• Title/Summary/Keyword: Gasoline Direct Injection

Search Result 188, Processing Time 0.022 seconds

An Experimental Study on the Stratified Combustion Characteristics in a Direction Injection Gasoline Engine (직접 분사식 가솔린 엔진을 이용한 성층 연소 특성에 관한 실험적 연구)

  • Lee, Chang-Hee;Lee, Ki-Hyung;Lim, Kyoung-Bin;Kim, Bong-Gyu
    • Transactions of the Korean Society of Automotive Engineers
    • /
    • v.14 no.2
    • /
    • pp.121-126
    • /
    • 2006
  • A gasoline-fueled stratified charge compression ignition (SCCI) engine with both direct fuel injection and intake temperature and compression ratio was examined. The fuel was injected directly by using the high temperature resulting from heating intake port. With this injection strategy, the SCCI combustion region was expanded dramatically without any increase in NOx emissions which were seen in the case of compression stroke injection. Injection timing during the intake temperature was found to be an important parameter that affects the SCCI region width. The effect of mixture stratification and the effect of fuel reformation can be utilized to reduce the required intake temperature for suitable SCCI combustion under each set of engine speed and compression ratio conditions.

Simulation Injection Mass with Variable Injection Condition in GDI Engine using AMESim (AMESim을 이용한, GDI 엔진에서 연료의 분사조건 변화에 따른 분사량 변화 예측)

  • Shin, Suk Shin;Song, Jingeun;Park, Jongho
    • Journal of ILASS-Korea
    • /
    • v.18 no.1
    • /
    • pp.61-65
    • /
    • 2013
  • In case of GDI engine, shape of injected fuel and injection mass are one of the most important factors for good fuel efficiency and power. But it should be too inefficient and difficult to acquire injection mass data by experiment because condition in engine vary with temperature, pressure, and so on. So, this paper suggests the AMESim (Advanced Modeling Environment for Simulation of Engineering Systems) as simulation program to calculate injection mass. For both simulation and experiment, n-heptane is used as fuel. In AMESim, I modeled the GDI injector and simulated several cases. In experiment, I acquired the injection mass using Bosch method to apply ambient pressure. The AMESim show reasonable result in comparison with experimental data especially at injection pressure 15 MPa. Other conditions are also in good accord with experimental data but error is a little bit large because the injection mass is so low.

A direct injection gasoline engine (실린더내 분사 가솔린 엔진)

  • 조진호
    • Journal of the korean Society of Automotive Engineers
    • /
    • v.18 no.3
    • /
    • pp.1-7
    • /
    • 1996
  • 이상 소개한 바와 같이 미쓰비시의 경우 현상의 기술로서도 실린더내 분사는 4l 클래스 엔진까지 확대가능하고 앞으로 더욱 엄격해질 배출가스의 규제와 저연비의 요구로 디젤엔진에 대신하여 소형트럭에까지 탑제가 확대될 것으로 추측된다. 그리고 이와 같은 초희박연소에 의한 저연비와 체적효율 향상에 따른 고출력의 양립은 지구환경보호측면에서도 크게 기대할 새로운 기술의 개가라 할수 있을 것이다.

  • PDF

A Study on Engine Performance Characteristics with Variation of Operating Condition in Diesel Engine (디젤엔진의 운전인자 변화에 따른 엔진의 성능특성에 관한 연구)

  • Kim, GiBok
    • Journal of the Korean Society of Industry Convergence
    • /
    • v.23 no.4_2
    • /
    • pp.645-651
    • /
    • 2020
  • In this study, It is necessary that we should study on more effective use about reciprocating engines because there are huge increase of air pollution. Diesel Engine is operated by injecting fuel directly to combustion chamber with high pressure. Diesel Engine has greater thermal efficiency and durability than Gasoline Engine. Also, Diesel Engine emitted low harmful exhaust witch caused by Gasoline Engine. There are many ways to improve of performance and decrease of harmful exhaust by controlling injection timing, changing amount of fuel and engine speed and so on. Especially, development and application of common rail direct injection Engine cause the increase of thermal efficiency by controlling a various of operating conditions. In this study we analyze characteristics of performance by changing a various of operating conditions.

