Common rail direct fuel injection is a directfuel injection system built around a high-pressure (over 2,000 bar or 200 MPa or 29,000 psi) fuel rail feedingsolenoid valves, as opposed to a low-pressurefuel pump feedingunit injectors (or pump nozzles). High-pressure injection delivers power and fuel consumption benefits over earlier lower pressure fuel injection,[citation needed] by injecting fuel as a larger number of smaller droplets, giving a much higher ratio of surface area to volume. This provides improved vaporization from the surface of the fuel droplets, and so more efficient combining of atmospheric oxygen with vaporized fuel delivering more completecombustion.
Common rail injection is widely used indiesel engines. It is also the basis ofgasoline direct injection systems used onpetrol engines.
In 1916Vickers pioneered the use of mechanical common rail systems inG-class submarine engines. For every 90° of rotation, four plunger pumps allowed a constant injection pressure of 3,000 pounds per square inch (210 bar; 21 MPa), with fuel delivery to individual cylinders being shut off by valves in the injector lines.[1] From 1921 to 1980Doxford Engines used a common rail system in theiropposed-piston marine engines, where a multicylinder reciprocating fuel pump generated a pressure around 600 bars (60 MPa; 8,700 psi), with fuel stored in accumulator bottles.[2] Pressure control was achieved by an adjustable pump discharge stroke and a "spill valve". Camshaft-operated mechanical timing valves were used to supply the spring-loaded Brice/CAV/Lucas injectors, which injected through the side of the cylinder into the chamber formed between the pistons. Early engines had a pair of timing cams, one for ahead running and one for astern. Later engines had two injectors per cylinder, and the final series of constant-pressure turbocharged engines was fitted with four. This system was used for the injection of both diesel and heavy fuel oil (600cSt heated to a temperature near 130 °C).
Common rail engines have been used in marine andlocomotive applications for some time. TheCooper-Bessemer GN-8 (circa 1942) is an example of a hydraulically operated common rail diesel engine, also known as a modified common rail.
The common rail system prototype for automotive engines was developed in the late 1960s byRobert Huber of Switzerland, and the technology was further developed by Dr. MarcoGanser at theSwiss Federal Institute of Technology in Zurich, later ofGanser-Hydromag AG (est. 1995) in Oberägeri.
The first common-rail-Diesel-engine used in a road vehicle was the MN 106-engine by East GermanVEB IFA Motorenwerke Nordhausen. It was built into a singleIFA W50 in 1985. Due to a lack of funding, the development was cancelled and mass production was never achieved.[3]
The first successful mass production vehicle with common rail, was sold in Japan in 1995. Dr. Shohei Itoh and Masahiko Miyaki of theDenso Corporation developed the ECD-U2 common rail system, mounted on theHino Ranger truck.[4] Denso claims the first commercial high-pressure common rail system in 1995.[5]
Modern common rail systems are governed by anengine control unit, which controls injectors electrically rather than mechanically. Prototyped in the 1990s byMagneti Marelli, Centro Ricerche Fiat inBari, and Elasis, with further development by physicist Mario RiccoFiat Group. Unfortunately Fiat were in a poor financial state at this time, so the design was acquired byRobert Bosch GmbH for refinement and mass production.[6] The first passenger car to use this system was the 1997Alfa Romeo 156 with a 2.4-LJTD engine,[7] and later that same year,Mercedes-Benz introduced it in theirW202 model. In 2001, common rail injection made its way into pickup trucks with the introduction of the 6.6 liter Duramax LB7 V8 used in the Chevrolet Silverado HD and GMC Sierra HD. In 2003 Dodge and Cummins launched common rail engines, and Ford followed in 2008 with the 6.4L Powerstroke. Today almost all non-commercial diesel vehicles use common rail systems.
The common rail system is suitable for all types of road cars with diesel engines, ranging fromcity cars (such as theFiat Panda) toexecutive cars (such as theAudi A8). The main suppliers of modern common rail systems areBosch,Delphi Technologies,Denso, andSiemens VDO (now owned byContinental AG).[8]
The automotive manufacturers refer to their common rail engines by their ownbrand names:
Solenoid orpiezoelectric valves make possible fineelectronic control over the fuel-injection time and quantity, and the higher pressure that the common rail technology makes available provides better fuelatomisation. To lower enginenoise, the engine's electronic control unit can inject a small amount of diesel just before the main injection event ("pilot" injection), thus reducing its explosiveness and vibration, as well as optimising injection timing and quantity for variations in fuel quality, cold starting, and so on. Some advanced common rail fuel systems perform as many as five injections per stroke.[9]
Common rail engines require a very short to no heating-up time, depending on the ambient temperature, and produce lower engine noise and emissions than older systems.[10]
Diesel engines have historically used various forms of fuel injection. Two common types include theunit-injection system and thedistributor/inline-pump systems. While these older systems provide accurate fuel quantity and injection timing control, they are limited by several factors:
In common rail systems, a high-pressure pump stores a reservoir of fuel at high pressure — up to and above 2,000 bars (200 MPa; 29,000 psi). The term "common rail" refers to the fact that all of thefuel injectors are supplied by a common fuel rail which is nothing more than a pressure accumulator where the fuel is stored at high pressure. This accumulator supplies multiple fuel injectors with high-pressure fuel. This simplifies the purpose of the high-pressure pump in that it only needs to maintain a target pressure (either mechanically or electronically controlled). The fuel injectors are typically controlled by theengine control unit (ECU). When the fuel injectors are electrically activated, a hydraulic valve (consisting of a nozzle and plunger) is mechanically or hydraulically opened and fuel is sprayed into the cylinders at the desired pressure. Since the fuel pressure energy is stored remotely and the injectors are electrically actuated, the injection pressure at the start and end of injection is very near the pressure in the accumulator (rail), thus producing a square injection rate. If the accumulator, pump, and plumbing are sized properly, the injection pressure and rate will be the same for each of the multiple injection events.
Third-generation[vague] common rail diesels now featurepiezoelectric injectors for increased precision, with fuel pressures up to 2,500 bar (250 MPa; 36,000 psi).[11]
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