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| {{Short description|Reciprocating engine valve actuation mechanism}} | |||
| :''In general mechanical terms, the word '''''desmodromic''''' is used to refer to mechanisms that have different controls for their actuation in different directions.'' | :''In general mechanical terms, the word '''''desmodromic''''' is used to refer to mechanisms that have different controls for their actuation in different directions.'' | ||
| ] |
] | ||
| A '''desmodromic valve''' is a reciprocating engine ] that is positively closed by a cam and leverage system, rather than by a more conventional spring. | |||
| ==How it works== | |||
| '''Desmodromic''' ] are those which are positively closed by a cam and leverage system, rather than relying on the more conventional valve springs to close them. The term is derived from two Greek roots, ''desmos'' (controlled, linked) and ''dromos'' (course, track). | |||
| The valves in |
The valves in a typical ] allow the air/fuel mixture into the ] at the beginning of the cycle and exhaust spent gases at the end of the cycle. In a conventional four-stroke engine, valves are opened by a cam and closed by return spring. A desmodromic valve has two cams and two actuators, for positive opening and closing without a return spring. | ||
| ==Etymology== | |||
| A desmodromic system uses extra cam lobes with rocker arms that close the valves, instead of valve springs. There is total control of the opening and closing action of the valves. | |||
| The word comes from the ] words ''desmos'' ({{lang|grc|]}}, translated as "bond" or "knot") and ''dromos'' ({{lang|grc|]}}, "track" or "way"). This denotes the major characteristic of the valves being continuously "bound" to the camshaft. | |||
| ==Advantages== | |||
| {{Unreferenced|section|date=January 2007}} | |||
| The primary benefit of desmodromic (abbreviated to "desmo") systems is to improve valve timing at higher engine revolutions. On very high-revving valve spring engines, the spring does not always have enough force to keep the valve in contact with the camshaft lobe. This is called "]". To a point, this can be compensated for by stiffer valve springs, but at the cost of increased wear and power consumption. (In some engines valve float from over revving can result in valves damaging pistons.) | |||
| ==Idea== | |||
| A desmodromic valve system camshaft can have steeper opening and closing ramps on its lobes, as the ] of a quickly opening valve is kept in check by the closing camshaft lobe; and likewise a quickly closing valve can not bounce off the ] since it is retained by the opening camshaft lobe. The Desmo system makes the valve movement conform precisely to the camshaft profile, with no opportunity to stray. The benefits of this system are only found at high engine rpms, and would normally only be considered necessary for racing and high performance applications. | |||
| The common valve spring system is satisfactory for traditional mass-produced engines that do not rev highly and are of a design that requires low maintenance.<ref>Rivola, A., et al.: "Modelling the Elastodynamic Behaviour of a Desmodromic Valve Train", ''Proceedings of SMA2002 International Conference on Noise & Vibration Engineering'',16–18 September 2002 - Leuven, Belgium</ref> At the period of initial desmodromic development, valve springs were a major limitation on engine performance because they would break from metal fatigue. In the 1950s new ] processes helped to remove impurities from the metal in valve springs, increasing their life and efficiency greatly. However, many springs would still fail at sustained operation above 8000 RPM.<ref name="herald">{{cite web |url=http://www.mrs.org/s_mrs/bin.asp?CID=2984&DID=94886&DOC=FILE.PDF |last=Falco |first=Charles M. |date=July 2003 |series=MRS Bulletin |page=514 |title=The Art and Materials Science of 190 mph Superbikes |url-status=dead |access-date=2006-11-02 |quote=Thus, neglecting all other factors, the faster an engine can be made to turn, the more power can be generated. Unfortunately, through at least the 1950s, valve springs often would fatigue and break when engines were operated for significant periods of time much above 8000 rpm. |archive-url=https://web.archive.org/web/20070307050308/http://www.mrs.org/s_mrs/bin.asp?CID=2984&DID=94886&DOC=FILE.PDF |archive-date=2007-03-07 }}</ref> The desmodromic system was devised to remedy this problem by completely removing the need for a spring. Furthermore, as maximum RPM increases, higher spring force is required to prevent ], leading to larger springs (with increased spring mass, and thus greater inertia), cam drag (as the valve springs require energy to compress, robbing the engine of power), and higher wear on the parts at all speeds, problems addressed by the desmodromic mechanism. | |||
| ==Design and history== | |||
| The more precise valve control allows higher valve acceleration and deceleration (without risk of collision between valves and piston), the elimination of valve float at high rpm, and lower friction (partly due to the lack of valve spings). | |||
| <!-- Deleted image removed: ] --> | |||
| ] | |||