An Study on Spray and Combustion Characteristics of Direct Injection LPG under Low Pressure Injection Condition (저압 분사조건에 따른 직접분사 LPG의 분무 및 연소특성 연구)

  • Hwang, Seong-Ill;Chung, Sung-Sik;Yeom, Jeong-Kuk;Lee, Jin-Hyun
    • Journal of the Korean Institute of Gas
    • /
    • v.20 no.1
    • /
    • pp.52-61
    • /
    • 2016
  • Liquefied petroleum gas is regarded as a promising alternative fuel as it is eco-friendly, has good energy efficiency and output performance, practically and has high cost competitiveness over competing fuels. In spark-ignition engine, direct injection technology improves engine volumetric efficiency apparently and operates engine using the stratified charge that has relatively higher combustion efficiency. This study designed a combustion chamber equipped with visualization system by applying gasoline direct injection engine principle. In doing so, the study recorded and analyzed ignition probability and flame propagation process of spark-ignited direct injection LPG in a digital way. The result can contribute as a basic resource widespread for spark-ignited direct injection LPG engine design and optimization extensively.

A Experimental Study on the Effects of the Impingement-wall on the Spray and Combustion Characteristics of Direct-Injection LPG (충돌벽면이 직분식 LPG의 분무 및 연소 특성에 미치는 영향에 관한 실험 연구)

  • Hwang, Seong-Ill;Chung, Sung-Sik;Yeom, Jeong-Kuk
    • Journal of Power System Engineering
    • /
    • v.19 no.2
    • /
    • pp.49-56
    • /
    • 2015
  • As an alternative fuel that can be used in SI engine, LPG is one of clean fuels with larger H/C ratio compared to gasoline, low $CO_2$ emission, and small amount of pollutants such as sulfur compounds. When LPG is used in spark ignition engine, volumetric efficiency of the engine can be improved and pumping loss can be reduced by performing direct injection into the combustion chamber instead of port fuel injection. LPG-DI engine allows for lean combustion and stratified combustion under low load. In case of stratified combustion, air fuel ratio can be greatly increased compared to theoretic mixture ratio combustion. Improved thermal efficiency of the engine and reduced pumping loss can be expected from stratified combustion. Accordingly in this study, an experimental apparatus for visualization was designed and manufactured to study the combustion process of LPG after injection and ignition, intended to examine ignition probability and combustion characteristics of spark ignition direct injection(SIDI) LPG fuel. Ambient pressure, ambient temperature and fuel injection pressure were found as important variables that affect ignition probability and flame propagation characteristics of LPG-air mixture. Also, it was verified that the injected LPG fuel can be directly ignited by spark plug under appropriate ambient conditions.

An Experimental Study on the Spray and Lean Combustion Characteristics of Bio-enthanol-Gasoline Blended Fuel of GDI (직접분사식 바이오에탄올-가솔린 혼합연료의 분무 및 희박연소 특성에 관한 실험적 연구)

  • Park, Gi-Young;Kang, Seok-Ho;Kim, In-Gu;Lim, Cheol-Soo;Kim, Jae-Man;Cho, Yong-Seok;Lee, Seong-Wock
    • Journal of ILASS-Korea
    • /
    • v.19 no.3
    • /
    • pp.115-122
    • /
    • 2014
  • As a demand for an automobile increases, air pollution and a problem of the energy resources come to the fore in the world. Consequently, governments of every country established ordinances for green-house gas reduction and improvement of air pollution problem. Especially, as international oil price increases, engine using clean energy are being developed competitively with alternative transportation energy sources development policy as the center. Bio ethanol, one of the renewable energy produced from biomass, gained spotlight for transportation energy sources. Studies are in progress to improve fuel supply methods and combustion methods which are key features, one of the engine technologies. DI(Direct Injection), which can reduce fuel consumption rate by injecting fuel directly into the cylinder, is being studied for Green-house gas reduction and fuel economy enhancement at SI(Spark Ignition). GDI(Galoine Direct Injection) has an advantage to meet the regulations for fuel efficiency and $CO_2$ emissions. However it produces increased number of ultrafine particles, that yet received attention in the existing port-injection system, and NOX. As fuel is injected into the cylinder with high-pressure, a proper injection strategy is required by characteristics of a fuel. Especially, when alcohol type fuel is considered. In this study, we tried to get a base data bio-ethanol mixture in GDI, and combustion for optimization. We set fuel mixture rate and fuel injection pressure as parameters and took a picture with a high speed camera after gasoline-ethanol mixture fuel was injected into a constant volume combustion chamber. We figured out spraying characteristic according to parameters. Also, we determine combustion characteristics by measuring emissions and analyzing combustion.

