Today, diesel engines are the pillar on which a lot of machines move: buses, trucks, construction equipment, and more.
In the early days, diesel engines were mostly seen as too dirty, not quick enough, and unpleasantly loud. Fast forward to the modern era, and you will find that diesel engines have undergone many improvements that make diesel fuel a lot more efficient and burn cleaner while being a lot more versatile. When talking about heat engines, diesel engines are up there with the very best, which has led to them being the preferred choice for a variety of operations, such as heavy-duty machinery, generation of power and vehicles.
BRIEF BACKGROUND OF DIESEL ENGINES
Basically, what powers the diesel motor is a compression ignition engine, which was invented over 100 years ago by a man called Rudolf Diesel. A lot of people who know about the diesel engine can only remember their appearance around the 1970's, which is when diesel engines began to be used in consumer cars. Back then, virtually every car manufacturer did their best to provide a passenger car that was powered by a diesel engine with the advent of the gas crunch. However, diesel motors go way back further than the 1970's. Rudolf Diesel (pictured here) is credited with inventing the diesel engine, and it is not just a recent discovery. Diesel was able to secure a patent for his diesel engine in 1892.
That's a brief background of the invention of the diesel engine, but what really is a diesel engine?
WHAT IS A DIESEL ENGINE?
There are various kinds of internal combustion engines, and a diesel engine is no exception. "Combustion" refers to burning. "Internal" refers to the inside of a thing. Therefore, when we say a diesel engine has an internal combustion engine, we imply that diesel engines are designed in a way that fuel gets burned right inside its cylinders, which are the engine's principal part. It is here that the production of power is carried out.
This differs greatly from external combustion engines, which are mostly found in steam locomotives. For steam engines, a huge fire gets started at one part of its boiler, which heats up the water in order to produce steam. Next, through special long tubes, the steam makes its way through twin cylinders located at the other side of its boiler. This leads to a back and forth movement of the piston, causing its wheels to move. This is external combustion, and the reason is that the fire occurs not inside its cylinder but outside.
On the other hand, in diesel engines, the fire gets burned right inside its cylinders. Energy is mostly conserved with internal combustion engines since there is no need for the heat to make its way from its point of production into the cylinder. The process occurs at the exact same spot. This is the reason that internal combustion motors have a higher efficiency than the external combustion engines.
Rudolf Diesel built the diesel engine in order to get diesel fuel converted right into mechanical energy. This internal combustion engine makes use of diesel fuel. In diesel engines, fuel burning takes place as a result of the high pressure, as well as the temperature that is built in the combustion unit.
Now let's consider the main components of a diesel engine and the functions that these components perform.
MAIN COMPONENTS OF A DIESEL ENGINE
At this point we will explore the parts that constitute a diesel engine and the vital functions that they perform. We will be discussing only those components which have direct involvement in the fuel cycle, especially, for a four-stroke diesel engine. Since the other components do not really have direct involvement in this cycle such as the alternator, they will not be highlighted here.
The key parts that make up the diesel engine are as follows:
1. Cylinder Block Assembly
In both the two-stroke diesel engine, as well as the four-stroke diesel engine, the cylinder block is the principal component. It plays a vital role in the functioning of other compartments in the engine which support how the machine operates. The material used to make the cylinder block is cast iron, and it possesses a level of precision that is high.
The components that make up the block cylinder include:
- The Cylinder
A press method is used to place the cylinder in the block engine in order to keep it tightly in place. It is produced using iron, as well as aluminium iron, and it is placed to help in the upward and downward movement of the piston.
- Water Jacket
This water sheath is placed in the engine block and is designed to help cool the engine. The water jacket has vents for the intake, as well as the outlet of water, which helps to circulate it and cool the temperature.
- Oil Feed Lines
This is the hole for oil, which is located on the engine’s cylinder block. Its role is to ensure that an oil line goes from the head of the engine’s cylinder right through to the crankcase. This is to help in the circulation of oil to ensure that every part of the diesel engine is supplied with oil.
2. Cylinder Head Assembly
This component of the diesel engine is placed on its top. Just like with the cylinder block, the cylinder head assembly is produced using cast material. In recent times, cylinder heads produced with aluminium are preferred because they are lighter, as well as stronger. In this component, there are several parts, such as the camshaft and the combustion chamber.