| Fully controlled valve movement was conceived during the earliest days of engine development, but devising a system that worked reliably and was not overly complex took a long time. Desmodromic valve systems are first mentioned in patents in 1896 by Gustav Mees.{{Citation needed|reason=the USPO's earliest patent with his name is 1899|date=January 2013}} Austin's marine engine of 1910 produced 300 bhp and was installed in a speedboat called "Irene I"; its all-aluminium, twin-overhead-valve engine had twin magnetos, twin carburettors and desmodromic valves.<ref>{{cite web |url=http://www.austinmemories.com/page98/page98.html |title=Austin Marine Engines |last=Baker |first=John |website=Austin Memories |archive-url=https://web.archive.org/web/20150821041415/http://www.austinmemories.com/page98/page98.html |archive-date=August 21, 2015 |url-status=dead |quote=In 1910 Herbert Austin decided to build a Marine engine that at the time was very advanced. It produced 300bhp and was installed in a speedboat called "Irene I" which was named after his eldest daughter who had married Colonel Waite. The all aluminium twin ohv engine had twin magneto, twin carburettor and desmodronic valves.}}</ref> The 1914 Grand Prix ] and Nagant (see Pomeroy "Grand Prix Car") used a desmodromic valve system (quite unlike the present day ] system).<ref>{{cite web|url=http://members.chello.nl/~wgj.jansen/ |title=Jansen ''Desmodromology'' |url-status=live |archive-url=https://archive.today/20120525104143/http://members.chello.nl/~wgj.jansen/ |archive-date=May 25, 2012 |access-date=September 20, 2016 }}</ref> | |||
| Azzariti, a short-lived Italian manufacturer from 1933 to 1934, produced 173 cc and 348 cc twin-cylinder engines, some of which had desmodromic valve gear, with the valve being closed by a separate camshaft.<ref>Title: The Illustrated Encyclopedia of Motorcycles, Editor: Erwin Tragatsch, Publisher: New Burlington Books, Copyright: 1979 Quarto Publishing, Edition: 1988 Revised, Page 81, {{ISBN|0-906286-07-7}}</ref> | |||
| ==Disadvantages== | |||
| {{Unreferenced|section|date=January 2007}} | |||
| At a time when combustion advantages of overhead valves were recognized, desmodromic valve drive seemed to be the solution for problems that arose in operating engines at higher speeds, long before computer analyses were available. Today, lift, velocity, acceleration, and jerk curves for cams have been modeled with computation to identify what limits valve motion.{{fact}} As analytic methods came into use, valve adjustment, hydraulic tappets, push rods, rocker arms and ] became largely a thing of the past,{{fact}} making desmodromic valve drive a cumbersome engineering relic. | |||
| The ] ] racing car of 1954–1955, and the ] sports racing car of 1955 both had desmodromic valve actuation. | |||
| Today most engines use an ] with symmetric cam profiles because maximum acceleration for opening valves is the same as that of catching them when closing.{{fact}} Therefore, speed of lift and catch is limited only by cam contact pressure of reciprocating valve mass. This conclusion escaped discovery until computer modeling showed that limiting stresses were ] for beginning and end of the valve stroke.{{fact}} | |||
| In 1956, ], a Ducati engineer, developed a desmodromic valve system for the Ducati 125 Grand Prix, creating the Ducati 125 Desmo. | |||
| Additional mass of the desmodromic mechanism outweighs its supposed advantage because valves cannot be raised or lowered any faster than cam-to-tappet stress allows without ]. Neither lift nor catch is affected by spring load in conventional cams because both occur at the base circle where spring force is at its minimum. Additionally, desmodromic cams use curved (lever) tappets that cause higher contact pressures than a flat tappet does for the same lift profile, thereby limiting valve acceleration. | |||
| He was quoted: | |||
| For flat spring loaded tappets the highest cam contact stress occurs at full lift when turning at zero speed (engine cranking) and diminishes with increasing speed, while the desmodromic cam has essentially no load at zero speed because, in the absence of springs, its load is entirely inertial,{{fact}} increasing with speed, its greatest acceleration occurring at its smaller contact radii. Acceleration forces for both types of cams increase with the square of velocity because they result from ] . {{fact}} | |||
| <blockquote>The specific purpose of the desmodromic system is to force the valves to comply with the timing diagram as consistently as possible. In this way, any lost energy is negligible, the performance curves are more uniform and dependability is better.</blockquote> | |||
| Desmodromic actuation was often justified by claims that springs could not close valves reliably at high speed and that the forces caused by suitably strong springs exceeded what cams could withstand. Since then, valve float was analyzed and found to be caused largely by resonance in valve springs that generated oscillating compression waves among coils, much like a Slinky.{{fact}} High speed photography showed that at specific resonant speeds, valve springs were no longer making contact at one or both ends, leaving the valve floating before crashing into the cam on closure. For this reason as many as three concentric valve springs, press fit into each other, were often used, not for more force (the inner ones having no significant spring constant), but to act as snubbers to prevent spring oscillations.{{fact}} | |||
| The engineers that came after him continued that development, and Ducati held a number of patents relating to desmodromics. Desmodromic valve actuation has been applied to top-of-the-range production ] motorcycles since 1968, with the introduction of the "widecase" Mark 3 single cylinders. | |||
