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VTEC (Variable Valve Timing & Lift Electronic Control) is a system developed by
Honda is a Japanese public multinational conglomerate manufacturer of automobiles, motorcycles, and power equipment, headquartered in Minato, Tokyo, Japan. Honda has been the world's largest motorcycle manufacturer since 1959, reaching a product ...
to improve the volumetric efficiency of a
four-stroke A four-stroke (also four-cycle) engine is an internal combustion (IC) engine in which the piston completes four separate strokes while turning the crankshaft. A stroke refers to the full travel of the piston along the cylinder, in either directio ...
internal combustion engine An internal combustion engine (ICE or IC engine) is a heat engine in which the combustion of a fuel occurs with an oxidizer (usually air) in a combustion chamber that is an integral part of the working fluid flow circuit. In an internal combus ...
, resulting in higher performance at high RPM, and lower fuel consumption at low RPM. The VTEC system uses two (or occasionally
three 3 is a number, numeral, and glyph. 3, three, or III may also refer to: * AD 3, the third year of the AD era * 3 BC, the third year before the AD era * March, the third month Books * '' Three of Them'' (Russian: ', literally, "three"), a 1901 ...
)
camshaft A camshaft is a shaft that contains a row of pointed cams, in order to convert rotational motion to reciprocating motion. Camshafts are used in piston engines (to operate the intake and exhaust valves), mechanically controlled ignition systems ...
profiles and hydraulically selects between profiles. It was invented by Honda engineer Ikuo Kajitani. It is distinctly different from standard VVT (
variable valve timing In internal combustion engines, variable valve timing (VVT) is the process of altering the timing of a valve lift event, and is often used to improve performance, fuel economy or emissions. It is increasingly being used in combination with varia ...
) systems which change only the valve timings and do not change the camshaft profile or valve lift in any way.


