A fundamental experimental study to determine the burning rates of ethanol and ethanol-blended fossil fuels is presented. Pure liquid ethanol or its blends with liquid fossil fuels such as gasoline or diesel, has been transpired to the surface a porous sphere using an infusion pump. Burning of the fuel takes place on the surface of the porous sphere, which is placed in an air stream blowing upwards with a uniform velocity at atmospheric pressure and temperature under normal gravity conditions. At low air velocities, when ignited, a flame envelopes the sphere. For each sphere size, air stream velocity and fuel type, the fuel feed rate will vary and the same is recorded as the burning rate for that configuration. The flame stand-off distances from the sphere surface are measured by post-processing the digital image of the flame photograph using suitable imaging software. The transition velocity at which the flame moves and establishes itself at the wake region of the sphere has been determined for different diameters and fuel types. Correlations of these parameters are also presented. © 2008 The Combustion Institute.

Vasudevan Raghavan

Department of Mechanical Engineering

Shintre Parag

AIR STREAM VELOCITIES

AIR STREAMS

AIR VELOCITIES

BURNING RATES

Digital images

ETHANOL-BLENDED FUELS

Experimental investigations

Experimental studies

FEED RATES

FLAME STAND-OFF

FUEL TYPES

GRAVITY CONDITIONS

IMAGING SOFTWARES

INFUSION PUMP

POROUS SPHERE

POST-PROCESSING

PRESSURE AND TEMPERATURES

PURE LIQUIDS

SPHERE SURFACES

TRANSITION VELOCITY

WAKE REGIONS

Atmospheric pressure

Ethanol

Flammability

Fossil fuels

Liquids

Photography

Pumps

Spheres

velocity

ETHANOL FUELS

IIT Madras is a public technical and research university located in Chennai, Tamil Nadu. Founded in 1959, it is recognised as an Institute of National Importance.

IIT Madras has been ranked as the top engineering institute in India for four years in a row by the National Institutional Ranking Framework of the MHRD

It currently offers undergraduate, postgraduate and research degrees across 16 disciplines in Engineering, Sciences, Humanities and Management. About 596 faculty belonging to science and engineering departments and centres of the Institute are engaged in teaching, research and industrial consultancy.

IIT Madras

Combustion and Flame

Experimental investigation of the effect of flow turbulence on the steady state burning of methanol is reported. A vertical air tunnel has been mounted with a grid at its exit plane in order to generate turbulence in the free jet stream. The flow field has been characterized using a hot-wire anemometer. Mean and fluctuating flow velocities and integral scale have been measured at an axial location of around 2 times its exit diameter (D). Three types of grids have been used. Classical porous sphere experiments have been carried out to analyze the steady-state burning rate of methanol over the surface of an inert sphere having constant diameter. Experiments have been done at atmospheric pressure under ambient temperature and normal gravity conditions. A porous sphere is positioned at an axial location of 2D, where the approaching flow has been characterized in detail. Results show that the burning rate as well as the flame stability are greatly influenced by the free stream turbulence. The ratio of turbulent time scales and the chemical time scales for grid mounted cases have been estimated from the integral scale, root mean square velocity fluctuation, flame stand-off distance and the vapor blowing velocity. Empirical expression relating the normalized burning rates to diffusion scale based Damköhlar number has been presented. A correlation for Sherwood number as a function of Reynolds number and turbulent intensity has also been proposed. © 2017 Elsevier Ltd

International Journal of Heat and Mass Transfer

Experimental study of burning of methanol fed porous spheres in grid generated turbulent field

A numerical study of steady burning of spherical ethanol particles in a spray environment is presented. A spray environment is modeled as a high temperature oxidizer stream where the major products of combustion such as carbon dioxide and water vapor will be present along with reduced amounts of oxygen and nitrogen. The numerical model, which employs variable thermophysical properties, a global single-step reaction mechanism, and an optically thin radiation model, has been first validated against published experimental results for quasi-steady combustion of spherical ethanol particles. The validated model has been employed to predict the burning behavior of the ethanol particle in high temperature modified oxidizer environment. Results show that based on the amount of oxygen present in the oxidizer the burning rate constant is affected. The ambient temperature affects the burning rate constant only after a sufficient decrease in the oxygen content occurs. In pure air stream, ambient temperature variation does not affect the evaporation constant. Results in terms of burning rates, maximum temperature around the particle, and the evaporation rate constants are presented for all the cases. The variation of normalized Damkhler number is also presented to show the cases where combustion or pure evaporation would occur. © 2011 American Society of Mechanical Engineers.