| An early response to spring problems led to the use of hairpin (mouse trap) springs that avoided resonance but were ungainly to locate in cylinder heads. Today's formula-one racing engines use gas springs that have no resonant parts, the bellows having a spring constant insignificant to the force of the pressurized gas. These springs are expensive and short lived, therefore, offering no benefit for most motors. | |||
| In 1959 the ] introduced one of their final designs: a desmodromic four-cylinder, 2000cc engine for their last ] Barchetta. | |||
| Current high performance valve springs are wound with varying pitch | |||
| (progressive) | |||
| {{fact}} whose number of active coils varies during the stroke, the | |||
| more closely wound coils being on the static end, becoming inactive as | |||
| the spring compresses. This prevents resonance because spring force | |||
| and mass varies with stroke.{{fact}} This advance in spring design | |||
| removed the main justification for desmodromic valve drive. | |||
| ==Comparison with conventional valvetrains== | |||
| Damage from ] formerly occurred at the apex of lift, where a benign contact with the piston | |||
| In modern engines, valve spring failure at high RPM has been mostly remedied. The main benefit of the desmodromic system is the prevention of ] at high rpm. | |||
| crown can be seen on most racing engines during overhaul. Overlap, when both valves are partially open, is where damaged could occur, but this is not where lift-off occurs, that being at maximum lift when only one valve is raised and is no longer an issue now that acceleration profiles are understood.{{fact}} | |||
| In traditional spring-valve actuation, as engine speed increases, the inertia of the valve will eventually overcome the spring's ability to close it completely before the piston reaches ] (TDC). This can lead to several problems. First, the valve does not completely return to its seat before combustion begins. This allows combustion gases to escape prematurely, leading to a reduction in cylinder pressure which causes a major decrease in engine performance. This can also overheat the valve, possibly warping it and leading to catastrophic failure. Second, and most damaging, the ] collides with the valve and both are destroyed. In spring-valve engines the traditional remedy for valve float is to stiffen the springs. This increases the seat pressure of the valve (the static pressure that holds the valve closed). This is beneficial at higher engine speeds because of a reduction in the aforementioned valve float. The drawback is increased forces on all valvetrain components and increased friction and associated temperature and wear. It does not decrease power because nearly all work put into compressing the spring is later released as the spring is allowed to uncompress. | |||
| Today desmodromic valve drive is an anachronism that, with diligence, can be made to work but at significant cost and design effort ].{{fact}} That overhead cams using flat tappets and spring valve closure offer advantages over desmodromic is seen in current automobile engines, none of which use desmodromic drive.{{fact}} Why other motor companies are not using desmodromic valve drive is mentioned in ] "Motorcycle Designs". | |||
| The desmodromic system avoids some of the shortcomings of spring-loaded valves because it is not subject to the high loads associated with compressing stiff springs. However, it must still overcome the inertia of the valve itself, and that depends on the mass distribution of the moving parts. The effective mass of a traditional valve with spring includes one-half of the valve spring mass for symmetric springs and all of the valve spring retainer mass. However, a desmodromic system must deal with the inertia of the two rocker arms per valve, so this advantage depends greatly on the skill of the designer. Another disadvantage is the contact point between the cams and rocker arms. It is relatively easy to use roller tappets in conventional valvetrains, although it does add considerable moving mass. In a desmodromic system the roller would be needed at one end of the rocker arm, which would greatly increase its moment-of-inertia and negate its "effective mass" advantage. Thus, desmo systems have generally needed to deal with sliding friction between the cam and rocker arm and therefore may have greater wear. The contact points on most Ducati rocker arms are hard-chromed to reduce this wear. Another disadvantage is the difficulty in incorporating hydraulic valve lash adjusters to a desmodromic system; thus frequent valve clearance (lash) adjustments are required. Additionally, each valve requires two lash adjustments - one for the opening rocker and another for the closing rocker. However, it is rare for most high RPM engines with conventional spring-loaded valvetrains to incorporate hydraulic lash adjusters – so they too require periodic checks and adjustments of valve lash. | |||
| ==Historical Examples== | |||
| Famous examples include the successful ] and ] race cars, and modern ] motorcycles. (see below) | |||
| ==Disadvantages== | |||
