Spelling suggestions: "subject:"aydrogen -- bthermal properties"" "subject:"aydrogen -- 3thermal properties""
1 |
Transport phenomena in microchannels and proton exchange membrane assemblies of fuel cellsChedester, R. Clint 08 1900 (has links)
No description available.
|
2 |
Three-dimensional transient numerical study of hot-jet ignition of methane-hydrogen blends in a constant-volume combustorKhan, Md Nazmuzzaman January 2015 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Ignition by a jet of hot combustion product gas injected into a premixed combustible mixture from a separate pre-chamber is a complex phenomenon with jet
penetration, vortex generation, flame and shock propagation and interaction. It has
been considered a useful approach for lean, low-NOx combustion for automotive engines, pulsed detonation engines and wave rotor combustors. The hot-jet ignition
constant-volume combustor (CVC) rig established at the Combustion and Propulsion
Research Laboratory (CPRL) of the Purdue School of Engineering and Technology
at Indiana University-Purdue University Indianapolis (IUPUI) is considered for numerical study. The CVC chamber contains stoichiometric methane-hydrogen blends,
with pre-chamber being operated with slightly rich blends. Five operating and design
parameters were investigated with respect to their eff ects on ignition timing. Di fderent pre-chamber pressure (2, 4 and 6 bar), CVC chamber fuel blends (Fuel-A: 30%
methane + 70% hydrogen and Fuel-B: 50% methane + 50% hydrogen by volume), active radicals in pre-chamber combusted products (H, OH, O and NO), CVC chamber
temperature (298 K and 514 K) and pre-chamber traverse speed (0.983 m/s, 4.917
m/s and 13.112 m/s) are considered which span a range of fluid-dynamic mixing and
chemical time scales. Ignition delay of the fuel-air mixture in the CVC chamber is
investigated using a detailed mechanism with 21 species and 84 elementary reactions
(DRM19). To speed up the kinetic process adaptive mesh refi nement (AMR) based
on velocity and temperature and multi-zone reaction technique is used.
With 3D numerical simulations, the present work explains the e ffects of pre-chamber pressure, CVC chamber initial temperature and jet traverse speed on ignition for a speci fic set of fuels. An innovative post processing technique is developed
to predict and understand the characteristics of ignition in 3D space and time.
With the increase of pre-chamber pressure, ignition delay decreases for Fuel-A
which is the relatively more reactive fuel blend. For Fuel-B which is relatively less
reactive fuel blend, ignition occurs only for 2 bar pre-chamber pressure for centered
stationary jet. Inclusion of active radicals in pre-chamber combusted product decreases the ignition delay when compared with only the stable species in pre-chamber
combusted product. The eff ects of shock-flame interaction on heat release rate is observed by studying flame surface area and vorticity changes. In general, shock-flame
interaction increases heat release rate by increasing mixing (increase the amount of
deposited vorticity on flame surface) and flame stretching. The heat release rate is
found to be maximum just after fast-slow interaction.
For Fuel-A, increasing jet traverse speed decreases the ignition delay for relatively
higher pre-chamber pressures (6 and 4 bar). Only 6 bar pre-chamber pressure is
considered for Fuel-B with three di fferent pre-chamber traverse speeds. Fuel-B fails
to ignite within the simulation time for all the traverse speeds.
Higher initial CVC temperature (514 K) decreases the ignition delay for both fuels
when compared with relatively lower initial CVC temperature (300 K). For initial
temperature of 514 K, the ignition of Fuel-B is successful for all the pre-chamber
pressures with lowest ignition delay observed for the intermediate 4 bar pre-chamber
pressure. Fuel-A has the lowest ignition delay for 6 bar pre-chamber pressure.
A speci fic range of pre-chamber combusted products mass fraction, CVC chamber
fuel mass fraction and temperature are found at ignition point for Fuel-A which were
liable for ignition initiation. The behavior of less reactive Fuel-B appears to me more
complex at room temperature initial condition. No simple conclusions could be made
about the range of pre-chamber and CVC chamber mass fractions at ignition point.
|
3 |
Experimental investigation on traversing hot jet ignition of lean hydrocarbon-air mixtures in a constant volume combustorChinnathambi, Prasanna 12 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / A constant-volume combustor is used to investigate the ignition initiated by a
traversing jet of reactive hot gas, in support of combustion engine applications that include novel wave-rotor constant-volume combustion gas turbines and pre-chamber IC engines. The hot-jet ignition constant-volume combustor rig at the Combustion and Propulsion Research Laboratory at the Purdue School of Engineering and Technology at Indiana
University-Purdue University Indianapolis (IUPUI) was used for this study. Lean premixed combustible mixture in a rectangular cuboid constant-volume combustor is ignited by a hot-jet traversing at different fixed speeds. The hot jet is issued via a converging nozzle
from a cylindrical pre-chamber where partially combusted products of combustion are produced by spark- igniting a rich ethylene-air mixture. The main constant-volume combustor (CVC) chamber uses methane-air, hydrogen-methane-air and ethylene-air
mixtures in the lean equivalence ratio range of 0.8 to 0.4. Ignition delay times and ignitability of these combustible mixtures as affected by jet traverse speed, equivalence ratio, and fuel type are investigated in this study.
|
4 |
Numerical study of hot jet ignition of hydrocarbon-air mixtures in a constant-volume combustorKarimi, Abdullah January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Ignition of a combustible mixture by a transient jet of hot reactive gas is important for safety of mines, pre-chamber ignition in IC engines, detonation initiation, and in novel constant-volume combustors. The present work is a numerical study of the hot-jet ignition process in a long constant-volume combustor (CVC) that represents a wave-rotor channel. The mixing of hot jet with cold mixture in the main chamber is first studied using non-reacting simulations. The stationary and traversing hot jets of combustion products from a pre-chamber is injected through a converging nozzle into the main CVC chamber containing a premixed fuel-air mixture. Combustion in a two-dimensional analogue of the CVC chamber is modeled using global reaction mechanisms, skeletal mechanisms, and detailed reaction mechanisms for four hydrocarbon fuels: methane, propane, ethylene, and hydrogen. The jet and ignition behavior are compared with high-speed video images from a prior experiment. Hybrid turbulent-kinetic schemes using some skeletal reaction mechanisms and detailed mechanisms are good predictors of the experimental data. Shock-flame interaction is seen to significantly increase the overall reaction rate due to baroclinic vorticity generation, flame area increase, stirring of non-uniform density regions, the resulting mixing, and shock compression. The less easily ignitable methane mixture is found to show higher ignition delay time compared to slower initial reaction and greater dependence on shock interaction than propane and ethylene.
The confined jet is observed to behave initially as a wall jet and later as a wall-impinging jet. The jet evolution, vortex structure and mixing behavior are significantly
different for traversing jets, stationary centered jets, and near-wall jets. Production of unstable intermediate species like C2H4 and CH3 appears to depend significantly on the initial jet location while relatively stable species like OH are less sensitive. Inclusion of minor radical species in the hot-jet is observed to reduce the ignition delay by 0.2 ms for methane mixture in the main chamber. Reaction pathways analysis shows that ignition delay and combustion progress process are entirely different for hybrid turbulent-kinetic scheme and kinetics-only scheme.
|
Page generated in 0.1177 seconds