Your search keyword '"Yaoting Li"' showing total 6 results

1. Biodiesel/butanol blends as a pure biofuel excluding fossil fuels: Effects on diesel engine combustion, performance, and emission characteristics

Author

Yongcheng Huang, Kun Luo, Jiyuan Wang, and Yaoting Li

Subjects

Alcohol fuel, Biodiesel, Waste management, business.industry, 020209 energy, Mechanical Engineering, Fossil fuel, Aerospace Engineering, 02 engineering and technology, Combustion, Diesel engine, Renewable energy, Diesel fuel, 020401 chemical engineering, Biofuel, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0204 chemical engineering, business

Abstract

Although both biodiesel and n-butanol are excellent renewable biofuels, most of the existing research works merely use them as the additives for petroleum diesel. As the main fuel properties of biodiesel and n-butanol are complementary, the biodiesel/ n-butanol blends are promising to be a pure biomass-based substitute for diesel fuel. In this paper, the application of the biodiesel/ n-butanol blends on an agricultural diesel engine was comprehensively investigated, in terms of the combustion, performance, and emission characteristics. First, the biodiesel/ n-butanol blends with 10%, 20%, and 30% n-butanol by weight were prepared and noted as BBu10 (10 wt% n-butanol + 90 wt% biodiesel), BBu20 (20 wt% n-butanol + 80 wt% biodiesel), and BBu30 (30 wt% n-butanol + 70 wt% biodiesel). It was found that adding 30 wt% n-butanol to biodiesel can reduce the viscosity by 39.3% and increase the latent heat of vaporization by 57.3%. Then the engine test results showed that with the addition of n-butanol to biodiesel, the peak values of the cylinder pressure and temperature of the biodiesel/ n-butanol blends were slightly decreased, the peak values of the pressure rise rate and heat release rate of the blends were increased, the fuel ignition was delayed, and the combustion duration was shortened. BBu20 has the approximate ignition characteristics with diesel fuel. Both the brake thermal efficiency and the brake-specific fuel consumption of BBu30 were increased by the average percentages of 2.7% and 14.9%, while NO x, soot, and CO emissions of BBu30 were reduced by the average percentages of 17.6%, 34.1%, and 15.4%, compared to biodiesel. The above variations became more evident as the n-butanol proportion increased.

Published

2020

2. Investigation on fuel properties and engine performance of the extraction phase liquid of bio-oil/biodiesel blends

Author

Yaoting Li, Jiating Zhang, Yongcheng Huang, Xudong Han, Kun Luo, Jiyuan Wang, and Shangsheng Yang

Subjects

Biodiesel, Thermogravimetric analysis, Materials science, 060102 archaeology, Renewable Energy, Sustainability and the Environment, 020209 energy, Extraction (chemistry), 06 humanities and the arts, 02 engineering and technology, medicine.disease_cause, Diesel engine, Combustion, Soot, Chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, medicine, 0601 history and archaeology, Heat of combustion, NOx

Abstract

In this paper, biodiesel was used to upgrade bio-oil by extracting the high-quality fuel fractions in bio-oil through solvent extraction. After the extraction, the upper layer blends of biodiesel and the high-quality bio-oil components, also called the “extraction phase liquid”, was obtained and denoted as EPBB. Firstly, Thermogravimetric (TG) and Fourier transform infrared (FTIR) analyses indicated that the light components originally in bio-oil, such as alcohols, ethers, ketones and carboxylic acids were extracted from bio-oil to biodiesel and formed the EPBB. Then the fuel properties of EPBB were measured at different temperatures. The results showed that the density of EPBB was higher, while its viscosity, surface tension and lower heating value (LHV) were lower than those of biodiesel. Accordingly, EPBB revealed better atomization and evaporation characteristics as compared to biodiesel. Finally, the engine performance of EPBB was tested on an unmodified direct-injection diesel engine. When compared with biodiesel, the ignition delay of EPBB was longer, the premixed combustion duration was longer, while the total combustion duration was shorter. The fuel economy of EPBB was comparable to that of biodiesel, and the NOx, soot, CO and UHC emissions of EPBB were all lower than those of biodiesel.

Published

2020

3. Development and validation of an improved atomization model for GDI spray simulations: Coupling effects of nozzle-generated turbulence and aerodynamic force

Author

Yongcheng Huang, Bin Lei, Kun Luo, Yaoting Li, and Mengmeng Liang

Subjects

Materials science, Characteristic length, Turbulence, 020209 energy, General Chemical Engineering, Sauter mean diameter, Organic Chemistry, Nozzle, Energy Engineering and Power Technology, 02 engineering and technology, Injector, Mechanics, Breakup, law.invention, Aerodynamic force, Fuel Technology, 020401 chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Ambient pressure

Abstract

By coupling the Wu-Faeth (WF) turbulent primary breakup theory with the classical Kelvin-Helmholtz (KH) and Rayleigh-Taylor (RT) aerodynamic instability theories, the influences of nozzle-generated turbulence and aerodynamic force on the GDI spray atomization were both modeled in this study. The developed WF-KH-RT model was applied to the spray simulation of a six-hole GDI injector. The model calibration showed that with a simple tuning of a few model parameters, the WF-KH-RT model could predict the spray morphology, spray tip penetration (STP) and Sauter Mean Diameter (SMD) under various injection pressure and ambient pressure conditions with a high fidelity. The influences of specific WF-KH-RT model parameters on the spray simulation were also studied. The results revealed that increasing the KH characteristic time constant B1, WF characteristic length constant Csx and RT characteristic length constant CRT will lead to the increase of STP and SMD under most conditions. As the ratio of fuel density to ambient density ρ f / ρ g decreases, the aerodynamic effect is enhanced while the turbulent effect is weakened in the primary breakup, as a result the sensitivity of STP and SMD to B1 increases, while that to Csx declines. In summary, the results of this study can provide an insight into the relationship between different mechanisms affecting the fuel spray atomization, and an instruction of calibrating the proposed novel atomization model in GDI engine spray simulations.

