Predictive modeling of piston assembly lubrication in reciprocating internal combustion engines

Xu, Huijie,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2005. / Vita. Includes bibliographical references.

An on-board distillation system to reduce cold-start hydrocarbon emissions from gasoline internal combustion engines

Ashford, Marcus Demetris, Matthews, Ronald D.,

January 2004

Thesis (Ph. D.)--University of Texas at Austin, 2004. / Supervisor: Ronald Matthews. Vita. Includes bibliographical references. Also available from UMI.

Application of turbochargers in spark ignition passenger vehicles /

Bester, Wallace William.

January 2006

Thesis (MScIng)--University of Stellenbosch, 2006. / Bibliography. Also available via the Internet.

Experimental investigation into the physico-chemical properties changes of palm biodiesel under common rail diesel engine operation for the elucidation of metal corrosion and elastomer degradation in fuel delivery system

Chandran, Davannendran

January 2017

Compatibility of fuel delivery materials (FDM) with biodiesel fuel in the fuel delivery system (FDS) under real-life common rail diesel engine (CRDE) operation poses a challenge to researchers and engine manufacturers alike. Although standard methods such as ASTM G31 and ASTM D471 for metals and elastomers, respectively, are deemed suitable for evaluating the effects of water content, total acid number (TAN) and oxidation products in biodiesel on FDM degradation, they do not resemble the actual engine operation conditions such as varying fuel pressure/temperature as well as the presence of a wide range of materials in the FDS of a diesel engine. Hence, the current allowable maximum 20 vol% of biodiesel with 80 vol% of diesel (B20) for use in diesel engines to date is debatable. Additionally, biodiesel utilization beyond B20 is essential to combat declining air quality and to reduce the dependence on fuel imports. This thesis aims to elucidate the actual compatibility present between FDM and biodiesel in the FDS under real-life CRDE operation. This was achieved through multi-faceted experimentations which commenced with analyses on the deteriorated palm biodiesel samples collected during and after CRDE operation. Next, the fuel properties which should be emphasized based on the deteriorated fuel were determined. This was then followed by ascertaining the effects of the emphasized fuel properties towards FDM degradation. Ultimately, the actual compatibility of FDM with biodiesel under engine operation through modified immersion investigations was determined. FDM degradation acceleration factors such as oxidized biodiesel, TAN and water content were eliminated since these factors were not affected based on the analysed fuel samples collected after engine operation. No oxidation products such as aldehydes, ketones and carboxylic acids were detected while the TAN and water content were within 0.446% and 0.625% of their initial values, respectively. Instead, the biodiesel’s dissolved oxygen (DO) concentration and conductivity value were not only found to have changed during and after engine operation by -93% and 293%, respectively, but were also found to have influenced biodiesel deterioration under engine operation. These two properties were subsequently discovered to have adversely affected FDM degradation independently. The copper corrosion rate and nitrile rubber (NBR) volume change increased by 9% and 13%, respectively, due to 22% increase in the conductivity value. In contrast, the copper corrosion rate and NBR volume swelling reduced by 91% and 27%, respectively, due to 96% reduction in the DO concentration. Ultimately, copper corrosion and NBR degradation were determined to be lowered by up to 92% and 73%, respectively, under modified immersion as compared to typical immersion condition. These outcomes distinctly show that acceptable to good compatibility is present between FDM and biodiesel under CRDE operation. The good compatibility is strongly supported since only a maximum lifespan reduction of 1.5 years is predicted for metal exposed to biodiesel as compared to diesel for a typical component lifespan of 15 years. For the elastomers, acceptable compatibility is found present between elastomer and biodiesel based on the determined 11% volume change which conforms to the tolerance level of elastomer degradation as stated by the elastomer manufacturers. These are especially true for the evaluated metals and elastomers investigated under the modified laboratory immersion which replicates similar conditions to a real-life CRDE. Overall, this work has contributed to the advancement of knowledge and application of biodiesel use in diesel engines.

Thermal analysis and fuel economy benefits of cylinder deactivation on a 1.0l spark ignition engine