| Fully controlled valve movement was thought of in the earliest days of engine development, but devising a system that worked reliably and was not overly complex took a long time. Desmodromic valve systems are first mentioned in patents in 1896 by Gustav Mees, and in 1907 the Aries is described as having a V4 engine with "desmodromique" valve actuation, but details are scarce. The 1914 Grand Prix Delage used a desmodromic valve system (quite unlike the present day Ducati system). <ref> Jansen ''Desmodromology'' (Retrieved 31 October 2006)</ref> | |||
| {{Disputed-section|Disputed section: Disadvantages|date = June 2011}} | |||
| Before the days when valve drive dynamics could be analyzed by computer,{{when|date=July 2023}} desmodromic drive seemed to offer solutions for problems that were worsening with increasing engine speed. Since those days, lift, velocity, acceleration, and jerk curves for cams have been modelled by computer<ref>{{cite web|url=http://www.profblairandassociates.com/pdfs/4sthead-Insight.pdf |title=4stHEAD Insight - Death of a Black Art |access-date=2011-12-06}}</ref> to reveal that cam dynamics are not what they seemed. With proper analysis, problems relating to valve adjustment, hydraulic ]s, push rods, rocker arms, and above all, ], became things of the past without desmodromic drive. | |||
| Today{{when|date=July 2023}} most automotive engines use ], driving a flat tappet to achieve the shortest, lightest weight, and most inelastic path from cam to ], thereby avoiding elastic elements such as ] and ]. Computers have allowed for fairly accurate acceleration modelling of valve-train systems. | |||
| Azzariti, a short lived Italian manufacturer from 1933 to 1934, produced 173 cc and 348 cc twin cylinder engines, some of which had desmodromic valve gear, with the valve being closed by a separate camshaft.<ref> Title: The Illustrated Encyclopedia of Motorcycles, Editor: Erwin Tragatsch, Publisher: New Burlington Books, Copyright: 1979 Quarto Publishing, Edition: 1988 Revised, Page 81, ISBN 0-906286-07-7</ref> | |||
| Before numerical computing methods were readily available, acceleration was only attainable by differentiating cam lift profiles twice, once for velocity and again for acceleration. This generates so much hash (noise) that the second derivative (acceleration) was uselessly inaccurate. Computers permitted integration from the jerk curve, the third derivative of lift, that is conveniently a series of contiguous straight lines whose vertices can be adjusted to give any desired lift profile. | |||
| In 1956 ], a Ducati Engineer, developed a desmodromic valve system for the Ducati 125 Grand Prix, creating the Ducati 125 Desmo. The engineers that came after him continued that development, and Ducati holds a number of patents relating to desmodromics. Desmodromic valve actuation has been applied to top-of-the-range production ] motorcycles since 1968, with the introduction of the "widecase" Mark 3 single cylinders. Ducati motorcycles with desmodromic valves have won numerous races and championships, including ] Championships from 1990-92, 1994-96, 1998-99, 2001, 2003-04 and 2006. ]'s return to ] was powered by a desmodromic-valved V4 990 cc engine, which went on to claim a one-two victory at the final 990 cc ] race at Valencia, Spain in 2006. | |||
| Integration of the ] curve produces a smooth acceleration curve while the third integral gives an essentially ideal lift curve (cam profile). | |||
| With such cams, which mostly do not look like the ones "artists" formerly designed, valve noise (lift-off) went away and valve train elasticity came under scrutiny. | |||
| Today,{{when|date=July 2023}} most cams have ] (symmetric) profiles with identical positive and negative acceleration while opening and closing valves. However, some high speed (in terms of engine RPM) motors now employ asymmetrical cam profiles in order to quickly open valves and set them back in their seats more gently to reduce wear. As well, production vehicles have employed asymmetrical cam lobe profiles since the late 1940s, as seen in the 1948 Ford V8.<ref>{{cite web|url=http://www.tildentechnologies.com/Cams/CamHistory.html|title=Cam Design History|website=www.tildentechnologies.com|access-date=11 April 2018}}</ref> In this motor both the intake and exhaust profiles had an asymmetric design. More modern applications of asymmetrical camshafts include Cosworth's 2.3 liter crate motors, which use aggressive profiles to reach upwards of 280 brake horsepower.<ref>{{Cite web |url=http://www.cosworth.com/media/335568/duratec_components_catalogue_2009_v1.0.pdf |title=Duratec Engine Components 2009/10 |publisher=Cosworth |access-date=2012-11-08 |archive-url=https://web.archive.org/web/20130618103720/http://cosworth.com/media/335568/duratec_components_catalogue_2009_v1.0.pdf |archive-date=2013-06-18 |url-status=dead }}</ref> An asymmetric cam either opens or closes the valves more slowly than it could, with the speed being limited by ] between curved cam and flat tappet, thereby ensuring a more controlled acceleration of the combined mass of the reciprocating componentry (specifically the valve, tappet and spring). | |||