- Valve and spring
The valve and spring play a vital role by serving as a door to help in the opening and closure of the intake, as well as the exhaust channels located in the combustion unit. The work of the so is to ensure that the value stays closed.
The function of the camshaft is to keep the valve pressed, and when this is achieved, the port that is responsible for the intake or the exhaust is opened.
- Rocker arm
This oscillating lever is responsible for ensuring that radial movement is conveyed into a linear movement in order to get the poppet valve opened from the engine’s cam lobe. A lobe that rotates raises and lowers one end, and the other end serves as the stem for the valve.
- Combustion chamber
This small space is designed mostly for combustion activities. What emanates from here is a fire blast that helps push down the piston. You will mostly find the combustion chamber in diesel engines that use indirect injection.
3. Piston & Connecting Rod
Pistons are built to help in the adjustment of cylinder volume. It is very important to regulate cylinder volume because it helps facilitate the operation of the engine. The downward movement of the piston will lead to an enlargement of the cylinder volume while an upward movement will cause the cylinder volume to retract. The function of the connecting rod is to ensure that the piston makes consistent upward and downward movements.
The parts that make up the piston are as follows:
- Ring compression
The rings ensure that air leakages do not occur with every compression stroke. Basically, the rings ensure that the gap between the walls of the piston, as well as the main liner, is closed.
- Oil ring
With the downward movement of the piston, the oil ring is responsible for wiping oil that comes in contact with the cylinder walls. It also performs the vital functions of creating a separation between the combustion and oil chambers, which helps ensure that there are no pressure leaks in the combustion chamber.
- Pin piston
This is responsible for creating a connection between the piston, as well as the connecting rod. It performs the function of a hinge and it is tubular in nature.
The material that is used to produce the crankshaft is cast-iron. The function of the crankshaft is to ensure that the upward and downward movement of the piston is done in a rotary manner. You can compare the principle by which the crankshaft works to what happens when you ride a bicycle. The crankshaft is built in such a way that it can we stand pressure which emanates from the piston. A customized iron alloy, which is very strong, is used to make this component.
Some of the parts that are found on the crankshaft:
- Crank pin
This pin connects to the connecting rod's large end.
- Crank journal
This pin performs the function of helping the crankshaft spin. You will basically find it resting on the bearings, and it mostly is attached to the lower part of the engine’s connecting rod.
- Weight balance
The crank pin is located opposite to the weight balance. The function of this component is to perform counterweight duties right inside the machine.
5. Oil Pan
The oil pan holds the engine oil. It is made with very strong and durable materials, such as thin iron.
6. Timing Chain Assembly
In the system that contains the valve mechanism, is the timing chain. It provides an angular connection between the crankshaft, as well as the camshaft rotation. This component is located in the front of the diesel engine. The connection between the sprocket gears of the crankshaft and camshaft is made possible by the timing chain.
7. Fly Wheel
The function of this component is to give balance to the speed of the diesel engine. The material used to make this component is solid iron, which serves as the torque storage. The flywheel basically acts as an energy reservoir. Energy is stored as kinetic energy, which is essential in helping the diesel engine to run, even if the production of power does not take place.
8. Fuel System Assembly
The first system goes all the way from the fuel tank to the engine injector. Fuel systems are designed to supply fuel during strokes right inside the combustion chamber. When it comes to diesel engines, fuel systems are categorized into two distinct types which are the conventional fuel systems and the common rail fuel systems. Common rail fuel systems are known to be much more efficient, as well as, economical.
All of the components that are discussed above play a vital role in ensuring that the diesel engine operates smoothly as required. If issues occur to any of the parts that have been discussed above, then, it will lead to a disruption in the working process of your diesel engine.
HOW DO DIESEL ENGINES WORK?
Before we go into details about how diesel engines work, you need to keep in mind that what basically differentiates diesel and gasoline engines is that for the diesel engines, the combustion chambers get supplied with fuel via the nozzles for fuel injection as soon as there is a very high air pressure which is appropriately hot to get the fuel ignited. Here is what really takes place when you start your vehicle that is powered by a diesel engine –
1. First, the key is turned in the vehicle's ignition.
Then, you exercise some patience to allow the engine to develop the needed heat that will get it to start in its cylinders. Once you turn the key, you initiate a process which involves the injection of fuel into the engine’s cylinders. This is done in the presence of very high pressure which causes the air to build up the heat by itself in the engine's cylinders. These days, the amount of time that is needed for this process to occur is significantly reduced.
