Your search keyword '"NATURAL gas"' showing total 32,175 results

1. Anionic oxyl radical formed on CrVI-oxo anchored on the defect site of the UiO-66 node facilitates methane to methanol conversion.

Author

Qin, Yuyao, Li, Liwen, Liu, Huixian, Han, Jinyu, Wang, Hua, Zhu, Xinli, and Ge, Qingfeng

Subjects

*METHANE, *NATURAL gas, *DENSITY functional theory, *METHANOL production, *METHANE as fuel, *METHANOL, *METAL-organic frameworks

Abstract

The direct conversion of methane to methanol has attracted increasing interest due to abundant and low-cost natural gas resources. Herein, by anchoring Cr-oxo/-oxyhydroxides on UiO-66 metal–organic frameworks, we demonstrate that reactive anionic oxyl radicals can be formed by controlling the coordination environment based on the results of density functional theory calculations. The anionic oxyl radicals produced at the completely oxidized CrVI site acted as the active species for facile methane activation. The thermodynamically stable CrVI-oxo/-oxyhydroxides with the anionic oxyl radicals catalyze the activation of the methane C–H bond through a homolytic mechanism. An analysis of the results showed that the catalytic performance of the active oxyl species correlates with the reaction energy of methane activation and H adsorption energies. Following methanol formation, N2O can regenerate the active sites on the most stable CrVI oxyhydroxides, i.e., the Cr(O)4Hf species. The present study demonstrated that the anionic oxyl radicals formed on the anchored CrVI oxyhydroxides by tuning the coordination environment enabled facile methane activation and facilitated methanol production. [ABSTRACT FROM AUTHOR]

Published

2024

2. High-throughput computational screening of MOF adsorbents for efficient propane capture from air and natural gas mixtures.

Author

Ercakir, Goktug, Aksu, Gokhan Onder, and Keskin, Seda

Subjects

*GAS mixtures, *HIGH throughput screening (Drug development), *SORBENTS, *PROPANE, *METAL-organic frameworks, *NATURAL gas, *MIXTURES

Abstract

In this study, we used a high-throughput computational screening approach to examine the potential of metal–organic frameworks (MOFs) for capturing propane (C3H8) from different gas mixtures. We focused on Quantum MOF (QMOF) database composed of both synthesized and hypothetical MOFs and performed Grand Canonical Monte Carlo (GCMC) simulations to compute C3H8/N2/O2/Ar and C3H8/C2H6/CH4 mixture adsorption properties of MOFs. The separation of C3H8 from air mixture and the simultaneous separation of C3H8 and C2H6 from CH4 were studied for six different adsorption-based processes at various temperatures and pressures, including vacuum-swing adsorption (VSA), pressure-swing adsorption (PSA), vacuum–temperature swing adsorption (VTSA), and pressure-temperature swing adsorption (PTSA). The results of molecular simulations were used to evaluate the MOF adsorbents and the type of separation processes based on selectivity, working capacity, adsorbent performance score, and regenerability. Our results showed that VTSA is the most effective process since many MOFs offer high regenerability (>90%) combined with high C3H8 selectivity (>7 × 103) and high C2H6 + C3H8 selectivity (>100) for C3H8 capture from air and natural gas mixtures, respectively. Analysis of the top MOFs revealed that materials with narrow pores (<10 Å) and low porosities (<0.7), having aromatic ring linkers, alumina or zinc metal nodes, typically exhibit a superior C3H8 separation performance. The top MOFs were shown to outperform commercial zeolite, MFI for C3H8 capture from air, and several well-known MOFs for C3H8 capture from natural gas stream. These results will direct the experimental efforts to the most efficient C3H8 capture processes by providing key molecular insights into selecting the most useful adsorbents. [ABSTRACT FROM AUTHOR]

Published

2024

3. Indoor Air Sources of Outdoor Air Pollution: Health Consequences, Policy, and Recommendations: An Official American Thoracic Society Workshop Report.

Author

Nassikas, Nicholas, McCormack, Meredith, Ewart, Gary, Bond, Tami, Brigham, Emily, Cromar, Kevin, Paulin, Laura, Rice, Mary, Thurston, George, Turpin, Barbara, Vance, Marina, Weschler, Charles, Zhang, Junfeng, Kipen, Howard, Hicks, Anne, Hopke, Philip, Meyer, Brittany, Balmes, John, Goldstein, Allen, and Nazaroff, William

Subjects

cooking, indoor air pollution, natural gas, volatile organic compounds, wood burning

Abstract

Indoor sources of air pollution worsen indoor and outdoor air quality. Thus, identifying and reducing indoor pollutant sources would decrease both indoor and outdoor air pollution, benefit public health, and help address the climate crisis. As outdoor sources come under regulatory control, unregulated indoor sources become a rising percentage of the problem. This American Thoracic Society workshop was convened in 2022 to evaluate this increasing proportion of indoor contributions to outdoor air quality. The workshop was conducted by physicians and scientists, including atmospheric and aerosol scientists, environmental engineers, toxicologists, epidemiologists, regulatory policy experts, and pediatric and adult pulmonologists. Presentations and discussion sessions were centered on 1) the generation and migration of pollutants from indoors to outdoors, 2) the sources and circumstances representing the greatest threat, and 3) effective remedies to reduce the health burden of indoor sources of air pollution. The scope of the workshop was residential and commercial sources of indoor air pollution in the United States. Topics included wood burning, natural gas, cooking, evaporative volatile organic compounds, source apportionment, and regulatory policy. The workshop concluded that indoor sources of air pollution are significant contributors to outdoor air quality and that source control and filtration are the most effective measures to reduce indoor contributions to outdoor air. Interventions should prioritize environmental justice: Households of lower socioeconomic status have higher concentrations of indoor air pollutants from both indoor and outdoor sources. We identify research priorities, potential health benefits, and mitigation actions to consider (e.g., switching from natural gas to electric stoves and transitioning to scent-free consumer products). The workshop committee emphasizes the benefits of combustion-free homes and businesses and recommends economic, legislative, and education strategies aimed at achieving this goal.

Published

2024

4. Mechanical properties and cage transformations in CO2-CH4 heterohydrates: a molecular dynamics and machine learning study.

Author

Zhang, Yu, Liu, Xintong, Shi, Qiao, Qu, Yongxiao, Hao, Yongchao, Fu, Yuequn, Wu, Jianyang, and Zhang, Zhisen

Subjects

*MACHINE learning, *MACHINE dynamics, *MOLECULAR dynamics, *GAS hydrates, *SPATIAL arrangement, *YOUNG'S modulus, *NATURAL gas

Abstract

The substitution of natural gas hydrates with CO2 offers a compelling dual advantage by enabling the extracting of CH4 while simultaneously sequestering CO2. This process, however, is intricately tied to the mechanical stability of CO2-CH4 heterohydrates. In this study, we report the mechanical properties and cage transformations in CO2-CH4 heterohydrates subjected to uniaxial straining via molecular dynamics (MD) simulations and machine learning (ML). Results indicate that guest molecule occupancy, the ratio of CO2 to CH4 and their spatial arrangements within heterohydrate structure greatly dictate the mechanical properties of CO2–CH4 heterohydrates including Young's modulus, tensile strength, and critical strain. Notable, the introduction of CO2 within clathrate cages, particularly within 512 small cages, weakens the stability of CO2–CH4 heterohydrates in terms of mechanical properties. Upon critical strains, unconventional clathrate cages form, contributing to loading stress oscillation before fracture of heterohydrates. Intriguingly, predominant cage transformations, such as 51262–4151063 or 425864 and 512–425861 cages, are identified, in which 4151062 appears as primary intermediate cage that is able to transform into 4151063, 425862, 425863, 512 and 51262 cages, unveiling the dynamic nature of heterohydrate structures under straining. Additionally, ML models developed using MD data well predict the mechanical properties of heterohydrates, and underscore the critical influence of the spatial arrangement of guest molecules on the mechanical properties. These newly-developed ML models serve as valuable tools for accurately predicting the mechanical properties of heterohydrates. This study provides fresh insights into the mechanical properties and cage transformations in heterohydrates in response to strain, holding significant implications for environmentally sustainable utilization of CO2–CH4 heterohydrates. [ABSTRACT FROM AUTHOR]

Published

2024

5. Investigation of gas hydrate phase equilibria in bulk and in a large particle size natural quartz sand for methane, carbon dioxide and natural gas.