| In contrast, desmodromic drive uses two cams per valve, each with separate rocker arm (lever tappets). Maximum valve acceleration is limited by the cam-to-tappet ] stress, and therefore is governed by both the moving mass and the cam contact area. Maximum rigidity and minimum contact stress are best achieved with conventional flat tappets and springs whose lift and closure stress is unaffected by spring force; both occur at the base circle,<ref>{{cite web |url=http://www.webcamshafts.com/pages/cam_glossary.html |title=Web Cam Inc - Performance and Racing Camshafts / Terminology |publisher=Webcamshafts.com |access-date=2011-12-06}}</ref> where spring load is minimum and contact radius is largest. Curved (lever) tappets<ref>{{cite web |url=http://www.usq.edu.au/users/grantd/motorcycle/ducati/DESMO.HTM |title=Desmodromic Valve Gear |publisher=Usq.edu.au |access-date=2011-12-06 |url-status=dead |archive-url=https://web.archive.org/web/20120212205457/http://www.usq.edu.au/users/grantd/motorcycle/ducati/DESMO.HTM |archive-date=2012-02-12 }}</ref> of desmodromic cams cause higher contact stress than flat tappets for the same lift profile, thereby limiting rate of lift and closure. | |||
| With conventional cams, stress is highest at full lift, when turning at zero speed (initiation of engine cranking), and diminishes with increasing speed as inertial force of the valve counters spring pressure, while a desmodromic cam has essentially no load at zero speed (in the absence of springs), its load being entirely inertial, and therefore increasing with speed. Its greatest inertial stress bears on its smallest radius. Acceleration forces for either method increase with the square of velocity resulting from ].<ref>{{cite web |url=http://www.glenbrook.k12.il.us/GBSSCI/PHYS/Class/energy/u5l1c.html |title=Kinetic Energy |publisher=Glenbrook.k12.il.us |access-date=2011-12-06 |url-status=dead |archive-url=https://web.archive.org/web/20120804234257/http://www.glenbrook.k12.il.us/gbssci/phys/Class/energy/u5l1c.html |archive-date=2012-08-04 }}</ref> | |||
| Valve float was analyzed and found to be caused largely by resonance in valve springs that generated oscillating compression waves among coils, much like a ]. High speed photography showed that at specific resonant speeds, valve springs were no longer making contact at one or both ends, leaving the valve floating<ref>{{cite web |url=http://www.engr.colostate.edu/~dga/high_speed_video/mechanisms/MERC_valve_spring_tests_1000-6000rpm_1000fps.wmv |title=MERC valve spring tests 1000-6000rpm |access-date=2008-06-25 |url-status=dead |archive-url=https://web.archive.org/web/20080911042106/http://www.engr.colostate.edu/~dga/high_speed_video/mechanisms/MERC_valve_spring_tests_1000-6000rpm_1000fps.wmv |archive-date=2008-09-11 }}</ref> before crashing into the cam on closure. | |||
| For this reason, today{{when|date=July 2023}} as many as three concentric valve springs are sometimes nested inside one other; not for more force (the inner ones having no significant spring constant), but to act as snubbers to reduce oscillations in the outer spring.{{Citation Needed|date=March 2016}} | |||
| An early solution{{When|date=November 2010}} to oscillating spring mass was the mousetrap or hairpin spring<ref>{{cite web |url=http://www.enginehistory.org/ACEvolution/ACLawrancePenguin.jpg |title=ACLawrancePenguin.jpg |access-date=2008-06-25 |url-status=dead |archive-url=https://web.archive.org/web/20080911042106/http://www.enginehistory.org/ACEvolution/ACLawrancePenguin.jpg |archive-date=2008-09-11 }}</ref> used on ]<ref>{{cite web|author=Greenpark-Productions. |url=http://members.shaw.ca/nortonmanx/engine.htm |title='1959 Norton Manx Restoration' September 2004—Engine Section, Welcome! |publisher=Members.shaw.ca |date=2005-02-25 |access-date=2011-12-06}}</ref> engines. These avoided resonance but were ungainly to locate inside cylinder heads. | |||
| Valve springs that do not resonate are progressive, wound with varying pitch or varying diameter called beehive springs<ref> {{webarchive |url=https://web.archive.org/web/20071009163218/http://www.wmr1.com/tipscont.htm |date=October 9, 2007 }}</ref> from their shape. The number of active coils in these springs varies during the stroke, the more closely wound coils being on the static end, becoming inactive as the spring compresses or as in the beehive spring, where the small diameter coils at the top are stiffer. Both mechanisms reduce resonance because spring force and its moving mass vary with stroke. This advance in spring design removed ], the initial impetus for desmodromic valve drive. | |||
| ==Examples== | |||
| ] | |||
| Famous examples include the successful ] and ] race cars and, most commonly, modern ] motorcycles. | |||
| Ducati motorcycles with desmodromic valves have won numerous races and championships, including ] from 1990 to 1992, 1994–96, 1998–99, 2001, 2003–04, 2006, 2008 and 2011. Ducati's return to ] was powered by a desmodromic ] 990 cc engine in the GP3 (]) bike, which went on to claim several victories, including a one-two finish at the final 990 cc ] race at Valencia, Spain in 2006. With the onset of the 800 cc era in 2007, they are generally still considered to be the most powerful engines in the sport, and have powered ] to the 2007 MotoGP Championship and Ducati to the constructors championship with the GP7 (Desmosedici) bike. | |||
| ==See also== | ==See also== | ||
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| ==Sources== | ==Sources== | ||
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Latest revision as of 21:21, 4 October 2024
Reciprocating engine valve actuation mechanism- In general mechanical terms, the word desmodromic is used to refer to mechanisms that have different controls for their actuation in different directions.
