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121	HEV Energy Management Considering Diesel Engine Fueling Control and Air Path Transients Huo, Yi 07 1900 (has links) This thesis mainly focuses on parallel hybrid electric vehicle energy management problems considering fueling control and air path dynamics of a diesel engine. It aims to explore the concealed fuel-saving potentials in conventional energy management strategies, by employing detailed engine models. The contributions of this study lie on the following aspects: 1) Fueling control consists of fuel injection mass and timing control. By properly selecting combinations of fueling control variables and torque split ratio, engine efficiency is increased and the HEV fuel consumption is further reduced. 2) A transient engine model considering air path dynamics is applied to more accurately predict engine torque. A model predictive control based energy management strategy is developed and solved by dynamic programming. The fuel efficiency is improved, comparing the proposed strategy to those that ignore the engine transients. 3) A novel adaptive control-step learning model predictive control scheme is proposed and implemented in HEV energy management design. It reveals a trade-off between control accuracy and computational efficiency for the MPC based strategies, and demonstrates a good adaptability to the variation of driving cycle while maintaining low computational burden. 4) Two methods are presented to deal with the conjunction between consecutive functions in the piece-wise linearization for the energy management problem. One of them shows a fairly close performance with the original nonlinear method, but much less computing time. / Thesis / Doctor of Philosophy (PhD) hybrid electric vehicle energy management diesel engine fueling control air path dynamics model predictive control
122	FTIR lubricant analysis: Concentration of dispersed sulphuric acid Sautermeister, F.A., Priest, Martin, Fox, M.F. January 2014 (has links) No / This paper aims to establish the acid concentration of finely dispersed droplets in hydrocarbon oils. Small quantities of aqueous sulphuric acid (H2SO4) were found to be trapped within hydrocarbon shells, making them inaccessible for concentration evaluation by titration. Fourier transform infrared spectroscopy (FTIR) used in the attenuated total reflection mode (ATR; FTIR-ATR) was applied to study the reaction products of squalane, C30H62, and an API Group I base oil with various concentrations of aqueous H2SO4. The absorbance comparison usually used for estimating acid concentrations was found to fail when small quantities of acid are trapped in the reaction product. It was found that the peak shift and changes in absorbance found for various pure aqueous acid concentrations were useful to establish the remaining concentration of the trapped H2SO4. This paper fulfils the identified need to study acid dissociation-dependent peak shifts of H2SO4 to find the acid concentration of finely dispersed droplets in hydrocarbon oils. Ftir ; Emulsion ; Lubricant degradation ; Marine diesel engine ; Sulphuric acid ; Acid dissociation ; Infrared-spectroscopy ; Water structure ; Solutes
123	<b>EVALUATING FUEL SAVINGS AND EMISSIONS IN AN OFF-ROAD DIESEL ENGINE USING AN EXHAUST GAS RECIRCULATION PUMP AND HIGH-EFFICIENCY TURBOCHARGER FOR TRANSIENT CYCLES</b> Audrey Willoughby (18405600) 18 April 2024 (has links) <p dir="ltr"> Diesel engines are widely used in various off-road settings, ranging from railroad locomotives and marine vessels to agricultural, construction, logging, and mining equipment. Diesel engines are favored due to their reliability, durability, high thermal efficiency, and capacity to generate significant power. However, they also emit a range of harmful pollutants, such as oxides of nitrogen (NOx), particulate matter (PM), carbon monoxide (CO), and hydrocarbons (HC). Over the past three decades, original engine manufacturers have faced increasingly stringent emission regulations. In the United States, the proposed Tier 5 emission standards aim to achieve a significant reduction in NOx emissions, targeting a reduction of up to 90%, as well as a reduction in particulate matter emissions of up to 75%. To meet these stringent regulations, original engine manufacturers are investigating new technologies.