Context and description

Japan Japan ( ja, 日本, or , and formally , ''Nihonkoku'') is an island country in East Asia. It is situated in the northwest Pacific Ocean, and is bordered on the west by the Sea of Japan, while extending from the Sea of Okhotsk in the north ...
levies a tax based on engine displacement, and Japanese auto manufacturers have correspondingly focused their
research and development Research and development (R&D or R+D), known in Europe as research and technological development (RTD), is the set of innovative activities undertaken by corporations or governments in developing new services or products, and improving existi ...
efforts toward improving the performance of their smaller engine designs. One method for increasing performance into a static displacement includes
forced induction In an internal combustion engine, forced induction is where turbocharging or supercharging is used to increase the density of the intake air. Engines without forced induction are classified as naturally aspirated. Operating principle Overvi ...
, as with models such as the
Toyota Supra is a sports car and grand tourer manufactured by the Toyota Motor Corporation beginning in 1978. The name "supra" is derived from the Latin prefix, meaning "above", "to surpass" or "go beyond". The initial four generations of the Supra were pr ...
and
Nissan 300ZX The Nissan 300ZX is a sports car that was produced across two different generations. As with all other versions of the Z, the 300ZX was sold within the Japanese domestic market under the name Fairlady Z. It was sold in Japan from 1983 to 2000 a ...
which used
turbocharger In an internal combustion engine, a turbocharger (often called a turbo) is a forced induction device that is powered by the flow of exhaust gases. It uses this energy to compress the intake gas, forcing more air into the engine in order to pro ...
applications and the
Toyota MR2 The Toyota MR2 is a line of two-seat, mid-engined, rear-wheel-drive sports cars manufactured in Japan and marketed globally by Toyota from 1984 until 2007 over three generations: W10 (1984–1989), W20 (1989–1999) and W30 (2000–2007). It ...
which used a
supercharger In an internal combustion engine, a supercharger compresses the intake gas, forcing more air into the engine in order to produce more power for a given displacement. The current categorisation is that a supercharger is a form of forced induct ...
for some model years. Another approach is the
rotary engine The rotary engine is an early type of internal combustion engine, usually designed with an odd number of cylinders per row in a radial configuration. The engine's crankshaft remained stationary in operation, while the entire crankcase and i ...
used in the
Mazda RX-7 The Mazda RX-7 is a front-engine, rear-wheel-drive, rotary engine-powered sports car that was manufactured and marketed by Mazda from 1978 until 2002 across three generations, all of which made use of a compact, lightweight Wankel rotary engine. ...
and RX-8. A third option is to change the cam timing profile, of which Honda VTEC was the first successful commercial design for altering the profile in real-time. The VTEC system provides the engine with valve timing optimized for both low and high RPM operations. In basic form, the single
cam lobe Calmodulin (CaM) (an abbreviation for calcium-modulated protein) is a multifunctional intermediate calcium-binding messenger protein expressed in all eukaryotic cells. It is an intracellular target of the secondary messenger Ca2+, and the bind ...
and follower/rocker arm of a conventional engine is replaced with a locking multi-part rocker arm and two cam profiles: one optimized for low-RPM stability and fuel efficiency, and the other designed to maximize high-RPM power output. The switching operation between the two cam lobes is controlled by the ECU which takes account of engine oil pressure, engine temperature, vehicle speed, engine speed and throttle position. Using these inputs, the ECU is programmed to switch from the low lift to the high lift cam lobes when certain conditions are met. At the switch point a solenoid is actuated that allows oil pressure from a spool valve to operate a locking pin which binds the high RPM
rocker arm In the context of an internal combustion engine, a rocker arm is a valvetrain component that typically transfers the motion of a pushrod to the corresponding intake/exhaust valve. Rocker arms in automobiles are typically made from stamped steel ...
to the low RPM ones. From this point on, the valves open and close according to the high-lift profile, which opens the valve further and for a longer time. The switch-over point is variable, between a minimum and maximum point, and is determined by engine load. The switch-down back from high to low RPM cams is set to occur at a lower engine speed than the switch-up (representing a
hysteretic Hysteresis is the dependence of the state of a system on its history. For example, a magnet may have more than one possible magnetic moment in a given magnetic field, depending on how the field changed in the past. Plots of a single component of ...
cycle) to avoid a situation in which the engine is asked to operate continuously at or around the switch-over point. The older approach to timing adjustments is to produce a camshaft with a
valve timing In a piston engine, the valve timing is the precise timing of the opening and closing of the valves. In an internal combustion engine those are usually poppet valves and in a steam engine they are usually slide valves or piston valves. Internal ...
profile that is better suited to low-RPM operation. The improvements in low-RPM performance, which is where most street-driven automobiles operate a majority of the time, occur in trade for a power and efficiency loss at higher RPM ranges. Correspondingly, VTEC attempts to combine low-RPM fuel efficiency and stability with high-RPM performance.


History

VTEC, the original Honda variable valve control system, originated from REV (Revolution-Modulated Valve Control) introduced on the CBR400 in 1983 known as HYPER VTEC. In the regular four-stroke automobile engine, the intake and exhaust valves are actuated by lobes on a camshaft. The shape of the lobes determines the timing, lift and duration of each valve. Timing refers to an angle measurement of when a valve is opened or closed with respect to the piston position (BTDC or ATDC). Lift refers to how much the valve is opened. Duration refers to how long the valve is kept open. Due to the behavior of the working fluid (air and fuel mixture) before and after combustion, which have physical limitations on their flow, as well as their interaction with the ignition spark, the optimal valve timing, lift and duration settings under low RPM engine operations are very different from those under high RPM. Optimal low RPM valve timing lift and duration settings would result in insufficient filling of the cylinder with fuel and air at high RPM, thus greatly limiting engine power output. Conversely, optimal high RPM valve timing lift and duration settings would result in very rough low RPM operation and difficult idling. The ideal engine would have fully variable valve timing, lift and duration, in which the valves would always open at exactly the right point, lift high enough and stay open just the right amount of time for the engine speed and load in use.


