MultiAir

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Fiat 875 cc two cylinder TwinAir engine featuring Multiair technology TwinAir.jpg
Fiat 875 cc two cylinder TwinAir engine featuring Multiair technology

MultiAir or Multiair is a hydraulically-actuated variable valve timing (VVT) and variable valve lift (VVL) engine technology enabling "cylinder by cylinder, stroke by stroke" [1] control of intake air directly via a gasoline engine's inlet valves. Developed by Fiat Powertrain Technologies, the technology addresses a primary engine inefficiency: pumping losses caused by restricting intake passage by the throttle plate that regulates air feeding the cylinders. [2]

Contents

Fiat S.p.A., now known as Stellantis, launched MultiAir in 2009, employing a proprietary electro-hydraulic system to precisely control air intake without a throttle valve [3] to increase engine power and torque, reduce fuel consumption, reduce emissions, and improve engine operation, offering "a more controllable flow of air during the combustion cycle in comparison with mechanical VVT systems." [4] The technology allows engines to be lighter and smaller while reducing pump losses. It can be adapted to existing engines by replacing the camshaft with the MultiAir system, thus requiring a new head only.

MultiAir was licensed to the Schaeffler Group in 2011, which also markets the system as Uniair. [5] Schaeffler began supplying Uniair systems in 2017 to Jaguar Land Rover, branded as Ingenium technology. [6]

Compatible with both naturally aspirated and forced-induction engines, MultiAir technology was patented by Fiat in 2002 and was launched at the 2009 Geneva Motor Show in the Alfa Romeo MiTo. [7] 1.4 L MultiAir engines for global markets are manufactured in Termoli, Italy at the Fiat Powertrain Technologies factory and the FCA's Dundee Engine Plant (formerly of Global Engine Alliance's GEMA manufacturing branch), with critical systems manufactured and assembled by Schaeffler Group. [5]

In 2010, the 1.4 L MultiAir engine won the International Engine of the Year [8] as well as Popular Science's Best of What's New. [1] In the same year, the Fiat SGE engine (0.9 L turbocharged and 1.0 L naturally aspirated TwinAir units), also using MultiAir technology, was launched in the Fiat 500. It is produced in Bielsko-Biała, Poland. It was named Best New Engine in 2011. [9]

Both FIRE and SGE units are equipped with MultiAir and use indirect fuel injection.

The GME (Hurricane) and GSE (FireFly) MultiAir II engines, which use direct fuel injection, were first made available in 2016.

Technology

How it works
"The MultiAir system is elegantly simple. An electrohydraulic actuator, a high-response, electronically activated solenoid—controls the pressure applied to hydraulic fluid (engine oil drawn from the sump) that fills a thin passageway that connects the intake valves and the camshaft. The solenoid valve regulates the amount of oil pumped by the cam action to either the valve or a bypass reservoir.

When pressurized, the hydraulic line behaves like a solid body and transmits the lift schedule imparted by the intake cam directly to the intake valve. When the solenoid is disengaged, a spring takes over valve actuation duties.

This electrohydraulic link allows independent operation of the two components, which enables near real-time control over the valve lift profiles, said Bernard. Whereas a closed solenoid normally transmits the pressure generated by the camshaft’s intake profile to the valve, an open solenoid breaks the hydraulic link between cam and valve, decoupling their operations." [10]
Society of Automotive Engineering, 2010

For variable valve timing, competing technologies (e.g., Honda's VTEC and BMW's VANOS) use electromechanical concepts, achieving valve lift variation via dedicated mechanisms; it can also be combined with camshaft phasers to allow control of both valve lift and phase. In contrast, MultiAir uses managed hydraulic fluid to provide variable valve control.

Control of a MultiAir engine's intake valves works via a valve tappet (cam follower), moved by a mechanical intake cam, which is connected to the intake valve through a hydraulic chamber, controlled by a normally open on/off solenoid valve. [11] The system allows optimum timing of intake valve operation.

MultiAir technology can increase power (up to 10%) and torque (up to 15%), as well as reduce consumption levels (up to 10%) and emissions of CO2 (up to 10%), particulates (up to 40%) and NOx (up to 60%) [3] [7] when compared to a traditional petrol engine. The system also provides smoother cold weather operation, greater torque delivery, and no engine shake at shut-off. [12]

Development

Research on critical related technologies started in the 1980s when engine electronic control reached market maturity. MultiAir was developed over ten years at Fiat's Centro Ricerche Fiat (CRF) in Orbassano outside Turin, [13] after a five-year delay during Fiat's 2000-2005 partnership with General Motors. [14] The vice president of Fiat Powertrain Research & Development, Rinaldo Rinolfi, led the team who developed the technology at a cost of over $100 million. [15]

Other systems

More advanced, fully camless valvetrain systems are under development but are not yet production-ready. [16] The Valvetronic system used by BMW allows the valve timing and lift to be varied, but not the cam profile. The ability to vary the latter is characteristic of camless and the MultiAir systems.

Applications

See also

Related Research Articles

<span class="mw-page-title-main">Camshaft</span> Mechanical component that converts rotational motion to reciprocal motion

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, mechanically controlled ignition systems and early electric motor speed controllers.