</p><p dir="ltr"> Cooled exhaust gas recirculation (EGR) is a widely used method to lower NOx emissions. The EGR flow rates are contingent on positive engine delta pressure (exhaust manifold pressure - intake manifold pressure) to drive EGR. Eaton’s Generation 3 Exhaust Gas Recirculation Pump (EGRP) eliminates the need for positive engine delta pressure and enables the application of a high-efficiency turbocharger. A high-efficiency turbocharger reduces the pumping work and thus improves fuel efficiency.</p><p dir="ltr"> Transient tests were conducted on a 13.6 L S750 John Deere Engine with both the stock hardware and the EGRP and high-efficiency turbocharger hardware, to evaluate the benefits of the new technology. The transient tests included the Constant Speed Load Acceptance Test (CSLA), the Nonroad Transient Cycle (NRTC), and the Low Load Application Cycle (LLAC). There was no aftertreatment systems in the test cell setup, so engine-out brake specific oxides of nitrogen (BSNOx) and engine-out brake specific particulate matter (BSPM) were examined. To evaluate the technology, results from the stock hardware setup were compared to the results from the EGRP and high-efficiency turbocharger setup.</p><p dir="ltr"> During the CSLA, the time response to 90% load with the EGRP-equipped engine was <a href="" target="_blank">generally slower</a> than the stock engine, with deviations ranging from 0.1s to 1.6s. This result was attributed to the EGR pump not reducing speed fast enough, resulting in insufficient fresh air to produce torque. In the NRTC, engine torque was compared between both configurations. It was discovered that the EGRP-equipped engine did not reach the desired torque setpoints. There was more EGR flow than expected and not enough fresh air. This pattern was also revealed in the LLAC.</p><h4> To ensure accurate comparisons, measured engine speed and load data from the EGRP configuration were used to establish a Modified NRTC and Modified LLAC. For the Modified NRTC, the brake specific fuel consumption (BSFC) improved by 1.3%, and the engine-out brake specific particulate matter improved by 33.1% with the EGRP and high-efficiency turbocharger. However, the engine-out BSNOx increased by 12.9%. For the Modified LLAC, the BSFC and engine-out BSNOx improved by 2.5% and 11.1%, respectively, with the EGRP setup. However, this improvement came at the expense of engine-out BSPM, which increased by 34.2%. The improvement in BSFC for both cycles could be attributed to the increased open-cycle efficiency seen in steady state data with the EGRP and high-efficiency turbocharger.</h4><p></p> Exhaust Gas Recirculation Pump Transient Cycles Diesel Engine
124	Contribution to the understanding of filtration and pressure drop phenomena in wall-flow DPFs Angiolini, Emanuele 01 September 2017 (has links) From the last decades of the 20th century, internal combustion engines have undergone a continuous improvement process aimed to the increase of their efficiency and decrease of the pollutants emissions. The reduction of the availability of fossil fuel and the increase of human-made pollution observed in the last decades is leading worldwide to more stringent emission standards that make the engine manufacturers to constantly look for fuel consumption and emission reductions while keeping engine performance. To comply with current and incoming emission regulations, the exhaust line of internal combustion engines has been gradually complicated by the presence of aftertreatment systems. Among them, the particulate filter is the device in charge of abating the emission of soot in the atmosphere. Concerning compression ignition engines, diesel particulate filters (DPF) were first commercially utilized in significant numbers in passenger car and heavy-duty engines since the beginning of the 21st century. Euro 6 emission standards limits the emitted particulate matter from direct injection engines, thus extending the use of particulate filters also to direct injection gasoline engines. A deep knowledge of the phenomena happening inside the DPF is required for the correct understanding of the behaviour of this system and its interaction with the engine. The precise knowledge of the filtration and pressure drop processes is mandatory for the design of the particulate filter and is also essential to wisely think up and analyse solutions aimed to limit the negative impact of the filter on the fuel consumption maintaining its capability of retaining soot particles. Thus, the present work pretends to provide a contribution to the understanding of these phenomena in wall-flow DPFs. The problem has been faced on a computational and experimental basis. A notable part of the work was dedicated to the development and validation of a one-dimensional DPF filtration model to be