DOHC VTEC

VTEC was introduced as a
DOHC An overhead camshaft (OHC) engine is a piston engine where the camshaft is located in the cylinder head above the combustion chamber. This contrasts with earlier overhead valve engines (OHV), where the camshaft is located below the combustion c ...
(dual overhead camshaft) system in Japan in the 1989 Honda Integra XSi, which used the B16A engine. The same year, Europe saw the arrival of VTEC in the Honda Civic and
Honda CRX The Honda CR-X (styled in some markets as Honda CRX), originally launched as the Honda Ballade Sports CR-X in Japan, is a front-wheel-drive sport compact car manufactured by Honda from 1983 until 1991. The first generation CRX was marketed in so ...
1.6i-VT, using a B16A1 variant. The
United States The United States of America (U.S.A. or USA), commonly known as the United States (U.S. or US) or America, is a country primarily located in North America. It consists of 50 states, a federal district, five major unincorporated territorie ...
market saw its first VTEC system with the introduction of the 1991
Acura NSX NSX may refer to: Stock exchanges * Namibian Stock Exchange (NSX) * National Stock Exchange (Jersey City, New Jersey), US (NSX) * National Stock Exchange of Australia (NSX) Other uses * Neon Swing X-perience (NSX), a US musical group * Honda N ...
, which used a 3-litre DOHC C30A V6 with . DOHC VTEC engines soon appeared in other vehicles, such as the 1992
Acura Integra GS-R The , marketed in North America as the Acura Integra, is an automobile produced by the Japanese automobile manufacturer Honda from 1985 until 2006, and then since 2021. It succeeded the Honda Quint, Quint as a more luxurious and sport-oriented ...
( B17A1), and later in the 1993
Honda Prelude The Honda Prelude is a car produced by Japanese car manufacturer Honda from 1978 until 2001. The two-door coupe was loosely derived from the Honda Accord, and spanned five generations. The Prelude was used by Honda to introduce the Japanese Honda r ...
VTEC ( H22A) and
Honda Del Sol The Honda CR-X del Sol (marketed in other markets as the Honda Civic del Sol, Honda del Sol and the Honda CRX) is a two-seater targa top car manufactured by Honda from 1992 until 1998. Despite the body resemblance to a mid-engine car design, the ...
VTEC ( B16A3). The Integra Type R (1995–2000) available in the Japanese market produces using a B18C 1.8-litre engine, producing more horsepower per litre than most super-cars at the time. Honda has also continued to develop other varieties and today offers several varieties of VTEC, such as i-VTEC and i-VTEC Hybrid.


SOHC VTEC

Honda also applied the system to
SOHC An overhead camshaft (OHC) engine is a piston engine where the camshaft is located in the cylinder head above the combustion chamber. This contrasts with earlier overhead valve engines (OHV), where the camshaft is located below the combustion cha ...
(single overhead camshaft) engines such as the D-Series and J-Series Engines, which share a common camshaft for both intake and exhaust valves. The trade-off was that Honda's SOHC engines benefited from the VTEC mechanism only on the intake valves. This is because VTEC requires a third center
rocker arm In the context of an internal combustion engine, a rocker arm is a valvetrain component that typically transfers the motion of a pushrod to the corresponding intake/exhaust valve. Rocker arms in automobiles are typically made from stamped steel ...
and
cam lobe Calmodulin (CaM) (an abbreviation for calcium-modulated protein) is a multifunctional intermediate calcium-binding messenger protein expressed in all eukaryotic cells. It is an intracellular target of the secondary messenger Ca2+, and the bind ...
(for each intake and exhaust side), and, in the SOHC engine, the spark plugs are situated between the two exhaust rocker arms, leaving no room for the VTEC rocker arm. Additionally, the center lobe on the camshaft cannot be utilized by both the intake and the exhaust, limiting the VTEC feature to one side. However, beginning with the J37A2 3.7L SOHC V6 engine introduced on all 2009-2012 Acura RL SH-AWD models, SOHC VTEC was incorporated for use with intake and exhaust valves, using a total of six cam lobes and six rocker arms per cylinder. The intake and exhaust rocker shafts contain primary and secondary intake and exhaust rocker arms, respectively. The primary rocker arm contains the VTEC switching piston, while the secondary rocker arm contains the return spring. The term "primary" does not refer to which rocker arm forces the valve down during low-RPM engine operation. Rather, it refers to the rocker arm which contains the VTEC switching piston and receives oil from the rocker shaft. The primary exhaust rocker arm contacts a low-profile camshaft lobe during low-RPM engine operation. Once VTEC engagement occurs, the oil pressure flowing from the exhaust rocker shaft into the primary exhaust rocker arm forces the VTEC switching piston into the secondary exhaust rocker arm, thereby locking both exhaust rocker arms together. The high-profile camshaft lobe which normally contacts the secondary exhaust rocker arm alone during low-RPM engine operation is able to move both exhaust rocker arms together which are locked as a unit. The same occurs for the intake rocker shaft, except that the high-profile camshaft lobe operates the primary rocker arm. The J37A2 is able to use both intake and exhaust VTEC by use of a novel design of the intake rocker arm. Each exhaust valve on the J37A2 corresponds to one primary and one secondary exhaust rocker arm. Therefore, there are a total of twelve primary exhaust rocker arms and twelve secondary exhaust rocker arms. However, each secondary intake rocker arm is shaped similar to a "Y" which allows it to contact two intake valves at once. One primary intake rocker arm corresponds to each secondary intake rocker arm. As a result of this design, there are only six primary intake rocker arms and six secondary intake rocker arms.