In combustion chambers that have already been preheated, diesel fuel starts quicker, and this is the reason that some manufacturers get to install glow plugs which use energy from the battery to get the air heated up beforehand in the cylinders at the time when the engine is first ignited. Innovation in the techniques for fuel management, as well as, the injection pressure is now able to build up considerable heat to get the feel ignited without the need for glow plugs.
2. A start light is activated.
As soon as the indicator gives the signal, you push down hard on the accelerator of your vehicle, and you turn the key in the vehicle's ignition to get it started. At this point, fuel is delivered by the fuel pumps into the engine. As the fuel makes its way, it comes in contact with fuel filters that get it cleaned before letting it through to the nozzles for fuel injection. Getting the feel cleaned is an ideal maintenance technique because contaminated fuel will get the injector nozzles clogged up.
3. Fuel is pressurized by the pump for fuel injection into the delivery tube.
Also referred to as a rail, the delivery tube keeps the feel highly pressurized at about 23,500 psi at the minimum while ensuring that every cylinder gets a supply of pressurized fuel at the right time. From the fuel injectors, diesel fuel is sprayed right into the cylinder's combustion chambers via the nozzles which are powered by the ECU of the engine. It is the engine control unit which regulates the pressure, determines fuel spray time, the duration of the fuel spray, etc. There are diesel fuel systems where other methods are employed for controlling the injection of fail. Today, new innovations are being explored to manufacture diesel engines which have higher power and responsiveness.
4. In the cylinders, fuel meets with air and fire.
In the previous step, we analyzed how the fuel gets to where it needs to be. While that process is ongoing, a different process takes place at the same time to transport air to the appropriate location which will result in a firepower play. An air cleaner is used in conventional diesel engines to supply air. However, today, turbochargers have taken over the game as they have the ability to pump very large air volumes right into the cylinders. If the conditions are right, turbochargers help in fuel economy while supplying even greater power. Turbochargers significantly enhance diesel vehicle power by at least 50% and can significantly lower the consumption of fuel by at least 20%.
5. Combustion begins.
At this point, the little fuel which is highly pressurized in the engine's pre-combustion chamber spreads combustion to the fuel, as well as, the air that is already present combustion chamber.
When the weather is cold, it may be quite a challenge to get a diesel engine started since the cylinder block has a cold metal, as well as, a cold head which draws out whatever heat is produced as compression strokes take place in the cylinder. This inhibits ignition. In order to circumvent this problem, manufacturers equip diesel engines with glow plugs. These little electric heaters are placed inside the cylinder and provide assistance in igniting the fuel when the engine needs to be started.
Resistive grid heaters are, also, sometimes used to get the inlet air heated up to get the engine to operating temperature. Electric resistive heaters that are placed right inside the engine block (engine block heaters) and are linked to the car’s utility grid get used for prolonged periods even if the engine of the vehicle is no longer running. This helps to lower the time needed to get the engine started subsequently.
When the weather is cold, diesel fuel stands a risk of getting waxed. This implies that it can solidify and be transformed into crystalline. In the fuel, the crystals continue to expand, and this keeps the engine starved of fuel. In order to tackle this issue, electric heaters which give off a low output are placed in the engine's fuel tank, as well as, around the fuel lines.
Then again, there are many diesel engines that possess a system for returning spills, and this ensures that any diesel that is spilled by the injector pump, as well as, the injectors gets sent back to the engine’s fuel tank. Once the engine of the car is warmed up, warm fuel being sent back will help to ensure that waxing does not occur in the fuel tank. Due to the innovations in fuel technology, there are special additives that have been added to ensure that waxing does not occur anymore.