Bech, Alexander

January 2018

The deactivation of a cylinder on a 1.0litre three cylinder turbocharged gasoline engine has been investigated providing novel information on thermal and fuel consumption effects associated with the technology. This comes in light of providing solutions to reduce fuel consumption and CO2 emissions resulting from internal combustion engines. The investigation has been carried out through the PROgram for Modelling of Engine Thermal Systems (PROMETS). A version of PROMETS was extensively developed to characterise a commercially produced TCE not fitted with cylinder deactivation technology. Developments include an improved gas-side heat transfer expression to account for increased heat transfer to coolant due to the addition of an integrated exhaust manifold; addition of an expression to represent natural convection to model heating of quiescent coolant in the block; and a method to estimate the boosted intake manifold pressure past the throttle due to turbocharging on a gasoline engine. The 0-D approach used in this thesis compared to higher resolution computational tools has allowed for thermal and performance predictions to be made within a couple of minutes compared to several hours or days. In effect, PROMETS has been a time and cost effective tool during the development stages of a prototype engine. The PROMETS model indicated that no adverse changes in engine thermal behaviour arose with cylinder deactivation. The largest temperature change of < 400 occurs in the exhaust valve lower stem for the deactivated cylinder. Temperature changes in other components throughout the engine are an order of magnitude smaller. Although the largest temperature differences between the deactivated and firing cylinders were found to be in the range of < 70 , these remain within normal engine operating temperatures of < 100 . Also, by on-setting deactivation past an oil temperature of 40 , warm-up times were marginally extended compared to operation on all cylinders from key-on. Experimental inputs representing changes in engine gross indicated thermal efficiency and the work loss associated with the motoring of a piston complemented modelling work in predicting fuel consumption changes due to deactivation. Reductions in pumping losses account for the majority of the fuel consumption benefit associated with deactivating a cylinder. The main limitation in the employment of cylinder deactivation stems from the deterioration in the gross indicated thermal efficiency. Modelled results show that fuel consumption improvements are highest on low and part load operation envelopes. As such over the NEDC and FTP-75 benefits are in the range of 3.5%. Applying the technology over dynamically loaded cycles such as the WLTC and ARTEMIS, results in benefits of less than 1.6%. Further to modelling work on cylinder deactivation, experimental work has been carried out with the aim of allowing any engine size to be tested to cover transient drive cycles for future research. Future research could be in the aim of investigating technologies to reduce CO2 and emissions resulting from ICEs. Results show that the control solution implemented has allowed eddy-current dynamometers normally used for constant speed and brake load conditions to operate cycles such as the WLTC or any transient brake torque and engine speed pattern. Benchmark fuel consumption values for two engines of differing swept volume are within a 4g error band equivalent to a 0.36% and 0.67% percentage error band demonstrating the excellence of the control system.

Mechanisms of soot transfer to oil of an HPCR diesel engine

Di Liberto, Gianluca

January 2017

High levels of soot-in-oil can cause an increase in engine wear and oil viscosity, thus reducing oil drain intervals. The mechanisms by which soot particles are entrained into the bulk oil are not well understood. The research reported in this thesis addresses questions on the mechanisms of soot transfer to the lubricating oil in light-duty diesel engines with high pressure EGR systems. Deposition as a result of blow-by gas passing the piston ring pack and by absorption to the oil film on the cylinder liner via thermophoresis are soot transfer mechanisms that have been considered in detail. The investigations are based on analytical and simulation studies, and results based on complementary experimental studies are used to validate these. The experimental investigations aimed at evaluating the typical rate of accumulation and size distribution of soot agglomerates in oil. The oil samples analysed were collected during regular services from light-duty diesel engine vehicles. These were representative of vehicles meeting Euro IV and V emission regulation standards driven under real-world conditions. The rate of soot-in-oil was determined by thermogravimetric analysis and results showed a concentration of approximately 1 wt% of soot-in-oil after 15,000 km. The particle size distribution was determined using a novel technique, Nanoparticle Tracking Analysis (NTA), applied for the first time to soot-laden oil samples by the author [1, 2]. Results showed an average particle size distribution of 150 nm, irrespective of oil drain interval. Almost the totality of the particles were between 70 and 400 nm, with micro particles not detected in any of the samples analysed. For the samples investigated in this work, the Euro standard did not influence either the rate of soot deposition or the particles size distribution. To the author’s best knowledge, this is the first time that rate of soot deposition and particles size distribution from oil samples collected from vehicles of different Euro standard driven under real-world conditions are analysed and compared. Exhaust Gas Recirculation (EGR) is a common technique used in diesel engines in order to reduce NO¬x emissions. However, it has the drawback that it increases the production of soot. In this work, particular attention has been given to its effects on the rate of soot deposition in oil. Both its influence on the soot produced during the combustion process and on the soot re-introduced in the combustion chamber by the EGR gas has been investigated through CFD simulations using Kiva-3V. Examining the relative importance of near–surface transport of soot by thermophoresis to the oil film on the liner and from blow-by gases to surfaces in the ring pack shows the former to be the dominant mechanism of soot transfer. EGR increases the rate of deposition of soot on the liner not only by increasing net production of soot, but also through the re-cycled particles. At EGR levels higher than 20%, the contribution of the Re-cycled soot becomes the major source for soot-in-oil. The study of soot deposition was evaluated during the entire engine cycle, including compression stroke and post-Exhaust Valve Opening (EVO) period. Existing deposition models found in the literature typically limit the domain to only from the Start of Injection (SOI) to (EVO) period [3-5]. Results from this thesis indicated that compression stroke and post-EVO period can contribute up to 30% of the total rate of soot deposition into oil.