VTEC-E

The earliest VTEC-E implementation is a variation of SOHC VTEC which is used to increase combustion efficiency at low RPM while maintaining the mid range performance of non-vtec engines. VTEC-E is the first version of VTEC to employ the use of roller rocker arms and because of that, it forgoes the need for having 3 intake lobes for actuating the two valves—two lobes for non-VTEC operation (one small and one medium-sized lobe) and one lobe for VTEC operation (the biggest lobe). Instead, there are two different intake cam profiles per cylinder: a very mild cam lobe with little lift and a normal cam lobe with moderate lift. Because of this, at low RPM, when VTEC is not engaged, one of the two intake valves is allowed to open only a very small amount due to the mild cam lobe, forcing most of the intake charge through the other open intake valve with the normal cam lobe. This induces swirl of the intake charge which improves air/fuel atomization in the cylinder and allows for a leaner fuel mixture to be used. As the engine's speed and load increase, both valves are needed to supply a sufficient mixture. When engaging VTEC mode, a pre-defined threshold for MPH (must be moving), RPM and load must be met before the computer actuates a solenoid which directs pressurized oil into a sliding pin, just like with the original VTEC. This sliding pin connects the intake rocker arm followers together so that, now, both intake valves are following the "normal" camshaft lobe instead of just one of them. When in VTEC, since the "normal" cam lobe has the same timing and lift as the intake cam lobes of the SOHC non-VTEC engines, both engines have identical performance in the upper powerband assuming everything else is the same. This variant of the VTEC-E is used in some D-series engines. With the later VTEC-E implementations, the only difference it has with the earlier VTEC-E is that the second normal cam profile has been replaced with a more aggressive cam profile which is identical to the original VTEC high-speed cam profile. This in essence supersedes VTEC and the earlier VTEC-E implementations since the fuel and low RPM torque benefits of the earlier VTEC-E are combined with the high performance of the original VTEC. There are 3 intake cam lobes: 2 for the low-RPM mode (1 for almost closed valve, 1 for normally opened) and 1 for the powerful mode when the VTEC solenoid is activated. The lowest RPM for activating the VTEC is 2500, or it may be higher if the load is weak - ECM dependant. With the VTEC solenoid is on the 3-rd biggest lobe begins to push all the intake valves with the more aggressively profile. This variant of the VTEC-E is used in the F23A, F22B and JDM F20B SOHC VTEC engines.


