Pushrod valvetrains may have their drawbacks
Transcription
Pushrod valvetrains may have their drawbacks
Fig. 1 – NASCAR Sprint Cup is perhaps the most famous circuit application of pushrod engines. Bespoke race engines such as this were designed within very strict guidelines (Courtesy of TRD) Rods and rockers Pushrod valvetrains may have their drawbacks but they thrive in some racing series. Wayne Ward looks at their design issues T 56 Large pushrod V8 engines have formed the backbone of the passenger automotive industry for many decades in the US, so it is natural that such engines have been used widely for motorsport and it is likely that this will continue for some time. It is only recently that the top tier of US circuit racing, NASCAR’s Sprint Cup, has allowed engine manufacturers to race with engines not based on a production cylinder block [Fig. 1]. However, the rules governing the design of these bespoke pushrod race engines mean they still closely resemble he pushrod or overhead valve (OHV) valvetrain has some the production blocks that preceded them, but are designed with attractive features, but simplicity and stiffness are not among modern principles in mind and using modern engineering methods them. It is therefore perhaps not a natural choice for a such as CFD and FEA. valvetrain for a race engine. Its widespread use in racing, Many people in motorsport will have only ever seen or studied especially in North America, is rooted in the popularity of large- overhead cam (OHC) engines, so it is worth explaining the basics displacement pushrod engines in production vehicles, and this in itself of the pushrod system. Most pushrod engines have two valves per is probably due to the comparatively low cost of gasoline in the US. cylinder, and one of the more appealing aspects of the valvetrain At the time of writing, the average price of gasoline in the US was $1 is the number of camshafts required and the position the camshaft per litre. In Australia the equivalent figure was $1.54, in the UK it was occupies in the engine. A typical OHC vee engine, such as a current $2.25 and in Italy it was $2.39. It is therefore not that hard to imagine Formula One engine or the previous Champ Car engine, will have why comparatively small-displacement engines have for many years four camshafts: one for inlet and one for exhaust on each bank. These been the norm for passenger vehicles outside the US. four camshafts are mounted at the very top of each bank, operating FOCUS : PUSHRODS, ROCKERS & LIFTERS the valves from above. A V8 pushrod engine uses a single camshaft, Technology contributed by Blair et al (3), Wagstaff gave paramount and this is mounted in the cylinder block, above and close to the importance to modelling the behaviour of the valve spring properly so crankshaft. Not only are there far fewer things to provide a half-speed that the predicted system response during resonant conditions (spring drive to, but the distance over which the drive is taken is very short surge) was accurate. In their paper on the subject of modelling the and the centre of gravity of the camshaft is low. Winston Cup valvetrain (Winston Cup eventually became Sprint Cup), In a typical pushrod engine, the cams cause a follower to translate McLaughlin and Haque (4) conclude that “the valve spring dynamics within a bore. In a race engine, these followers will generally through dominates the performance of the valvetrain”, especially in situations choice be a roller follower, so named because a roller at the tip of the such as valve bounce. follower is carried on a bearing. Flat-faced followers are used only So, in our calculations of the behaviour of a pushrod valvetrain by Sprint Cup racers because the rules dictate this. Into the follower system, we need to pay great attention not only to the design of the is located the lower end of the pushrod, and this part of the linkage specialist valvetrain components such as pushrods, lifters, rockers and connects the bottom end of the engine to the top. The upper end of so on, but we should also take care to model the behaviour of the the pushrod operates a rocker. Typically the rocker will have a roller spring. The valvetrain engineer has to pay special attention not only tip, but rollerless rockers have been developed and used with some to the natural frequencies of the spring, and their relation to both the success in NASCAR. There is a good picture of such a rocker in the fundamental