A Comparative Environmental Life Cycle Assessment of the Combustion of Ammonia/Methane Fuels in a Tangential Swirl Burner

Razón, Luis F.; Valera‐Medina, Agustin

doi:10.3389/fceng.2021.631397

Cited by 7 publications

(7 citation statements)

References 27 publications

(43 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Valera-Medina [16] Ammonia blends with methane for heat generation. Most studies conclude that current technologies used to produce green ammonia need to be improved.…”

Section: Razon Andmentioning

confidence: 99%

“…Their study focused on alkaline units, denoting that there is still work to do to improve cell lifetime, power densities, and fuel consumption for less impactful devices. Further work was presented by Razon and Valera-Medina [16], who studied ammonia in gas turbines. Blends of ammonia-methane were evaluated, with results showing that ammonia produced from nuclear or wind energy could potentially support global decarbonisation with a −27% to −32% reduction in global warming potential.…”

Section: Introductionmentioning

confidence: 99%

“…LCA studies on ammonia as a fuel for transport [11,[61][62][63] and power generation [12,15,16,64] are less numerous than studies on ammonia production solely. Even though a straightforward comparison cannot be made due to differences in functional units, impact assessment methods, and in some cases, blends with other fuels, our results show a good agreement with those found in the literature.…”

mentioning

confidence: 99%

“…In this study, without co-generation, the average impact of 1 kWh of ammonia-based on wind electrolysis is −41%, −36%, and 2629% relative to a natural gas conventional power plant, for GWP, ODP, and TAP, respectively. Razon and Valera-Medina [16] used pure methane as the benchmark for their LCA results of ammonia/methane blends in a gas turbine. A summary of the average percentage difference relative to benchmark they reported for GWP and those found in this study (without co-generation) are shown in Figure 7.…”

mentioning

confidence: 99%

See 3 more Smart Citations

Environmental Life Cycle Assessment of Ammonia-Based Electricity

Boero

Kardux²,

Ковалева

et al. 2021

Energies

Self Cite

View full text Add to dashboard Cite

In recent years, several researchers have studied the potential use of ammonia (NH3) as an energy vector, focused on the techno-economic advantages and challenges for full global deployment. The use of ammonia as fuel is seen as a strategy to support decarbonization; however, to confirm the sustainability of the shift to ammonia as fuel in thermal engines, a study of the environmental profile is needed. This paper aims to assess the environmental life cycle impacts of ammonia-based electricity generated in a combined heat and power cycle for different ammonia production pathways. A cradle-to-gate assessment was developed for both ammonia production and ammonia-based electricity generation. The results show that electrolysis-based ammonia from renewable and nuclear energy have a better profile in terms of global warming potential (0.09–0.70 t CO2-eq/t NH3), fossil depletion potential (3.62–213.56 kg oil-eq/t NH3), and ozone depletion potential (0.001–0.082 g CFC-11-eq/t NH3). In addition, surplus heat for district or industrial applications offsets some of the environmental burden, such as a more than 29% reduction in carbon footprint. In general, ammonia-based combined heat and power production presents a favorable environmental profile, for example, the carbon footprint ranges from −0.480 to 0.003 kg CO2-eq/kWh.

show abstract

“…Valera-Medina [16] Ammonia blends with methane for heat generation. Most studies conclude that current technologies used to produce green ammonia need to be improved.…”

Section: Razon Andmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Environmental Life Cycle Assessment of Ammonia-Based Electricity

Boero

Kardux²,

Ковалева

et al. 2021

Energies

Self Cite

View full text Add to dashboard Cite

show abstract

“…Currently, comparisons with other fuels have shown that ammonia's versatility can enable its use for combustion or in fuel cell devices [4], potentially delivering greater hydrogen quantities than other options (i.e., liquid organic hydrogen carriers, LOHC) at lower costs. Similarly, life cycle analyses denote how ammonia-fuelled systems present great potential to deliver green, sustainable stranded hydrogen [5][6][7] whilst reducing greenhouse emissions in support of the reduction in large carbon footprint scenarios.…”

Section: Introductionmentioning

confidence: 99%

Methane/Ammonia Radical Formation during High Temperature Reactions in Swirl Burners

et al. 2021

Self Cite

View full text Add to dashboard Cite

Recent studies have demonstrated that ammonia is an emerging energy vector for the distribution of hydrogen from stranded sources. However, there are still many unknown parameters that need to be understood before ammonia can be a substantial substitute in fuelling current power generation systems. Therefore, current attempts have mainly utilised ammonia as a substitute for natural gas (mainly composed of methane) to mitigate the carbon footprint of the latter. Co-firing of ammonia/methane is likely to occur in the transition of replacing carbonaceous fuels with zero-carbo options. Hence, a better understanding of the combustion performance, flame features, and radical formation of ammonia/methane blends is required to address the challenges that these fuel combinations will bring. This study involves an experimental approach in combination with numerical modelling to elucidate the changes in radical formation across ammonia/methane flames at various concentrations. Radicals such as OH*, CH*, NH*, and NH2* are characterised via chemiluminescence whilst OH, CH, NH, and NH2 are described via RANS κ-ω SST complex chemistry modelling. The results show a clear progression of radicals across flames, with higher ammonia fraction blends showing flames with more retreated shape distribution of CH* and NH* radicals in combination with more spread distribution of OH*. Simultaneously, equivalence ratio is a key parameter in defining the flame features, especially for production of NH2*. Since NH2* distribution is dependent on the equivalence ratio, CFD modelling was conducted at a constant equivalence ratio to enable the comparison between different blends. The results denote the good qualitative resemblance between models and chemiluminescence experiments, whilst it was recognised that for ammonia/methane blends the combined use of OH, CH, and NH2 radicals is essential for defining the heat release rate of these flames.

show abstract

E-fuels: Pathway toward cleaner future

Havukainen,

Sillman

2024

Decarbonization Strategies and Drivers to Achieve Carbon Neutrality for Sustainability

View full text Add to dashboard Cite

A Comparative Environmental Life Cycle Assessment of the Combustion of Ammonia/Methane Fuels in a Tangential Swirl Burner

Cited by 7 publications

References 27 publications

Environmental Life Cycle Assessment of Ammonia-Based Electricity

Environmental Life Cycle Assessment of Ammonia-Based Electricity

Methane/Ammonia Radical Formation during High Temperature Reactions in Swirl Burners

E-fuels: Pathway toward cleaner future

Contact Info

Product

Resources

About