Abstract
This paper presents a joint experimental and numerical study on premixed laminar ammonia/methane/air flames, aiming to characterize the flame structures and NO formation and determine the laminar flame speed under different pressure, equivalence ratio, and ammonia fraction in the fuel. The experiments were carried out in a lab-scale pressurized vessel with a Bunsen burner installed with a concentric co-flow of air. Measurements of NH and NO distributions in the flames were made using planar laser-induced fluorescence. A novel method was presented for determination of the laminar flame speed from Bunsen-burner flame measurements, which takes into account the non-uniform flow in the unburned mixture and local flame stretch. NH profiles were chosen as flame front markers. Direct numerical simulation of the flames and one-dimensional chemical kinetic modeling were performed to enhance the understanding of flame structures and evaluate three chemical kinetic mechanisms recently reported in the literature. The stoichiometric and fuel-rich flames exhibit a dual-flame structure, with an inner premixed flame and an outer diffusion flame. The two flames interact, which affects the NO emissions. The impact of the diffusion flame on the laminar flame speed of the inner premixed flame is however minor. At elevated pressures or higher ammonia/methane ratios, the emission of NO is suppressed as a result of the reduced radical mass fraction and promoted NO reduction reactions. It is found that the laminar flame speed measured in the present experiments can be captured by the investigated mechanisms, but quantitative predictions of the NO distribution require further model development.
Highlights
The growing demand of energy and the urgent need of reducing the emission of greenhouse gases are the main drivers of the development of disruptive technologies for clean power production
We focus on the analysis of the laminar flame speed and the nitric oxide (NO) distribution from experiments and numerical simulations
The structure and laminar flame speed have been investigated for laminar premixed ammonia/methane/air jet flames in a pressurized constant-pressure vessel under a range of equivalence ratios (0.8−1.2), pressures (1−3 bar), and ammonia/methane molar ratios (0.2−0.8)
Summary
The growing demand of energy and the urgent need of reducing the emission of greenhouse gases are the main drivers of the development of disruptive technologies for clean power production. For land-based applications, solar-, wind-, and biomass-based energy production systems have been developed extensively.[1] For other applications, such as maritime transportation, vehicles, and power generation in places depleted of natural resources, other solutions must be implemented, and as a result of the requirements in terms of energy density and reliability, the use of combustion systems running carbon-neutral or carbon-free fuels has been suggested.[2−5]. Ammonia (NH3) is considered a possible candidate fuel in the future carbon-free energy system.[2,3] It is cost-effective to produce, being mainly formed by the traditional Haber−Bosch process, using hydrogen (H2) as a source. Ammonia is safe and simple to transport and store, especially when compared to other carbon-free fuels, such as hydrogen, as a result of its low reactivity and low pressure of condensation, which allows it to be stored in liquid form at ambient temperature and pressure as low as 10 bar
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