3-Stage VTEC

3-Stage VTEC is a version that employs three different cam profiles to control intake valve timing and lift. Due to this version of VTEC being designed around a SOHC valve head, space was limited; so VTEC can modify only the opening and closing of the intake valves. The low-end fuel economy improvements of VTEC-E and the performance of conventional VTEC are combined in this application. From idle to 2500-3000 RPM, depending on load conditions, one intake valve fully opens while the other opens just slightly, enough to prevent pooling of fuel behind the valve, also called 12-valve mode. This 12 Valve mode results in swirl of the intake charge which increases combustion efficiency, resulting in improved low end torque and better fuel economy. At 3000-5400 RPM, depending on load, one of the VTEC solenoids engages, which causes the second valve to lock onto the first valve's camshaft lobe. Also called 16-valve mode, this method resembles a normal engine operating mode and improves the mid-range power curve. At 5500-7000 RPM, the second VTEC solenoid engages (both solenoids now engaged) so that both intake valves are using a middle, third camshaft lobe. The third lobe is tuned for high-performance and provides peak power at the top end of the RPM range. In newer version of 3-Stage i-VTEC combined VTC and PGM-FI to allow ECU to control full range of mode to archive greater fuel economy improvements and performance. Honda CR-Z able to switch between low-end mode and standard mode from 1000 rpm to 2250 rpm uninterrupted and engage to high cam mode from 2250 rpm upward on SOHC.


i-VTEC

Honda i-VTEC (intelligent-VTEC) is a system that combines VTEC with Honda's VTC (Variable Timing Control), a continuously variable camshaft phasing system used on the exhaust camshaft of DOHC VTEC engines. The technology first appeared on Honda's K-series four-cylinder engine family in 2001. Most Honda or Acura four-cylinder powered vehicles sold in the United States used i-VTEC by the 2002 model year with the exception being the 2002 Honda Accord. VTEC controls of valve lift and valve duration are still limited to distinct low- and high-RPM profiles, but the exhaust camshaft is now capable of advancing between 25 and 50 degrees, depending upon engine configuration. Phasing is implemented by a computer-controlled, oil-driven adjustable cam sprocket. Both engine load and RPM affect VTEC. The exhaust phase varies from fully retarded at idle to somewhat advanced at full throttle and low RPM. The effect is further optimization of torque output, especially at low and midrange RPM. There are two types of i-VTEC K series engines which are explained in the next section. Honda's J-Series SOHC engines use an entirely different system also, confusingly, marketed as i-VTEC. Honda J-Series Engines using i-VTEC combine SOHC VTEC operation with Honda VCM (Variable Cylinder Management) variable displacement technology to improve fuel economy under light loads.


K-Series

The K-Series engines have two different types of i-VTEC system implementations. The first type is for performance engines like the K20A2 or K20Z3 used in the 2002-2006 RSX Type S or the 2006-2011 Civic Si and the second type is for economy engines like the K20A3 or K24A4 used in the 2002-2005 Civic Si or 2003-2007 Accord. The performance i-VTEC system is basically the same as the DOHC VTEC system of the B16A's. Both intake and exhaust cams have three cam lobes per cylinder. However, the valvetrain has the added benefit of roller rockers and VTC continuously variable intake cam timing. Performance i-VTEC is a combination of conventional DOHC VTEC with VTC (which operates for intake valves only). The VTC is available in the economy and performance i-VTEC engines. The economy i-VTEC used in K20A3/K24A4 engines is more like the SOHC VTEC-E in that the intake cam has only two lobes, one very small and one larger, as well as no VTEC on the exhaust cam. At low RPM only one valve on the intake opens fully, promoting combustion chamber swirl and improved fuel atomization. This allows a leaner air/fuel mixture to be used, improving fuel economy. At higher RPM, both intake valves run off the larger intake cam lobe, improving total air flow and top-end power. The two types of engines are easily distinguishable by the factory rated power output: the performance engines make around or more in stock form, while the economy engines do not make much more than .


R-Series

The i-VTEC system in the R-Series engine uses a modified SOHC VTEC system consisting of one small and two large lobes. The large lobes operate the intake valves directly while the small lobe is engaged during VTEC. Unlike typical VTEC systems, the system in the R-Series engine operates in a 'reverse' fashion engaging only at low to mid RPMs. At low RPMs, the small lobe locks onto one of the larger lobes and keeps one of the intake valves partially open during the compression cycle, similar to the
Atkinson Cycle The Atkinson-cycle engine is a type of internal combustion engine invented by James Atkinson in 1882. The Atkinson cycle is designed to provide efficiency at the expense of power density. A variation of this approach is used in some modern auto ...
. The ability for Honda to switch between Atkinson cycle and normal cycle allows excellent fuel efficiency without sacrificing too much performance.


i-VTEC with Variable Cylinder Management (VCM)