frequency of the stimulus – that is, the cam profile – and previous ‘Focus’ article on the subject (1). its harmonics, but also to the natural frequencies of the associated Pushrod valvetrain development continues apace within the tight components. confines of NASCAR, especially in its top two series, Sprint Cup and This was brought to my attention during a conversation on the Nationwide. Sprint Cup, the top series, mandates the use of flat-faced subject with the late Prof Blair: his point was that it is very easy for lifters, while Nationwide allows roller followers. As we shall see, the people not to understand the system and to have a pushrod with type of lifter fundamentally affects the tuning potential of the engine. a natural frequency that causes resonance in the valve spring. Any component will have a number of different stiffnesses depending Considerations in valvetrain design: stiffness and natural frequencies The pushrod valvetrain is technically difficult to deal with, owing to on the direction; for example, a simple rectangular beam has two different bending stiffnesses, an axial stiffness and a torsional stiffness. A part will also have a number of natural frequencies. An several factors, chief among which are its inherent compliance and the axisymmetric component such as a pushrod can have its lateral and fact that there are a number of points at which clearance may appear longitudinal stiffnesses tuned independently so that their fundamental in the system. The complexity of the system lends itself very well to natural frequencies fall outside the operating range of the engine. As calculations that can be carried out by computer. Even in the 1960s, is the case with valve springs and the avoidance of surge, we need advances in computing power allowed engineers to treat the pushrod to ensure that significant harmonics from the cam do not excite valvetrain as a far more complex multi-mass system than had been resonances in the valvetrain components. This might entail designing possible in practice before. the components such that their natural frequencies are four, five or In his paper on the subject, Wagstaff (2) calculated the system response for a variety of degrees of freedom in the system, and more times higher than the basic natural frequency of the cam. The consideration of component stiffness was also highlighted included the effects of clearances within his calculations. The method during discussions I had with component suppliers and technical by which he arrived at the main damping coefficients in the system experts at some of the top NASCAR engine suppliers. With the advent was by practical experiment; it is probably still by the study of the of valvetrain simulation software and the increasingly widespread use vibration of practical systems that an accurate correlation between of valvetrain rigs, people have really begun to appreciate the value of modern valvetrain simulation software and real-life engines can be improving component stiffness. arrived at. In common with the articles published in Race Engine Consequently, we have seen some very strong trends in component design over recent years – pushrods have become thicker and heavier; valvetrain engineers are now more than happy to sacrifice some mass in order to significantly increase the stiffness of the components in the system, especially on the pushrod side of the rocker; and steel has begun to supplant aluminium for rockers, not only for greater stiffness but for lower moment of inertia and material trends will be expanded in the component discussions that follow. t Fig. 2 – The bearings are the largest feature on a pushrod camshaft and, along with the cam profile, dictate the base circle diameter. Base circle diameter has a significant effect on camshaft stiffness (Courtesy of Comp Cams) too. More on these design 57 FOCUS : PUSHRODS, ROCKERS & LIFTERS Fig. 3 – Flat-faced lifters, while out of date now, even for roadcars, are mandated by NASCAR for Sprint Cup (Courtesy of Trend) (22.22 mm) in diameter [Fig. 3]. As far as pushrod engines are concerned, flat-faced followers are an arcane technology, used only rarely in current production engines, despite the fact that they are much simpler and therefore less expensive, to produce. Given the focus placed on low production costs by car producers, for them to use roller lifters in preference to cheap, flat lifters there must be very real benefits to using roller lifters, even