Author

Cruz-Castro, Lucila, Ramirez-Jaramillo, Edgar, and Albiter-Hernández, Apolinar

Subjects

*POROUS materials, *SAND, *PHASE equilibrium, *POROUS silica, *PERMEABILITY, *GAS hydrates, *NATURAL gas

Abstract

In the present work, a comparison of the P–T equilibrium points of gas hydrates formation in bulk phase and porous medium (large particle size natural quartz sand) was studied for three different gas-hydrates: CO2, CH4 and a sample of natural gas. The effect of the large particle size in the P–T equilibrium conditions during the formation of gas hydrates was analyzed. Isochoric method and a cooling-heating rate of 0.7 K/h were used. The experimental results are compared with literature data and with the software CSMHyd and PVTsim. It was found that the P–T equilibrium points obtained in bulk are similar, within the experimental error, to the P–T points obtained in the large particle size natural quartz sand (gas + water + porous medium), in the range of temperature and pressure of 270–285 K and 1–14 MPa. For the systems gas (CO2, CH4) + water, the results were compared with literature data with an average deviation less than 7%. The system natural gas + water + porous medium was compared with similar experiments reported in the literature with smaller porous size silica (6–100 nm). A similar tendency is observed in systems with a porous size greater than 20 nm. Highlights: Porosity and permeability of quartz sand were measured experimentally. Phase equilibria of CH4, CO2, and natural gas hydrates in quartz sand were measured. The methodology is validated for gas hydrates stability in bulk phase and porous media. Experimental results are compared with literature and software CSMHyd and PVTsim. [ABSTRACT FROM AUTHOR]

Published

2024

6. Hydrophobic-treated yolk-shell SnS2@CSs Z-scheme confinement reactor for solar-electro-driven hydrogen peroxide production in neutral media.

Author

Cai, Jiaqi and Zhang, Lei

Subjects

*CHEMICAL kinetics, *HYDROGEN peroxide, *SURFACE chemistry, *NATURAL gas, *HYDROGEN production

Abstract

This work combines the nanoconfined material with the air-breathing gas diffusion electrode equips a wide practical range of applications for the synthesis of high-yield H 2 O 2 and upgrading of H 2 O 2 products. [Display omitted] • Yolk-shell SnS 2 @CSs Z-scheme nanoreactor is controllably synthesized. • Hydrogen peroxide production is increased through the nano-confinement effect. • Continuous hydrophobic layers allow air to spontaneously diffuse into the AGPE. • The photoelectrode has a good reusability and stability for activation of O 2 /H 2 O. • Hydrogen peroxide is produced under neutral condition media. The diffusion and adsorption properties of the O 2 /H 2 O corpuscles at active sites play a crucial role in the fast photo-electrocatalytic reaction of hydrogen peroxide (H 2 O 2) production. Herein, SnS 2 nanosheets with abundant interfacial boundaries and large specific areas are encapsulated into hollow mesoporous carbon spheres (CSs) with flexibility, producing a yolk-shell SnS 2 @CSs Z-scheme photocatalyst. The nanoconfined microenvironment of SnS 2 @CSs could enrich O 2 /H 2 O in catalyst cavities, which allows sufficient internal O 2 transfer, improving the surface chemistry of catalytic O 2 to O 2 − conversion and increasing reaction kinetics. By shaping the mixture of SnS 2 @CSs and polytetrafluoroethylene (PTFE) on carbon felt (CF) using the vacuum filtration method, the natural air-breathing gas diffusion photoelectrode (AGPE) was prepared, and it can achieve an accumulated concentration of H 2 O 2 about 12 mM after a 10 h stability test from pure water at natural pH without using electrolyte and sacrificial agents. The H 2 O 2 product is upgraded through one downstream route of conversion of H 2 O 2 to sodium perborate. The improved H 2 O 2 production performance could be ascribed to the combination of the confinement effect of SnS 2 @CSs and the rich triple phase interfaces with the continuous hydrophobic layer and hydrophilic layer to synergistically modulate the photoelectron catalytic microenvironment, which enhanced the transfer of O 2 mass and offered a stronger affinity to oxygen bubbles. The strategy of combining the confined material with the air-breathing gas diffusion electrode equips a wide practical range of applications for the synthesis of high-yield hydrogen peroxide. [ABSTRACT FROM AUTHOR]

Published

2024

7. The impact of support selection and Co loading amount on the catalytic performance for methane combustion.

Author

Niu, Juntian, Jin, Ziwei, Guo, Baihe, Liu, Haiyu, Jin, Yan, and Ran, Jingyu

Subjects

*ALUMINUM oxide, *CERIUM oxides, *CATALYTIC activity, *METAL catalysts, *NATURAL gas

Abstract

Methane (CH 4) is a key component of natural gas and is essential for energy production and utilization. However, due to its strong greenhouse effect, efficient catalytic combustion methods are needed to convert it into CO 2 and H 2 O. This study systematically evaluates the catalytic performance of Co, CoO, and Co 3 O 4 in methane catalytic combustion, particularly highlighting the superior activity of Co 3 O 4. To improve catalytic efficiency, this paper examines the effects of SiO 2 , Al 2 O 3 , and CeO 2 as support materials using co-precipitation and impregnation methods. The results show a significant improvement in the catalytic activity of Co 3 O 4 supported on CeO 2 , attributed to CeO 2 's unique redox properties and high oxygen storage capacity. Additionally, the study explores the impact of different loading amounts (5%, 10%, 15%, 20%) of Co 3 O 4 (x)-CeO 2 catalysts on their performance. The optimal 10%wt Co 3 O 4 –CeO 2 catalyst achieves methane conversion rates of 10%, 50%, and 90% at temperatures of 376 °C, 473 °C, and 578 °C, respectively, demonstrating exceptional stability during a 20-h stability test and the ability to adapt to fluctuations in CH 4 concentrations in low-oxygen environments, while also exhibiting significant catalytic activity across a range of methane concentrations from 0.5% to 2.5%. These findings provide important theoretical and experimental guidance for the application of cobalt-based catalysts in CH 4 combustion, paving the way for future catalyst design and optimization. [Display omitted] • Co 3 O 4 shows the best catalytic activity in CH 4 combustion compared to Co and CoO. • Supporting Co 3 O 4 on CeO 2 significantly improves catalytic performance. • The 10%wt Co 3 O 4 –CeO 2 catalyst shows the best stability after running for 20 h. [ABSTRACT FROM AUTHOR]

Published

2024

8. Gas Leaks, Gas Shutoffs, and Environmental Justice in New York City.

Author

Kucheva, Yana and Etemadpour, Ronak

Subjects

*NATURAL gas, *ENVIRONMENTAL racism, *GREENHOUSE gases, *DATA security failures, *CITIES & towns, *ENVIRONMENTAL justice

Abstract

Gas leaks in cities with older infrastructure are relatively common. The unburned methane which they release is a potent greenhouse gas with harmful health effects. Using administrative municipal data on gas leak reports, we provide a systematic analysis of residential gas leaks in New York City and their association with socioeconomic inequality. We find that both the reporting of gas leaks and the prevalence of resulting residential gas shutoffs is strongly structured by already existing inequalities across neighborhoods. Therefore, we argue that the gas infrastructure in urban areas is an important environmental justice issue as those communities who experience the brunt of failing gas infrastructure are the same communities who have faced decades of disinvestment and environmental racism. [ABSTRACT FROM AUTHOR]

Published

2024

9. Numerical simulation of natural gas flow characteristics and hydrate formation risk in deepwater submarine pipelines.

Author

Liu, Wenyuan

Subjects

*UNDERWATER pipelines, *OCEAN temperature, *GAS flow, *LOW temperatures, *FACTOR analysis, *NATURAL gas

Abstract

The development of flow assurance technology in submarine pipelines affects the safety, efficiency, and economy of deepwater natural gas development. In this study, in order to accurately predict the hydrate formation risk in deepwater submarine pipelines, a novel mathematical prediction model of hydrate formation risk has been established. The model has been applied and sensitivity analysis of typical factors has been carried out. The model prediction results show that: (1) Due to the low temperature of the seabed, hydrate formation region (HFR) often exists in submarine pipelines. (2) When other conditions are constant, hydrate formation region increases with the decrease in seawater temperature. (3) When other conditions are constant, the temperature drop, and the length of hydrate formation region decrease with the increase of gas transmission rate. (4) When other conditions are constant, the temperature drop, and the length of hydrate formation region decreases with the increase of gas transport temperature. (5) Reasonable setting of gas transmission temperature and gas transmission rate can help to reduce the hydrate risk and consumption of inhibitors during submarine natural gas transmission. Highlights: The hydrate risk prediction model for submarine pipeline is established. The model has been applied in submarine pipeline natural gas transmission. The T-P distribution characteristics in submarine pipeline are analyzed. The hydrate formation region in submarine pipeline is determined. [ABSTRACT FROM AUTHOR]

Published

2024

10. Gas market integration in South America: The role of Argentine gas to reduce the regional exposure to liquefied natural gas imports.