In 2003, Honda introduced an i-VTEC V6 (an update of the J-series) that includes Honda's cylinder deactivation technology which closes the valves on one bank of (3) cylinders during light load and low speed (below ) operation. According to Honda,
VCM technology works on the principle that a vehicle only requires a fraction of its power output at cruising speeds. The system electronically deactivates cylinders to reduce fuel consumption. The engine is able to run on 3, 4, or all 6 cylinders based on the power requirement, essentially getting the best of both worlds. V6 power when accelerating or climbing, as well as the efficiency of a smaller engine when cruising.
The technology was originally introduced to the US on the 2005
Honda Odyssey Honda Odyssey can refer to three motor vehicles manufactured by Honda: * Honda Odyssey (ATV), an all-terrain vehicle (1977—1989) * Honda Odyssey (minivan), a brand of two different Honda minivan models for different markets ** Honda Odyssey (inte ...
minivan, and can now be found on the Honda Accord Hybrid, the 2006 Honda Pilot, and the 2008 Honda Accord. Example: EPA estimates for the 2011 (271 hp SOHC 3.5L) V6 Accord are 24 mpg combined vs. 27 in the two 4-cylinder-equipped models. i-VTEC VCM was also used in the 1.3-liter LDA engine used in the 2001-2005
Honda Civic Hybrid The is a series of automobiles manufactured by Honda since 1972. Since 2000, the Civic has been categorized as a compact car, while previously it occupied the subcompact class. , the Civic is positioned between the Honda Fit/City and Honda Acc ...
.


i-VTEC i

A version of i-VTEC with direct injection, first used in 2004
Honda Stream The Honda Stream is a car manufactured by the Japanese automaker Honda since October 2000. The second generation model was officially presented on 13 July 2006. It has been described as a multi-purpose vehicle (MPV) or as an estate car. __TOC__ ...
. Direct injection 2.0L DOHC i-VTEC I gasoline engine. * The 2-litre DOHC i-VTEC I integrates the i-VTEC system which uses the VTEC and VTC which uses a direct injection system for an air-fuel ratio of up to 65:1 for an unprecedented level of ultra-lean combustion. Stable combustion is achieved by using less fuel than conventional direct injection engines which have an air-fuel ratio of 40:1. * Combustion control through the use of high-precision EGR valves and a newly developed high-performance catalyst enable the 2.0 litre DOHC i-VTEC I lean-burn direct injection engine which qualify as an Ultra Low Emissions Vehicle.


AVTEC

The AVTEC (
Advanced VTEC VTEC (Variable Valve Timing & Lift Electronic Control) is a system developed by Honda to improve the volumetric efficiency of a four-stroke internal combustion engine, resulting in higher performance at high RPM, and lower fuel consumption at lo ...
) engine was first announced in 2006. It combines continuously variable valve lift and timing control with continuously variable phase control. Honda originally planned to produce vehicles with AVTEC engines within next 3 years. Although it was speculated that it would first be used in 2008 Honda Accord, the vehicle instead utilizes the existing i-VTEC system. As of late 2017, no Honda vehicles use the AVTEC system.


Differences from other VTECs

Honda's advanced VTEC technology departs greatly from its previous incarnations by no longer relying on switching between two sets of lobes on a given
camshaft A camshaft is a shaft that contains a row of pointed cams, in order to convert rotational motion to reciprocating motion. Camshafts are used in piston engines (to operate the intake and exhaust valves), mechanically controlled ignition systems ...
. It instead uses a single
cam lobe Calmodulin (CaM) (an abbreviation for calcium-modulated protein) is a multifunctional intermediate calcium-binding messenger protein expressed in all eukaryotic cells. It is an intracellular target of the secondary messenger Ca2+, and the bind ...
per valve, and two rocker arms per valve whereby the second rocker arm has a movable pivot point, thereby providing the varying cam lift. Advanced VTEC motors still use the now standard oil pressure controlled variable cam gear angle mechanism. With these two technologies combined Honda has developed an infinitely variable valve timing and lift system ("VVTL"). Previous versions of VTEC included only staged VVTL i.e. High-Low. With the introduction of i-VTEC the systems gained infinitely variable valve timing but still only staged lift i.e. High-Low. The "infinitely variable" portion of the A-VTEC is what makes it stand out as a serious evolutionary step in the world of VTEC.