for production engines. For racing, where engineers have a choice, roller lifters are used [Fig. 4]. As mentioned, flat-faced lifters suffer in limiting lift velocities, and the relationship between lift velocity and follower radius is widely documented (1). There are two real advantages to using roller followers. The first is that the design and development engineers have much more freedom with cam profiles and the resultant valve Camshafts lift profiles. Care must be exercised here though; the paper by Prof Camshafts for pushrod engines differ significantly from those used in Blair (2) published in Race Engine Technology gives examples of OHC engines, and not just because a single camshaft carries the cam cam profiles for flat-faced lifters, but the lessons of tempering the lobes to open all of the engine’s valves. A striking difference is the ‘aggression’ of cam profiles apply equally to all types of followers. fact that the largest features on the shaft are the cam bearing journal If we ignore the matter of contact (Hertzian) stresses, the limiting diameters [Fig. 2, page 57] . The camshafts slide into the block from factor for a roller follower is pressure angle. This is the angle between one end of the engine; the radius from the camshaft axis to the top of the axis of the follower translation – that is, the lifter bore axis – and the cam lobes is therefore limited. the normal to the cam/follower contact. There is a critical angle beyond which the follower will tend to bind in the bore rather than translate consumption, development of camshaft profiles is very important. smoothly. High pressure angles can also lead to increased friction and When the cam lobe radius (base circle radius plus cam lift) is at the wear. The maximum pressure angle is a function of follower velocity and maximum possible size, increasing lift necessarily means that the also of acceleration at the point of maximum pressure angle. In general, base circle diameter is reduced. This leads to increased flexing of roller-lifter pressure angle is influenced by the base circle diameter of the the camshaft between the bearings, and this is the source of the first camshaft and the follower roller radius, lift and any eccentricity (lifter of the valvetrain engineer’s ‘headaches’. Higher lift camshafts with bore axis offset from camshaft axis) with larger base circle diameters more aggressive levels of valve acceleration are controlled by heavier having smaller pressure angles for a given lift profile. Offsetting the lifter springs. The forces due to the spring and the acceleration of the masses bore axis so that it doesn’t intersect the camshaft axis can be an effective and inertias in the system, combined with the lower stiffness of the way to control pressure angles. Rothbart (5) and Chen (6) both provide camshaft, can lead to significant deformation. the mathematical formulae for pressure angle for roller followers. NASCAR limits the camshaft journal diameter to 2.362 in (60 mm), The level of surface finish achieved and any surface treatments preventing any scope for stiffening the camshaft by increasing bearing or coatings applied will have a direct effect on frictional losses. The diameter. As ever, there are design options to provide more camshaft surface finish will dictate the lubrication regime, specifically the stiffness that the NASCAR valvetrain designer may use. Other race extent to which the operating cycle at any engine speed the cam- series don’t impose similar bearing size restrictions, and valvetrain lifter contact operates in a fully hydrodynamic/elastohydrodynamic designers may choose to take the associated rise in friction from the regime, and what proportion of the cycle is a mixed regime. A better larger bearings to give more scope for performance improvement. surface finish leads to a lower proportion of the cycle operating in a mixed lubrication regime: the greater the proportion of the cycle Lifters Lifters (also widely known as followers or tappets) come in two basic types for racing – flat-faced and roller. Flat-faced lifters limit cam profile development because of the restrictions they place on the opening and closing velocity of the cam. Basically, the higher the opening or closing velocity, the larger the diameter of lifter required. This can be overcome to an extent by using ‘mushroom’ lifters that have an increased diameter cam-contact face. However, NASCAR’s premier series, which enforces the use of