Global ETD Search

1	Spray development and combustion in direct injection diesel engines Cho, Sung Taek January 1999 (has links) No description available. 621.43 Exhaust gas recirculation
2	Utilizing a cycle simulation to examine the use of exhaust gas recirculation (EGR) for a spark-ignition engine: including the second law of thermodynamics Shyani, Rajeshkumar Ghanshyambhai 10 October 2008 (has links) The exhaust gas recirculation (EGR) system has been widely used to reduce nitrogen oxide (NOx) emission, improve fuel economy and suppress knock by using the characteristics of charge dilution. However, previous studies have shown that as the EGR rate at a given engine operating condition increases, the combustion instability increases. The combustion instability increases cyclic variations resulting in the deterioration of engine performance and increasing hydrocarbon emissions. Therefore, the optimum EGR rate should be carefully determined in order to obtain the better engine performance and emissions. A thermodynamic cycle simulation of the four-stroke spark-ignition engine was used to determine the effects of EGR on engine performance, emission characteristics and second law parameters, considering combustion instability issues as EGR level increases. A parameter, called 'Fuel Fraction Burned,' was introduced as a function of the EGR percentage and used in the simulation to incorporate the combustion instability effects. A comprehensive parametric investigation was conducted to examine the effects of variations in EGR, load and speed for a 5.7 liter spark-ignition automotive engine. Variations in the thermal efficiencies, brake specific NOx emissions, average combustion temperature, mean exhaust temperature, maximum temperature and relative heat transfer as functions of exhaust gas recycle were determined for both cooled and adiabatic EGR configurations. Also effects of variations in the load and speed on thermal efficiencies, relative heat transfers and destruction of availability due to combustion were determined for 0% EGR and 20% EGR cases with both cooled and adiabatic configurations. For both EGR configurations, thermal efficiencies first increase, reach a maximum at about 16% EGR and then decrease as the EGR level increases. Thermal efficiencies are slightly higher for cooled EGR configuration than that for adiabatic configuration. Concentration of nitric oxide emissions decreases from about 2950 ppm to 200 ppm as EGR level increases from 0% to 20% for cooled EGR configuration. The cooled EGR configuration results in lower nitric oxide emissions relative to the adiabatic EGR configuration. Also second law parameters show the expected trends as functions of EGR. Brake thermal efficiency is higher for the 20% EGR case than that for the no EGR case over the range of load (0 to WOT) and speed (600 rpm to 6000 rpm). Predictions made from the simulation were compared with some of the available experimental results. Predicted thermal efficiencies showed a similar trend when compared to the available experimental data. Also, percentage of unused fuel availability increases as the EGR level increases, and it can be seen as one of the effects of deteriorating combustion quality as the EGR level increases. Exhaust Gas Recirculation Availability Combustion Instabilities
3	Transient optimisation of a diesel engine Wijetunge, Roshan January 2001 (has links) No description available. 621.43
4	Computation and Analysis of EGR Mixing in Internal Combustion Engine Manifolds Sakowitz, Alexander January 2013 (has links) This thesis deals with turbulent mixing processes occurring in internal combustion engines, when applying exhaust gas recirculation (EGR). EGR is a very efficient way to reduce emissions of nitrogen oxides (NOx) in internal combustion engines. Exhaust gases are recirculated and mixed with the fresh intake air, reducing the oxygen con- centration of the combustion gas and thus the peak combustion temperatures. This temperature decrease results in a reduction of NOx emissions. When applying EGR, one is often faced with non-uniform distribution of exhaust among and inside the cylinders, deteriorating the emission performance. The mixing of exhaust gases and air is governed by the flow in the engine intake manifold, which is characterized by unsteadiness due to turbulence and engine pulsations. Moreover, the density cannot be assumed to be constant due to the presence of large temperature variations.Different flow cases having these characteristics are computed by compressible Large Eddy Simulations (LES). First, the stationary flows in two T-junction type geometries are investigated. The method is validated by comparison with experimental data and the accuracy of the simulations is confirmed by grid sensitivity studies. The flow structures and the unsteady flow modes are described for a range of mass flow ratios between the main and