Another very important component of diesel engines is the governor which could be either mechanical or electronic. It is responsible for limiting engine speed by exercising control over how much fuel is being delivered. In diesel engines, air that comes in is never throttled. Therefore, if a diesel engine does not have a governor, over speeding is very likely. For fuel injection systems that are governed in a mechanical way, the gear train of the engine is what drives them. Fuel delivery control in mechanical systems functions by combining weights and springs. However, modern diesel engines that are controlled electronically manage fuel delivery, as well as, limit the revolutions that occur through an Electronic control unit (ECU). The ECU works by getting signals on the speed of the motor and uses actuators to regulate fuel amounts and the timing of fuel injections.
Now that we have analyzed how a diesel engine basically works let us analyze the types of diesel engines and see the principles on which they work.
TYPES OF DIESEL ENGINES
To better understand how diesel engines work, we need to consider the different kinds of diesel engines that we have today. There are different ways to classify diesel engines, but one very popular way to do so is to classify them based on their working mechanism. In that case, diesel engines are classified into two types which are the two-stroke diesel engine, as well as, the four-stroke diesel engine.
1. Two-stroke Diesel Engines
This basically refers to a diesel engine that operates in just two strokes. Its inventor was Hugo Guldner in the year 1899. The technology on which 2 stroke diesel engines work was advanced during the 1930's other to produce machines that had an enhanced power to weight ratio, as well as, output range. Diesel stream liners in the 1930's were the first mobile vehicles on which day 2-stroke diesel power was applied. As time went on, the two-stroke diesel engines began to be modified for use in the locomotive and marine industries. In fact, this is what paved the pathway towards dieselising railroads from the 1940's and 50's.
Diesel engines basically work by using compression ignition. This refers to the process of fuel injection after having the compression chamber compress the air, thus, resulting in the self-ignition of the fuel. This process differs from gasoline engines which make use of the Otto cycle where fuel mixes with air and, then, gets into the combustion chamber to be lighted up by spark plugs.
Internal combustion engines that work in two strokes have a simpler mechanism than the four-stroke engines. However, they have a more complex nature with regards to thermodynamics and aerodynamics. Basically, the theory on how internal combustion engines operate involves four cycles which are –
- The Intake
- The Compression
- The Ignition
- The Exhaust
In two-stroke diesel engines, this process takes place in just a single revolution and in 360 mechanical degrees. This is in contrast to four-stroke diesel engines where this process takes place in 2 full revolutions and in 720 mechanical degrees. For two-stroke diesel engines, multiple functions can take place at any point in time as the engine runs.
How It Works
Intake is initiated at the point where the piston rests at BDC (bottom dead center). At this point, the cylinder wall ports let in air through the cylinder. Artificial aspiration is very important in the operation of a two-stroke diesel engine, and they utilize a blower that is driven mechanically to get the cylinder charged with needed air. Alternatively, turbo-compressors are used too. During the early phase, remnant combustion gases are forced out from the last-occurring power stroke using the charged air. This process is called scavenging.
The piston rises, and the air charge that was let in during the intake is compressed. Fuel injection takes place at the TDC (top dead center) which leads to combustion emanating from the very highly pressurized air charge, as well as, the heat that results from compression, thus, causing the piston to be driven downward.
With the downward movement of the piston right inside the cylinder, it gets to a certain level in which the exhaust port opens up so that combustion gases with high pressure can be expelled. In recent times, a 2 stroke diesel engine makes use of a poppet valve that is mounted on top, as well as, uniflow scavenging. As the piston continues to move downward, the ports for the intake of air will become exposed which causes the cycle to begin all over again.
2. Four-stroke Diesel Engines
These are also internal combustion engines which make use of about 4 piston strokes (the intake, the compression, the ignition, and the exhaust) in a single operating cycle. For an operating cycle to take place, the crankshaft must complete two revolutions at 720 degrees. This kind of diesel engine is probably the most widely seen small engine out there. Practically, four-stroke diesel engines make use of about 5 strokes to complete an operating cycle. These 5 strokes include –
- The Intake
In this event, air and fuel mix together and get supplied into the combustion chamber. With the movement of the piston from the top dead center to bottom dead center, the intake event takes place as an opening of the intake valve occurs. The piston moves downward towards the bottom dead center which leads to the creation of low cylinder pressure. The mixture of air and fuel goes right through the intake valve with force created by ambient atmospheric pressure. This pressurized air-fuel mixture goes right into the cylinder where it fills the low-pressure area that has been created from the motion of the piston.