Fulltext

Journal of Heat Transfer

Numerical modeling of steady burning characteristics of spherical ethanol particles in a spray environment

A fundamental study to investigate the emission characteristics of ethanol-blended fossil fuels is presented. Employing a heterogeneous experimental setup, emissions are measured from diffusion flames around spherical porous particles. Using an infusion pump, ethanol-fossil fuel blend is transpired into a porous sphere kept in an upward flowing air stream. A typical probe of portable digital exhaust gas analyzer is placed in and around the flame with the help of a multi-direction traversing mechanism to measure emissions such as un-burnt hydrocarbons, carbon monoxide and carbon dioxide. Since ethanol readily mixes with water, emission characteristics of ethanol-water blends are also studied. For comparison purpose, emissions from pure ethanol diffusion flames are also presented. A simplified theoretical analysis has been carried out to determine equilibrium surface temperature, composition of the fuel components in vapor-phase and heat of reaction of each blend. These theoretical predictions are used in explaining the emission characteristics of flames from ethanol blends. © 2010 Elsevier Inc.

Experimental Thermal and Fluid Science

Emissions from ethanol-blended fossil fuel flames

In this study, based on the extinction characteristics of nonpremixed flames, global single-step kinetics parameters are estimated for ethanol oxidation in air. Using a quasi-steady heterogeneous experimental setup, the air velocity at which an envelope flame surrounding the sphere transits to a wake flame that burns in the rear region of the sphere, termed as the transition or the extinction velocity, were obtained in a previous study. These extinction velocities for different sphere sizes are employed to estimate the single-step kinetics parameters. The estimated global single-step kinetics has been employed in a numerical model and extinction characteristics of opposed-flow ethanol-air diffusion flames have been predicted and validated against the available experimental results in literature.

Combustion Science and Technology

On the estimation and validation of global single-step kinetics parameters of ethanol-air oxidation using diffusion flame extinction data

Droplet combustion behaviour of an RP-1 surrogate fuel (RP-1-s), its constituents, and two novel energetic fuels – 1,3-bishomocubane dimer (BHCD) and bis(nitratomethyl)-1-3-bishomocubane (DNMBHC) was investigated. The novel energetic fuels, envisioned as potential fuels in rocket propulsion were observed to be completely miscible with RP-1-s. Experiments were also conducted on a 10% w/w mixture of BHCD in RP-1-s (BHCD10) and a 10% w/w mixture of DNMBHC in RP-1-s (DNMBHC10). Tests were carried out under ambient atmospheric conditions using the suspended droplet method. The combustion behaviour of RP-1-s as characterized by the burn rate constants and flame dimensions was found to lie between those of its constituent fuels – methylcyclohexane (MCH), n-dodecane, and isocetane. Condensed phase pyrolysis leading to droplet swelling and eventually microexplosion were observed for both BHCD and DNMBHC, and their blends with RP-1-s. DNMBHC was found to combust almost 3.5 times as fast as RP-1-s while BHCD was found to combust slightly slower than RP-1-s. Both BHCD and DNMBHC were found to be extremely sooty as compared to RP-1-s. The intensity of sooting is however expected to be much lower in an actual scenario where liquid oxygen would be used for combustion, and the droplet sizes are small. The potential of the novel energetic compounds DNMBHC and BHCD to serve as additives to RP-1-s for performance enhancement was assessed to be worthy of further exploration. © 2019 Elsevier Ltd

Fuel

Droplet combustion studies on two novel energetic propellants, an RP-1 surrogate fuel, and their blends

