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Diesel cycle

The diesel cycle is the combustion process of a type of internal combustion engine in which the burning of the fuel is triggered not by a spark plug as in the Otto cycle, but rather by the heat generated in compressing the fuel-air mixture. They are used not only in automobiles but use for use in emergency power generation and in diesel-electric submarines.

In the Otto cycle the fuel and air are mixed outside the cylinder and drawn into it through the intake valve. The mixture is then compressed, and ignited at the right time with a spark plug. This is timed so that the charge is ignited just before the piston reaches the top of the compression stroke, and by the time the combustion is complete it has just started its downward motion. This means that the heating takes place at a constant volume, so the pressure and temperature of the charge increases dramatically.

In the Diesel cycle only air is drawn into the engine and compressed. The fuel is then injected directly into the cylinder with a high-pressure fuel injector when the piston reaches the top of its motion. The fuel is thicker and burns more slowly than petrol, so the piston is already moving down by the time the combustion completes. Thus the Diesel actually loses some of the potential energy of the charge, energy that the Otto cycle captures, although it is less stressful on the engine.

Given that the Diesel is not as efficient, in theory, as an Otto cycle engine, and is also more complex due to the nature of the injectors, it may be surprising that it is used at all. However the key to the Diesel cycle is that the fuel cannot possibly cause the dreaded condition in the Otto cycle known as knock. Knock occurs when the fuel ignites at the wrong time, typically from heating while it is being compressed, or coming into contact with hot spots inside the cylinder. This results in lack of power, and possible damage to the engine's internal parts. In order to avoid the problem, Otto cycle engines are often run at lower pressures and temperatures than they are theoretically capable of.

In the Diesel this problem simply can't happen, because the fuel isn't in the engine until the exact moment it is needed. This allows the Diesel to be run at much higher compression ratios, typically double that of an Otto engine of the same size. Since efficiency is strongly related to compression ratio, in practice the Diesel engine is considerably more efficient than a similar power Otto. In fact the Diesel engine has the lowest specific fuel consumption of any large engine, 0.26 lb/hp.h (0.16 kg/kWh) for very large marine engines.

Another advantage of the Diesel engine is that the incoming air charge is not mixed with fuel. This allows practices which would waste incoming fuel in Otto cycle engines, such as high pressure forced induction and a large degree of valve overlap , or use of a two-stroke cycle, without wasting anything other than some of the incoming air. In fact, two-stroke Diesels with high pressure forced induction, particularly turbocharging, make up a large percentage of the very largest Diesel engines.

A related but independent source of efficiency is the lack of a throttle valve, since engine speed and power are regulated by directly controlling fuel flow rather than flow of the fuel-air mixture as in the Otto-cycle engine. Otto-cycle engines can be quite efficient when the throttle is wide open and the engine is heavily loaded, thereby keeping engine speed and therefore airflow low; however as load decreases and engine speed tends to increase, thus airflow increases and the throttle is partially closed, greatly restricting the influx of air. These two conditions of increased airflow through a smaller aperture result in increasingly large parasitic losses of energy with decreasing load, culminating at idle speed, when the engine is attempting to pull a large volume of air through an almost completely shut air intake, resulting in a large waste of energy maintaining a large manifold vacuum. In contrast, the Diesel engine idles with no restriction on airflow, thus wasting even less energy by air intake than at full speed, requiring only a tiny amount of fuel to keep it idling at low speed. This (along with the difficulties sometimes found in starting a cold Diesel engine with the less volatile fuel oil) accounts for the common practice of drivers of Diesel-engined vehicles of leaving the vehicle idling for long periods, rather than shutting the engine off.

In addition it is easier to make a slower-burning fuel than petrol, which means that diesel fuel is less expensive to produce and more common. Diesel fuel also has more energy for a given volume than petrol, meaning it takes up less room and longer-range is a common benefit. On the downside, the slower-burning fuel leads to slower maximum RPM, and thus smaller RPM range.

The fuel used in diesel engines is chemically identical to home heating oil. However, the price of diesel fuel typically includes a road tax while home heating oil does not, and hence it is generally illegal to use the cheaper heating oil as diesel fuel.

In North America diesel engines are primarily used in large trucks, where the low-stress, high-efficiency cycle leads to much greater engine life and lower operational costs. However cars continue to use gasoline, primarily due to consumer desire for "peppy" cars with a wider range of RPM. In Europe the use of diesel engines is far more common in cars as well. There is considerable interest today in hybrid cars using Diesel engines for most power, with an electric motor to provide the "pep". Current models seem to suggest that cars with all the performance of modern designs can deliver over 100mpg, on the less expensive fuel.

The Diesel cycle is particularly well suited to aviation, where the combination of low specific fuel consumption and low volume make for a smaller aircraft for any given range requirement. Although there was some interest in them in the 1940s, the metallurgy of the era required large blocks to contain the higher compression ratios, which led to them being fairly heavy for their power. They fell from favour after WWII, and from that point on everyone was thinking turbines only. More recently they appear to be making something of a comeback, notably in Europe where avgas is very expensive and hard to find.

Diesel engines are also used in conventional submarines. In these submarines, the diesel engine is run when the submarine is on the surface which charges batteries that power the submarine when it is submerged.

Last updated: 05-07-2005 02:21:19
Last updated: 05-13-2005 07:56:04