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Uncertainty analysis of net heat release rate predictions in a single cylinder pilot compression ignited natural gas engineMarvel, Brandon T 13 December 2008 (has links)
A zero dimensional single zone model was developed to determine the crank resoled heat release rate at various injection timings (15°-60° BTDC) and the associated uncertainties from a pilot ignited natural gas engine. The uncertainty analysis examines the percentage contribution from various sources of error, including cylinder pressure measurements, intake manifold pressure measurements, and the impact of assumptions such as constant versus temperature dependent specific heat ratios. In particular, uncertainty percentage contributions and uncertainty magnification factors were used to quantify and compare the uncertainties in heat release rates using temperature dependent specific heat ratio correlations to constant specific heat ratio assumption. It is demonstrated that the error associated with the constant specific heat ratio assumption contributes to about 40 percent error (full scale value) in the net heat release estimates in comparison to using temperature dependent specific heat ratio correlations.
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Outdoor Gas Emission Sampling System: A Novel Method for Quantification of Fires in Outdoor ConditionsTukaew, Panyawat 02 May 2017 (has links)
This study presents the design, construction and testing of an Outdoor Gas Emission Sampling (OGES) System capable of gas sampling and calorimetry in outdoor conditions with wind. In large-scale, outdoor fire tests, wind-driven emission plumes present a challenge in heat release rate quantification because the emission plume rises upward at an angle. A new gas sampling system with a flexible hood design and smaller control volume has been designed and tested. Bulk flow rate, oxygen, carbon dioxide, and carbon monoxide concentrations are measured for heat release rate calculations. Two stages of experimentation are described. Experiments at intermediate-scale (indoor only) that were conducted to evaluate the performance of a smaller control volume for measurements, and large-scale (indoor and outdoor) experiments, to demonstrate feasibility in realistic field conditions as well as the new flexible hood design. Experiments show that the OGES system is capable of calculating the heat release rate of pool fires with an accuracy of 23% using oxygen consumption (OC) and carbon dioxide generation (CDG) methods. Further improvements of the OGES system for outdoor field deployment are also discussed.
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Linear Modeling and Analysis of Thermoacoustic Instabilities in a Gas Turbine CombustorFannin, Christopher A. 29 July 2000 (has links)
A dynamic model is developed for the purpose of predicting stability characteristics of an industrial-scale, swirl-stabilized premixed combustor located at the National Energy Technology Laboratory (NETL) in Morgantown, WV. The model consists of modular blocks that assemble into an open-loop transfer function depicting the frequency response of the thermoacoustic system. These blocks include the system acoustic response to unsteady heat release forcing, the air-side coupling of acoustic particle velocity to inlet fuel mass fraction, transport delays present in the mixing nozzle and combustion chamber, and dynamic heat release excitation from unsteady inlet fuel mass fraction. By examing the frequency response with linear stability techniques, the existence of limit cycles due to linear instabilities is predicted. Further, the frequency response analysis is used to predict limit cycle frequencies in the case of predicted instability. The analysis predictions are compared with the results of tests performed at NETL, demonstrating a capability of replicating many of the observed stability characteristics. / Ph. D.
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Virtual Sensors for Combustion Parameters Based on In-Cylinder Pressure / Skattning av förbränningsparametrar baserat på cylindertryckmätningJohansson, Tobias January 2015 (has links)
Typically the combustion in engines are open-loop controlled. By using an in-cylinder pressure sensor it is possible to create virtual sensors for closed-loop combustion control (CLCC). With CLCC it is possible to counteract dynamic effects as component ageing, fuel type and cylinder variance. A virtual sensor system was implemented based on a one-zone heat-release analysis, including signal processing of the pressure sensor input. A parametrisation of the heat-release based on several Vibe functions was implemented with good results. The major focus of the virtual sensor system was to perform a tolerance analysis on experimental data, where typical error sources in a production heavy-duty vehicle were identified and their effect on the estimates quantified. It could be concluded that estimates are very much dependent on the choice of heat-release and specific heat ratio models. Especially crank angle phasing has a large impact on estimation performance, stressing the importance of accounting for crankshaft torsion in production vehicles. Biodiesel advances the combustion angle and give a lower IMEP and total heat amount compared to standard diesel. However, error sensitivity is not affected. Further investigations must be made on improving the signal processing in terms of gain error compensation and filtering. Also a better understanding of how errors propagate between subsystems in a CLCC system is required for successful implementation.
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Dynamics of confined fire plumes : a study of interactions between fires and surfacesXing, Hui Juan January 2001 (has links)
No description available.
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Heat release effects on decaying homogeneous compressible turbulenceLee, Kurn Chul 15 May 2009 (has links)
High Mach-number compressible flows with heat release are inherently more
complicated than incompressible flows due to, among other reasons, the activation
of the thermal energy mode. Such flow fields can experience significant fluctuations
in density, temperature, viscosity, conductivity and specific heat, which affect velocity
and pressure fluctuations. Furthermore, the flow field cannot be assumed to be
dilatation-free in high Mach numbers and even in low Mach-number flows involving
combustion, or in boundary layers on heated walls. The main issue in these
high-speed and highly-compressible flows is the effect of thermal gradients and fluctuations
on turbulence. The thermal field has various routes through which it affects
flow structures of compressible turbulence. First, it has direct influence through pressure,
which affects turbulence via pressure-strain correlation. The indirect effects of
thermal fields on compressible turbulence are through the changes in flow properties.
The high temperature gradients alter the transport coefficient and compressibility of
the flow. The objective of this work is to answer the following questions: How do
temperature fluctuations change the compressible flow structure and energetics? How
does compressibility in the flow affect the non-linear pressure redistribution process?