coupled with the existing pressure drop model. The model was implemented in OpenWAM¿, the open-source gas dynamics software for internal combustion engines and components computation developed at CMT - Motores Térmicos. The developed computational tool was applied to the assessment of the aftertreatment (DOC&DPF) volume downsizing potential in post- and pre-turbo aftertreatment configuration. The study is completed with experimental analysis to support theoretical insights discussing how the soot deposition profile and the particulate layer properties impact on the DPF pressure drop. / Desde las últimas décadas del siglo XX, se ha producido un proceso de mejora continua de los motores de combustión interna alternativos con el fin de aumentar su eficiencia y reducir las emisiones contaminantes. La reducción de la disponibilidad de combustibles fósiles y el incremento de la polución de origen antropogénico observados en las ultimas décadas ha provocado el progresivo endurecimiento de las normativas anticontaminación a nivel mundial obligando a los fabricantes de motores a buscar la reducción continua del consumo de combustible y emisiones, manteniendo las prestaciones del motor. El cumplimiento de las actuales y futuras normativas anticontaminación requiere de la instalación de diversos sistemas de postratamiento de gases en la línea de escape de los motores de combustión interna alternativos, aumentando su complejidad. Entre estos sistemas, el filtro de partículas es el equipo encargado de la reducción de la emisión de hollín a la atmósfera. Con respeto a los motores de encendido por compresión, los filtros de partículas diésel se implementaron por primera vez de forma masiva en vehículos de pasajeros y vehículos pesados a principio del siglo XXI. La normativa anti contaminación Euro 6 limita las emisiones de partículas de los motores de inyección directa, extendiendo el uso de filtros de partículas a los motores de inyección directa de gasolina. Es necesario tener un conocimiento profundo de los fenómenos que tienen lugar en el DPF para comprender el comportamiento de este sistema y su interacción con el motor. El conocimiento de los procesos de filtrado y perdida de presión es vital para el diseño del filtro de partículas y resulta esencial para encontrar y analizar soluciones que ayuden a limitar el impacto negativo del DPF sobre el consumo de combustible sin perder la capacidad de retener partículas de hollín. En este contexto, este trabajo pretende aportar una contribucción a la comprensión de estos fenómenos en filtros de partículas de flujo de pared. Esta tarea se ha planteado desde un punto de vista computacional y experimental. Parte importante de este trabajo ha consistido en el desarrollo y validación de un modelo de filtrado unidimensional de DPF que se ha acoplado con el modelo de caida de presión ya existente. El modelo se ha implementado en OpenWAM¿, el software de libre acceso para el cálculo fluidodinámico de motores de combustión interna y sus componentes desarrollado en CMT - Motores Térmicos. La herramienta computacional desarrollada se ha aplicado a la evaluación del potencial de reducción de volumen de sistemas de postratamiento (DOC&DPF) en configuraciones post- y pre-turbo. Este estudio se ha completado con un análisis experimental para dar respaldo a los conceptos teóricos empleados discutiendo como el perfil de deposición del hollín y las propiedades de la capa de partículas afectan a la perdida de presión del DPF. / Des les últimes dècades del segle XX, s'ha produït un procés de millora contínua dels motors de combustió interna alternatius amb l'objectiu d'augmentar la seua eficiència i reduir les emissions contaminants. La reducció de la disponibilitat de combustibles fòssils i l'increment de la polució d'origen antropòlogic observats en les últimes dècades ha provocat que les normatives anticontaminació s'han fet més rígides a nivell mundial, obligant als fabricants de motors a buscar la reducció contínua del consum de combustibles i emissions, mantenint les prestacions dels motors. El cumpliment de les normes anticontaminació actuals i futures, requereixen de l'instalació de diversos sistemes de post-tractament de gasos a l'eixida dels motors de combustió interna alternatius, llavors augmentant la complexitat. Entre aquestos sistemes, el filtre de partícules es l'equip encarregat de la reducció de les partícules de sutge a l'atmosfera. Respecte als motors d'encès per compressió, els filtres de partícules van instalar-se de manera massiva als vehicles de passatgers i vehicles pesats al principi