Effect of the operation strategy and spark plug conditions on the torque output of a hydrogen port fuel injection engine

In this research, combustion characteristics of gasoline compression ignition engines have been analyzed numerically and experimentally with the aim of expanding the high load operation limit. The mechanism limiting high load operation under homogeneous charge compression ignition (HCCI) combustion was clarified. It was confirmed that retarding the combustion timing from top dead center (TDC) is an effective way to prevent knocking. However, with retarded combustion, combustion timing is substantially influenced by cycle-to-cycle variation of in-cylinder conditions. Therefore, an ignition timing control method is required to achieve stable retarded combustion. Using numerical analysis, it was found that ignition timing control could be achieved by creating a fuel-rich zone at the center of the cylinder. The fuel-rich zone works as an ignition source to ignite the surrounding fuel-lean zone. In this way, combustion consists of two separate auto-ignitions and is thus called two-step combustion. In the simulation, the high load operation limit was expanded using two-step combustion. An engine system identical to a direct-injection gasoline (DIG) engine was then used to validate two-step combustion experimentally. An air-fuel distribution was created by splitting fuel injection into first and second injections. The spark plug was used to ignite the first combustion. This combustion process might better be called spark-ignited compression ignition combustion (SI-CI combustion). Using the spark plug, stable two-step combustion was achieved, thereby validating a means of expanding the operation limit of gasoline compression ignition engines toward a higher load range.

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Three-dimensional numerical investigation on wall film formation and evaporation in port fuel injection engines

Numerical Heat Transfer Part A Applications ◽

10.1080/10407782.2016.1139960 ◽

2016 ◽

Vol 69 (12) ◽

pp. 1405-1422 ◽

Cited By ~ 7

Author(s):

Hong Liu ◽

Yan’an Yan ◽

Ming Jia ◽

Maozhao Xie ◽

Chia-fon F. Lee

Keyword(s):

Numerical Investigation ◽

Fuel Injection ◽

Film Formation ◽

Three Dimensional ◽

Port Fuel Injection ◽

Wall Film

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Gain-Scheduling Control of Port-Fuel-Injection Processes

SpringerBriefs in Electrical and Computer Engineering - Linear Parameter-Varying Control for Engineering Applications ◽

10.1007/978-1-4471-5040-4_4 ◽

2013 ◽

pp. 39-78

Author(s):

Andrew P. White ◽

Guoming Zhu ◽

Jongeun Choi

Keyword(s):

Fuel Injection ◽

Gain Scheduling ◽

Port Fuel Injection ◽

Gain Scheduling Control

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ANALISIS PENGKONSUMSIAN BAHAN BAKAR SISTEM SFI (SEQUENTIAL MULTI PORT FUEL INJECTION) PADA MESIN TIGA SILINDER 1000 CC

Jurnal Teknik ◽

10.31000/jt.v8i2.1506 ◽

2019 ◽

Vol 8 (2) ◽

Author(s):

Amir Amir ◽

Ali Rosyidin

Keyword(s):

Fuel Injection ◽

Port Fuel Injection

Motor bakar merupakan salah satu mesin kalor yang banyak digunakan sebagai alat penggerak mula. Kemajuan teknologi menjadikan tingkat kebutuhan penggunaan motor bakar semakin meningkat, tetapi berbanding terbalik dengan adanya persediaan bahan bakar daripada motor bakar tersebut. Sistem injeksi dirancang untuk mendapatkan nilai yang mendekati ideal pada kondisi mesin. Bahan bakar diinjeksikan dan dalam jumlah yang sudah tepat, sesuai dengan jumlah udara yang masuk ke dalam intake manifold.Semakin lama waktu pemakain suatu mesin, maka akan semakin menurun kemampuan mesin tersebut, dan akan semakin banyak bahan bakar yang hatus dikomsumsi untuk menghasilkan daya yang besar untuk mengatasi diperlukan Inovasi teknologi menggunakan SFI (Sequential multi port Fuel Injection) merujuk kepada gambaran performance dari kinerja yang diperhatikan kebutuhan penggunaan mesin tersebut, diperlukan perawatan secara berkala dan untuk menghemat pengkomsumsian bahan bakar. SFI(Sequential multi port Fuel Injection) Engine menyediakan kira-kira 10% tenaga putaran yang lebih besar setiap kali melakukan percepatan.Kata kunci : Motor Bakar, Fuel Injection, Performance

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Comparison of Gasoline Direct-Injection (GDI) and Port Fuel Injection (PFI) Vehicle Emissions: Emission Certification Standards, Cold-Start, Secondary Organic Aerosol Formation Potential, and Potential Climate Impacts

Environmental Science & Technology ◽

10.1021/acs.est.6b06509 ◽

2017 ◽

Vol 51 (11) ◽

pp. 6542-6552 ◽

Cited By ~ 89

Author(s):

Georges Saliba ◽

Rawad Saleh ◽

Yunliang Zhao ◽

Albert A. Presto ◽

Andrew T. Lambe ◽

...

Keyword(s):

Vehicle Emissions ◽

Fuel Injection ◽

Secondary Organic Aerosol ◽

Direct Injection ◽

Organic Aerosol ◽

Climate Impacts ◽

Gasoline Direct Injection ◽

Aerosol Formation ◽

Port Fuel Injection ◽

Certification Standards

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Comparison of primary aerosol emission and secondary aerosol formation from gasoline direct injection and port fuel injection vehicles

Atmospheric Chemistry and Physics ◽

10.5194/acp-18-9011-2018 ◽

2018 ◽

Vol 18 (12) ◽

pp. 9011-9023 ◽

Cited By ~ 18

Author(s):

Zhuofei Du ◽

Min Hu ◽

Jianfei Peng ◽

Wenbin Zhang ◽

Jing Zheng ◽

...

Keyword(s):

Volatile Organic Compounds ◽

Organic Compounds ◽

Fuel Injection ◽

Direct Injection ◽

Gasoline Direct Injection ◽

Vehicle Exhaust ◽

Port Fuel Injection ◽

Gasoline Vehicles ◽

Volatile Organic ◽

The Impact

Abstract. Gasoline vehicles significantly contribute to urban particulate matter (PM) pollution. Gasoline direct injection (GDI) engines, known for their higher fuel efficiency than that of port fuel injection (PFI) engines, have been increasingly employed in new gasoline vehicles. However, the impact of this trend on air quality is still poorly understood. Here, we investigated both primary emissions and secondary organic aerosol (SOA) formation from a GDI and a PFI vehicle under an urban-like driving condition, using combined approaches involving chassis dynamometer measurements and an environmental chamber simulation. The PFI vehicle emits slightly more volatile organic compounds, e.g., benzene and toluene, whereas the GDI vehicle emits more particulate components, e.g., total PM, elemental carbon, primary organic aerosols and polycyclic aromatic hydrocarbons. Strikingly, we found a much higher SOA production (by a factor of approximately 2.7) from the exhaust of the GDI vehicle than that of the PFI vehicle under the same conditions. More importantly, the higher SOA production found in the GDI vehicle exhaust occurs concurrently with lower concentrations of traditional SOA precursors, e.g., benzene and toluene, indicating a greater contribution of intermediate volatility organic compounds and semi-volatile organic compounds in the GDI vehicle exhaust to the SOA formation. Our results highlight the considerable potential contribution of GDI vehicles to urban air pollution in the future.

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