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* [[Overhead valve]]
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* [[Cam-in-block]]
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* [[Camless]]
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==External links==
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* [http://www.samarins.com/glossary/dohc.html OHV, SOHC, DOHC engine animated diagrams]
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[[Category:Valvetrain]]
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[[Category:Engine valves]]
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[[Category:Motorcycle engines]]

Revision as of 09:25, 17 April 2008

A cylinder head sliced in half shows two overhead camshafts—one above each of the two valves.

Overhead camshaft, commonly abbreviated to OHC, valvetrain configurations place the engine camshaft within the cylinder heads, above the combustion chambers, and drive the valves or lifters in a more direct manner, when compared with Overhead valves (OHV) and pushrods.

When compared directly with OHV pushrod (or I-Head) systems with the same number of valves, the reciprocating components of the OHC system are fewer and in total will have less mass. Though the system that drives the cams may become more complex, most engine manufacturers easily accept the added complexity in trade for better engine performance and greater design flexibility. Another performance advantage is gained as a result of the better optimized port configurations made possible with overhead camshaft designs. With no intrusive pushrods , the overhead camshaft cylinder head design can use straighter ports, of more advantageous crossection and length.

The OHC system can be driven using the same methods as an OHV system, these methods may include using a rubber/kevlar toothed timing belt, chain, or in less common cases, gears.

Many OHC engines today employ Variable Valve Timing and multiple valves to improve efficiency and power. OHC also inherently allows for greater engine speeds over comparable cam-in-block designs.

There are two overhead camshaft layouts:

  • Single overhead camshaft - or SOHC
  • Double overhead camshaft - or DOHC

Single overhead camshaft

A single overhead camshaft cylinder head from a 1987 Honda CRX Si.

Single overhead camshaft (SOHC) is a design in which one camshaft is placed within the cylinder head. In an inline engine this means there is one camshaft in the head, while in a V engine or a horizontally-opposed engine (boxer; Flat engine) there are two camshafts: one per cylinder bank.

The SOHC design has less reciprocating mass than a comparable pushrod design. This can allow for higher engine speeds, which in turn will increase power output for a given torque. The cam operates the valves directly or through a rocker arm as opposed to overhead valve pushrod engines, which have tappets, long pushrods and rocker arms to transfer the movement of the lobes on the camshaft in the engine block to the valves in the cylinder head.

SOHC designs offer reduced complexity compared to pushrod designs when used for multivalve heads, in which each cylinder has more than two valves. An example of a SOHC design using shim and bucket valve adjustment was the engine installed in the Hillman Imp (4 cylinder, 8 valve), a small early 1960s 2-door saloon car with a rear mounted alloy engine, based on the Coventry Climax FWMA race engines. Exhaust and inlet manifolds were both on the same side of the engine block (thus not a crossflow cylinder head design). However, this did offer excellent access to the spark plugs.

In the early 1980s Toyota and Volkswagen also used a directly actuated, SOHC parallel valve configuration with two valves for each cylinder. The Toyota system used hydraulic tappets while the Volkswagen system used bucket tappets with shims for valve lash adjustment. Of all valvetrain systems this is the least complex configuration possible.

Double overhead camshaft

Overhead view of Suzuki GS550 head showing dual camshafts and drive sprockets.

A double overhead camshaft (also called DOHC, dual overhead cam, or twin cam (TC)) valve train layout is characterized by two camshafts being located within the cylinder head, where there are separate camshafts for inlet and exhaust valves. Typical automotive engines equipped with dual overhead camshafts can have from two to four camshafts in total, depending on the engine configuration. The term Twin Cam doesnt tell the exact location of camshafts, but it is mostly used to describe DOHC structure.

Double overhead camshafts are not required in order to have multiple inlet or exhaust valves, but are necessary for more than two valves that are directly actuated (though still usually via tappets). Not all DOHC engines are multivalve engines—DOHC was common in two valve per cylinder heads for decades before multivalve heads appeared, however today DOHC is synonymous with multi-valve heads, since almost all DOHC engines have between three and five valves per cylinder.

History

Among the early pioneers of DOHC were Isotta Fraschini's Giustino Cattaneo, Austro-Daimler's Ferdinand Porsche Stephen Tomczak (in the Prinz Heinrich), and W. O. Bentley (in 1919); Sunbeam built small numbers between 1921 and 1923. The first DOHC engines were two- or four-valve per cylinder designs from companies like Fiat (1912), Peugeot Grand Prix (1913, 4 valve), Alfa Romeo GP (1914, 4 valve) and 6C (1925), Maserati Tipo 26 (1926), Bugatti Type 51 (1931), and Audi. Most Ferraris used two-valve DOHC engines as well.

When DOHC technology was introduced in mainstream vehicles, it was common for it to be heavily advertised. While used at first in limited production and sports cars, FIAT is credited as the first car company to use a belt-driven DOHC engine across their complete product line, in the mid-1960s.Template:Fact

See also


External links