Author

Vilela Pinto dos Anjos, Henrique, Szklo, Alexandre, and Chávez Rodríguez, Mauro Francisco

Subjects

GAS dynamics, NATURAL gas reserves, INTERNATIONAL economic integration, LIQUEFIED gases, PRICES, LIQUEFIED natural gas, NATURAL gas

Abstract

After spending several years as net importer of natural gas, the development of unconventional gas reserves in Argentina can revert this scenario and change the dynamics of the Southern Cone regional gas integration. To assess the role of Argentine gas, this study utilised the TIMES-ConoSur optimisation model, which represents the regional integration of the gas and electricity systems. To improve the level of detail of the results, updates and modifications in different settings were made in the first version of the model. In addition, four scenarios were tested with two levels of LNG (liquefied natural gas) prices and including or not the interconnection between Argentina gas network and Brazil integrated network. The role of the Argentine gas was analysed based on its production potential and the export potential to the neighbour countries. Findings indicated that the development of the Argentine gas reserves can be a game changer, as it can affect directly the regional dynamics and the gas supply of the neighbour countries. The main future dynamics of the other countries in the region were also assessed, such as the role of Bolivian gas, the challenges to develop pre-salt gas and how will be the future of LNG in the region. [ABSTRACT FROM AUTHOR]

Published

2024

11. Toward improving efficiency and mitigating emissions in a natural gas/diesel direct injection dual fuel engine using EGR.

Author

Sehili, Youcef, Tarabet, Lyes, Cerdoun, Mahfoudh, Loubar, Khaled, and Lacroix, Clément

Abstract

As emissions regulations become more and more stringent and conventional fuel sources rarefaction, new alternatives are emerging to address this situation. Dual fuel engines are among the promising solutions, offering both ecological and economic advantages. However, these engines often confront constraints linked to high levels of unburnt hydrocarbons (HC) at low loads and NOx emissions at high loads. To overcome these problems and guarantee high-efficiency overall operating loads, exhaust gas recirculation (EGR) is a potential solution. In the present experimental study, appropriate modifications have been carried out to a single-cylinder diesel engine to ensure dual fuel operation with EGR. Natural gas and diesel are used as the primary and pilot fuel, respectively. At low load operations, the EGR rate is increased up to 35% until the reduction of unburnt hydrocarbons. However, at high loads, the EGR rate is carefully adjusted, as the combustion efficiency easily deteriorates due to oxygen amount lack in the combustion chamber. Also, minimizing NOx emissions is prioritized in all load conditions while keeping thermal efficiency in sight. In addition, the variation in the amount of pilot fuel is studied for improving the combination of dual fuel engine operation with the EGR technique. This made it possible to determine the influence of load, EGR rate, and pilot fuel quantity on the engine in response to the triple challenges of reducing NOx and HC and improving thermal efficiency. The results show that an adequate EGR rate of 30%, depending on the operating conditions, can reduce HC emissions by >25% while increasing thermal efficiency by around 20%. This result is accompanied by a significant reduction, over 90%, in NOx emissions. [ABSTRACT FROM AUTHOR]

Published

2024

12. Stratification characteristics of hydrogen-blended natural gas for gas risers inside residential users.

Author

Cen, Kang, Su, Linxin, Wen, Yunqiao, Song, Bin, Zeng, Zelin, Li, Liansong, and Li, Qiang

Subjects

GREY relational analysis, FIELD research, COMPUTER simulation, GASES, HYDROGEN, NATURAL gas

Abstract

In this paper, a CFD model is developed to examine the stratification characteristics of hydrogen-blended natural gas in residential gas risers. Meanwhile, the accuracy of the CFD model is validated by field experiments. The effects of relevant parameters on stratification are analyzed, including hydrogen blending ratio, riser internal diameter, riser height, media temperature, and media pressure. The relative importance of relevant parameters for stratification is identified using the orthogonal experiment design and improved grey relational analysis. Furthermore, a device is designed to mitigate the impact of blended gas stratification. The results show that the stratification of hydrogen-blended natural gas inside residential gas risers is significant in the direction of gravity. The maximum stratification height in standing for 8 h can reach up to 17.4 cm. The stratification height presents a negative correlation with riser internal diameter, riser height, and media temperature, while that represents a positive correlation with hydrogen blending ratio and media pressure. Furthermore, the effects of these parameters on stratification height could be ranked as follows: media pressure > hydrogen blending ratio > riser internal diameter > riser height > media temperature. These achievements provide effective guidance for residential users on safely using hydrogen-blended natural gas. [ABSTRACT FROM AUTHOR]

Published

2024

13. Experimental analysis and modeling on the blending limit of domestic burner with porous media for hydrogen enriched natural gas.

Author

Chen, Yiyu, Niu, Jie, Liu, Wenjie, Long, Liwen, Huang, Taiming, Sun, Yingkai, Wan, Zhongmin, and Yu, Bo

Subjects

*HYDROGEN as fuel, *POROUS materials, *THERMAL efficiency, *DOPING agents (Chemistry), *HYDROGEN flames, *NATURAL gas

Abstract

The combustion technology of hydrogen enriched natural gas can directly apply hydrogen energy to household gas, playing an important role in promoting the development of hydrogen energy. This study designed a domestic burner with porous media for hydrogen enriched natural gas. The effect of hydrogen blending ratio on the primary mix process in the injector was analyzed numerically, and an experiment was conducted to investigate the flame morphology, thermal efficiency and pollutant emissions of the hydrogen-enriched natural gas. The results show that there is a risk of backfire inside the injector when the hydrogen blending ratio exceeds 45%, and the pre-mixing uniformity decreases as the hydrogen doping ratio increases. Corresponding to variable hydrogen doping ratios, two combustion modes appear in the porous medium region, immerged combustion and surface combustion. When a combustion mode transition occurs, CO emissions increase rapidly, while thermal efficiency and NOx emissions show a downward trend. Additionally, the critical hydrogen doping ratio of mode transition drops as the porous density increases. Overall, taking the environmental characteristic and efficiency into considerations, the maximum hydrogen blending ratio should be not exceed 35%. [Display omitted] • A domestic burner with porous media for hydrogen enriched natural gas was designed. • The effect of hydrogen blending ratio on the primary mix process was analyzed. • The combustion performance and emissions of the domestic burner was investigated. • The transition of combustion mode induced by hydrogen doping ratio was observed. [ABSTRACT FROM AUTHOR]

Published

2024

14. Turquoise hydrogen to reduce emissions of the north American oil upstream sector.

Author

Pelucchi, Silvia, Maporti, Diego, Mocellin, Paolo, and Galli, Federico

Subjects

*CARBON emissions, *PETROLEUM industry, *GAS turbines, *CARBON analysis, *SENSITIVITY analysis, *NATURAL gas

Abstract

In Canadian remote oil sites, natural gas extracted with the bitumen is flared or vented, impacting on the environment. Providing a pipeline network to recover the gas is unaffordable in most cases. Here we propose the economic framework of an innovative process to recover the gas, based on pyrolysis at T = 1223 K and P = 0.1 MPa, performed in situ. Part of produced hydrogen combusts to sustain the process, while solid carbon is sold. We conceptualised and simulated in Aspen Plus two process alternatives. In configuration 1, the remaining part of hydrogen is sent to a gas turbine, where it burns to produce electricity. In configuration 2, the unburnt hydrogen is purified and sold. Both configurations reduce CO 2 emissions by more than 92 % compared to flaring. Both configurations produce a profit over 10 years, being their IRR above 20 % and payback time below 3.5 y. • Flaring and venting natural gas contribute to 1.7 % of Canada's global emissions. • Methane pyrolysis is a promising technology to abate oil sector's emissions. • We present techno-economics and sensitivity analysis of two process alternatives. • Turquoise H 2 sustains energetically the process that produces carbon, to be sold. • Emissions compared to the flaring scenario are reduced by over 90 %. [ABSTRACT FROM AUTHOR]

Published

2024

15. Mathematical modeling for hydrogen blending in natural gas pipelines moving towards industrial decarbonization: Economic feasibility and CO2 reduction analysis.

Author

Ruiz Diaz, Daniela Fernanda, Zhao, Jiadong, Pham, John Minh Quang, Ramirez, Christopher, Qin, Huiting, Jimenez, Adrian Jose, Pulianda, Akhil Muthappa, Choudhary, Chelsea, McDonell, Vince, and Li, G.P.