flat-faced lifters, does not allow mushroom lifters and goes further than this in limiting the follower to be 0.875 in 58 Fig. 4 – Roller lifters are preferred to flat-faced types owing to their greater tuning potential; they allow more scope for cam profile development (Courtesy of Johnson Lifters) t In order to improve engine performance and control fuel Fig. 5 – The blue trace is the desired valve lift profile, and red is the reality. Note the significant valve float near maximum lift, and serious valve bounce following very early seating (Courtesy of Trend) during which the cam-to-follower contact is one of hydrodynamic (or elastohydrodynamic) lubrication, then the lower the frictional losses. A low-friction coating means that any time operating in the mixed lubrication region is subject to a lower coefficient of friction, and this in turn lowers the overall frictional losses. Where we have the correct conditions for hydrodynamic lubrication, the tangential friction component is negligible, and the subsurface stress field is very similar to that of a static contact. Subsurface fatigue leads to pitting, the fatigue crack being initiated at or close to the site of maximum stress. The depth of this maximum stress depends on the geometry of the contacting bodies, the loads and the materials in use. Where there is a more significant friction component, as is the case with mixed lubrication, there are two main effects on the subsurface stresses. First, and most important, the maximum stress is increased. Those who produce titanium and aluminium pushrods for competition say they are chosen primarily by motorcycle competitors. Composite materials are perhaps not ideal candidates for The second effect is to reduce the depth at which the maximum stress pushrods, but if they are allied to more conventional metallic occurs in the material. Where lubrication is inadequate and sliding materials, they become more practical. In an ideal world, one motion is dominant, then the maximum stress is very close to the might reasonably design a pushrod using a composite material surface, and surface damage can be confused with conventional wear with fibres running in a predominantly axial direction; this would mechanisms rather than subsurface fatigue. provide the maximum axial and bending stiffness. However, the In terms of roller followers, the same grade of material may be more tangential stiffness would be poor, as there would only be resin highly stressed if used for a roller (compared to a flat follower) without providing stiffness in this direction. Careful thought is required here suffering from surface wear or subsurface fatigue, as the contact in order to provide a cylindrical pushrod tube with excellent axial should be one of pure rolling rather than sliding. This is not to say that stiffness per unit mass combined with sufficient tangential stiffness rolling contacts won’t suffer from fatigue, but it will happen at a higher to prevent splitting of the tube. level of stress. In aiming for maximum system stiffness, we might expect there to be a There are options to ‘fit’ a thin sleeve around a CFRP (carbon fibre reinforced polymer) inner, but the only company willing to trend towards shorter pushrods, and this could be achieved with a taller talk about development projects involving composites for use lifter. However, the angularity of the pushrod and its effect on frictional in pushrods does not take this approach; instead it uses a metal losses between the lifter and its bore need to be considered. Wear of matrix composite with a carbon fibre reinforcement. Its comment the lifter bore may become a problem when angularity is too great. One on the carbon-reinforced material is that it provides a lot of extra supplier of the complete range of pushrod valvetrain components, from stiffness in compression, but the properties of the material in cams to rockers, said its philosophy is to keep the pushrod seat in the bending are not optimal. The highly directional properties of fibre lifter as low as possible in order to minimise angularity. reinforced composite materials would apply to short-fibre metal matrix composites to an extent, especially if the material had any Pushrods significant extrusion during processing. One pushrod manufacturer The vast majority of pushrods are made from steel. NASCAR is quite admits to investigating aluminium beryllium materials in the past. specific on the types of materials it will allow