A desmodromic valve is a reciprocating engine poppet valve that is positively closed by a cam and leverage system, rather than by a more conventional spring.
The valves in a typical four-stroke engine allow the air/fuel mixture into the cylinder at the beginning of the cycle and exhaust spent gases at the end of the cycle. In a conventional four-stroke engine, valves are opened by a cam and closed by return spring. A desmodromic valve has two cams and two actuators, for positive opening and closing without a return spring.
Etymology
The word comes from the Greek words desmos (δεσμός, translated as "bond" or "knot") and dromos (δρόμος, "track" or "way"). This denotes the major characteristic of the valves being continuously "bound" to the camshaft.
Idea
The common valve spring system is satisfactory for traditional mass-produced engines that do not rev highly and are of a design that requires low maintenance. At the period of initial desmodromic development, valve springs were a major limitation on engine performance because they would break from metal fatigue. In the 1950s new vacuum melt processes helped to remove impurities from the metal in valve springs, increasing their life and efficiency greatly. However, many springs would still fail at sustained operation above 8000 RPM. The desmodromic system was devised to remedy this problem by completely removing the need for a spring. Furthermore, as maximum RPM increases, higher spring force is required to prevent valve float, leading to larger springs (with increased spring mass, and thus greater inertia), cam drag (as the valve springs require energy to compress, robbing the engine of power), and higher wear on the parts at all speeds, problems addressed by the desmodromic mechanism.
Design and history
Fully controlled valve movement was conceived during the earliest days of engine development, but devising a system that worked reliably and was not overly complex took a long time. Desmodromic valve systems are first mentioned in patents in 1896 by Gustav Mees. Austin's marine engine of 1910 produced 300 bhp and was installed in a speedboat called "Irene I"; its all-aluminium, twin-overhead-valve engine had twin magnetos, twin carburettors and desmodromic valves. The 1914 Grand Prix Delage and Nagant (see Pomeroy "Grand Prix Car") used a desmodromic valve system (quite unlike the present day Ducati system).
Azzariti, a short-lived Italian manufacturer from 1933 to 1934, produced 173 cc and 348 cc twin-cylinder engines, some of which had desmodromic valve gear, with the valve being closed by a separate camshaft.
The Mercedes-Benz W196 Formula One racing car of 1954–1955, and the Mercedes-Benz 300SLR sports racing car of 1955 both had desmodromic valve actuation.
In 1956, Fabio Taglioni, a Ducati engineer, developed a desmodromic valve system for the Ducati 125 Grand Prix, creating the Ducati 125 Desmo.
He was quoted:
The specific purpose of the desmodromic system is to force the valves to comply with the timing diagram as consistently as possible. In this way, any lost energy is negligible, the performance curves are more uniform and dependability is better.
The engineers that came after him continued that development, and Ducati held a number of patents relating to desmodromics. Desmodromic valve actuation has been applied to top-of-the-range production Ducati motorcycles since 1968, with the introduction of the "widecase" Mark 3 single cylinders.
In 1959 the Maserati brothers introduced one of their final designs: a desmodromic four-cylinder, 2000cc engine for their last O.S.C.A. Barchetta.
Comparison with conventional valvetrains
In modern engines, valve spring failure at high RPM has been mostly remedied. The main benefit of the desmodromic system is the prevention of valve float at high rpm.
In traditional spring-valve actuation, as engine speed increases, the inertia of the valve will eventually overcome the spring's ability to close it completely before the piston reaches top dead centre (TDC). This can lead to several problems. First, the valve does not completely return to its seat before combustion begins. This allows combustion gases to escape prematurely, leading to a reduction in cylinder pressure which causes a major decrease in engine performance. This can also overheat the valve, possibly warping it and leading to catastrophic failure. Second, and most damaging, the piston collides with the valve and both are destroyed. In spring-valve engines the traditional remedy for valve float is to stiffen the springs. This increases the seat pressure of the valve (the static pressure that holds the valve closed). This is beneficial at higher engine speeds because of a reduction in the aforementioned valve float. The drawback is increased forces on all valvetrain components and increased friction and associated temperature and wear. It does not decrease power because nearly all work put into compressing the spring is later released as the spring is allowed to uncompress.