Subjects

*NATURAL gas pipelines, *GAS as fuel, *CARBON emissions, *GREENHOUSE gases, *CARBON dioxide, *NATURAL gas

Abstract

Hydrogen blending has proved to be a promising alternative to reduce CO 2 emissions in current applications such as the industrial sector in which natural gas is the fuel source since it can mitigate GHG emissions and help to reach nation's goal of decarbonization. This study explored the feasibility of different hydrogen blend compositions going from 1% to 30% hydrogen content (by volume) by computational simulations to determine the best performance of the system considering real operating conditions from Central Plant at UC Irvine. This work also performed an economic analysis as part of the implementation plan. It was determined that a blend of 19% H 2 content could be implemented without any major renovation of utility infrastructure based on the operating conditions and change in the properties of the mixture. An addition of 30% H 2 can reduce around 11% of the emissions produced by pure natural gas. This is equivalent to 1422 kg of CO 2 in 1 h. It is evident that the higher the H 2 content, the better the CO 2 benefits that would be produced, but for the actual application of higher hydrogen content, there is a need for a better understanding of the effects of hydrogen in the current natural gas pipeline. Based on the CO 2 savings, it was determined that a 30% blending of hydrogen may save about 22.2% of the economic cost compared to natural gas. • A hydrogen blending model is developed considering a hydrogen content between 1% and 30% by volume. • Real operating conditions such as temperature, pressure, pipeline dimensions, and power output requirements were considered based on UCI power plant for validation. • An economic analysis is considered as part of the implementation plan. • A blend of 19% H 2 content could be implemented without major renovation of infrastructure based on the operating conditions and change in the properties of the mixture. • 30% H 2 can reduce ∼11% of the emissions produced by pure natural gas. [ABSTRACT FROM AUTHOR]

Published

2024

16. Balancing cleaner energy and geopolitical interests in the complex transition of the European electricity mix: from Fukushima to the Ukraine war.

Author

Cataldi, Marcio, Espinosa, Nieves, Jerez, Sonia, Montávez, Juan Pedro, Da Silveira, Larissa Haringer Martins, Dupont, Jairton, and Teixeira, Marcos Alexandre

Abstract

In the modern world, electric energy plays a pivotal role in sustaining life and driving technological, scientific, and human development. Consequently, the selection and availability of the energy sources used for electricity generation have become crucial elements of strategic planning for countries and economic blocks. Moreover, the impact of these choices extends beyond the mere energy demand/supply, affecting economies, societies and the environment across geographical boundaries. This study delves into the various factors influencing the composition and the recent expansion of the European electricity mix. It explores the interplay of environmental, climatic, political, economic, and external factors that shape Europe's energy choices. To conduct this analysis, we utilized data from the International Energy Agency on electricity generation and GHG emissions. Data mining techniques were employed to uncover patterns and trends in the monthly data from 2010 to 2022, from which political and economic milestones such as the shutdown of nuclear power plants and the European Union's increased reliance on natural gas imports from Russia were examined. The study also discusses the impact of using natural gas for power generation on increasing GHG emissions. Ultimately, this research reveals that the European Union choices in transitioning towards a cleaner electricity mix have not yet proven efficient. In fact, these choices may have inadvertently created favorable conditions for Russia's invasion of Ukraine, triggering, not only a humanitarian crisis, but also an economic downturn in Europe due to soaring energy prices. This crisis could potentially extend beyond Europe and impact the whole planet in 2023 and on, including developing countries that rely on stable energy prices for their sustainable growth. [ABSTRACT FROM AUTHOR]

Published

2024

17. Atomically Dispersed Iron‐Copper Dual‐Metal Sites Synergistically Boost Carbonylation of Methane.

Author

Cheng, Qingpeng, Yao, Xueli, Li, Guanna, Li, Guanxing, Zheng, Lirong, Yang, Kaijie, Emwas, Abdul‐Hamid, Li, Xingang, Han, Yu, and Gascon, Jorge

Subjects

*BIMETALLIC catalysts, *CHEMICAL synthesis, *NATURAL gas, *DENSITY functional theory, *COPPER

Abstract

The direct liquid‐phase oxidative carbonylation of methane, utilizing abundant natural gas, offers a mild and straightforward alternative. However, most catalysts proposed for this process suffer from low acetic acid yields due to few active sites and rapid C1 oxygenate generation, impeding their industrial feasibility. Herein, we report a highly efficient 0.1Cu/Fe‐HZSM‐5‐TF (TF denotes template‐free synthesis) catalyst featuring exclusively mononuclear Fe and Cu anchored in the ZSM‐5 channels. Under optimized conditions, the catalyst achieved an unprecedented acetic acid yield of 40.5 mmol gcat−1 h−1 at 50 °C, tripling the previous records of 12.0 mmol gcat−1 h−1. Comprehensive characterization, isotope‐labeled experiments and density functional theory (DFT) calculations reveal that the homogeneous mononuclear Fe sites are responsible for the activation and oxidation of methane, while the neighboring Cu sites play a key role in retarding the oxidation process, promoting C−C coupling for effective acetic acid synthesis. Furthermore, the methyl‐group carbon in acetic acid originates solely from methane, while its carbonyl‐group carbon is derived exclusively from CO, rather than the conversion of other C1 oxygenates. The proposed bimetallic catalyst design not only overcomes the limitations of current catalysts but also generalizes the oxidative carbonylation of other alkanes, demonstrating promising advancements in sustainable chemical synthesis. [ABSTRACT FROM AUTHOR]

Published

2024

18. A Game-Theoretic Analysis of the Interaction Between Embargoes, Price Caps and Tariffs in EU-Russia Gas Trade.

Author

Ehrhart, Karl-Martin, Schlecht, Ingmar, Schmitz, Jan, and Wang, Runxi

Subjects

COMMERCIAL policy, PRICE regulation, ENERGY policy, NATURAL gas, TARIFF

Abstract

Geopolitical tensions have put the use of strategic trade policy instruments back on the agenda of policy makers. In this paper we investigate the interaction of the threat and use of three unilateral trade policy instruments: embargoes, import price caps and tariffs. In a game-theoretic framework with different scenarios and game variants, we show that the strategic use of the right combination of the respective trade policy instruments can be used to achieve more desirable outcomes for the players. In our setup, a credible threat of a tariff supports the successful implementation of an import price cap. While the results can be generalised, we show the concrete functioning of the interplay of these strategic trade policy instruments in a hypothetical game of resumption of natural gas sales from Russia to the EU. Following the application to this example, we derive policy suggestions to improve the EU's position in the specific game. [ABSTRACT FROM AUTHOR]

Published

2024

19. Uncertainty prediction of conventional gas production in Sichuan Basin under multi factor control.

Author

Li, Haitao, Yu, Guo, Fang, Yizhu, Chen, Yanru, Sun, Kaijun, Liu, Yang, Chen, Yu, Zhang, Dongming, Qiusong, Chen, Liu, Qingquan, and Zhang, Dongti

Subjects

BAYESIAN analysis, PRODUCTION planning, NATURAL gas production, FACTORS of production, SENSITIVITY analysis, NATURAL gas

Abstract

The establishment of a natural gas production model under multi factor control provides support for the formulation of planning schemes and exploration deployment decisions, and is of great significance for the rapid development of natural gas. Especially the growth rate and decline rate of production can be regulated in the planning process to increase natural gas production. The exploration and development of conventional gas in the Sichuan Basin has a long history. Firstly, based on the development of conventional gas production, the influencing factors of production are determined and a production model under multi factor control is established. Then, single factor analysis and sensitivity analysis are conducted, and multi factor analysis is conducted based on Bayesian networks. Finally, combining the multivariate Gaussian mixture model and production sensitivity analysis, a production planning model is established to predict production uncertainty under the influence of multiple factors. The results show that: 1) the production is positively correlated with the five influencing factors, and the degree of influence is in descending order: recovery rate, proven rate, growth rate, decline rate, and recovery degree. After being influenced by multiple factors, the fluctuation range of production increases and the probability of realization decreases. 2) The growth rate controls the amplitude of the growth stage, the exploration rate and recovery rate control the amplitude of the stable production stage, the recovery degree controls the amplitude of the transition from the stable production stage to the decreasing stage, and the decreasing rate controls the amplitude of the decreasing stage. 3)The article innovatively combines multiple research methods to further obtain the probability of achieving production under the influence of multiple factors, providing a reference for the formulation of production planning goals. [ABSTRACT FROM AUTHOR]

Published

2024

20. How the USA can feasibly cut methane emissions 30% by 2030: anaerobic digestion of organic waste and various measures in oil and gas production.