del segle XXI. La normativa anti contaminació Euro 6 limita les emissions de partícules dels motors d'inyecció directa, estenent l'ús del filtre de partícules als motors d'injecció directa de gasolina. És necessari tindre un coneixement dels fenòmens que tenen lloc al DPF per a comprendre el comportament del sistema i la seua interacció amb el motor. El coneixement dels processos de filtrat i la pèrdua de pressió és vital per al diseny del filtre de partícules i resulta essencial per a trobar i analitzar les solucions que ajuden a limitar l'impacte negatiu del DPF sobre el consum de combustible sense perdre la capacitat de retenir partícules de sutge. En aquest context, el projecte pretén aportar una contribució a la comprensió d'aquestos fenòmens en els filtres de partícules de flux de paret. Aquesta feina s'ha plantejat des d'un punt de vista computacional i experimental. Part important d'aquest treball ha consistit en el desenvolupament i validació d'un model de filtrat unidimensional de DPF que s'ha acoplat a un model de pèrdua de pressió existent. El model s'ha implementat en OpenWAM¿, el software de lliure accés per al cálcul fluidodinámic de motors de combustió interna i els seus components desenvolupats al CMT - Motores Térmicos. La ferramenta computacional desenvolupada s'ha aplicat a la evaluació del potencial de reducció del volum de sistemes de post tractament (DOC&DPF) en les configuracions post- i pre-turbo. Aquest estudi s'ha completat amb una anàlisi experimental per a donar suport als concepts teòrics emprats discutint com el perfil de la disposició de sutge i les propietats de la capa de partícules que afecten a la pèrdua de pressió del DPF. / Angiolini, E. (2017). Contribution to the understanding of filtration and pressure drop phenomena in wall-flow DPFs [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/86157 Diesel engine DPF Filtration model Aftertreatmant volume downsizing Pre-DPF water injection INGENIERIA AEROESPACIAL
125	Efficient Operation of Diesel Generator Sets in Remote Conditions Wheeler, Kaitlyn Rose 19 July 2017 (has links) Diesel engine and generator sets (gensets) have been extensively used for standby and remote power generation over the past hundred years. Due to their use for standby power, these diesel gensets are designed to operate in conjunction with the grid, which relates to a fixed speed operation with a 60 Hz AC output. For operation in remote conditions, such as military and disaster relief applications, this fixed speed operation results in limiting the power output available from the engine, as well as the overall efficiency of the system. The removal of this grid connectivity requirement could result in an increase in system efficiency. At a given load, the engine operates more efficiently at lower speeds, which corresponds to an increase in the system efficiency. This low speed operation also results in lower power output. Knowledge of the load is important in order to determine the most efficient operating point for fixed speed operations. Operating at a higher power output for a given speed also results in higher system efficiency. The addition of a battery pack will allow for a higher apparent load, resulting in higher operating efficiency. The addition of a battery pack will also allow for energy storage, which allows for a higher operating efficiency, as well as "engine off time". A controlled series capacitor converter should be used to ensure that the maximum power is transferred from the genset to the battery/load. Knowledge of the load and equipment available should be used in order to determine the ideal dispatch strategy. Overall, operation at the grid frequency limits the efficiency of the overall system for remote operations where grid frequency is not required. The simulated genset had an efficiency of 24% for a 3 kW when operated at 1800 RPM, and increase from the 17% efficiency at it normal operating speed of 3600 RPM. This corresponded to a fuel savings of 3 gallons over 24 hours of continuous operation. When a battery is incorporated into the system, the efficiency of the system will increase for a given output load. For example, the simulated genset has an efficiency of 15% for a 1 kW load, which increases to 24% when a battery is added and charged at 2 kW. / Master of Science / Diesel engine and generator sets (gensets) have been extensively used for emergency and remote power generation over the past hundred years. Due to their use for emergency power, these diesel gensets are designed to operate in the same way as the grid. This results in a