<span class="mw-page-title-main">VTEC</span> Automobile variable valve timing technology

VTEC 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 low RPM. The VTEC system uses two camshaft profiles and hydraulically selects between profiles. It was invented by Honda engineer Ikuo Kajitani. It is distinctly different from standard VVT systems which change only the valve timings and do not change the camshaft profile or valve lift in any way.

<span class="mw-page-title-main">Variable valve timing</span> Process of altering the timing of a valve lift event

Variable valve timing (VVT) is the process of altering the timing of a valve lift event in an internal combustion engine, and is often used to improve performance, fuel economy or emissions. It is increasingly being used in combination with variable valve lift systems. There are many ways in which this can be achieved, ranging from mechanical devices to electro-hydraulic and camless systems. Increasingly strict emissions regulations are causing many automotive manufacturers to use VVT systems.

<span class="mw-page-title-main">VVT-i</span> Automobile variable valve timing technology

VVT-i, or Variable Valve Timing with intelligence, is an automobile variable valve timing technology developed by Toyota. It was introduced in 1995 with the 2JZ-GE engine found in the JZS155 Toyota Crown and Crown Majesta.

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<span class="mw-page-title-main">MIVEC</span> Automobile variable valve timing technology

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<span class="mw-page-title-main">Variable camshaft timing</span> Automobile variable valve timing technology

Variable camshaft timing (VCT) is an automobile variable valve timing technology developed by Ford. It allows for more optimum engine performance, reduced emissions, and increased fuel efficiency compared to engines with fixed camshafts. It uses electronically controlled hydraulic valves that direct high pressure engine oil into the camshaft phaser cavity. These oil control solenoids are bolted into the cylinder heads towards the front of the engine near the camshaft phasers. The powertrain control module (PCM) transmits a signal to the solenoids to move a valve spool that regulates the flow of oil to the phaser cavity. The phaser cavity changes the valve timing by rotating the camshaft slightly from its initial orientation, which results in the camshaft timing being advanced. The PCM adjusts the camshaft timing depending on factors such as engine load and RPM.

<span class="mw-page-title-main">Active valve control system</span> Automobile variable valve timing technology

The active valve control system (AVCS) is an automobile variable valve timing technology used by Subaru. It varies the timing of the valves by using hydraulic oil pressure to rotate the camshaft, known as "phasing", in order to provide optimal valve timing for engine load conditions. The system is closed loop using the camshaft sensors, crankshaft sensors, air flow meter, throttle position as well as oxygen sensors and/or Air-Fuel ratio sensors in order to calculate engine load. The ECU is programmed to operate control valves that adjust the delivery of the hydraulic pressure in order to move the camshaft into the position that will provide the engine with the best performance while meeting emissions standards.

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References

  1. 1 2 "Fiat's Multiair engine wins Popular Science Award". Popular Science via Allpar.com. November 17, 2010. Archived from the original on March 3, 2016. Retrieved May 31, 2016.
  2. Mark Gillies (October 2009). "Fiat's Multiair Valve-Lift System Explained". Car and Driver.
  3. 1 2 "Best new engine 2010". "International Engine of the Year". Archived from the original on 2012-06-30. Retrieved 2010-09-15.
  4. Mike Hanlon (March 7, 2009). "Fiat releases MultiAir engine technology – is this a fundamental internal combustion engine design breakthrough?". Gizmag.
  5. 1 2 David Zoia (March 7, 2011). "Schaeffler Expects Other Takers for MultiAir Technology". Wards Automotive. Archived from the original on August 6, 2016. Retrieved May 30, 2016.
  6. springerprofessional.de: Drivetrain | UniAir Valve Control for Ingenium Petrol Engine | springerprofessional.de, accessdate: 27. January 2018
  7. 1 2 "「MultiAir」 is launched on the Alfa Romeo MiTo". alfaromeopress.com. Retrieved 2009-06-18.
  8. "Fiat's 1.4-liter turbocharged Multiair powerplant wins "Best New Engine of 2010" award". green.autoblog.com. Retrieved 2011-01-22.
  9. "Fiat 875cc TwinAir". ukipme.com. Archived from the original on 2013-02-05. Retrieved 2012-01-03.
  10. Steven Ashley (October 7, 2010). "Inside Fiat's innovative MultiAir system". Society of Automotive Engineers.
  11. "The Fiat Multiair Technology: how it works". fiatgroupautomobilespress.com. Retrieved 2014-07-28.
  12. "Multiair". fiatgroup.com. Retrieved 2009-06-29.
  13. WebCite query result: WebCite query result, accessdate: 16. June 2016
  14. The Boston Globe: Fiat hopes tech will make Chrysler deal work - The Boston Globe, accessdate: 16. June 2016
  15. "Fiat retrofits Chrysler engine, shelves dinosaurs to save gas". pittsburghlive.com. Retrieved 2009-06-29.
  16. "Valeo has customers for seamless engine with "smart valve actuation"". autobloggreen.com. Retrieved 2009-06-29.
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