Author

Lerner, Michael Scott

Subjects

*RENEWABLE natural gas, *PETROLEUM waste, *GAS wells, *FOOD waste, *WASTE gases

Abstract

The USA has committed to cutting its emissions of methane, an extremely potent greenhouse gas, by at least 30% by 2030 (‘30 × 30’). This is part of the Global Methane Pledge, signed by 155 countries, to keep global warming within 1.5 °C and thereby to forestall the disastrous effects of ‘runaway climate change’. It will be a major challenge for the USA to reach 30 × 30 and there is no consensus on how to do so. This paper provides a concrete, data‐driven roadmap to indicate how to reach 30 × 30 feasibly, focusing on two enormous sources of methane emissions: organic waste and oil and gas production. It calculates that building approximately 4700 anaerobic digesters (ADs) to process food waste and animal manure would cost about $74.2 billion in capital expenditure (capex) and cut 13.6% of total US methane emissions per year. On average, each project would take roughly 2–6 years to build. Of the various methane mitigation measures analyzed in the oil and gas sectors, the most impactful would be full compliance with the US Environmental Protection Agency's (EPA's) revised New Source Performance Standards (NSPS) for oil and gas production by 2029. This would cut 17.5% of total US methane emissions annually, at a cumulative capex of $20.7 billion from 2024 to 2029. Together, the 13.6% cut from food waste and manure ADs and the 17.5% cut from full NSPS compliance would amount to a 31.5% reduction, exceeding the 30 × 30 goal. Greater clarity from the federal government on funding eligibility and additional incentives would accelerate the buildout of ADs. [ABSTRACT FROM AUTHOR]

Published

2024

21. Geochemical influences of hydrogen storage in depleted gas reservoirs with N2 cushion gas.

Author

Muhammed, Nasiru Salahu, Haq, Bashirul, Al Shehri, Dhafer, and Amao, Abduljamiu

Subjects

*GAS reservoirs, *NATURAL gas, *GAS mixtures, *CARBON dioxide, *CLAY minerals, *GEOLOGICAL carbon sequestration

Abstract

Geochemical investigation of hydrogen (H 2), brine, rock formations, and residual gases (nitrogen – N 2 , methane – CH 4 , and carbon dioxide – CO 2) is crucial for understanding H 2 storage processes in depleted gas reservoirs. This study examines the effects of injecting a gas mixture (60% H 2 + 30% N 2 + 5% CH 4 + 5% CO 2) into Bandera Grey sandstone with notable clay mineral content. The experiment lasted 50 days at 42 °C, 1350 psi, and 5 wt% NaCl brine, with detailed analytical characterization before and after aging. Results show minimal sample reactivity, causing slight alterations in petrophysical characteristics. Dissolution primarily affected dolomite and barite minerals, while illite and kaolinite caused pore blockage. Gas chromatography data indicate only 0.45% of injected H 2 is lost (via dissolution in brine and reaction with CO 2), CH 4 increased by 6.22%, N 2 remained stable, and CO 2 decreased by 1%. These results provide valuable insights into the feasibility and safety of utilizing depleted gas reservoirs for H 2 storage. • Effect of storing 60% H 2 and 40% cushion gas in clay-rich sandstone is investigated. • Geochemical reactions (dissolution/precipitation) induced by the mixture are very weak. • PH increased from 6.13 to 7.24 led to mineral dissolution and precipitation. • Only 0.45% of injected H 2 was lost based on gas chromatography. • Findings provide insights into the feasibility and safety of depleted gas reservoirs for H 2 storage. [ABSTRACT FROM AUTHOR]

Published

2024

22. Moving hydrogen through the UK gas distribution network.

Author

Sargent, Michael and Sargent, Philip

Subjects

*GAS distribution, *THERMODYNAMICS, *FLUE gases, *BOILER efficiency, *COMBUSTION gases

Abstract

We state the appropriate thermodynamic and transport properties to use for the delivery of hydrogen through pre-existing natural gas distribution networks. We show that the flow is not as fully-turbulent as past work has assumed, that hydrogen makes the flow even less turbulent, and that the pipe friction calculation requires more careful treatment in this partially-turbulent regime. We propose that the relevant final energy demand is the energy delivered as heated water. The different dew points of the flue gases from hydrogen versus natural gas combustion affect the boiler efficiency. This impacts the relative amount of hydrogen required to be delivered. We find that to deliver the same amount of useful energy as hot water, hydrogen requires a gas velocity of 3.076 × and a pressure gradient that is 1.29 × higher. The compression power increase required to deliver hydrogen through the low pressure network can be up to 7.85 × that for natural gas, depending on the flow regime. • Replacing natural gas with hydrogen reduces the Reynolds number. • Hydrogen flue gas changes the efficiency of a condensing boiler. • Replacing natural gas with hydrogen increases the pressure drop 1.29x. • The changing efficiency of condensing boilers affects how much hydrogen is needed. • The Blasius parameter ρ 3 / 4 ⋅ μ 1 / 4 has a very low temperature dependence. [ABSTRACT FROM AUTHOR]

Published

2024

23. Potential toxic effects linked to taurine interactions with alkanolamines and diisopropylamine.

Author

Pensini, Erica, Hsiung, Caitlyn, and Kashlan, Nour

Subjects

FOURIER transform infrared spectroscopy, CARBON sequestration, POISONS, NATURAL gas, GROUNDWATER pollution

Abstract

Diisopropylamine (DIPA), aminomethyl propanol (AMP), amino ethoxy ethanol (AEE), diethanolamine (DEA), ethanolamine (EA), pyridine (PYR) and methyl diethanolamine (MDEA) are used for carbon capture and to sweeten sour gas, and are found in groundwater. They are also used in cosmetic products. Taurine is abundant in the body, with key biological functions linked to its charged SO groups. Interactions between SO and amines have not been studied, but can strongly affect the biological function of taurine. Fourier transform infrared spectroscopy indicates SO...HN hydrogen bonding between taurine and DIPA, AMP, AEE, DEA, EA and MDEA. These interactions induce the formation of hydrophobic amine-taurine clusters, thus decreasing amine miscibility in water, as revealed by light scattering. This effect is most marked for DIPA, leading to turbid mixtures indicative of micron-sized droplets. PYR and taurine likely interact via S...N bonding. This study offers insights regarding potential mechanisms of amine toxicity to humans. [ABSTRACT FROM AUTHOR]

Published

2024

24. Identification of gas-liquid two-phase flow patterns based on flexible ultrasound array and machine learning.

Author

Liu, Hang, Fan, Jinhui, Lin, Xinyi, Lin, Kai, Wang, Suhao, Liu, Songyuan, Wang, Fei, and Song, Jizhou

Subjects

TWO-phase flow, NATURAL gas transportation, PIEZOELECTRIC composites, NATURAL gas extraction, COUPLING agents (Chemistry), NATURAL gas

Abstract

Ultrasound technology has been recognized as the mainstream approach for the identification of gas-liquid two-phase flow patterns, which holds great value in engineering domain. However, commercial rigid probes are bulky, limiting their adaptability to curved surfaces. Here, we propose a strategy for autonomous identification of flow patterns based on flexible ultrasound array and machine learning. The array features high-performance 1–3 piezoelectric composite material, stretchable serpentine wires, soft Eco-flex layers and a polydimethylsiloxane (PDMS) adhesive layer. The resulting ultrasound array exhibits excellent electromechanical characteristics and offers a large stretchability for an intimate interfacial contact to curved surface without the need of ultrasound coupling agents. We demonstrated that the flexible ultrasound array combined with machine learning can accurately identify gas-liquid two-phase flow patterns, in a circular pipeline. This work presents an effective tool for recognizing gas-liquid two-phase flow patterns, offering engineering opportunities in petroleum extraction and natural gas transportation. [ABSTRACT FROM AUTHOR]

Published

2024

25. Differences in the Genesis and Sources of Hydrocarbon Gas Fluid from the Eastern and Western Kuqa Depression.

Author

Yang, Xianzhang, He, Taohua, Wang, Bin, Zhou, Lu, Zhang, Ke, Zhao, Ya, Zeng, Qianghao, Huang, Yahao, He, Jiayi, and Wen, Zhigang

Abstract

The Kuqa Depression is rich in oil and gas resources and serves as a key production area in the Tarim Basin. However, controversy persists over the genesis of oil and gas in the various structural zones of the Kuqa Depression. This study employs natural gas composition analysis, gas carbon isotope analysis and gold pipe thermal simulation experiments, to comprehensively analyze the differences in the genesis and sources of hydrocarbon gas fluid from the eastern and western Kuqa Depression. The results show that the Kuqa Depression is dominated by alkane gas, with an average gas drying coefficient of 95.6, with nitrogen and carbon dioxide as the primary non-hydrocarbon gases. The average of δ13C1, δ13C2 and δ13C3 values in natural gas are −27.70‰, −20.43‰ and −21.75‰, respectively. Based on comprehensive natural gas geochemical maps, the CO2 in the natural gas from the Tudong and Dabei areas, as well as the KT-1 well of the Kuqa Depression, is thought to be of organic origin. Additionally, natural gas formation in the Tudong area is relatively simple, consisting entirely of thermally generated coal gas derived from the initial cracking of kerogen. The natural gas in the KT-1 well and the Dabei area are mixed gasses, formed by the initial cracking of kerogen from highly evolved lacustrine and coal-bearing source rocks, exhibiting characteristics resembling those of crude oil cracking gas. The methane (CH4) content of natural gas in the Dabei area is high and the carbon isotopes are unusually heavy. Considering the regional geological background, potential source rock characteristics and geochemical features may be related to the large-scale invasion of dry gas contributed by CH4 from highly evolved, underlying coal-bearing source rocks. Consequently, the CH4 content in the mixed gas is generally high (Ln (C1/C2) can reach up to 5.38), while the relative content of heavy components is low, though remains relatively unchanged. Thus, the map of the relative content of heavy components still reflects the characteristics of the original gas genesis (initial cracking of kerogen). Mixed-source gas was analyzed using thermal simulation experiments and natural gas composition ratio diagrams. The contributions of natural gas from deep, highly evolved coal-bearing source rocks in the KT-1 well and the Dabei area accounted for more than 90% and approximately 60%, respectively. This analysis provides theoretical guidance for natural gas exploration in the research area. [ABSTRACT FROM AUTHOR]