for its race series, and One thing is certain in terms of materials selection, and that is the much of the rest of the market benefits from the same materials and choice of the type of material for the ends of the pushrod. Where a manufacturing techniques. single-piece component is specified, the ends are clearly going to NASCAR mandates the use of magnetic steel materials for pushrods. subject to any surface treatments required for the ends. With nitriding for a given geometry is not greatly affected by the choice of steel. So being mentioned as a common surface treatment for pushrod ends in unless another property such as strength or toughness is required, order to improve wear resistance, the body of the pushrod will benefit the pushrod designer and manufacturer need not venture into exotic from the improved corrosion resistance imparted by this process. and expensive materials. If using a steel material, the stiffnesses and Where three-piece pushrods are specified, the ends will generally be natural frequencies of the pushrod are a function of geometry alone. much harder than the body. As we have mentioned earlier, there is Where steels are required for extreme use, especially in drag racing often no advantage to using an exotic steel in the body of the pushrod, applications, the choice of materials may extend to tool steels for the and so the ends use a material that is much harder and wear resistant. main body of the pushrod. Compared to more conventional steels, Tool steels are common choices here for many applications, although these offer improved strength, toughness and impact properties. the grade of steel used is not universal. Suppliers who gave more Some race series do not limit the use of materials to steels. In such series, both aluminium and titanium pushrods are used, but more adventurous producers have looked into other types of materials. 60 be of the same material as the body, and the body will therefore be Since most steel materials have very similar elastic moduli, the stiffness detailed answers on materials selection admitted to using both shockresisting and hot-work tool steels. In terms of pushrod manufacture, the ability to react quickly to FOCUS : PUSHRODS, ROCKERS & LIFTERS Fig. 6 – Improved understanding of valvetrain dynamics has given rise to much stiffer pushrods. This is a 0.75 in (19 mm) part and is available with wall thicknesses to 0.188 in, or 4.8 mm (Courtesy of Manton Pushrods) pushrod length to be used for a number of valves, with any fine adjustment taken up by the screw and locknut. However, if the engine supplier uses steel rockers and is prepared to hold a larger inventory of pushrods, or is able to have pushrods made quickly to his exact orders is vital. As we shall see later, engine suppliers are now far requirements, he can machine a hemispherical socket directly into the more likely to use ‘fixed’ rockers, as in without adjusting screws. This body of a rocker. This strategy is not an option for those who continue requires that they are able to quickly source pushrods of the correct to use aluminium rockers. To a large extent, steels have supplanted aluminium for expensive of different lengths. This may mean resorting to measures such as applications where the design has been optimised for stiffness and inertia hard turning, especially where pushrods are made of hardened and [Figs. 7 and 8]. There are a number of suitable alloys in terms of having tempered steels. Hard turning lends itself to materials such as tool sufficient fatigue strength, but one company mentioned that it favours steels. One supplier was very proud to say that it can ship solid (one- 7000 series alloys in terms of stiffness. However, we should not assume piece) tool steel pushrods of any length within 24 hours of the order that the aluminium rocker body is static in terms of materials selection. being received. In discussing rocker materials for this article, it was pointed out that, in In many cases, the pushrod will be the most flexible single terms of elastic modulus (stiffness), all aluminium alloys are “not created component in the valvetrain. Great strides in valve control have been equal”. There are some that would offer a very significant improvement made since valvetrain test rigs became more widely available on 2000 and 7000 series alloys in terms of stiffness. Some aluminium [Fig. 5]. Such test machinery has helped point the way towards stiffer alloys, whose unconventional