the branch inlet. A comparison to RANS computations showed qualitatively different flow fields.Thereafter, pulsating inflow conditions are prescribed on the branch inlet in or- der to mimic the large pulsations occurring in the EGR loop. The flow modes are investigated using Dynamical Mode Decomposition (DMD).After having established the simulation tool, the flow in a six-cylinder engine is simulated. The flow is studied by Proper Orthogonal Decomposition (POD) and DMD. The mixing quality is studied in terms of cylinder-to-cylinder non-uniformity and temporal and spatial variances. It was found that cycle-averaging of the concentration may give misleading results. A sensitivity study with respect to changes in the boundary conditions showed that the EGR pulsations, have large influence on the results. This could also be shown by POD of the concentration field showing the significance of the pulses for the maldistribution of exhaust gases.Finally, the flow in an intake manifold of a four-cylinder engine is investigated in terms of EGR distribution. For this geometry, pipe bends upstream of the EGR inlet were found to be responsible for the maldistribution. / <p>QC 20130207</p> Turbulent Mixing Large Eddy Simulation URANS Internal Combustion Engines Intake Manifolds T-junction Exhaust Gas Recirculation
5	Combustion and emission characteristics of biofuels in diesel engines Labecki, Lukasz January 2010 (has links) This study was concerned with the performance of biofuels in diesel engines. Generally, the basic combustion and emission characteristics of Rapeseed Oil (RSO) and Soya Oil (SO) result in a lower in-cylinder pressure peak than diesel. This led to the reduction of Nitrogen Oxides (NOx) emissions and to relatively high soot emissions. Further measurements of RSO were done in order to investigate the influence of injection pressure, injection timing and Exhaust Gas Recirculation (EGR) on combustion and emission characteristics. A high soot emission from RSO was reduced by increased injection pressure. Moreover, injection timing also had to be varied in order to reduce the soot emissions from RSO. The retarded injection timing (3 deg bTDC) and increased injection pressure (1200 bar) for the blend of 30% RSO resulted in a reduction of soot emission to the same level as from diesel fuel. Further investigation regarding the soot emissions was done for Rapeseed Methyl Ester (RME) under turbocharged engine operation. The application of the boost pressure resulted in stable engine operation at a late injection timing of 5 deg aTDC. A simultaneous reduction of soot and NOx emissions has been achieved for RME at an injection timing of TDC and high EGR percentage (40 – 50 %). The soot particles size distribution under different engine operating conditions for RME and diesel has also been investigated. Moreover, the characteristic of Electrostatic Mobility Spectrometer (EMS) and the design of primary dilution system have been provided in order to understand the influence of the dilution process and to obtain more real results. Generally, RME showed less particles concentration in the nucleation mode when compared to diesel. Moreover, high EGR caused a shift of the particles from the nucleation mode by agglomeration into the accumulation mode for both fuels. The effect of injection pressure could only be seen in the accumulation mode, where high injection pressure slightly reduced the concentration number. The soot emission was effectively reduced by the usage of the diesel particulate filter (DPF). For this purpose, the soot particles size distributions before and after the DPF have been measured at different engine speeds and loads. At low engine torque, the soot was effectively filtered while the operation under high engine loads resulted in low soot particle concentration especially in the nucleation mode, after the DPF. 621.43
6	Study of power plant with carbon dioxide capture ability through modelling and simulation Biliyok, Chechet January 2013 (has links) With an increased urgency for global action towards climate change mitigation, this research was undertaken with the aim of evaluating post-combustion CO2 capture as an emission abatement strategy for gas-fired power plants. A dynamic rate-based model of a capture plant with MEA solvent was built, with imposed chemical equilibrium, and validated at pilot scale under transient conditions. The model predicted plant behaviour under multiple process inputs and disturbances. The validated model was next used to analyse the process and it was found that CO2 absorption is mass transfer limited. The model was then improved by explicitly adding reactions rate in the model continuity, the first such dynamic model to be reported for the capture process. The model is again validated and is observed to provide better predictions than the previous model. Next, high fidelity models of a gas-fired