The mixture of air and fuel keeps flowing, and the cylinder keeps getting filled a little bit past the bottom dead center, and the direction of the piston starts changing. The intake valve stays open a few degrees from the rotation of the crankshaft after the bottom dead center. The intake valve gets closed to seal the deal mixture of fuel and air in the cylinder
- The Compression
This is the point where the mixture of fuel and air is compressed tightly in the cylinder. The sealing of the combustion chamber forms the charge, which refers to the amount of air and fuel mixture that is compressed and trapped, ready to be ignited. The compression of the air and fuel mixture makes it possible for the release of greater energy with the ignition of the charge. In order for the cylinder to get sealed so as to provide the needed compression, the valves for intake, as well as, exhaust needs to be closed. By compression, we refer to the process by which a charge is reduced or squeezed from large to small volumes inside the combustion chamber. The momentum that is needed for charge compression is maintained by the flywheel.
With the compression of the charge by the engine’s piston, the compressive force is increased, and this leads to the generation of heat. The air and fuel mixture which gets compressed and heated in the charge causes a rise in the charge temperature, as well as, a rise in the vaporization of the fuel. The rise in the temperature of the child takes place uniformly in every part of the combustion chamber, and this leads to the production of faster combustion after ignition.
The rise in the vaporization of fuel takes place as little fuel droplets undergo total vaporization due to the generated heat. The rise in the droplet surface area that is now exposed to the flame of the ignition makes room for the charge to be burned more completely inside the combustion chamber.
- The Ignition
This event takes place with the ignition and oxidization of the charge via a chemical reaction causing heat energy to be released. By ignition (or combustion), we refer to the very quick oxidizing chemical reaction which involves the chemical combination of fuel and oxygen to release energy as heat.
Only a short time is required for problems combustion to get flame spread all through the entire combustion chamber. Sparks from spark plugs and results in combustion at about 20 degrees of the rotation of the crankshaft before top dead center. A progressive flame front, which refers to the wall that acts as a separation between the charge and the byproducts of combustion consumers the atmospheric oxygen, as well as, the fuel vapor. As the flame front continues to make its way throughout the combustion chamber, the whole charge gets burned.
- The Power
This refers to a stroke of operation in the engine where the head of the piston is forced apart from the head of the cylinder by hot expanding gases. Torque is applied to the crankshaft when the force and movements of the piston get transferred via the connecting rod. The rotation of the crankshaft is initiated by the application of torque. What determines how much torque is produced is the piston pressure, piston size, and engine throw. Both valves remain closed when the power stroke occurs.
- The Exhaust
The stroke takes place with the expulsion of spent gases out of the combustion chamber which is released right into the atmosphere. This happens to be the last stroke, and it takes place with the opening of the exhaust valve while the intake valve stays closed. It is the movement of the piston which gets the exhaust gases evacuated into the atmosphere.
When the piston gets to bottom dead center during this stroke, a complete combustion cycle has occurred while the cylinder gets filled up by exhaust gases. At this point, an opening of the exhaust valve takes place and the flywheel, as well as, other parts that move cause the piston to be pushed back to top dead center. This process causes the exhaust gases to be forced out of the exhaust valve. When the exhaust stroke takes place, you will find that the piston stays at top dead center and this signals the completion of one operating cycle.
Now that we have understood how two stroke and four stroke diesel engines operate, another important aspect to consider is the fuel injection process in diesel engines.
FUEL INJECTION IN A DIESEL ENGINE
In diesel engines, fuel injection systems are located at its heart. The system pressurizes and injects fuel which is forced into compressed air inside the combustion chamber. Here are the components of the fuel injection system in a diesel engine -
- The fuel injection pump which has the function of getting fuel highly pressurized
- The high-pressure pipe that performs the function of supplying the injection nozzle with fuel
- Injection nozzle that gets fuel injected right into the cylinder
- The feed pump which performs the function of sucking fuel out of the fuel tank
- The fuel filter which filters the fuel
Key Functions of a Fuel Injection System
The fuel injection system in a diesel engine performs 4 key functions as follows:
- Feeding fuel
The body of the injection pump has several pump elements built into it. With the elevation of the plunger by the cam, the high-pressure compression of the fuel takes place which is, then, forwarded to the injector.