manufacturing methods impart some valvetrains, and improving the stiffness of pushrods has certainly been truly impressive strength and stiffness properties, may prove to be very an important part of this [Fig. 6]. successful. However, the machining and subsequent handling of parts In terms of axial stiffness, where materials are essentially fixed in made from them will prove to be crucial, as such materials often have terms of modulus – as is the case with NASCAR’s ferrous magnetic very low ductility. Any accidental ‘dings’ or hard contacts can initiate rule – the valvetrain specialist will look to increase pushrod cross- fatigue cracks. sectional area, and the trend in recent years has been towards largerdiameter pushrods in order to improve valve control. Such pushrods Where the rocker contacts the valve lash cap, we most often find a roller bearing. The roller bearing, providing that it rolls, has very low t length to suit each valve, unless they are to hold a large inventory clearly come with a significant weight penalty, but the importance of stiffness outweighs considerations of pushrod mass generally. When questioning the senior engineers at some of the NASCAR Sprint Cup engine suppliers, one of them noted that they are currently at the limit of what is possible by increasing pushrod diameter, as the bore in which it operates is the restriction to further increases in diameter and stiffness. Fig. 7 – These rockers are made from investment-cast precipitation hardening 17-4 steel. Note the coated tip roller and bronze-bushed pivot bearing (Courtesy of Stage V Engineering) Rockers Where rockers are concerned, there are two main aims: the reduction of moment of inertia around the rocker pivot, and an increase in stiffness, both of which are valuable to the valvetrain designer. With lower moment of inertia, we find reduced forces and, as is the case when using a lighter valve, a lighter spring is required, reducing forces and therefore reducing frictional losses. Stiffness helps with the control of the valve. If the valvetrain development engineer wants the valve to dance to his tune, then rocker stiffness is an important part of his method of achieving this. With pushrods we find that people are prepared to sacrifice lightness to gain stiffness, while with rockers they are prepared to sacrifice ease of use to gain stiffness and reduce inertia. In sacrificing ease of use, I’m referring to deleting the adjusting screw and locknut on the pushrod end of the rocker. These allow, within reason, one Fig. 8 – These machined steel rockers are mounted very solidly on shaft mountings in the head, held on purpose-designed rocker stands (Courtesy of Jesel) 61 FOCUS : PUSHRODS, ROCKERS & LIFTERS pushrod engine projects involved at Indianapolis. The Indy race was USAC-sanctioned, and ran to different rules from the rest of the CART races; it was therefore an Indy-only exception that was granted to pushrod engines. However, there was no stipulation that the engine had to be production-based. Sensing an advantage, a new engine was designed in secret by Ilmor which produced prodigious power, and which was to take a stunning, if controversial, victory in the 1994 Indy 500. The engine was a two-valve-per-cylinder 3.43 litre pushrod V8, designed to minimise the disadvantages of the Fig. 9 – Stud-mount (or pedestal mount) aluminium rockers mounted on a head. Not visible are the pushrod guides required to prevent the rockers from becoming misaligned (Courtesy of Harland Sharp) pushrod layout as far as valvetrain stiffness and other limitations were concerned. The camshaft was mounted as high in the vee of the engine as was practical, minimising the pushrod length. The most striking difference from any other pushrod engine is the use of a type of cam follower more normally seen in an OHC engine. A finger follower was chosen, providing a very direct coupling between the cam and the pushrod. This is a very stiff component friction as it sweeps across the top of the valve. However, because between the two surfaces contacting the cam and pushrod. It is lighter it is required to be supported on a shaft, the rocker loses stiffness in than a comparable conventional flat-faced lifter, and suffers none of this area. The rollerless rocker, which was discussed in the previous the complexity and lack of stiffness that can be associated with a roller Race Engine Technology article on pushrod valvetrains (1), is aimed lifter. Furthermore, compared