Mixing controlled compression ignition with methanol: An experimental study of injection and EGR strategy

Gainey, Brian; Gandolfo, John; Yan, Zeng; Lawler, Benjamin

doi:10.1177/14680874221105161

Cited by 5 publications

(4 citation statements)

References 30 publications

(34 reference statements)

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“…The ECU used in the experiment was manufactured by BOSCH, model ME788. The Methanol flow control unit (13) controlled the flow of methanol into the methanol dissociating device (1) based on engine information provided by ECU (14).…”

Section: Methodsmentioning

confidence: 99%

“…Methanol, with a hydrogen mass fraction of 12.5%, is also considered a promising liquid hydrogen carrier due to its ability to conveniently and efficiently produce hydrogen through methods such as dissociating or reforming. 13 Hydrogen has a very high flame speed. 14 Adding hydrogen to the engine can shorten the flame development period, leading to earlier heat release.…”

Section: Introductionmentioning

confidence: 99%

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Study on methanol-hydrogen engine in extended-range electric vehicles

Jiang,

Zhang,

Zhang

et al. 2024

International Journal of Engine Research

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The demand for clean and efficient new vehicle models is steadily increasing. Methanol-hydrogen engines use methanol as the main fuel and can recover the heat from engine exhaust to dissociate part of methanol into hydrogen-rich syngas. The syngas is recirculated back into the engine cylinder to improve combustion. Therefore, methanol-hydrogen engines have a higher energy utilization efficiency. This paper designed a methanol-hydrogen engine system based on a Miller cycle methanol engine. Bench tests showed that combusting methanol and dissociated methanol gas together could accelerate the fuel burn rate and improve the engine’s fuel economy. At a fixed engine speed of 2500 r/min, the BSFC of the methanol-hydrogen engine was reduced up to 5.55% compared to the original methanol engine. Further, a methanol-hydrogen extended-range electric vehicle powertrain model was built in Simulink. Simulation results indicated that, under the WTLC cycle, the methanol-hydrogen engine achieved a 22.60% reduction in fuel consumption per 100 km and saved 58.89% in fuel costs compared to the conventional gasoline engine. The methanol-hydrogen engine presented potential application in the extended-range electric vehicle.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Study on methanol-hydrogen engine in extended-range electric vehicles

Jiang,

Zhang,

Zhang

et al. 2024

International Journal of Engine Research

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“…Gainey et al [93] conducted experiments with methanol CI utilizing EGR on a 0.423 L single-cylinder research engine at medium to high loads, employing a standard diesel CR of 16. Their findings indicated a decrease in engine-out NO x emissions with increasing EGR, accompanied by an elongation of the heat release and a slight reduction in efficiency.…”

Section: Egrmentioning

confidence: 99%

“…One possibility is employing a pilot injection alongside a larger main injection to spread out the cooling effect induced by methanol injection while utilizing the pilot as a means to preheat the combustion chamber, thereby facilitating the ignition of the main injection. Gainey et al [93] demonstrated that advancing both the pilot and main injections could positively influence efficiency, provided that excessive fuel does not combust before TDC. Additionally, they highlighted the significance of pilot size, emphasizing that an insufficiently sized pilot might fail to adequately assist the main injection in ignition.…”

Section: Pilot Injectionmentioning

confidence: 99%

Renewable Methanol as a Fuel for Heavy-Duty Engines: A Review of Technologies Enabling Single-Fuel Solutions

Pu,

Dejaegere,

Svensson

et al. 2024

Energies

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To meet climate targets, a global shift away from fossil fuels is essential. For sectors where electrification is impractical, it is crucial to find sustainable energy carriers. Renewable methanol is widely considered a promising fuel for powering heavy-duty applications like shipping, freight transport, agriculture, and industrial machines due to its various sustainable production methods. While current technological efforts focus mainly on dual-fuel engines in shipping, future progress hinges on single-fuel solutions using renewable methanol to achieve net-zero goals in the heavy-duty sector. This review examines the research status of technologies enabling methanol as the sole fuel for heavy-duty applications. Three main categories emerged from the literature: spark-ignition, compression-ignition, and pre-chamber systems. Each concept’s operational principles and characteristics regarding efficiency, stability, and emissions were analyzed. Spark-ignition concepts are a proven and cost-effective solution with high maturity. However, they face limitations due to knock issues, restricting power output with larger bore sizes. Compression-ignition concepts inherently do not suffer from end-gas autoignition, but encounter challenges related to ignitability due to the low cetane number of methanol. Nonetheless, various methods for achieving autoignition of methanol exist. To obtain stable combustion at all load points, a combination of techniques will be required. Pre-chamber technology, despite its lower maturity, holds promise for extending the knock limit and enhancing efficiency by acting as a distributed ignition source. Furthermore, mixing-controlled pre-chamber concepts show potential for eliminating knock and the associated size and power limitations. The review concludes by comparing each technology and identifying research gaps for future work.

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