power plant, a scaled-up capture plant and a compression train were built and integrated for 90% CO2 capture. Steam for solvent regeneration is extracted from the power plant IP/LP crossover pipe. Net efficiency drops from 59% to 49%, with increased cooling water demand. A 40% exhaust gas recirculation resulted in a recovery of 1% efficiency, proving that enhanced mass transfer in the capture plant reduces solvent regeneration energy demands. Economic analysis reveals that overnight cost increases by 58% with CO2 capture, and cost of electricity by 30%. While this discourages deployment of capture technology, natural gas prices remain the largest driver for cost of electricity. Other integration approaches – using a dedicated boiler and steam extraction from the LP steam drum – were explored for operational flexibility, and their net efficiencies were found to be 40 and 45% respectively. Supplementary firing of exhaust gas may be a viable option for retrofit, as it is shown to minimise integrated plant output losses at a net efficiency of 43.5%. Areas identified for further study are solvent substitution, integrated plant part load operation, flexible control and use of rotating packed beds for CO2 capture. 621.31
7	Study of power plant with carbon dioxide capture ability through modelling and simulation Biliyok, Chechet 11 1900 (has links) With an increased urgency for global action towards climate change mitigation, this research was undertaken with the aim of evaluating post-combustion CO2 capture as an emission abatement strategy for gas-fired power plants. A dynamic rate-based model of a capture plant with MEA solvent was built, with imposed chemical equilibrium, and validated at pilot scale under transient conditions. The model predicted plant behaviour under multiple process inputs and disturbances. The validated model was next used to analyse the process and it was found that CO2 absorption is mass transfer limited. The model was then improved by explicitly adding reactions rate in the model continuity, the first such dynamic model to be reported for the capture process. The model is again validated and is observed to provide better predictions than the previous model. Next, high fidelity models of a gas-fired power plant, a scaled-up capture plant and a compression train were built and integrated for 90% CO2 capture. Steam for solvent regeneration is extracted from the power plant IP/LP crossover pipe. Net efficiency drops from 59% to 49%, with increased cooling water demand. A 40% exhaust gas recirculation resulted in a recovery of 1% efficiency, proving that enhanced mass transfer in the capture plant reduces solvent regeneration energy demands. Economic analysis reveals that overnight cost increases by 58% with CO2 capture, and cost of electricity by 30%. While this discourages deployment of capture technology, natural gas prices remain the largest driver for cost of electricity. Other integration approaches – using a dedicated boiler and steam extraction from the LP steam drum – were explored for operational flexibility, and their net efficiencies were found to be 40 and 45% respectively. Supplementary firing of exhaust gas may be a viable option for retrofit, as it is shown to minimise integrated plant output losses at a net efficiency of 43.5%. Areas identified for further study are solvent substitution, integrated plant part load operation, flexible control and use of rotating packed beds for CO2 capture. post-combustion MEA dynamic modelling model validation combined cycle NGCC CCGT Exhaust gas recirculation EGR
8	Návrh EGR výměníku pro recirkulaci výfukových plynů / Design of Exhaust Gas Recirculation Exchanger Bazala, Jiří January 2011 (has links) This diploma dissertation focuses on the constructional solutions of EGR exchangers in the form of a CAD model, on their CFD simulation, on the drawing of relevant conclusions, and also on the comparison of two developmental types of these exchangers.
9	<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
10	Recognizing Combustion Variability for Control of Gasoline Engine Exhaust Gas Recirculation using Information from the Ion Current Holub, Anna, Liu, Jie January 2006 (has links) <p>The ion current measured from the spark plug in a spark ignited combustion engine is used </p><p>as basis for analysis and control of the combustion variability caused by exhaust gas </p><p>recirculation. Methods for extraction of in-cylinder pressure information from the ion </p><p>current are analyzed in terms of reliability and processing efficiency. A model for the </p><p>recognition of combustion variability using this information is selected and tested on both </p><p>simulated and car data.</p> Internal combustion engines ion current exhaust gas recirculation engine control neural networks K-nearest neighbour combustion variability

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