fixed speed operation in order to achieve 60 Hz. For operation in remote conditions, such as military and disaster relief applications, this fixed speed operation results in limiting the power output available from the engine, as well as the overall efficiency of the system. Increasing the efficiency of the diesel engine will increase the overall system efficiency, which is the relationship between the energy into the engine as compared to the energy produced. At a given load, or energy output requirement, the engine will operate more efficiently at lower speeds. This low speed operation, however, will result in a lower power output. Therefore, knowledge of the load is important in order to determine the most efficient operating point for a diesel engine, and the genset as a system. Operating at a higher power output for a given speed also results in higher system efficiency. The addition of a battery pack will allow for a higher apparent load, or the load seen by the engine, resulting in higher operating efficiency for the engine. The addition of a battery pack will also allow for energy storage, which allows for “engine off time”, or time which the system can provide power silently. Analysis should be conducted to ensure that the maximum power is transferred from the genset to the battery/load. Knowledge of the load and all equipment available should be used in order to determine the ideal charging and discharging strategy for the battery and system. Overall, operation at the grid frequency limits the efficiency of the overall system for remote operations where grid frequency is not required. A simulation was conducted to illustrate this concept. The simulated genset would save approximately 3 gallons of fuel over a 24 hour operating time when run at of speed of 1800 RPM, as opposed to its normal operating speed of 3600 RPM. When a battery is incorporated into the system, an additional gallon of fuel can be saved over a 24 hour period. mobile hybrid power system fuel consumption energy storage diesel engine generator
126	<b>ENHANCING ENGINE RELIABILITY IN MARINE AND MINING APPLICATIONS: A COMPREHENSIVE STUDY OF FAULT ANALYSIS AND VALIDATION-BASED DAMAGE MODELING</b> Anushka George (19320724) 20 November 2024 (has links) <p dir="ltr">Ensuring the reliability and efficiency of engines in marine and mining applications is critical for operational safety and performance. This thesis explores two interconnected areas of engine reliability: the analysis of marine diesel engine faults and the development of a framework that linked together the vehicle simulation model developed by Cummins and the damage model developed by Cummins. The first part of the research describes a comprehensive literature survey on common faults in marine diesel engines, focusing on issues such as fuel system failures, turbocharger malfunctions, and cooling system inefficiencies. Additionally, it investigates various hardware redundancy strategies to mitigate these faults and enhance engine reliability. The findings demonstrated that hardware redundancy is expected to reduce the likelihood of engine failure by ensuring continuous operation even in the event of component malfunctions. </p><p dir="ltr">The second part of the research centers on the development and validate of a framework that links the Cummins vehicle simulation tool and Cummins damage modeling tool to perform damage calculations for mine haul truck engines. The validation of the framework ensures the accuracy of simulation models, which is crucial for predictive maintenance and performance optimization. The validated data is then used in various damage models to estimate and compare the damage accumulation in diesel and hybrid engine scenarios for mine haul applications. The findings provide insights into these engines' relative durability and performance under real-world conditions for this specific duty cycle. Notably, the comparative analysis revealed that hybrid engines tend to accumulate higher levels of oxidation and creep damage in components such as the exhaust manifold and turbine housing. In contrast, diesel engines are more susceptible to high cycle fatigue and wear in components like the piston rings and cylinder heads. </p><p dir="ltr">This thesis aims to bridge the gap between theoretical research and practical application by combining a thorough literature review, empirical validation, and damage modeling using tools developed by Cummins. </p> Diesel engine perfomance Damage Modeling Engine simulation data Engine Failures