- Injection timing adjustments
When we talk about the delay in ignition, we refer to that time period which exists between fuel injection, ignition, and combustion, and the time when the highest combustion pressure is attained. Basically, this time period can be said to be almost constant regardless of the speed of the engine, and a timer helps in the adjustment or alteration of the injection timing. This helps in the achievement of optimum combustion.
- Fuel quantity adjustments
Air intake constantly occurs in diesel engines regardless of the speed as well as, the rotating load. As the quantity of injections is altered with engine speed while the timing of injection remains constant, it will create a change in the output, as well as, the consumption of fuel. Basically, the output of the diesel engine is nearly proportional to the quantity of fuel injected, and the accelerator pad helps to adjust this.
- Fuel atomizing
With injection pump pressurization of fuel and the injection nozzle atomization, fuel is thoroughly mixed with air which helps to enhance ignition. This produces total combustion.
How Fuel Injection Systems Work
Fuel injection pumps are very complex. They are all calibrated in a way that helps them to always supply appropriate amounts of fuel inside the combustion chamber through fuel injectors. The result is that power output, and fuel efficiency are maintained. Most of the time, injection pumps are indirectly driven by gears, by chains, or even a timing belt from the crankshaft.
Fuel injection pumps are timed precisely to supply appropriate diesel volumes to the cylinder chamber just before the arrival of the cylinder at TDC position of the compression stroke. What this accomplishes is to ensure the availability of fuel at just the right point where it is needed. Here, heat which is produced from high-pressure piston compression ignites the fuel which supplies the power that the diesel engine needs. Fuel injection pumps are designed to function up to thousands of times in a single minute.
How does a diesel engine work?
Back in the days, automobiles powered by diesel engines were generally seen as noisy, dirty, and slow, and were far behind gasoline-fueled cars. Today, however, diesel engines are relied on to power buses, trucks, construction equipment, trains, and even ships. Modern diesel engines burn fuels in a much cleaner manner than their predecessors did, and they are preferred in cars for their efficiency.
These attributes, however, don’t tell us what a diesel engine is.
So what is a diesel engine?
Engines are categorized in various ways. They’re differentiated as external or internal, gasoline or diesel, rotary or reciprocating, and spark or ignition. These differentiations can get confusing to ordinary people.
To understand better what a diesel engine is and how it relates to the many other types of engines, it’s a good idea to look at engines from a wider perspective. Let’s start from what an engine is.
Engine (or heat engine) – it is a machine that converts the chemical energy stored in fuels into mechanical energy. The following sequence of events is what actually happens in an engine:
- Fuel is ignited, and this sets off a chemical process called fuel combustion.
- Combustion releases heat energy.
- Heat causes gas expansion.
- Since the expanding gas has nowhere to go inside the cylinder, it pushes at the only movable part—the piston. At this point, the chemical energy from the expanding gas converts to mechanical energy.
- The piston moves downward, and this linear movement causes the crankshaft to move.
- The crankshaft converts the linear motion into rotary motion, which makes the wheels of an automobile move.
Types of Heat Engines
There are two types of engines or heat engines, namely:
- External combustion engine – the combustion of fuel occurs away from the main machine. A classic example is the steam engine where boiling water is used. The steam from the boiler travels inside long pipes to the main machine where the pistons are. The pressure from the steam forces the pistons to move back and forth, which in turn causes wheels or turbines to move.
- Internal combustion engine – fuel combustion takes place inside an engine block. Since combustion occurs inside a confined space, the expansion of fuel becomes more explosive, more forceful, and more efficient. For this reason, the internal type wastes less energy than the external type. Examples of this type of engines are those used in automobiles and aircrafts.
Types of Internal Combustion (IC) Engines
- Rotary – the cylinders of this engine are arrayed in a radial configuration around a crankshaft. This is an obsolete type of IC engine, and it was originally designed for aviation purposes.
- Reciprocating (or piston engine) – this IC engine uses reciprocating pistons to convert the energy produced by the combustion of fuel into rotary motion. We’re more interested in reciprocating IC engines because it is the type used for motor vehicles.