Published

2024

26. Detection of underground natural gas pipeline micro-leakage based on UAV hyperspectral remote sensing and GIS.

Author

Geng, Shihao, Guo, Qiaozhen, Ran, Weiwei, and Jiang, Jinbao

Subjects

*METAHEURISTIC algorithms, *NATURAL gas, *VECTOR data, *UNDERGROUND pipelines, *REMOTE sensing, *NATURAL gas pipelines

Abstract

Detection of underground natural gas pipeline micro-leakage based on unmanned aerial vehicle (UAV) hyperspectral remote sensing and GIS. Hyperspectral images can indirectly detect underground natural gas pipeline micro-leakage through spectral and spatial variation characteristics of surface vegetation. However, most of existing studies were based on ground-mounted platforms, which could only perform small-range single-point detection and might occur misidentifications. UAV hyperspectral remote sensing can allow wide-range detection of surface vegetation. Moreover, underground pipeline distribution GIS data can provide prior knowledge about leakage points to exclude misidentifications. Therefore, a natural gas pipeline micro-leakage experiment was set up. UAV hyperspectral images of grasslands and pipeline distribution vector data were obtained, which led to a proposed new wide-range multi-points detection methodology of underground natural gas micro-leakage. Firstly, the vegetation identification index (WVI) $\left({{R_{470}} + {R_{674}}} \right)/\left({{R_{555}} + {R_{750}}} \right)$R470+R674/R555+R750 was designed based on WOA–VMD (whale optimization algorithm – variational modal decomposition) to segment and extract the vegetation stress zones. Then, UAV- and GIS-based natural gas micro-leakage vegetation stress identification model was constructed to obtain the leak points of natural gas micro-leakage. Finally, the recognition ability was evaluated by comparing with three stress vegetation identification indices proposed in previous studies. The result showed that there was no missing or false detection in identification results; the identification and positioning effect was better than other indices, which could meet the practical application requirements. [ABSTRACT FROM AUTHOR]

Published

2024

27. Important contributions of natural gas combustion to atmospheric nitrate aerosols in China: Insights from stable nitrogen isotopes.

Author

Lin, Yu-Chi, Fan, Mei-Yi, Hong, Yihang, Yu, Mingyuan, Cao, Fang, and Zhang, Yan-Lin

Subjects

*NITROGEN isotopes, *ATMOSPHERIC aerosols, *COMBUSTION gases, *NATURAL gas, *STABLE isotopes

Published

2024

28. Probabilistic co‐expansion planning for natural gas and electricity energy systems with wind curtailment mitigation considering uncertainties.

Author

Shabanian‐Poodeh, Mostafa, Hooshmand, Rahmat‐Allah, and Kabiri‐Renani, Yahya

Subjects

*DISTRIBUTION planning, *NATURAL gas, *WIND power, *GAS turbines, *COST control

Abstract

In response to growing reliance on electricity and gas systems, this paper introduces a stochastic bi‐level model for the optimized integration of these systems. This integration is achieved through sizing and allocating of power‐to‐gas (P2G) and gas‐to‐power (G2P) units. The first level of the model focuses on decisions related to P2G and G2P unit installations, while the second level addresses optimal system operation considering decisions made from first level and stochastic scenarios. The primary aim is to enhance energy‐sharing capabilities through coupling devices and mitigate wind generation curtailment. An economic evaluation assesses the model's effectiveness in reducing costs. N − 1 contingency analysis gauges the integrated system's ability to supply load under emergency conditions. Two new indices, performance of the electricity system and performance of the natural gas system, are proposed for N − 1 contingency analysis. These indices quantify the proportion of the supplied load to the total load, thereby illustrating the system's capacity to meet demand. For numerical investigation, the proposed model is applied to a modified IEEE 14‐bus power system and a 10‐node natural gas system. Numerical results demonstrate a 9.426% reduction in investment costs and a significant 10.6% reduction in wind curtailment costs through proposed planning model. [ABSTRACT FROM AUTHOR]

Published

2024

29. Effects of eco-friendly cyclodextrin on the methane hydrate formation in the complex systems.

Author

Zhai, Jiaqi, Wang, Kun, Wang, Dongjun, Pan, Zhen, and Bai, Junwen

Subjects

*SODIUM dodecyl sulfate, *NATURAL gas storage, *METHANE hydrates, *NATURAL gas transportation, *NATURAL gas

Abstract

Due to the increasing demand for natural gas, solidified natural gas (SNG) technology provides an attractive option for natural gas storage and transportation. However, the use of sodium dodecyl sulfate (SDS) to promote hydrate formation will have a negative impact on the environment. To overcome this difficulty, the compounding system of environmentally friendly additives with SDS was intended to find the synergistic promotion effects aiming to reduce the usage of SDS in this study. Three kinds of cyclodextrins including αCD, βCD, hydroxypropyl-βCD (HPCD) with SDS were compounded to study the effect of their interaction on hydrate formation kinetics. The result showed that when used with SDS, the formation of hydrates was promoted by αCD and βCD but inhibited by HPCD. It is emphasized that the promoting effect depended on the water channel (completely hydrophilic zones) formed by H-bonds between cyclodextrin and SDS self-assembled channel-type complexes. Compared with 500 ppm SDS used along, it was possible to reduce the dosage of SDS by 40%. Finally, by observing the morphology of hydrate formation, it is found that the addition of cyclodextrins would affect the driving force for hydrate growth in the horizontal direction during hydrate formation. This study provides theoretical support for further understanding of cyclodextrin and surfactant compounding and shows an effective way for the application of SNG industry. [ABSTRACT FROM AUTHOR]

Published

2024

30. Thermodynamic analysis of a cascade organic Rankine cycle power generation system driven by hybrid geothermal energy and liquefied natural gas.

Author

Pan, Zilin, Fu, Yufei, Chen, Hongwei, and Song, Yangfan

Subjects

WORKING fluids, RANKINE cycle, EXERGY, ENERGY conservation, HEAT sinks, LIQUEFIED natural gas, NATURAL gas, GEOTHERMAL resources

Abstract

The combination of renewable energy and liquefied natural gas (LNG) cold energy can effectively improve energy utilization efficiency and achieve the goal of energy conservation and emission reduction, which is one of the important directions of future development. This work proposed a cascade organic Rankine cycle (ORC) driven by a geothermal heat source and an LNG heat sink. Seven organic fluids are chosen as candidates to form different working fluid pairs. The effects of the main design parameters on system performance are carried out through the thermodynamic analysis. Then, the optimal design conditions and fluid selection schemes are searched based on the singleobjective optimization results. Finally, the exergy destruction study is conducted under the optimal design conditions and working fluid pair. Results showed that the cascade ORC system using the working fluid pair of R601/R290 had the highest exergy efficiency, which could reach 20.02%. At the same time, under the optimal design conditions, the secondary cycle condenser and LNG direct expansion brought high exergy destruction, which was respectively 29.3% and 25.8%, and followed by the two turbines in the cascade ORC system, which were 16.1%, 11.2% and 7.7%. [ABSTRACT FROM AUTHOR]

Published

2024

31. Short-term natural gas load forecasting based on EL-VMD-Transformer-ResLSTM.

Author

Zhao, Mingzhi, Guo, Guangrong, Fan, Lijun, Han, Long, Yu, Qiancheng, and Wang, Ziyi

Subjects

*NATURAL gas consumption, *TRANSFORMER models, *NATURAL gas, *CITY dwellers, *BOX-Jenkins forecasting

Abstract

Due to changes in urban residents' consumption habits and lifestyles, accurately predicting natural gas consumption has become increasingly important. To address this issue, this paper proposes a forecasting model that combines Ensemble Learning (EL), Variational Mode Decomposition (VMD), Transformer, and LSTM. First, XGBoost, CatBoost, and LightGBM are used as base learners in the ensemble learning framework, with the predictions generated by the ensemble model integrated into the original dataset. Next, the VMD method is employed to decompose the natural gas load sequence into several intrinsic mode functions (IMFs), effectively extracting the inherent features of the natural gas load sequence. Finally, the data is input into the Transformer-ResLSTM network for prediction. This network replaces the original Transformer decoder structure with an LSTM network and fully connected layers, creating a new decoder structure. Additionally, a residual connection mechanism is introduced in both the encoder of the Transformer network and the new decoder structure. Experimental results show that, compared to traditional models such as ARIMA, Transformer, GRU, and LSTM, the proposed hybrid model significantly improves prediction accuracy, reducing MSE by 92–98% and MAE by 74–83%. In summary, this method demonstrates significant potential and practical value in enhancing the accuracy of natural gas load forecasting. [ABSTRACT FROM AUTHOR]