Entropy generation during the quasi-steady combustion of spherical liquid fuel particles has been presented in detail. The effects of freestream velocity, particle diameter, ambient temperature and gravity, on the entropy generation rate, have been discussed in detail. In the range of sub-critical freestream velocity, where an envelope flame is present, the entropy generation rate presents a minimum value. At a critical velocity, where the flame transition occurs, the entropy generation rate reaches a maximum value. Flame transition significantly affects the entropy generation rate, which suffers a sharp decrease in its value after the transition. Heat transfer and chemical reaction contribute almost equally to the total entropy generation rate. When normal gravity is considered in an upward flow configuration, there is an increase in the entropy generation rate as compared to the zero gravity case. The effect of gravity poses a complex variation pattern in the entropy generation rate, for a downward flow configuration. The entropy generation rate decreases with increasing ambient temperature. The entropy generation rate increases with the particle diameter. A correlation has been presented for the non-dimensional entropy generation number as a function of Froude number. © 2006 Elsevier Masson SAS. All rights reserved.

International Journal of Thermal Sciences

Entropy generation during the quasi-steady burning of spherical fuel particles

In this work, experimental and numerical investigations of spheres burning in a convective environment have been carried out. In the numerical simulations, transient axi-symmetric Navier-Stokes equations along with species and energy conservation equations are solved using a finite volume technique based on non-orthogonal semi-collocated grids. A global single step reaction involving two reactants, two products and one inert species together with an Arrhenius rate equation has been used to model kinetics. For the sake of comparison, an infinite rate chemistry model has also been attempted. The density of the mixture has been evaluated from ideal gas equation of state. Thermo-physical properties like thermal conductivity and viscosity have been evaluated using the Chapman-Enskog description of binary gas mixtures. Specific heats and species enthalpies have been evaluated using piece-wise polynomials of temperature. The burning of isolated spherical particles in a mixed convective environment at atmospheric pressure has been simulated for various particle sizes, free-stream velocities and ambient temperatures. The numerical predictions have been compared with experimental results obtained using the porous sphere technique and the agreement is found to be good. Correlations have been developed for the critical Reynolds number at which transition from the envelope to wake flame occurs and also for the mass burning rates at sub-critical or super-critical Reynolds number regimes. It is observed that, at higher ambient temperatures, transition to wake flame is delayed to a higher critical Reynolds number value. The infinite rate chemistry model predicts flame shapes and mass burning rates with reasonable accuracy in the sub-critical Reynolds number regime, but it fails to predict transition to wake flame shape. For analyzing transition phenomena, a finite rate chemistry model is required. © 2005 Elsevier Ltd. All rights reserved.

Flame shapes and burning rates of spherical fuel particles in a mixed convective environment

The combustion of a fuel droplet in a mixed convective environment has been simulated both theoretically and experimentally. In the theoretical model, the flow and transport equations have been solved subject to the assumptions of constant properties (except for density) and infinite rate kinetics, using the finite element method. The gas density has been treated as a variable, only to determine the buoyancy force contribution, and it has been evaluated assuming an ideal gas mixture. A porous-sphere facility has been employed for simulating the burning characteristics of a fuel droplet experimentally. The effects of airflow rate and droplet size have been studied for both upward and downward airflow configurations. Theoretical predictions for the mass burning rate and flame shape are in excellent agreement with the experimental results of the present study and also those reported in the literature. For upward airflow configuration, the mass burning rate is under-predicted by 15 to 20 percent when buoyancy effects are neglected. For downward airflow configuration, the flame shape is similar to the case of upward airflow for low air velocities. For higher downward air velocities, a flattened cylindrical flame front is obtained due to the opposing natural convection and forced convection flow fields, which has been predicted successfully. A detailed parametric study involving the variation of Reynolds number, ambient temperature and ambient oxygen concentration has also been carried out.

Combustion of a fuel droplet in a mixed convective environment

International Journal of Hydrogen Energy

Political, economic and environmental impacts of biomass-based hydrogen

Applied Thermal Engineering

Experimental determination of suitable ethanol–gasoline blend rate at high compression ratio for gasoline engine

Experimental investigation of burning rates of pure ethanol and ethanol blended fuels

Journal	Combustion and Flame
ISSN	00102180
Open Access	No