Patent

A related U.S. patent (6,968,819) was filed on January 5, 2005. Advanced VTEC has a standard camshaft and rocker arms, attached as they normally are with camshaft overhead, and rocker arms pushing down on the
poppet valve A poppet valve (also called mushroom valve) is a valve typically used to control the timing and quantity of gas or vapor flow into an engine. It consists of a hole or open-ended chamber, usually round or oval in cross-section, and a plug, usual ...
s. The camshaft is surrounded by a partially open drum which has secondary rocker arms attached to it via a pivoting point. These secondary rocker arms, which have a varying depth profile (similar to cams), are directly actuated by the camshaft, in a scissor-like manner. The primary rocker arms are actuated by the secondary (drum attached) rocker arms. The drum will only rotate to advance or retard the position of the secondary rocker arms, to take advantage of their varying profiles. Thus, through varying the position of the drum about its axis, each cam profile is changed to an optimal height for maximum engine performance without sacrificing fuel efficiency at lower speeds.


VTEC TURBO

The VTEC TURBO engine series were introduced in 2013 as part of the Earth Dreams Technology range and include new features such as gasoline direct injection, turbochargers, Dual Cam VTC and VTEC on the exhaust profile instead of the intake, marking the end of the 'traditional sound' of VTEC in this engine. VTEC implementation on the exhaust rocker arms causes the turbo to be spooled quicker, eliminating turbo lag. VTEC Turbo engines come in three displacement capacities: a 1.0 liter 3-cylinder, a 1.5 liter 4-cylinder, and a 2.0 liter 4-cylinder. Initial implementation for European vehicles included 2-litre 4-cylinder turbocharged engine used from 2015 Honda Civic Type R until present, which included
Euro 6 The European emission standards are vehicle emission standards for pollution from the use of new land surface vehicles sold in the European Union and EEA member states and the UK, and ships in EU waters. The standards are defined in a seri ...
emissions compliance.


VTEC in motorcycles

Apart from the Japanese market-only
Honda CB400SF The Honda CB400 Super Four is a CB series standard motorcycle produced by Honda at the Kumamoto plant from 1992 to the present. The CB400 embodies the typical Universal Japanese Motorcycle produced through the 1970s, updated with modern techn ...
Super Four HYPER VTEC, introduced in 1999, the first worldwide implementation of VTEC technology in a
motorcycle A motorcycle (motorbike, bike, or trike (if three-wheeled)) is a two or three-wheeled motor vehicle steered by a handlebar. Motorcycle design varies greatly to suit a range of different purposes: long-distance travel, commuting, cruising ...
occurred with the introduction of Honda's
VFR800 The Honda VFR800 (Interceptor) is a sport touring motorcycle made by Honda since 1998. The model was the successor to the VFR750F and shares the V4 engine configuration with the Honda VF and VFR series. Fifth Generation: 1998–2001 VFR800Fi (R ...
sportbike in 2002. Similar to the SOHC VTEC-E style, one intake valve remains closed until a threshold of 6800 (6600 after 2006) RPM is reached, then the second valve is opened by an oil-pressure actuated pin. The dwell of the valves remains unchanged, as in the automobile VTEC-E, and little extra power is produced, but with a smoothing-out of the torque curve. Critics maintain that VTEC adds little to the VFR experience, while increasing the engine's complexity. Honda seemed to agree, as their VFR1200, a model announced in October 2009, came to replace the VFR800, which abandons the VTEC concept in favor of a large capacity narrow-vee "unicam", i.e., SOHC, engine. However, the 2014 VFR800 reintroduced the VTEC system from the 2002-2009 VFR motorcycle. Honda incorporated the technology into the NC700 series, including the NC700D Integra, released in 2012, using a single camshaft to provide two timing routines for the intake valves.


References

;General * * *


External links

* Honda tech pages
VTECi-VTEC DOHC



World Honda: New i-VTEC Technology
{{DEFAULTSORT:Vtec Variable valve timing Honda Motorcycle engines 1989 introductions