Published

2024

32. Heterogeneous catalysis of methane hydroxylation with nearly total selectivity under mild conditions.

Author

Fang, Geqian, Yu, Wenjun, Wang, Xiaodong, and Lin, Jian

Subjects

*METHANE hydrates, *NATURAL gas, *HETEROGENEOUS catalysis, *SHALE gas, *REACTIVE oxygen species

Abstract

The efficient utilization of methane, a vital component of natural gas, shale gas and methane hydrate, holds significant importance for global energy security and environmental sustainability. However, converting methane into value-added oxygenates presents a formidable challenge due to its inert nature. Direct selective oxidation of methane (DSOM) under mild conditions is essential for reducing energy consumption and carbon emissions compared with traditional indirect routes. Achieving total selectivity in methane hydroxylation remains elusive due to the competitive CO2 formation. This feature article highlights recent advancements in methane hydroxylation using thermo-, photo-, and electro-catalytic systems. Through strategically designing the structure of catalysts to control the reactive oxygen species and optimizing reaction parameters, significant progress has been made in enhancing oxygenate selectivity and minimizing overoxidation. A comprehensive understanding of the mechanisms underlying methane hydroxylation with total selectivity offers insights for improving catalyst design and reaction parameter optimization, promoting sustainable methane utilization. [ABSTRACT FROM AUTHOR]

Published

2024

33. A novel static mixer for blending hydrogen into natural gas pipelines.

Author

Di, Tao, Sun, Xu, Chen, Pengchao, Huang, Qiyu, and Liu, Xiaoben

Subjects

*NATURAL gas pipelines, *FLOW velocity, *PRESSURE drop (Fluid dynamics), *MASS (Physics), *NATURAL gas

Abstract

A novel static mixer is designed specifically to blend hydrogen into natural gas pipelines, and its effectiveness is validated by numerical simulation method. Firstly, the structural model of the proposed static mixer model for hydrogen-methane blending is introduced, and the evaluation indicators are defined. Secondly, the computational fluid dynamic model for the mixing process is established based on the Large Eddy Simulation(LES) method, and the accuracy of the numerical results is validated against the experimental data of a benchmark gas mixing model. Subsequently, using LES, effects structural parameters (angle and height of trapezoidal baffle, number of mixing elements, and spacing and installation distance of mixing elements) and flow parameters (main flow velocity and hydrogen blending ratio) on the mixing homogeneity and pressure drop of the static mixer are investigated systematically to explore the optimal design and operational conditions. The numerical results showed that the static mixer can significantly improve the mixing efficiency of hydrogen and natural gas with acceptable pressure loss. In the range of flow conditions concerned, a best performance of mixing could be obtained by installing the mixer at a distance of 3 D (D is the diameter of the natural gas pipeline) downstream the blending point, setting the spacing between mixing elements as 1 D and employing four mixing elements. Finally, the underlying physics of mass transportation are analyzed based on the vortex structures generated by the mixer. • A novel static mixer is designed to blend hydrogen into natural gas pipelines. • A Large eddy simulation solution procedure is proposed to solve multi-component mixing. • Effects of key parameters of the static mixer and operating conditions are revealed. • The mixing mechanism of static mixer is revealed based on vortex dynamics analysis. [ABSTRACT FROM AUTHOR]

Published

2024

34. Novel combustion instability diagnosis method in a hydrogen/natural gas co-firing gas turbine combustor using a combination of four criteria: Temporal kurtosis, permutation entropy, energy of entropy, and zero-crossing rate.

Author

Jang, Dae Jin, Joo, Seongpil, Kim, Min Kuk, Hwang, Jeongjae, and Lee, Min Chul

Subjects

*GAS dynamics, *ROOT-mean-squares, *GAS turbines, *DYNAMIC pressure, *NATURAL gas

Abstract

In this study, we developed a diagnosis method for combustion instability and validated its performance using experimental data obtained from a hydrogen/natural gas co-firing gas turbine combustor. Four criteria, namely temporal kurtosis, permutation entropy, energy entropy, and zero-crossing rate, were considered. First, the performance of each criterion was compared with that of the conventional method for determining combustion instability using the root mean square (RMS) of dynamic pressure. Temporal kurtosis the best performance in terms of detection speed (instability onset detected 0.71 s earlier than the RMS method). Permutation entropy yielded the best performance in terms of accuracy and precision with accuracy, recall, precision, and F1-score values of 96.6%, 100%, 92.6%, and 96.2%, respectively. The performances of combinations of these criteria were investigated using AND and OR gates. Twenty-two cases were considered and the combination of permutation entropy and zero-crossing rate (best case) achieved detection time, accuracy, precision, recall, and F1-score values of 8.49 s, 97.2%, 93.9%, 100%, and 96.8%, respectively. Other combinations exhibited competitive performance; however, the method combining two criteria was selected to simplify the computing process. The proposed method is expected to contribute to the safe and stable operation of hydrogen/natural gas co-firing gas turbines. • A Novel diagnostic method for detecting the onset of combustion instability is proposed. • The detection speeds and accuracies of TK, PE, EoE, and ZCR are assessed. • TK can detect instability onset 0.71 s earlier than the root mean square method. • PE achieved superior performance with 96.6% accuracy and 92.6% recall. • The PE∩STD ZCR combination improved accuracy (97%) and recall (100%). [ABSTRACT FROM AUTHOR]

Published

2024

35. Experimental testing and geometric optimization of a domestic cooker burning 80%Natural-Gas+20%Hydrogen.

Author

Liu, X.Y., Huang, G.L., Zhen, H.S., and Wei, Z.L.

Subjects

*FLAME, *FLAME temperature, *GAS mixtures, *GAS flow, *HEAT transfer, *NATURAL gas

Abstract

In urban pipelines, blending hydrogen into natural gas has been considered as an effective way of hydrogen usage to reduce carbon emission on household appliances. However, few studies, especially experimental ones are dedicated to address the characteristics of a typical domestic cooker due to the transition from natural gas to 20%hydrogen-enriched natural gas. This study experimentally investigated the changes in terms of the gas flow rate, flame temperature, heat transfer and emission characteristics of a domestic cooker as a result of such transition. Using a self-developed gas blending system, the flow rates of the both the mixed fuel and its components are obtained. The data shows that after blending hydrogen, the mixed gas flow rate becomes higher. Compared to the original cooker burning natural gas, hydrogen blending results in a decreased natural gas flow rate, leading to lower carbon emission. In addition, the thermal input to the cooker is lowered and hydrogen blending leads both the inner and outer combustion zones of the flame to shorten while the flame temperature to increase. As an attempt to optimize the performance of the cooker, the effects of wok stand height on heat transfer efficiency and NO/NO x /CO emissions are examined. It is found that the cooker fueled by 20%hydrogen-enriched natural gas exhibits lower heat transfer efficiency, higher NO/NO x emissions and lower CO emission. According to the fact that the heat transfer efficiency increases at lower wok stand height, the wok stand height is lowered from its original 7 cm–6 cm and 5 cm. The finding indicates that when the wok stand height is moderately decreased to 6 cm, NO/NO x emissions decrease and CO emission is only marginally increased. This study proposes that when natural gas is replaced by 20%hydrogen-enriched natural gas on a swirl flame cooker, the wok stand height can be slightly lowered to exploit the advantages of blended hydrogen combustion. • A systematic experimental study of the flow/temperature/emission/heat transfer of a cooker. • The changed flow rates are measured by using a self-developed device. • The height of the swirling flame shortens after blending hydrogen to natural gas. • The flame temperature/NOx emission increase while CO emission decrease. • Lowering the wok leads to higher heat transfer efficiency, lower NO x while only marginally higher CO. [ABSTRACT FROM AUTHOR]

Published

2024

36. CO2-based methane: an overlooked solution for the energy transition.

Author

Servin-Balderas, Ivonne, Wetser, Koen, ter Heijne, Annemiek, Buisman, Cees, and Hamelers, Bert

Subjects

SYNTHETIC natural gas, CARBON sequestration, RENEWABLE energy transition (Government policy), WATER electrolysis, CARBON dioxide, NATURAL gas

Abstract

Background: Fossil fuels can be replaced with electricity and hydrogen. However, the implementation and use of these low-carbon energy carriers require a sociotechnical transition. This transition might not be completed in time. Main text: CO 2 -based methane is a substitute for natural gas that is less carbon-intensive. This methane is synthesized by capturing CO 2 from air and by performing water electrolysis to produce hydrogen. CO 2 -based methane is compatible with our current fossil-based society. An analysis of the substitution of natural gas with different energy carriers will be performed, and the results will be compared. The effects of CO 2 -based methane, hydrogen, and electricity will be evaluated for energy storage, high-temperature level heat production, and residential heating. The multi-level perspective will be applied to assess these energy carriers in the context of our society. Conclusions: CO 2 -based methane is the least energy efficient energy carrier among those analyzed. Nevertheless, this type of methane supports the acceleration of the energy transition. Highlights: CO2-based methane is a valuable, renewable, and carbon-neutral energy carrier that supports a timely energy transition. The implementation of hydrogen and electricity requires more modifications to our current sociotechnical society than the implementation of CO2-based methane. The urgency of reducing CO2 emissions is not being considered adequately in the current societal discussion, and a multi-level perspective analysis should provide valuable results that account for the temporal aspect. [ABSTRACT FROM AUTHOR]

Published

2024

37. A review of challenges with using the natural gas system for hydrogen.

Author

Martin, Paul, Ocko, Ilissa B., Esquivel‐Elizondo, Sofia, Kupers, Roland, Cebon, David, Baxter, Tom, and Hamburg, Steven P.