Measurement and Prediction of Spray Targeting Points according to Injector Parameter and Injection Condition (인젝터 설계변수 및 분사조건에 따른 분무타겟팅 지점의 측정 및 예측)

  • Mengzhao Chang;Bo Zhou;Suhan Park
    • Journal of ILASS-Korea
    • /
    • v.28 no.1
    • /
    • pp.1-9
    • /
    • 2023
  • In the cylinder of gasoline direct injection engines, the spray targeting from injectors is of great significance for fuel consumption and pollutant emissions. The automotive industry is putting a lot of effort into improving injector targeting accuracy. To improve the targeting accuracy of injectors, it is necessary to develop models that can predict the spray targeting positions. When developing spray targeting models, the most used technique is computational fluid dynamics (CFD). Recently, due to the superiority of machine learning in prediction accuracy, the application of machine learning in this field is also receiving constant attention. The purpose of this study is to build a machine learning model that can accurately predict spray targeting based on the design parameters of injectors. To achieve this goal, this study firstly used laser sheet beam visualization equipment to obtain many spray cross-sectional images of injectors with different parameters at different injection pressures and measurement planes. The spray images were processed by MATLAB code to get the targeting coordinates of sprays. A total of four models were used for the prediction of spray targeting coordinates, namely ANN, LSTM, Conv1D and Conv1D & LSTM. Features fed into the machine learning model include injector design parameters, injection conditions, and measurement planes. Labels to be output from the model are spray targeting coordinates. In addition, the spray data of 7 injectors were used for model training, and the spray data of the remaining one injector were used for model performance verification. Finally, the prediction performance of the model was evaluated by R2 and RMSE. It is found that the Conv1D&LSTM model has the highest accuracy in predicting the spray targeting coordinates, which can reach 98%. In addition, the prediction bias of the model becomes larger as the distance from the injector tip increases.

The Effects of Tumble and Swirl Flow on the Behavior of Liquid/Vapor Phases in a DI Gasoline Engine (직분식 엔진에서 실린더 내 연료의 액.기상 거동에 미치는 텀블과 스월의 영향)

  • 강정중;최동석;김덕줄
    • Transactions of the Korean Society of Automotive Engineers
    • /
    • v.10 no.2
    • /
    • pp.23-30
    • /
    • 2002
  • This present study experimentally investigates the behavior of liquid and vapor phase of fuel mixtures with changing the in-cylinder air motion in an optically accessible engine. The conventional MPI/DOHC engine was modified to gasoline direct injection engine with swirl motion. The images of liquid and vapor phases were captured in the motoring operation condition using exciplex fluorescence method. Two dimensional spray fluorescence images of liquid and vapor phases were acquired to analyze spray behaviors and fuel distribution inside of cylinder respectively, In early injection timings $(BTDC\;270^{\circ},\;180^{\circ})$, tumble flow transported most of vapor phase to the lower region and the both sides of cylinder, so vapor phase didn't become uniform distribution up to the half of the compression stroke. In the case of swirl flow, the fuel mixture was confined near the swirl origin in upper region of cylinder. In late injection timings $(BTDC\;90^{\circ})$, tumble flow transported vapor phase to the intake valve and swirl flow to the exhaust valve.