What is the main effect of spatial transport-coefficient variation? We perform direct
numerical simulations (DNS) to answer the above questions. The investigations are categorized into four parts: 1) Turbulent energy cascade and kinetic-internal energy
interactions under the influence of temperature fluctuations; 2) Return-to-isotropy of
anisotropic turbulence under the influence of large temperature fluctuations; 3) The
effect of turbulent Mach number and dilatation level on small-scale (velocity-gradient)
dynamics; 4) The effect of variable transport-coefficients (viscosity and diffusivity) on
cascade and dissipation processes of turbulence. The findings lead to a better understanding
of temperature fluctuation effects on non-linear processes in compressible
turbulence. This improved understanding is expected to provide direction for improving
second-order closure models of compressible turbulence.
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拡散火炎のPLIF計測と熱発生速度の検討YAMASHITA, Hiroshi, HAYASHI, Naoki, YAMAMOTO, Kazuhiro, ASADA, Yasuo, 山下, 博史, 林, 直樹, 山本, 和弘, 麻田, 泰生 05 1900 (has links)
No description available.
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Spatial and temporal distribution of latent heating in the South Asian monsoon regionZuluaga-Arias, Manuel D. January 2009 (has links)
Thesis (M. S.)--Earth and Atmospheric Sciences, Georgia Institute of Technology, 2010. / Committee Chair: Peter J. Webster; Committee Member: Judith A. Curry; Committee Member: Robert X. Black. Part of the SMARTech Electronic Thesis and Dissertation Collection.
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Controlling Object Heat Release Rate using Geometrical FeaturesKraft, Stefan Marc 08 June 2017 (has links)
An experimental study was conducted to determine the effect of complex geometries on the burning rate of materials made using additive manufacturing. Controlling heat release rate has applicability in limiting fire hazards as well as for designing fuels for optimal burning rate. The burning rate of a structure is a function of the material properties as well as the airflow through it, which is dictated by the geometry. This burning rate is generally proportional to the porosity for objects in which the flow is limited by the path constriction. The relations between porosity and burning rate are well studied for wood cribs, which are layers of wood sticks. Crib and other objects with various geometric features were constructed of ABS plastic and coal powder using additive manufacturing processes. A cone calorimeter using oxygen calorimetry was used to measure the heat release rate of the crib specimens. Within the flow limited burning regime, the burning rate of an object is proportional to the porosity factor. Porosity factors calculated from a 1-D theoretical burn rate model as well as from two empirical models were found to correlate the heat release rate results for the crib samples. The heat release rate results of the complex geometries generally correlated to the same porosity factor; however, the model was modified to account for differences between regularly shaped cribs and objects with different sized flow areas. Using the empirical models provides good correlation for the crib burning data and gives a clearer delineation between the flow-limited and surface area controlled regimes. / Master of Science / An experimental study was conducted to determine the effect of complex geometries on the burning rate of materials made using additive manufacturing. Burning rate of objects is dependent on material composition, as well as on the shape of the object itself. Controlling burning rate has applicability in limiting fire hazards in built environments, as well as in the design of fuels. The burning rate of a structure is related to the type of material and the capacity for airflow through it. This burning rate is generally proportional to a defined parameter called a porosity factor, which can encompass geometric and material properties. Relationships between porosity and burning rate for cribs, layered wood objects, have been established. In this work, cribs and more geometrically complex objects were constructed of red oak, ABS plastic and coal powder. The constructed specimens were burned and resulting data evaulated. These data were also used to compare empirical and theoretical crib porosity models. Burning rate results of the objects with complex geometries generally correlated to the same porosity factors; however, the models were modified to account for differences between regularly shaped cribs and objects with different sized flow areas. Using the empirical models provides good correlation for the burning rate data and requires less analytical effort than does the theoretical model.
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Experimental Study of the Role of Intermediate-Temperature Heat Release on Octane SensitivityPeterson, Jonathan 07 1900 (has links)
Increasing the efficiency of the spark-ignition engine can help to reduce the environmental impact of the transportation sector. Engine knock obstructs the increased efficiency that could be gained by increasing the compression ratio in a spark-ignition (SI) engine.
A fuel’s propensity to knock is measured by the research octane number (RON) and the motor octane number (MON) in a co-operative fuel research (CFR) engine. A fuel’s octane sensitivity (OS) is the difference between the RON and MON. Modern downsized and turbocharged engines operate at what is considered to be beyond-RON conditions. Studies have shown that having a fuel with higher OS improves knock resistance at beyond-RON conditions.
This study aims to gain a better understanding of the role of intermediate-temperature heat release (ITHR) in defining OS and its subsequent impact on SI operation through the experimental framework. The ITHR of toluene primary reference fuels (TPRFs) fuels with matching RON and varying OS was studied at RON-like and MON-like homogeneous charge compression ignition (HCCI) conditions for two different matching criteria.
The first criterion was to control the combustion phasing by matching half of the heat release (CA50) to 3 crank angle degrees after top dead center. The second criterion was to match the compression ratios.
Results showed that at RON-like HCCI conditions, TPRF fuels display decreasing ITHR with increasing OS. Furthermore, it was shown that TPRF fuels with low sensitivity displayed a greater increase in ITHR from MON-like conditions to RON-like conditions. Thus, the sensitivity of ITHR to changes in operating conditions was found to be a contributing factor to OS.
In the beyond-RON conditions (relevant to current modern engines), there is a potential for improved engine efficiency by using fuels with high OS to allow for higher compression ratios. The experimental results of this work show that OS is negatively correlated with ITHR. Thus, high-sensitivity fuels can be designed by choosing components and additives that reduce the amount of ITHR.
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