to a conventional flat-faced cylindrical squarely at maximising stiffness while minimising inertia. However, lifter, it is not limited by having to increase lifter diameter to increase because there is some sliding action of the rocker tip across the lash lift velocity. While the finger follower’s lower pad, which contacts the cap, frictional forces tend to load the valve laterally. To minimise this cam, may have to increase in size in order to accommodate aggressive frictional force, the profile of the tip is not a simple radius, but aims to profiles, this never becomes limited by having to house two cylindrical replicate the rolling action of an involute. Rollerless rockers are not in lifters within a confined space. Depending on your preference for the widespread use, and although they have been developed for NASCAR relative widths of cam and finger follower, the finger pad needs to be Sprint Cup, they have still found only limited acceptance among only slightly narrower, or wider, than the width of the cam lobe. Another area of the rocker assembly that has an effect on stiffness In the engine’s single Indianapolis outing, it used its power advantage over the four-valve-per-cylinder OHC V8s to charge to is the pivot. Opinions vary as to whether a plain bearing or rolling victory in what can be argued wasn’t a great car. The same Penske element bearing is the best compromise here between friction and PC23 cars failed to qualify for the race a year later, this time without stiffness. The plain bearing option is felt to offer greater stiffness, the considerable power of the Mercedes 500I [Fig. 10, page 64], but rolling element bearings are said to offer low friction. The plain which was said to produce more than 1000 hp. Sensing that the bearing option also requires a feed of pressurised oil to each rocker Mercedes was too powerful to allow other engines to compete, USAC pivot, and this can involve significant complication. Rockers that use dropped the boost pressure for pushrod engines immediately after rolling element bearings at the pivot do not require a pressurised oil Indy, and then again later in the year. It would also later retrospectively feed and can rely on an oil mist or splash lubrication. The mounting of the rocker and the choice of pivot style are also important considerations. Shaft-mounted rockers are favoured where maximum stiffness is required, and the rocker stands to which the rocker shafts are attached are designed with stiffness in mind. Studmount rockers remain popular, although they require pushrod guide plates in order to keep the rockers in the correct orientation [Fig. 9]. Pushrod valvetrain alternatives: the Ilmor-Mercedes 500I Mercedes is not a company known for its pushrod engines in recent times, but in 1994 the Ilmor-designed Mercedes-Benz 500I engine – designed and manufactured by British race engine specialist Ilmor – took Indianapolis by storm. The rule makers had provided pushrod engines with a capacity and boost pressure advantage in an effort to keep such engines competitive when ranged against small, bespoke OHC race engines. This was ostensibly to keep the production-based 62 Fig. 10 – The ultimate pushrod engine for circuit racing? The Mercedes-Benz 500I had an unusual pushrod valvetrain, and over 1000 hp, which it used to win the Indy 500 in 1994 before being banned (Courtesy of Daimler) t engine suppliers. FOCUS : PUSHRODS, ROCKERS & LIFTERS SOME EXAMPLES OF PUSHROD, ROCKER & LIFTER (TAPPET) SUPPLIERS AUSTRALIA Yella Terra Australia +61 39 555 5522 Jesel +1 732 901 1800 www.jesel.com Johnson Lifters +1 734 955 6500 www.johnsonlifters.com Koerner Racing Engines +1 520 294 5758 www.koernerracing.com LSM System Engineering +1 248 674 4967 www.lsmeng.com Manley +1 732 905 3366 www.manleyperformance.com Manton +1 951 245 6565 www.mantonpushrods.com Morel Lifters/John Callies +1 216 671 5400 www.johncalliesinc.com Performance Forged Products +1 323 722 3460 Procomp Electronics +1 909 605 1123 www.procompelectronics.com PRW Industries +1 714 792 1000 www.prw-usa.com Scorpion Performance +1 954 779 3600 www.scorpionperformance.com Smith Brothers +1 800 367 1533 www.pushrods.net Stage V +1 909 594 8383 www.stagev.com T&D +1 775 884 2292 www.tdmach.com Titan Speed Engineering +1 800 308 4826 www.titanspeed.com Topline Hylift Johnnson +1 800 441 1400 www.toplineauto.com Trend Performance +1 586 447 0400 www.trendperform.com Trick Flow Specialities +1 330 630 