Numerical simulation of a direct injection spark ignition engine using ethanol as fuel

Srivastava, Shalabh.

January 2008

Thesis (M.S.)--Michigan State University. Dept. of Mechanical Engineering, 2008. / Title from PDF t.p. (viewed on July 27, 2009) Includes bibliographical references (p. 119-122). Also issued in print.

Parametric studies using a mathematical model of a two-stroke cycle spark ignition engine

Sathe, Vijay Vishwanath,

January 1969

Thesis (M.S.)--University of Wisconsin--Madison, 1969. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

EXPERIMENTAL INVESTIGATION AND MODELING OF MINIMUM HOT SURFACE IGNITION TEMPERATURE FOR AVIATION FLUIDS

Mehmed S Ulcay (8802791)

07 May 2020

<p>A hot surface is one of the ignition sources which may lead to fires in the presence of aviation fluid leakage. Bleeding ducts and exhaust pipes that are at elevated temperatures are potential sources of ignition. A database of Minimum Hot Surface Ignition Temperatures (MHSIT) resulting from experiments conducted three decades ago at the Air Force Research Laboratory (AFRL), Dayton, OH has served as a valuable source of estimating safe operating temperatures. However, MHSIT for some of the aviation fluids such as Jet-A and MIL-PRF-23699 (lubrication oil) are not readily available. Further, the ranges of the hot surface and flammable liquids’ temperatures and the range of the air stream velocities need to be extended for use in higher pressure ratio and higher performance aircraft engines developed since the generation and interpretation of the original data. The air velocities (V_A) in the modern engines have increased by a factor of two and documenting their effects on the MHSIT for a range of test fluid temperatures and air temperatures (T_F, T_A) is important.</p> <p>The objectives of this study are to develop a generic test apparatus to study MHSIT and to model an air-fuel mixture space to find the range of temperatures and velocities that lead to ignition. Among various leakage scenarios, the test apparatus simulates spray (atomized particles injected through a nozzle) and stream (dripping from a 3 mm tube) injection. A semiempirical ignition model was developed using an ignition temperature and delay time expression based on an energy balance between the heat lost to the cross-stream flow, the heat added from the hot surface and the heat released by the nascent chemical reactions to estimate the MHSIT.</p> <p> </p> <p>MHSIT is measured including the effects of V_A, T_F, T_Aand the effects of obstacles. Ignition probability is evaluated as a function of the hot surface temperature. The probabilistic nature of the hot surface ignition process was established. New flammable fluids (Jet-A & MIL-PRF-23699) have been tested and MHSIT database was expanded. A large number of ignition experiments were completed to evaluate ignition probability at various flow conditions of aviation fluids: (1) Jet-A, (2) Hydraulic oil (MIL-PRF-5606) and (3) Lubrication oil (MIL-PRF-23699). Uncertainty of the experimental measurements for these tests have been documented. Air velocities were extended up to 7 m/s. Effects of flammable liquid and air temperature on MHSIT were studied. The empirical constants for the semi-empirical model were determined using these experimental data.</p><p>The ignition probability is strongly correlated with hot surface temperature and progressively weakly correlated with air velocity, fluid parcel size, air temperature, and test fluid temperature. Parameters investigated in this study are useful design choices considering MHSIT for a given flow condition.</p><p></p>

Mechanical Engineering

hot surface ignition

flammable fluids

modeling

ignition probability

Investigations of HCCI control using duel fuel strategies

Aldawood, Ali Mohammad A.

January 2014

No description available.

660

Internal combustion engines--Ignition

Scaling the thermal stability test

Nevell, Roger Thomas

January 1997

No description available.

536.7

The combustion of residual fuel oil, coal and coal slurries

Pourkashanian, M.

January 1987

No description available.

621.43

Ignition of coal slurry fuels

The chemistry of ignition improvers

Poxon, Mark David

January 1990

No description available.

547

Diesel fuel ignition improvers

The design and development of the `Watt` variable compression ratio engine

Cowley, George Russell.

January 1982

2 folded ill. in pocket Bibliography: leave 71

Second law analysis of premixed compression ignition combustion in a diesel engine using a thermodynamic engine cycle simulation

Oak, Sushil Shreekant

10 October 2008

A second law analysis of compression ignition engine was completed using a thermodynamic engine cycle simulation. The major components of availability destruction and transfer for an entire engine cycle were identified and the influence of mode of combustion, injection timing and EGR on availability balance was evaluated. The simulation pressure data was matched with the available experimental pressure data gathered from the tests on the Isuzu 1.7 L direct injection diesel engine. Various input parameters of the simulation were changed to represent actual engine conditions. Availability destruction due to combustion decreases with advanced injection timing and under premixed compression ignition (PCI) modes; but it is found to be insensitive to the level of EGR. Similarly, trends (or lack of trends) in the other components of availability balance were identified for variation in injection timing, EGR level and mode of combustion. Optimum strategy for efficient combustion processes was proposed based on the observed trends.

Second law

premixed compression ignition

Factors in charge preparation and their effect on performance and emissions from a direct injection spark ignition engine

Alger, Terrence Francis

14 March 2011

Not available / text

Mechanical engineering

Spark ignition engines