621.43

Variable stroke crank shaft for an internal combustion engine

Ismail, Fareed

January 2012

Thesis (MTech (Mechanical Engineering))--Cape Peninsula University of Technology, 2012. / Our planet is continuously being depleted of its natural resources leading to a need to conserve energy and the environment. One of the major energy consumers is the conventional internal combustion engine. Many attempts have been made to make these conventional internal combustion engines more efficient focusing mostly on the combustion side of the engine. The focus of this study is on the modification of the reciprocating and rotating components of the sub-assembly of a conventional internal combustion engine. An in-depth review was carried out on the fundamentals of spark ignition internal combustion engines and savings on fuel consumptions. A prototype single piston internal combustion engine was developed that can adjust its stroke length. Lengthening or shortening the stroke and simultaneously extending or retracting the connecting rod's travel distance, allows the internal combustion engine to function very efficiently consequently reducing the free space between the piston and cylinder head at TDC position. This allows the internal combustion engine to alter its power capability on demand whilst maintaining relatively high compression efficiency. The method of altering the stroke length is achieved by manipulating gears situated internally and externally of the engine sub-assembly. The control of these eccentric gears lowers or lifts the crankshaft in a radial motion. The eccentrics also control the automatic extension or retraction of the connecting rod's travel distance. The externally concentric gears control the mechanism that allows the internal combustion engine to change its capacity easily as adapted for automation. This study does not extend into the automation issues of the external mechanism. The prototype engine that was built could not endure vigorous testing and it failed after running for a short while. The primary focus had been on the kinematics of the engine mechanism - and to show whether the idea was feasible. The engine passed the kinematics test but failed possibly due to dynamic loads. Investigating this requires measuring instantaneous temperatures from which peak pressures can be deduced. This was not done because it was outside the scope of the project.

Internal combustion engines

Análise dinâmica e balanceamento de virabrequins leves de motores / Dynamics analysis and balancing of lightweight crankshaft for engines

Rodrigues, Alex de Souza, 1979-

24 August 2018

Orientador: Marco Lúcio Bittencourt / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-24T04:09:11Z (GMT). No. of bitstreams: 1 Rodrigues_AlexdeSouza_M.pdf: 4083435 bytes, checksum: d064f345587c31e235681e0db1417f27 (MD5) Previous issue date: 2013 / Resumo: Devido às atuais exigências de leis de emissão e redução de consumo de combustível, busca-se reduzir o peso dos componentes sem impacto aos critérios de projeto. Neste sentido, torna-se importante entender e discutir os critérios de projeto do componente em estudo. Este trabalho tem por objetivo entender a influência da redução do contrapeso de uma árvore de manivelas quatro cilindros em linha. Assim, para analisar o impacto da redução de massa nos contrapesos, foi realizado um estudo de sensibilidade nesta região do componente. Para analisar esta viabilidade, foram discutidos alguns critérios de balanceamento e a dinâmica do virabrequim em operação no motor. Nestas metodologias de balanceamento, resumiu-se a teoria básica mais comumente utilizada. Neste trabalho, aplicou-se o conjunto de ferramentas analisadas em um estudo de caso para um virabrequim forjado de um motor quatro cilindros em linha, obtendo-se a diferença dos critérios de balanceamento utilizados em relação à análise dinâmica. Foi observado que há critério de balanceamento que não considera efeito dinâmico importante. Finalmente, demonstrou-se que quando se deseja ter um contrapeso leve, existem alternativas de geometria que minimizam o impacto da retirada de massa / Abstract: Due to the current emission standard and fuel consumption requirements, lightweight components with no impact in the design criterion are desired. As a consequence, it is vital to understand and discuss the design criteria of the studied component. This work aims to understand the influence of crankshaft counterweight reduction in an inline-four cylinder engine. Thus, to analyze the counterweight mass reduction, it was done a sensitivity study at this region. In order to analyze this feasibility, it was discussed some balancing criteria and also the crankshaft under virtual engine operation. In these balancing methodologies, it was summarized the basic theory usually designed. In this work, it was applied a package of tools in a study of case for a 4cyl. in-line engine crankshaft, obtaining the difference between some balancing methods versus the dynamics analysis. It was noticed that there are balancing methodologies which do not mind important dynamics effect. All in all, it was showed that if a lightweight design is desired, there are some ways to minimize the unbalancing impact when saving counterweight mass / Mestrado / Mecanica dos Sólidos e Projeto Mecanico / Mestre em Engenharia Mecânica