127	<b>ENHANCING ENGINE RELIABILITY IN MARINE AND MINING APPLICATIONS: A COMPREHENSIVE STUDY OF FAULT ANALYSIS AND VALIDATION-BASED DAMAGE MODELING</b> Anushka George (19320724) 02 August 2024 (has links) <p dir="ltr">Ensuring the reliability and efficiency of engines in marine and mining applications is critical for operational safety and performance. This thesis explores two interconnected areas of engine reliability: the analysis of marine diesel engine faults and the development of a framework that linked together the vehicle simulation model developed by Cummins and the damage model developed by Cummins. The first part of the research describes a comprehensive literature survey on common faults in marine diesel engines, focusing on issues such as fuel system failures, turbocharger malfunctions, and cooling system inefficiencies. Additionally, it investigates various hardware redundancy strategies to mitigate these faults and enhance engine reliability. The findings demonstrated that hardware redundancy is expected to reduce the likelihood of engine failure by ensuring continuous operation even in the event of component malfunctions. </p><p dir="ltr">The second part of the research centers on the development and validate of a framework that links the Cummins vehicle simulation tool and Cummins damage modeling tool to perform damage calculations for mine haul truck engines. The validation of the framework ensures the accuracy of simulation models, which is crucial for predictive maintenance and performance optimization. The validated data is then used in various damage models to estimate and compare the damage accumulation in diesel and hybrid engine scenarios for mine haul applications. The findings provide insights into these engines' relative durability and performance under real-world conditions for this specific duty cycle. Notably, the comparative analysis revealed that hybrid engines tend to accumulate higher levels of oxidation and creep damage in components such as the exhaust manifold and turbine housing. In contrast, diesel engines are more susceptible to high cycle fatigue and wear in components like the piston rings and cylinder heads. </p><p dir="ltr">This thesis aims to bridge the gap between theoretical research and practical application by combining a thorough literature review, empirical validation, and damage modeling using tools developed by Cummins. </p> Diesel engine perfomance Damage Modeling Engine Simulation data Engine failures
128	No/Nox Removal In Diesel Engine Exhaust Under Different Energizations And Reactor Configurations Kumar, Bijendra 01 1900 (has links) In India, with the increase in the number of industries and vehicles the environment is getting more and more polluted. More than industries it is the rapid growth of vehicles which causes serious environmental crisis in the form of air pollution and has become alarming particularly in cities. The industrial and vehicular growth cannot be neglected, as the country’s economic and social well being is largely dependent on them. But this should not come at the cost of our health and eco system. The industrial and vehicular emissions must be controlled in order to keep our air clean. Continued efforts in this direction are being taken up across the globe to investigate an efficient and economical technique. There are many air pollutants being emitted from both natural and manmade sources. The major air pollutants identified as hazardous to human health are nitrogen oxides (NOx), carbon monoxide (CO), particulate matter (PM), volatile organic compounds (VOC), and sulfur dioxides (SOx). Among these, nitrogen oxides are considered to be difficult to remove. The sources of NOx are thermal power plants, stationary and mobile diesel engines, gasturbine engine, ironore sintering plants and various other smallscale utilities. There are conventionally available technologies to remove NOx such as chemical scrubbing, catalysis etc. But these techniques are either difficult to operate or do not bring down the level of NOx to the required norms imposed by the government. The failure of conventional techniques to remove NOx to the expected limit led to the development of alternative nonconventional techniques. Prominent among these new alternative techniques is electric discharge plasma, where the gas is partially ionized and temperature of electrons is considerably higher than that of ions and background gas molecules. Diesel engines are getting popular due to their inherent merits and their number is increasing considerably. Unfortunately, the exhaust of diesel engine being complex with high