The desmodromic system avoids some of the shortcomings of spring-loaded valves because it is not subject to the high loads associated with compressing stiff springs. However, it must still overcome the inertia of the valve itself, and that depends on the mass distribution of the moving parts. The effective mass of a traditional valve with spring includes one-half of the valve spring mass for symmetric springs and all of the valve spring retainer mass. However, a desmodromic system must deal with the inertia of the two rocker arms per valve, so this advantage depends greatly on the skill of the designer. Another disadvantage is the contact point between the cams and rocker arms. It is relatively easy to use roller tappets in conventional valvetrains, although it does add considerable moving mass. In a desmodromic system the roller would be needed at one end of the rocker arm, which would greatly increase its moment-of-inertia and negate its "effective mass" advantage. Thus, desmo systems have generally needed to deal with sliding friction between the cam and rocker arm and therefore may have greater wear. The contact points on most Ducati rocker arms are hard-chromed to reduce this wear. Another disadvantage is the difficulty in incorporating hydraulic valve lash adjusters to a desmodromic system; thus frequent valve clearance (lash) adjustments are required. Additionally, each valve requires two lash adjustments - one for the opening rocker and another for the closing rocker. However, it is rare for most high RPM engines with conventional spring-loaded valvetrains to incorporate hydraulic lash adjusters – so they too require periodic checks and adjustments of valve lash.
Disadvantages
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Before the days when valve drive dynamics could be analyzed by computer, desmodromic drive seemed to offer solutions for problems that were worsening with increasing engine speed. Since those days, lift, velocity, acceleration, and jerk curves for cams have been modelled by computer to reveal that cam dynamics are not what they seemed. With proper analysis, problems relating to valve adjustment, hydraulic tappets, push rods, rocker arms, and above all, valve float, became things of the past without desmodromic drive.
Today most automotive engines use overhead cams, driving a flat tappet to achieve the shortest, lightest weight, and most inelastic path from cam to valve, thereby avoiding elastic elements such as pushrod and rocker arm. Computers have allowed for fairly accurate acceleration modelling of valve-train systems.
Before numerical computing methods were readily available, acceleration was only attainable by differentiating cam lift profiles twice, once for velocity and again for acceleration. This generates so much hash (noise) that the second derivative (acceleration) was uselessly inaccurate. Computers permitted integration from the jerk curve, the third derivative of lift, that is conveniently a series of contiguous straight lines whose vertices can be adjusted to give any desired lift profile.
Integration of the jerk curve produces a smooth acceleration curve while the third integral gives an essentially ideal lift curve (cam profile). With such cams, which mostly do not look like the ones "artists" formerly designed, valve noise (lift-off) went away and valve train elasticity came under scrutiny.
Today, most cams have mirror image (symmetric) profiles with identical positive and negative acceleration while opening and closing valves. However, some high speed (in terms of engine RPM) motors now employ asymmetrical cam profiles in order to quickly open valves and set them back in their seats more gently to reduce wear. As well, production vehicles have employed asymmetrical cam lobe profiles since the late 1940s, as seen in the 1948 Ford V8. In this motor both the intake and exhaust profiles had an asymmetric design. More modern applications of asymmetrical camshafts include Cosworth's 2.3 liter crate motors, which use aggressive profiles to reach upwards of 280 brake horsepower. An asymmetric cam either opens or closes the valves more slowly than it could, with the speed being limited by Hertzian contact stress between curved cam and flat tappet, thereby ensuring a more controlled acceleration of the combined mass of the reciprocating componentry (specifically the valve, tappet and spring).
In contrast, desmodromic drive uses two cams per valve, each with separate rocker arm (lever tappets). Maximum valve acceleration is limited by the cam-to-tappet galling stress, and therefore is governed by both the moving mass and the cam contact area. Maximum rigidity and minimum contact stress are best achieved with conventional flat tappets and springs whose lift and closure stress is unaffected by spring force; both occur at the base circle, where spring load is minimum and contact radius is largest. Curved (lever) tappets of desmodromic cams cause higher contact stress than flat tappets for the same lift profile, thereby limiting rate of lift and closure.
With conventional cams, stress is highest at full lift, when turning at zero speed (initiation of engine cranking), and diminishes with increasing speed as inertial force of the valve counters spring pressure, while a desmodromic cam has essentially no load at zero speed (in the absence of springs), its load being entirely inertial, and therefore increasing with speed. Its greatest inertial stress bears on its smallest radius. Acceleration forces for either method increase with the square of velocity resulting from kinetic energy.
Valve float was analyzed and found to be caused largely by resonance in valve springs that generated oscillating compression waves among coils, much like a Slinky. High speed photography showed that at specific resonant speeds, valve springs were no longer making contact at one or both ends, leaving the valve floating before crashing into the cam on closure.
