Hobbies Cars & Motorcycles What Is Common Rail Direct Injection (CRD)? How Does CRD Work? Share PINTEREST Email Print Mark Houston Design Cars & Motorcycles Cars Basics Buying & Selling How Tos Reviews Tools & Products Classic Cars Exotic Cars Corvettes Mustangs Tires & Wheels Motorcycles Used Cars SUVs Trucks ATVs & Off Road Public Transportation By Christine & Scott Gable Automotive Writers B.S.E, Art Education, Millersville University Christine and Scott Gable are hybrid auto and alternative fuel experts who brewed biodiesel and traveled 125,000 miles on waste vegetable oil. our editorial process Christine & Scott Gable Updated April 23, 2018 Diesel engine technology has advanced by seeming light-years over the last two decades or so. Gone are the days of sulfur-laden black, sooty diesel smoke spewing out of the stacks of semi trucks. The lumbering and cantankerous beasts that filled the roadways — and clogged our airways — are now just a memory. Though diesels have always been very fuel efficient, stringent emissions laws and expectations of performance by the car buying public have forced developments that have taken the lowly diesel from an embarrassment to be endured all the way to cleaner air and economic powerhouse champions. Old News: Mechanical Indirect-injection Diesels of yore relied on a simple and effective — yet not altogether efficient and accurate method of distributing fuel to the engine's combustion chambers. The fuel pump and injectors on early diesels were completely mechanical, and though precision machined and ruggedly built, the working pressure of the fuel system was not sufficiently high enough to render a sustained and well-defined spray pattern of fuel. And in these old mechanical indirect systems, the pump had to do double duty. It not only supplied fuel system pressure but also acted as the timing and delivery device. Additionally, these elementary systems relied on simple mechanical inputs (there were no electronics yet) such as fuel pump revolutions per minute (RPMs) and throttle position to meter their fuel delivery. Subsequently, they often delivered a shot of fuel with a poor and ill-defined spray pattern that was either too rich (most often) or too lean. That resulted in either a rich belch of sooty black smoke or insufficient power and a struggling vehicle. To make matters worse, the low-pressure fuel had to be injected into a pre-chamber to ensure proper atomization of the charge before it could mosey into the main combustion chamber to do its work. Hence the term, indirect-injection. And if the engine was cold and the outside air was cold, things really got lethargic. Though the engines had glow plugs to help them start, it would take several minutes of running time before they were sufficiently heat soaked to allow smooth running. Why such a bulky, multi-stage process? And why so much trouble with cold temperatures? The main reason is the nature of the diesel process and the limitations of early diesel technology. Unlike gasoline engines, diesels have no spark plugs to ignite their fuel mixture. Diesels depend on heat generated by the intense compression of air in the cylinders to ignite the fuel when it’s sprayed into the combustion chamber. And when cold, they need the assistance of glow plugs to bolster the heating process. Furthermore, since there is no spark to initiate combustion, the fuel must be introduced into the heat as an extremely fine mist in order to properly ignite. The New Way: Electronic Common Rail Direct Injection (CRD) Modern diesels have owed their resurgence in popularity to advances in fuel delivery and engine management systems that allow the engines to return power, performance, and emissions equivalent to their gasoline counterparts, while simultaneously producing superior fuel economy. It’s the high-pressure fuel rail and the computer controlled electronic injectors that make all the difference. In the common rail system, the fuel pump charges the fuel rail at a pressure of up to 25,000 psi. But unlike indirect injection pumps, it is not involved in fuel discharge. Under the control of the onboard computer, this fuel quantity and pressure accumulates in the rail independently of engine speed and load. Each fuel injector is mounted directly above the piston within the cylinder head (there is no pre-chamber) and is connected to the fuel rail by rigid steel lines that can withstand the high pressure. This high pressure allows for a very fine injector orifice that completely atomizes the fuel and precludes the need for a pre-chamber. The actuation of the injectors comes via a stack of piezoelectric crystal wafers that move the jet needle in tiny increments allowing for the spray of fuel. Piezo crystals function by expanding rapidly when an electric charge is applied to them. Like the fuel pump, the injectors are also controlled by the engine computer and can be fired in rapid succession several times during the injection cycle. With this precise control over injector firings, smaller, staggered quantities of fuel delivery (5 or more) can be timed over the course of the power stroke to promote complete and accurate combustion. In addition to timing control, the short duration, high-pressure injections allow a finer and more accurate spray pattern that also supports better and more complete atomization and combustion. Through these developments and improvements, the modern common rail direct injection diesel engine is quieter, more fuel efficient, cleaner, and more powerful than the indirect mechanical injection units they have replaced.