oxygen content makes the existing pollution control techniques insufficient particularly with regard to removal of NOx. So there is a need for investigating better technology which can effectively abate the pollutants from diesel engine exhaust. Electric Discharge plasma is one such alternative technique which has been very successful in large volumes of flue gas cleaning and hence, its potential is being explored in the cleaning of small volumes of vehicular exhausts, in particular, diesel engine exhaust. In the present work we investigated the relative performance of different electric discharge plasma reactors, with different type of voltages like AC, DC and pulse. The reactors were evaluated for NOx removal efficiency and NO conversion. This research work is a feasibility study to find whether electric discharge plasma can be used more effectively as an alternative technology for the after treatment of diesel engine exhaust in cascade with some cheaper adsorbents, if necessary. The scope of this qualitative experimental study can briefly be summarized as below: . • To study different reactors for NO conversion and NOx removal . • To study the effect of dielectric pellets in enhancing the radical production which in turn will have a bearing on the chemical reactions . • To study the effect of different types of voltages on the cleansing process . • To propose an efficient reactor system subject to the experimental conditions studied. Diesel Engine - Exhaust Nitric Oxide Electric Discharge Plasma Technique Air Pollution - India Nitrogen Oxide Pollution - Control Diesel Engine Exhaust - Air Pollutants Air Pollution Control Pulse Energization Wire-cylinder Reactor Pipe-cylinder Reactor Heat Engineering
129	Undersökning av avgasemissioner till vatten från dieselinombordsmotorer i fritidsbåtar : En jämförande studie av olika bränslen Östman, Ninnie January 2006 (has links) <p>In this Masters Thesis emissions to water from diesel engines in pleasure boats when driven with alternative fuels have been investigated. Two alternative fuels, Fischer-Tropsch-diesel (FT-diesel) and a blend of FT-diesel and rapeseed methyl ester (RME) have been compared with diesel of Swedish environmental class 1 (diesel EC1). The alternative fuels have been compared using two older marine diesel engines, and water samples have been taken from the water in the exhaust system before the exhaust compounds reaches the recipient. The water samples have been analysed with gas chromatography (GC) and mass spectrometry (GC/MS), to analyse volatile and semi volatile compounds including aldehydes and ketons. To investigate the acute toxicity of the exhaust water a 24 h ecotoxicological test was preformed with the crustacean Artemia fransiscana.</p><p>The results showed considerable differences in emissions of poly aromatic hydrocarbons (PAHs) and alkylated benzenes. From diesel EC1, the amounts of PAHs and alkylated benzenes were significantly higher than from pure FT-diesel and FT-diesel containing 20 % of RME. Pure FT-diesel generated the lowest amounts of PAH and alkylated benzenes. The FT-diesel containing 20 % RME generated higher amounts of benzene than diesel EC1. FT-diesel and FT-diesel with a 20 % blend of RME generated the same amount of acetone, which in turn was higher than the concentration of acetone in the exhaust water, using diesel EC1. Based on the analysis, FT-diesel is the best alternative from an exhaust emission point-of-view, concerning both the amounts and the difference in chemical composition of the combustion products released into the water.</p><p>The ecotoxicological test showed no effect on the test organism using either of the samples.</p> / <p>Fritidsbåtsintresset är stort i Sverige och båtlivet betyder mycket för många svenskar. Tyvärr är användningen av fritidsbåtar förknippad med en rad miljöproblem. Avgasutsläpp till vatten och luft från fritidsbåtsmotorer påverkar den lokala miljön avsevärt. Gammal teknik med dålig förbränning används fortfarande i stor utsträckning. På kort sikt, innan den gamla tekniken är utbytt, är det viktigt att den äldre motorparken använder miljöanpassade bränslen för att utsläppen till sjöar och hav ska bli så skonsamma som möjligt. Det är dock viktigt att utvärdera miljöpåverkan av dessa alternativa bränslen, så att det verkligen är ett bättre alternativ ur miljösynpunkt.