Published

2021

4. 3D simulation study on the influence of lubricant oil droplets on pre-ignition in turbocharged DISI engines

Author

Fansheng Meng, Zhechen Guo, Wenjia Zhang, Yongcheng Huang, and Yaoting Li

Subjects

Materials science, Kinetic model, 020209 energy, Mechanical Engineering, Aerospace Engineering, 02 engineering and technology, Mechanics, 3d simulation, Automotive engineering, law.invention, Ignition system, 020303 mechanical engineering & transports, 0203 mechanical engineering, law, Flame propagation, Oil droplet, 0202 electrical engineering, electronic engineering, information engineering, Lubricant, Turbocharger

Abstract

A skeletal chemical kinetic model for the simulation of auto-ignition and flame propagation characteristics of primary reference fuel (PRF) was developed. Coupled with this model, 3D simulations were applied to investigate the influence of lubricant oil droplets on pre-ignition in a turbocharged direct-injection spark-ignition (DISI) engine at low-speed high-load operating conditions. First, a simulation study on the influence of a lubricant oil droplet on auto-ignition of gasoline substitute and air mixture was performed in a constant-volume chamber. The results revealed that with an increase of the lubricant oil droplet diameter, the ignition delay time for the air/fuel mixture initially decreased and then increased. The ignition delay time was further shortened with the increase of the temperature of the lubricant oil droplet and the temperature and pressure of the mixture. Moreover, it was found that when n-heptane (n-C7H16) was used as a substitute for the direct evaporation product of the lubricant oil droplet, the shortening of the ignition delay time for the air/fuel mixture caused by lubricant oil evaporation was not enough to initiate pre-ignition. When octyl hydrogen peroxide ketone (C8KET) was chosen as a representative of the accumulated stable reactive radicals, the ignition delay time was significantly shortened and was short enough to trigger pre-ignition. Therefore, pre-ignition may not be induced by the direct evaporation product of an lubricant oil droplet but by the accumulated stable reactive radicals. A simulation study on auto-ignition and flame propagation of the air/fuel mixture with the presence of a lubricant oil droplet was then conducted in a turbocharged DISI engine. The results successfully predicted the auto-ignition of the air/fuel mixture near the lubricant oil droplet before the spark ignition timing. Finally, a more convincing mechanism for pre-ignition induced by lubricant oil droplets is proposed to provide some clues for further investigation.

Published

2017

5. Experimental and Modeling Study on Ignition Characteristics of 2, 5-Dihydrofuran

Author

Xibin Wang, Xiangshan Fan, Ziqing Li, Chuanzhou Wu, Kangkang Yang, and Yaoting Li

Subjects

Materials science, 020209 energy, Strategy and Management, Mechanical Engineering, Nuclear engineering, Metals and Alloys, 02 engineering and technology, Industrial and Manufacturing Engineering, law.invention, Ignition system, 020401 chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering

Published

2016

6. A comprehensive experimental investigation on the PFI spray impingement: Effect of impingement geometry, cross-flow and wall temperature

Author

Yaoting Li, Chenglong Tang, Rixin Chen, Yongcheng Huang, Shangsheng Yang, and Kun Luo

Subjects

Materials science, 020401 chemical engineering, 020209 energy, Mie scattering, 0202 electrical engineering, electronic engineering, information engineering, Energy Engineering and Power Technology, Geometry, 02 engineering and technology, Penetration (firestop), 0204 chemical engineering, Leidenfrost effect, Industrial and Manufacturing Engineering, Port fuel injection

Abstract

In this work, an experimental study on the effects of the impingement geometry, the cross-flow intensity and the wall temperature on the characteristics of an impinging port fuel injection (PFI) spray was conducted. The transient development of the impinging spray was recorded by a high-speed camera with Mie scattering. Based on the high-speed images, the spray tip penetration (S) and the impinged spray height (Hw) were obtained. The results show that with the increase of the impingement distance (Lw), S increases and Hw decreases at the same time after the impingement. As the impingement angle (θw) increases, S decreases while Hw first increases and then decreases. With the increase of the cross-flow velocity (Uc), less part of the spray impinges onto the wall, and S significantly increases. As the wall temperature (Tw) rises, S does not show much variation. However, Hw increases gently for Tw lower than 420 K, and it increases sharply for Tw higher than 420 K due to the Leidenfrost mechanism. The effects of the above factors (Lw, θw, Uc, Tw) on S and Hw were finally evaluated and compared through the introduction of a contribution index.

Published

2019