Two Types of Reciprocating IC Engines
- Spark ignition (or gasoline engine) – this engine type uses a fuel-air mixture which is compressed by reciprocating pistons to about 10% of its original volume. Compressing gas makes it hot and highly combustible. The mixture is then ignited by a spark, which sets off the combustion process.
- Compression ignition (or diesel engine) – this reciprocating IC engine compresses air up to 4% of its original volume. The more compressed air becomes, the hotter it gets. Fuel is then injected into the cylinders. The injection of fuel into a chamber of highly-compressed air results in instantaneous ignition, which sets off an explosive combustion of gases.
Summing up, a diesel engine (or compression ignition engine) is a reciprocating IC engine that uses diesel as fuel and depends on a compression ignition mechanism for fuel combustion. It was invented in 1892 by Rudolf Diesel and other engineers after 13 long years of developing it. Its invention came at a time when the main power source used by people and industries was the steam engine.
What are the main parts of a diesel engine?
Below are the principal components of a diesel engine. They are contained in a cylinder block, which is a structure usually made of cast iron or aluminum alloy.
Cylinder – the part of the combustion chamber where combustion takes place, which in turn causes the gas to expand. The expansion of gas pushes the piston down to enlarge the space inside the cylinder.
Pistons – the movable parts inside a cylinder, which move up or down to adjust the cylinder’s volume. A downward movement of the piston enlarges the cylinder volume while an upward movement reduces it. Connecting rods ensure that the pistons make consistent upward and downward movements.
Cylinder head assembly – this component of the diesel engine is located on top of the cylinders. It is cast in the same material as the cylinder block. It holds the valves and fuel injectors.
Crankshaft – this is the part responsible for transforming the piston’s up-and-down movements into rotary motion. It is found inside a crankcase which is located below the cylinders.
Camshaft – it works closely with the timing chain and the crankshaft to control the amount of combustible mixture that gets into the engine by opening and closing the valves at the precise time. It’s sometimes called the brain of the engine for this reason.
Fuel injection – the direct fuel injection system is designed to withstand extreme heat and pressure. It is one of the more complex parts of a diesel engine. It is made up of the following components:
- fuel injection pump – pressurizes the fuel
- high-pressure pipe – supplies the injection nozzle with fuel
- injection nozzle – sprays the fuel into the cylinder in a precise manner
- feed pump – draws fuel out of the fuel tank
- fuel filter – ensures that impurities are screened out of the system
The fuel injection system is responsible for supplying the fuel, adjusting its quantity and timing, pressurizing and atomizing it to ensure complete combustion.
How Diesel Engines Work
This is what happens under the hood of a diesel-powered vehicle.
1. Heat builds up when you turn the key – turning the ignition key initiates a process which involves the compression of air and building up of heat. This is the point where you wait for a second or two.
2. Fuel is pumped when you step on the accelerator – the start light goes on, which signals that you may now step on the accelerator. The fuel pump sends the fuel to the delivery tubes, which keeps the fuel pressurized. Fuel is then sprayed through the fuel injector nozzles into the cylinders in clockwork precision. The pressure of the fuel as well as the timing and duration of injecting it is regulated by the engine control unit (ECU).
3. Combustion begins – when the pressurized fuel and hot air meet in the chamber, instantaneous ignition results and fuel combustion begins. In extremely cold weather, starting a diesel may not be as quick since its cold metallic block will absorb much of the heat produced. When this happens, the chamber does not reach the required temperature to start instantaneous ignition. To prevent this from occurring, modern diesel engines are designed with glow plugs. These little electric heaters are placed inside the cylinders to assist ignition.
4. Chemical energy converts into mechanical energy – as mentioned earlier, the energy stored in fuels converts to heat, which causes air to expand and push the pistons.
5. Reciprocating motion converts into rotary motion – the reciprocating motion of the pistons is converted into rotary motion by the crankshaft.
6. Waste gases exit and fresh air gets in – the exhaust gases are expelled and fresh air and fuel are let in.
This is a repeating cycle of compressed air ignition, fuel combustion, energy conversion, motion conversion, and exhaust expulsion. The details of how pistons work and the phases of the power cycle in diesel engines will be covered more thoroughly under the next heading.
The Power Cycle in Diesel Engines
There are four phases or strokes to a diesel engine’s power cycle. Each phase is differentiated by the position of the piston and how that position affects the power cycle.