For this reason, today as many as three concentric valve springs are sometimes nested inside one other; not for more force (the inner ones having no significant spring constant), but to act as snubbers to reduce oscillations in the outer spring.
An early solution to oscillating spring mass was the mousetrap or hairpin spring used on Norton Manx engines. These avoided resonance but were ungainly to locate inside cylinder heads.
Valve springs that do not resonate are progressive, wound with varying pitch or varying diameter called beehive springs from their shape. The number of active coils in these springs varies during the stroke, the more closely wound coils being on the static end, becoming inactive as the spring compresses or as in the beehive spring, where the small diameter coils at the top are stiffer. Both mechanisms reduce resonance because spring force and its moving mass vary with stroke. This advance in spring design removed valve float, the initial impetus for desmodromic valve drive.
Examples
Famous examples include the successful Mercedes-Benz W196 and Mercedes-Benz 300 SLR race cars and, most commonly, modern Ducati motorcycles.
Ducati motorcycles with desmodromic valves have won numerous races and championships, including Superbike World Championships from 1990 to 1992, 1994–96, 1998–99, 2001, 2003–04, 2006, 2008 and 2011. Ducati's return to Grand Prix motorcycle racing was powered by a desmodromic V4 990 cc engine in the GP3 (Desmosedici) bike, which went on to claim several victories, including a one-two finish at the final 990 cc MotoGP race at Valencia, Spain in 2006. With the onset of the 800 cc era in 2007, they are generally still considered to be the most powerful engines in the sport, and have powered Casey Stoner to the 2007 MotoGP Championship and Ducati to the constructors championship with the GP7 (Desmosedici) bike.
See also
Sources
- Rivola, A., et al.: "Modelling the Elastodynamic Behaviour of a Desmodromic Valve Train", Proceedings of SMA2002 International Conference on Noise & Vibration Engineering,16–18 September 2002 - Leuven, Belgium
- Falco, Charles M. (July 2003). "The Art and Materials Science of 190 mph Superbikes" (PDF). MRS Bulletin. p. 514. Archived from the original (PDF) on 2007-03-07. Retrieved 2006-11-02.
Thus, neglecting all other factors, the faster an engine can be made to turn, the more power can be generated. Unfortunately, through at least the 1950s, valve springs often would fatigue and break when engines were operated for significant periods of time much above 8000 rpm.
- Baker, John. "Austin Marine Engines". Austin Memories. Archived from the original on August 21, 2015.
In 1910 Herbert Austin decided to build a Marine engine that at the time was very advanced. It produced 300bhp and was installed in a speedboat called "Irene I" which was named after his eldest daughter who had married Colonel Waite. The all aluminium twin ohv engine had twin magneto, twin carburettor and desmodronic valves.
- "Jansen Desmodromology". Archived from the original on May 25, 2012. Retrieved September 20, 2016.
- Title: The Illustrated Encyclopedia of Motorcycles, Editor: Erwin Tragatsch, Publisher: New Burlington Books, Copyright: 1979 Quarto Publishing, Edition: 1988 Revised, Page 81, ISBN 0-906286-07-7
- "4stHEAD Insight - Death of a Black Art" (PDF). Retrieved 2011-12-06.
- "Cam Design History". www.tildentechnologies.com. Retrieved 11 April 2018.
- "Duratec Engine Components 2009/10" (PDF). Cosworth. Archived from the original (PDF) on 2013-06-18. Retrieved 2012-11-08.
- "Web Cam Inc - Performance and Racing Camshafts / Terminology". Webcamshafts.com. Retrieved 2011-12-06.
- "Desmodromic Valve Gear". Usq.edu.au. Archived from the original on 2012-02-12. Retrieved 2011-12-06.
- "Kinetic Energy". Glenbrook.k12.il.us. Archived from the original on 2012-08-04. Retrieved 2011-12-06.
- "MERC valve spring tests 1000-6000rpm". Archived from the original on 2008-09-11. Retrieved 2008-06-25.
- "ACLawrancePenguin.jpg". Archived from the original on 2008-09-11. Retrieved 2008-06-25.
- Greenpark-Productions. (2005-02-25). "'1959 Norton Manx Restoration' September 2004—Engine Section, Welcome!". Members.shaw.ca. Retrieved 2011-12-06.
- WMR Archived October 9, 2007, at the Wayback Machine
External links
- Desmo Information and Wallpapers
- "Desmodromology": for further investigation and visualisation.
- The newest Desmodromic:"Desmotronic" detailed information and visualisation.
- Mercedes Benz's patent, showing the exact construction of the system used in the W196 and 300SLR. (requires Tiff reader)
- DVVA: Desmodromic fully Variable Valve Actuation
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