</p><p>I detta examensarbete har utsläpp till vatten från dieselinombordsmotorer vid drift med olika bränslen undersökts. Två miljöanpassade dieselbränslen; FT-diesel (Fischer-Tropsch) och en procentinblandning av rapsmetylester (RME) i FT-diesel, har jämförts med diesel av svensk miljöklass 1 (MK1). Bränslena har testkörts i två äldre, marina dieselmotorer och prover har tagits på det avgasblandade kylvattnet innan det når recipienten. Det avgasblandade kylvattnet har analyserats med avseende på delvis flyktiga och flyktiga föreningar, aldehyder samt ketoner. Analyserna har skett med gaskromatografi och masspektormetri (GC/MS-screening) på externt laboratorium. För att testa avgasvattnets akuta giftighet har även ett akut (24h) ekotoxikologiskt test utförts på kräftdjuret Artemia fransiscana.</p><p>Analysresultatet visade skillnad i utsläpp av polyaromatiska kolväten (PAH) och alkylbensener. Vid körning med diesel MK1 genererades betydligt högre halter av PAH:er och alkylbensener, än vid körning med FT-diesel och FT-diesel med 20 % inblandning av RME. Ren FT-diesel gav de lägsta halterna av PAH:er och alkylbensener.</p><p>Utsläppshalterna av bensen uppvisade inte lika stor skillnad mellan de olika bränslena. Blandningen FT-diesel med 20 % RME gav lite högre halter bensen än vad diesel MK1 gjorde. Ren FT-diesel uppvisade lägst halt bensen. Utsläpp av aceton visade sig vara lika för FT-diesel och FT-diesel med 20 % RME och gav högre halter än vad diesel MK1 gjorde. Baserat på analysresultaten är FT-diesel det bästa bränslet ur emissionssynpunkt med avseende på vilka ämnen som hamnar i vattenfasen.</p><p>Det ekotoxikologiska testet visade ingen skillnad mellan de olika bränslena. Avgasvatten från bränslena hade inte någon akut toxisk effekt på testdjuret.</p> diesel engine combustion emission FT-diesel RME PAH alkylated benzenes GC/MS ecotoxicological test Environmental toxicology Miljötoxikologi
130	Coupling of CFD analysis of the coolant flow with the FE thermal analysis of a diesel engine Eroglu, Sinan January 2007 (has links) In the process of engine design, it is important for the engine designer to predict the accurate component temperatures. Controlling the temperature of engine components requires a better understanding of the coolant behaviour in the coolant jacket of an engine which is critical to internal combustion engine design, The studies reported in the literature emphasize the influence of the cooling system on other engine operation such as exhaust emission, fuel consumption and engine wear. In this context, much work has been done with the purpose of improving the coolant jacket design and components of the cooling system to achieve higher performance. (Some of these studies) Previous researches have shown the possibility of achieving higher engine efficiency and performance with higher coolant temperature. This project aims at understanding the coolant flow behaviour in the coolant jackets of a diesel engine and investigating the possibility of running the engine at higher coolant temperatures by predicting the temperature distribution of the structure which is required for the assessment of the durability ofthe engine components. In this thesis, CFD (Computational Fluid Dynamics) and FE (Finite Element) techniques are used to study coolant flow in the coolant jackets and to predict the temperature distribution within the engine structure respectively. The objectives are to develop an FE model of the engine structure for thermal analyses and a CFD model of the fluid domain for the coolant flow CFD analyses. A number of case studies are carried out with the purpose of determining the most suitable technique for accurate temperature prediction. The methodology of manual coupling approach between CFD and FE analyses, which is more widely used in industry, and conjugate approach are demonstrated. Using these approaches, thermal analysis of the engine is conducted with the purpose of identifying the thermally critical locations throughout the engine. Furthermore, the influences of higher coolant temperature on these thermally critical regions of the engine are highlighted by carrying out four case studies with coolant inlet temperatures of 110°C, !ISOC, 117.5"C and !20°C. The temperature rise at the particular points around thermally critical regions is found to be in the range of 3-9 degrees at the higher coolant temperatures. This slight increase in temperature of critical locations may affect the durability of the structure. However, without carrying out the structural analyses it is not possible to comment on the durability of the engine structure. The effects of surface roughness and viscosity on heat transfer rate are also investigated and shown to be insignificant. 629.2

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