- Piston: Starts from the top, moves downward to the bottom
- Valve: Inlet valve opens
The piston starts from the top dead center (TDC) and moves downward to the bottom dead center (BDC). This movement creates a low-pressure area (or partial vacuum) in the cylinder. At the same moment, the intake valve opens and draws air in. The cylinder keeps getting filled a little bit past the BDC, and the piston starts to move back to the TDC. The intake valve slowly closes to seal off the air inside the cylinder.
- Piston: Rises from the bottom to the top
- Valve: Exhaust and inlet valves are closed
As the inlet valve is sealed tight and the piston rises to the TDC, the trapped air is squeezed up to 1/25 or 4% of the original volume it occupied. The extreme compression of air generates a tremendous amount of heat.
3. Power (with ignition event)
- Piston: Pushed from the top going down to the bottom
- Valve: Exhaust and inlet valves remain closed
The previous compression stroke creates a condition that causes instantaneous ignition with the injection of fuel. Combustion takes place rapidly and energy is released as heat. This causes air expansion which in turn pushes the piston to the BDC position, while both the inlet and outlet valves remain closed. The power from the piston is transferred as torque to the crankshaft via a connecting rod.
- Piston: Moves from the bottom going up to the top
- Valve: Exhaust valve opens
This stroke takes place with the expulsion of spent gases out of the chamber. The exhaust valve opens and the piston is pushed back to the TDC. The exhaust stroke signals the completion of one power cycle.
Two-stroke versus Four-stroke Engines
Diesel engines are designed to work either as two-stroke or four-stroke engines. Understanding how these designs work in diesel engines will make it so much easier for you to understand how diesel engines work.
The four-stroke engine
The first four-stroke engine was patented in 1876 by Nikolaus Otto. It used the principle of charged compression ignition and came before the invention of the diesel IC engine. In a four-stroke engine, the piston completes all the four phases—intake, compression, ignition, and exhaust—and turns the crankshaft twice.
Here’s how the crankshaft revolves in relation to the four phases:
- Intake – the inlet valve opens, the piston goes down, and the crankshaft turns 180 degrees.
- Compression – all valves are closed, the piston goes up, and the crankshaft completes the first revolution or 360 degrees.
- Power – all valves remain closed, the piston goes down, and the crankshaft turns another 180 degrees.
- Exhaust – the outlet valve opens, the piston goes up, and the crankshaft completes the second revolution or 720 degrees.
The two-stroke engine
In 1879, Karl Benz patented the first two-stroke gas engine. Diesel engines that use a two-stroke cycle have a simpler mechanism than the four-stroke type but involve more complex thermodynamics and aerodynamics. In two-stroke diesel engines, all four phases of the cycle take place in one crankshaft revolution as opposed to two revolutions in the four-stroke diesel engine.
Some of the phases occur simultaneously in a two-stroke engine which is how it completes a full cycle with only one revolution. This is how the phases occur in relation to the revolution of the crankshaft:
- Power, exhaust, and inlet strokes – the piston starts from the top. Diesel fuel is injected into the highly-compressed air in the cylinder and causes instantaneous ignition. Fuel combustion causes gas expansion which pushes the pistons downward.
As the piston travels downward, all the exhaust valves open and exhaust gases rush out. As the piston reaches the bottom, inlet ports along the cylinder are uncovered and fresh charged air gets in. At this point, the crankshaft makes half a revolution (or 180 degrees).
- Compression stroke – the valves close, while the piston starts to go up, covering the inlet ports and compressing air. The cycle is completed with one full revolution. The piston reaches the top and starts another power cycle again.
Since a two-stroke type of diesel engine completes a power cycle in a single revolution, it has the potential of producing twice the power that a four-stroke type produces. For this reason, many high-power engines are built using the two-stroke concept.
The layout of a two-stroke engine is necessarily different from a four-stroke type. It has at least two exhaust valves on top of the cylinder. The inlet ports along the cylinder wall are alternately covered and exposed with the upward and downward movement of the piston. Turbochargers are used to pressurize the intake air.
To ensure the peak performance of a diesel engine, it is important to know its parts and understand how each part works. We hope this article has helped you as you learn more about diesel engines.