Motores de combustão interna

Internal combustion engines

Desenvolvimento e validação de metodologia para analise de vibrações torcionais em motores de combustão interna / Development and validation of a methodology for torsional vibrations analysis in internal combustion engines

Mendes, Alexandre Schalch

02 February 2005

Orientadores: Pablo Siqueira Meirelles, Douglas E. Zampieri / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecanica / Made available in DSpace on 2018-08-04T03:09:14Z (GMT). No. of bitstreams: 1 Mendes_AlexandreSchalch_M.pdf: 7112696 bytes, checksum: 0f7bdbd014e6bd5c62865524aaa15fca (MD5) Previous issue date: 2005 / Resumo: Este trabalho tem como objetivo a análise do fenômeno das vibrações torcionais em árvores de manivelas de motores de combustão interna para aplicações veiculares. Como exemplo, a formulação proposta será aplicada no estudo da árvore de manivelas de um motor fabricado pela empresa MWM Motores Diesel Ltda., de seis cilindros em linha, quatro tempos, considerando-se a utilização de um amortecedor de vibrações de material elastomérico acoplado ao componente. Da análise das vibrações torcionais é possível de se obter os torques atuantes em cada secção do virabrequim. Estes esforços poderão ser aplicados posteriormente como condições de contorno a um modelo de elementos finitos, para que juntamente aos demais carregamentos existentes, seja feita a verificação do ciclo de fadiga atuante, de modo a avaliar o coeficiente de segurança do componente. Apesar de não ser este o foco deste trabalho, pode-se notar a importância da análise das vibrações torcionais no dimensionamento estrutural de uma árvore de manivelas. Iremos comparar as amplitudes de vibrações torcionais teóricas às obtidas experimentalmente, para a validação do modelo matemático proposto / Abstract: The scope of this work is the study of the crankshaft torsional vibration phenomenon for internal combustion engines. As an example, the formulation will be applied to an engine for a vehicular application, manufactured by MWM Motores Diesel Ltda., with six cylinders in line configuration, four strokes and considering a rubber damper assembled to the component. From the torsional vibrations analysis, it is possible to ca1culatethe actuating torque in each crankshaft section. These loads can be applied as boundary conditions to a finite element model and with the consideration of the other existing loads it is possible to determine the fatigue cyc1e,to calculate the safety factor ofthe component. This is not the objective ofthis work, but it is possible to note the importance of the torsional vibrations analysis in the structural dimensioning of the crankshafts. The obtained results by the presented methodology will be compared to the measured values for the validation of the proposed mathematical model / Mestrado / Mecanica dos Sólidos e Projeto Mecanico / Mestre em Engenharia Mecânica

Motores de combustão interna

Internal combustion engines

Combustion aided by a glow plug in diesel engines under cold idling conditions

Li, Qile

January 2016

Glow plugs are widely used to promote the desired cold start and post-cold start combustion characteristics of light duty diesel engines. The importance of the glow plug becomes more apparent when the compression ratio is low. An experimental investigation of combustion initiation and development aided by the glow plug has been carried out on a single cylinder HPCR DI diesel engine with a low compression ratio of 15.5:1. High speed imaging of combustion initiated by the glow plug in a combustion bomb has been used to add understanding of initiation process. Complementary CFD studies have been carried out using ANSYS Fluent 14.0 to explore the interactions between the glow plug and the spray behavior. Observation of successful combustion initiation show that two conditions must be met, compression heating and heat transfer from the glow plug must raise temperature of gas nearby to at least 413ºC and the vapour/air equivalence ratio no lower than 0.15-0.35. The initiation site was at spray edge close to the glow plug, the flame grew locally before expanding downstream in direction of spray penetration after the end of the main injection. Experimental studies carried out on the engine indicated that the engine IMEP, heat release and combustion stability were continuously improved by using the glow plug at ambient temperatures higher than the temperature requiring the glow plug for initiation of combustion. A rapid development of premixed combustion was achieved associated with improved engine work output, heat release rate and cycle-by-cycle stability. The premixed combustion was enhanced by strengthening spray vaporization through the glow plug. In this study, the combustion behavior was enhanced by the glow plug up to ambient temperature of 20ºC. Initiation delay was shortened by a rapid development of combustion aided by the glow plug. An initiation delay model was developed to account for both physical part (transport delay) and chemical part (chemical delay). The transport delay (ms) is equivalent to the time for spray to transport to the vicinity of the glow plug, dictated by parameters including S, distance between the glow plug tip and the injector tip (mm).