Components of fuel systems in diesel, hydrogen ICE, natural gas and hydrogen fuel cell technologies

Fuel pump

The fuel system is a critical part of any engine, playing a pivotal role in powering vehicles efficiently and effectively. As fuel technologies evolve, a better understanding of the fuel system enables Original Equipment Manufacturers (OEMs) to meet their emission goals, optimize vehicle performance, ensure safety and comply with regulations.

 The fuel system is part of the powertrain and includes all components necessary for regulating fuel delivery to the engine. This includes: the fuel tank, pump, filter, injectors and sensors. On the other hand, the fuel delivery system and its components are a subset of the fuel system; it specifically focuses on components directly involved in delivering fuel from the tank to the engine.

This article looks at the key components of fuel systems across different engine types, including diesel ICE, hydrogen ICE, natural gas and hydrogen fuel cells.

 

Click on the 'blue' spots on this interactive and find out more about the components of a fuel system.
 

Components of the fuel system in diesel engines

Diesel engines are well-suited for use in heavy-duty applications due to their torque and durability. The fuel system in a diesel engine comprises several key components, including:

Filtration: Advanced filtration technology used in Cummins diesel engines removes contaminants such as debris and water from the fuel before it gets to the fuel injectors. Given the extreme fuel pressures in diesel engines and fine nozzle holes on injectors, fuel quality can significantly affect engine performance and longevity.

Fuel Pumps: Diesel engines commonly use multiple fuel pumps: The low-pressure pump pulls fuel from the tank and delivers it to the high-pressure pump, which then pressurizes and regulates fuel flow to the injectors. In commercial trucks, these pumps are designed to ensure optimal fuel delivery in the most demanding driving conditions. The high-pressure pump is particularly critical in achieving the required injection pressure for efficient combustion.

Fuel Rail: The fuel rail is a manifold responsible for distributing fuel to the injectors. It ensures even and efficient delivery of fuel across all engine cylinders. Furthermore, the fuel rail enables the fuel system to deliver the optimal fuel pressure across a range of engine operating conditions, which is crucial for consistent engine performance and emissions reductions.

Pressure Sensor: Located in the fuel rail, these components are essential for maintaining the appropriate fuel pressure, which is critical for maintaining engine integrity and performance. The pressure sensor measures the fuel pressure and communicates with the engine control unit (ECU) to fire the injectors long enough to deliver the correct amount of fuel. The fuel pressure sensor can also be used to detect issues with the fuel system, such as leaks.

Mechanical Dump Valve: Many common rail diesel fuel systems have a mechanical dump valve (MDV) located in the fuel rail. The MDV is a spring-loaded valve that is forced open when fuel pressure exceeds a pre-set limit. It acts as a safety device to release pressure if it exceeds safe limits and protects the fuel system components from damage. Some diesel engines even possess electronic dump valves which can be used for improved fuel pressure control.

Fuel Injectors: Fuel injectors deliver precise amounts of fuel into the combustion chamber with spray patterns that ensure optimal mixing of fuel and air. This precision is vital for efficient combustion, maximizing fuel efficiency and reducing emissions. In commercial vehicles, the performance of fuel injectors directly impacts engine efficiency, power output and emission levels.

Plumbing: Both metallic and non-metallic fuel lines seal and transfer fuel throughout the system. Appropriately sized fuel plumbing is critical for meeting engine application demands and preventing leaks. In commercial vehicles, robust plumbing is essential to withstand the rigors of long-distance travel and varying operating conditions.

Components of the fuel system in natural gas and hydrogen ICE engines

Natural gas and hydrogen ICE engines will play a critical role in the shift to reducing emissions. One benefit of these engines is that they fit the same envelope as a diesel engine, requiring less change to the vehicle. Gaseous fuel systems have fewer components than an equivalent diesel fuel system but are still critical to delivering optimal performance and meeting stricter emissions.

Filtration: Filtration in natural gas and hydrogen ICE vehicles cleans the fuel and removes compressor oils. This is critical for the performance and longevity of the engine. For example, in natural gas-powered trucks, compressor oils adversely affect the fuel system.

On-engine Shut Off Valve and Pressure Regulator: Since natural gas and hydrogen engines are expected to deliver diesel-like performance, on-engine pressure regulators may be used to regulate the fuel pressure delivered to the injectors. This ensures accurate fueling at any engine operating condition. Shut-off valves may also be integrated into the regulator. These valves prevent fuel flow to the engine when the vehicle is shut off.

Injectors: Gaseous fuel injectors ensure the correct amount of fuel enters the combustion chamber. For instance, in hydrogen ICE vehicles, the injector is designed to handle the unique properties of hydrogen while still meeting engine performance demands.

Components of the fuel system in hydrogen fuel cell vehicles

Hydrogen fuel cells represent a cutting-edge approach to sustainable transportation. Their fuel systems include:

Fuel Injector / Proportion Control Valve: Fuel cells may opt for either an injector or proportional control valve to regulate the flow of hydrogen to the fuel cell stack. It ensures the precise amount of hydrogen is delivered to the stack to react with oxygen and generate electricity, which provides power to the vehicle.

Ejectors: These help to recirculate unused hydrogen back to the fuel cell stack. This is critical for increasing efficiency and ensuring durability of the fuel cell.

Hydrogen Re-circulation Pump: Working in conjunction with the ejector, this pump recirculates unused hydrogen from the fuel cell stack back into the system.

Purge Valve and Water Drain Valve: These components are responsible for removing excess water and non-hydrogen contents to maximize the efficiency of the system.