1555 www.trickflow.com Yella Terra USA +1 601 485 3355 www.yellaterra.com Wenteq +1 209 608 2374 www.wenteqmachine.com WW Rockers +1 706 216 4340 www.wwrockers.com www.yellaterra.com.au UK Arrow Precision Engineering +44 1455 234200 www.arrowprecision.com USA Alan Johnson Performance Engineering +1 805 922 1202 www.alanjohnsonperformance.com Bullet Racing Cams +1 662 893 5670 www.bulletcams.com CAM FX +1 818 961 0318 www.roller-lifters.com CHE Precision +1 805 499 8885 www.cheprecision.com Comp Cams +1 901 795 2400 www.compcams.com Crane Cams +1 866 388 5120 www.cranecams.com Crower +1 619 661 6477 www.crower.com Elgin Industries +1 800 323 6764 www.elginind.com Engine Works +1 423 391 0032 www.engine-worksperformance.com Ferrea +1 954 733 2505 www.ferrea.com Harland Sharp +1 440 238 3260 www.harlandsharp.com ban purpose-designed pushrod race engines from competing. If it hadn’t taken such measures, it was inevitable that the quad-cam OHC engines would need to be granted a substantial performance boost, or engine manufacturers would have had to design engines to compete with the 500I at Indy. Summary The pushrod valvetrain presents a number of difficulties to the valvetrain development engineer when compared to an OHC system. simulation model of a Winston Cup valvetrain to study valve bounce”, disadvantages offers an interesting engineering challenge. Almost 20 Proc. IMechE, Part K: Journal of Multi-body Dynamics, 2002 years ago, Ilmor showed what can be done within an open set of rules. 5. Rothbart, H.A., “Cams: Design, Dynamics, and Accuracy”, Most other competition is more strictly governed, but there are still Wiley, 1956 significant opportunities for improvement, as shown by the relatively 6. Chen, F.Y., “Mechanics and Design of Cam Mechanisms”, recent trends towards stiffer components throughout the valvetrain. Pergamon, 1982, ISBN 0-0802-8049-8 References Credits 1. Ward, W., ‘Focus’ article on pushrod valvetrains, Race Engine The author wishes to thank the following for their assistance: Jochen Storm and Wolfgang Schattling of Daimler; Dave Grob, Dennis Ventrello and Steve Kutch of Jesel; Billy Godbold, Chris Douglas and Dan Hodgdon of Comp Cams; Andy Anderson and Bob Fox of Trend Peformance; Eric Hansen of Stage V Engineering; Steve Becker of Harland Sharp, Pierre Chango of Smith Brothers Pushrods, Jason Diroff of Johnson Lifters and Robin Manton of Manton Pushrods. Technology magazine, issue 45, 2010 2. Wagstaff, P.R., “Analysis of Valve Gear Dynamics with a Digital Computer”, Proc. IMechE, 1967-68, vol 182, Part 3L 3. Blair, G.P., McCartan, C.D., and Herman, H., “Pushrod Operation”, Race Engine Technology magazine, issue 12, 2006 4. McLaughlin, S., and Haque, I., “Development of a multi-body 64 n While it can appear arcane to an engineer, overcoming its inherent P E T M -U E N FR L A O G R CA R .C SI U N I TTE TOR O H E I TO EC SL ON T EW - M N ET E - .R W W W 4 WAYS TO BUY: 1) ONLINE AT WWW.HIGHPOWERMEDIA.COM 2) CALL US ON +44 (0)1934 713 957 DOWNLOAD A SUBS FORM FROM WWW.HIGHPOWERMEDIA.COM AND RETURN BY: 3) FAX TO +44 (0)208 497 2102 4) POST TO ADDRESS BELOW ISSUE 061 ISSU E 060 race engine TECHNOLOGY 062 OLOGY MARCH/APRIL 2012 race engin race engin e TECHN ISSUE OLOGY FEBR UARY e TECHN S: KNOWLE TREVORing IndyCar’s os Oversee eration V6 turb new-gen Semi Hemi Dossier • Head t • PRI and IMIS Report • Mach ine Tools Focus PE e15 y’s 1005 , EURO UK £12.50 • Sonn USA $25, 01_061COVER.indd era www.highpowermed ia.com gine heads MAN U FACTU SOLU RING State of TIONS the machine Simon acing Moto3 • MoroR Knowles • Gilles • Trevor USA $20, UK £10, EUROPE ia.com wermed turbo I N WO R LD STRU CT ENG IN U RAL EE Focus on race RING bl en ocks an d Show e Digest V8 Engin MARCH/APRI L 2012 hpo www.hig : F1’s new RT RA s V6 Insigh Pro Mod • ECUs Focus • R2B2 Powertr MAY 2012 SIM ON ing for Toyota ods Focus EFI • Pushr KERS • ASI Show Report NASCAR G KEEPIN S TH ING G IN N us R U T ings foc ain bear GILLES Prepar PO WE i Hemi enon Cosworth Focus • ng’s Le DeltaWi ge challen phenom • Lotus Bearings EAT A TH R DAY’S TO TO ES ns ENG IN Ma SPEED OF SOU ND Dmph IRT D IGG E REI NVENTI NG THE HEART TO PRO M R Focus on piston techn OD ology CHAL Goodwi LENG ER n’s Se m and Block s Focus still Formula Student • Zytek’s Mans • Focus • All-electric ing at Le R17 • DeltaW s Could thi F1 BEYOND THE Goodwin Connection • Pistons Aston Martin G DI TU RBO NS I6the future? 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