Pressure Relief Valve: This is a safety device that protects the fuel cell stack from excessive fuel pressure. It is a critical component in all hydrogen fuel cell vehicles for safe operations under all conditions.

Shut Off Valve: This valve allows fuel flow into the injector and acts as an on/off valve that closes when the engine is shut off.

The fuel system is an integral part of any engine; each component ensures the efficient and safe operation of the engine. Cummins is at the forefront of developing low-emissions engine technology. As technology advances and the demand for cleaner fuel options increases, understanding these components and how they optimize engine performance is vital.

Cummins Components Business Unit

Components Business Unit

Cummins Custompaks are being used for water management as Thailand struggles with its water crisis

CustomPak on site

Water crisis

Sixty Cummins Inc. CustomPaks are in service in Thailand as part of a critical water management plan aimed at easing the country’s water crisis – a crisis that has caused enormous economic and social damage and stirred conflict among communities.

Over the past several decades, Thailand has continually faced water problems caused by severe drought. Water reserves in dams and reservoirs are insufficient while water resources are often contaminated with toxins caused by urban communities and the industrial and agricultural sectors.

Severe flooding is a threat, too, at a time when the realities of climate change are hanging over the country.

As a result, the allocation of precious water resources, which must be shared among various stakeholders including new and existing industry, large and small agriculture, and cities and villages has become a flashpoint.

Kittithanapat Engineering Co. (KTP), has been involved in the water management system since 1996, working closely with authorities such as the Royal Irrigation Department, Department of Water Resources, Bangkok Metropolitan Authority and others.

CustomPaks on site

600 hp CustomPaks

To help KTP meet its often urgent requirements, Cummins DKSH (Thailand) has recently supplied 60 Australian-built CustomPaks – 45 powered by Cummins’ X15 engine rated at 600 hp, and 15 powered by the QSL9 rated at 325 hp. These fully self-contained powerpacks are emissions certified to Tier 3.

The CustomPaks are coupled to hydraulically-driven, large-volume submersible water pumps sourced by KTP from US company Moving Water Industries (MWI); KTP is the exclusive distributor in Thailand for these MWI Hydroflo pumps.

Prior to Cummins’ involvement, KTP was using another diesel engine brand but service support wasn’t up to the standard required.

Long-serving KTP engineer Kittisak Thanasoot says Cummins DKSH’s reputation for technical and aftersales support along with the reliability of the Cummins product were a key reason behind KTP’s decision to specify the CustomPaks for the Royal Irrigation Department.

The ability of Cummins DKSH to respond to short delivery times was also important.

“Supplying large quantities of high horsepower diesel engines for emergency situations such as flash flooding can be a challenge for KTP,” says Kittisak Thanasoot.

“Responding to the needs of the government agencies to manage such problems in a timely manner and with least impact on communities, KTP has found the answer in our partnership with Cummins DKSH.”

Power, pride and passion

Parked semi truck

The switch back to Cummins power has been beneficial for iconic New Zealand company Uhlenberg Haulage. It's all about whole-of-life costs.

Uhlenberg Haulage is closing in on 60 years in business, having been founded in 1966 by Mike and Carol Uhlenberg.

Based in Eltham, Taranaki, in New Zealand’s North Island, the operation is today owned and operated by their sons Chris, Daryl and Tony Uhlenberg.

Describing the Uhlenbergs as “old school family truckies”, Daryl talks about the company’s time-honored journey with a definite tone of pride, especially the work of his parents in laying the foundations for what is today an iconic fleet in its own right.

Cummins Inc. made its debut in the Uhlenberg fleet in 1971 with an NH250 powering a second-hand Kenworth K923 used in logging. A second Kenworth, a new W924 with a Cummins NTC335, followed soon after hauling an LPG tanker.

The Uhlenberg operation today comprises 40 prime movers and a variety of trailing gear to cater for the myriad of a jobs the fleet is involved in.

A number of Peterbilts feature in the fleet although Kenworth is now the brand of choice with six new units to be delivered over the next 12 months to cater for business growth.

Cummins’ X15 Euro 5 engine rated at 550 or 600 hp is the preferred power specification, with 18 red engines currently in the fleet.

Uhlenberg family in front of truck

Whole-of-life support

“The switch to Cummins has been a very good experience for us. We have nothing but praise for the Cummins organization,” says Daryl.

“The whole-of-life picture is the key thing for us and we’ve got that nailed with the support we get from Cummins – parts availability, scheduled maintenance, life expectancy and in-frame rebuilds.

“So the red engines turn up, we run them to life, which is 900,000 to 1.2 million kilometers, and then Cummins does an in-frame overhaul in a timely manner. If there’s an issue, parts and support are close by.

“The support we get from Cummins Palmerston North is fantastic, second to none.”

Daryl recently looked under a Kenworth that was in the workshop for a service and was surprised to see no oil leaking from the one-million-kilometer X15. “I remember when I was a fitter we had to wear a raincoat when working under a truck,” he jokes.

Fuel agnostic

Acknowledging that the push to decarbonize is now “very real”, Daryl likes the idea of Cummins’ fuel agnostic concept where one base internal combustion engine, optimized to run on diesel, can also be customized to run on ultra-low and zero-carbon fuels like renewable natural gas and hydrogen.

“My father was a pioneer of linehaul trucking in New Zealand and he always embraced new technology. He was never scared of it,” he says.

“I tend to be a little more cautious but I can see where a 500 hp natural gas or hydrogen engine would work for us in short haul applications,” he admits. “We’re certainly willing to look closely at these alternative fuel technologies when suitable infrastructure is in place.”

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