Abstract

Hydrogen, as an energy carrier, is attractive to many stakeholders based on the assumption that the extensive global network of natural gas infrastructure can be repurposed to transport hydrogen as part of a zero‐carbon energy future. Therefore, utility companies and governments are rapidly advancing efforts to pilot blending low‐carbon hydrogen into existing natural gas systems, many with the goal of eventually shifting to pure hydrogen. However, hydrogen has fundamentally different physical and chemical properties to natural gas, with major consequences for safety, energy supply, climate, and cost. We evaluate the suitability of using existing natural gas infrastructure for distribution of hydrogen. We summarize differences between hydrogen and natural gas, assess the latest science and engineering of each component of the natural gas value chain for hydrogen distribution, and discuss proposed solutions for building an effective hydrogen value chain. We find that every value chain component is challenged by reuse. Hydrogen blending can circumvent many challenges but offers only a small reduction in greenhouse gas emissions due to hydrogen's low volumetric energy density. Furthermore, a transition to pure hydrogen is not possible without significant retrofits and replacements. Even if technical and economic barriers are overcome, serious safety and environmental risks remain. [ABSTRACT FROM AUTHOR]

Published

2024

38. Efficiency Enhancement in the Liquefied Natural Gas Storage Scheme: Exploring Thermal Performance for Enhanced Energy Storage Solutions.

Author

Salman, Muntadher Nahi, Ranjbar, Seyyed Faramarz, Jafari, Moharram, and Talati, Faramarz

Abstract

The ongoing transition in the energy sector demands more efficient and reliable energy storage solutions. Our study addresses this need by optimizing the industrial process of liquefied natural gas (LNG) storage, focusing on enhancing thermal performance and energy efficiency. Leveraging a standard LNG storage design, we meticulously evaluated critical supporting variables, modeled key components, and conducted integrated cycle simulations. The primary goal was to minimize the volume of stored gas (achieving a reduction to approximately 1/600th of its gaseous state) while maintaining optimal storage conditions. Our methodology prioritizes insulation over pressure‐bearing factors in large‐scale tanks, aligning with the unique thermal challenges of LNG storage. Simulations were based on methane, which constitutes over 86% of the natural gas in the Middle East, ensuring relevance to the region's resources. The results are promising, with a compression stage reaching a maximum pressure of 2.377, an energy efficiency ratio of 60.71%, and a performance coefficient of 3.188. These findings offer a significant step forward in developing more effective and efficient LNG storage systems, contributing to the broader goal of sustainable energy management. [ABSTRACT FROM AUTHOR]

Published

2024

39. Natural gas accumulation conditions and exploration directions of Carboniferous clastic rocks in the northeastern margin of Junggar Basin, China.

Author

Yanzhao Wei, Yiming, Abulimiti, Weian Wu, Aicheng Wu, Fan Yang, Chaowei Liu, Zesheng Wang, and Boyu Zhou

Subjects

*NATURAL gas, *CLASTIC rocks, *VOLCANIC ash, tuff, etc., *SANDSTONE, *SHALE gas

Abstract

The Carboniferous strata in the northeastern Junggar Basin are an important exploration field for natural gas in the basin. However, volcanic rocks have long been the primary exploration target. In contrast, the exploration and research of clastic rocks associated with source formations have been largely overlooked, resulting in an insufficient understanding of the reservoir forming conditions and exploration potential of Carboniferous clastic rocks. Through the evaluation of Carboniferous source rocks, effective source stove characterization, clastic reservoir evaluation, oil and gas source correlation, and reservoir formation model construction in this region, three key findings have been made. First, the Carboniferous in the northeastern Junggar Basin has developed three sets of high-quality gas source rocks: the Dishuiquan Formation, the Songkalsu B Member, and the Shiqiantan Formation. These formations correspond to three hydrocarbon source centers: the Sannan--Dishuiquan Sag, the Wucaiwan Sag--Dajing area, and the Dongdao Haizi Sag--Baijiahai High. Second, the Carboniferous system in the northeast has developed multiple types of large-scale reservoirs, including sand conglomerates, sandstones, turbidites, dolomitic rocks, and shale. These reservoirs are generally characterized by low porosity to ultra-low porosity and low permeability to ultra-low permeability reservoirs. There is a dissolution pore development zone at depths of 2900-4500 m. Third, a comparison of oil and gas sources reveals that all three sets of gas source rocks contribute to the natural gas found in the northeast, with obvious characteristics of near-source reservoir formation. The Carboniferous clastic rocks host two types of natural gas reservoirs: unconventional and conventional near-source reservoirs. It is predicted that there is an orderly accumulation pattern of shale gas, tight sandstone gas, and conventional natural gas reservoirs. This study reveals that the Carboniferous clastic rock source and reservoir configuration in the northeastern Junggar Basin is highly favorable, and the natural gas reservoirs in source and near-source clastic rocks represent important exploration directions. [ABSTRACT FROM AUTHOR]

Published

2024

40. Helium resources accumulation regulations and their development prospects in China.

Author

Jian Li, Xiaobo Wang, Zhusong Xu, Huiying Cui, Xiaomei Wang, Bin Zhang, Jianying Guo, Shizhen Tao, Jianfa Chen, Zengye Xie, Jixian Tian, and Yifeng Wang

Subjects

*HELIUM, *ECONOMIC development, *NATURAL gas, *GRANITE

Abstract

Helium is a globally scarce strategic resource that is relevant to national economies and the development of high-tech industries, and China primarily depends on imported helium for its industrial applications. Therefore, there is an urgent demand for clarifying helium formation and enrichment patterns, searching for helium-rich fields, and realizing China's helium resource inventory and development potential. This article analyzes the reservoir characteristics and accumulation conditions of typical helium-rich fields in China, and clarifying the origin and source of helium as well as the main controlling factors of helium enrichment. It was recognized that helium in natural gas in China mainly comes from crustal sources. Relatively shallow buried ancient U--Th-rich granite basement or intrusion, large and stable ancient uplift or submarine formed in the early period, good overburden of huge thick paste-salt rock or mudstone cover, and channels connecting the basement and reservoir, were the main controlling factors of helium enrichment. Four types of helium-rich gas reservoirs, namely helium-rich conventional gas, helium-rich shale gas, helium-rich non-hydrocarbon gas, and helium-rich water-soluble gas, have been modeled and predicted to be helium-rich favorable exploration areas. Based on this analysis, the prospect of helium resource development in China has been analyzed. It was proposed that the exploration of helium-rich fields and the comprehensive development and utilization of medium- and low-abundance helium resources are important ways to increase the domestic helium production in China in the future. [ABSTRACT FROM AUTHOR]

Published

2024

41. Differences in gas sources of the Changxing--Feixianguan formations around the Kaijiang-Liangping Trough and favorable exploration directions for coal-formed gas generated by the Upper Permian Longtan Formation, Sichuan Basin, China.

Author

Shipeng Huang, Zhenyu Zhao, Ai Yue, Hua Jiang, Xingwang Tian, Qingchun Jiang, Debo Ma, Wei Song, and Haijing Song

Subjects

*HYDROGEN isotopes, *NATURAL gas, *SHALE gas, *CARBON isotopes

Abstract

Through the analysis of natural gas composition, carbon and hydrogen isotopes of alkane gases, reservoir bitumen, source rock conditions, and source--reservoir combinations, this study clarifies the differences in gas sources and the origins of natural gas in the Permian Changxing Formation--Triassic Feixianguan Formation on both sides of the Kaijiang--Liangping Trough. Additionally, it identifies favorable exploration directions for coal-formed gas generated by the Longtan Formation in the Sichuan Basin. The following understanding was obtained: (1) The natural gas in the Changxing--Feixianguan formations mainly composed of alkane gas, typical of dry gas. (2) The carbon isotope values of methane and ethane in the Changxing--Feixianguan formations on the east side of the trough are lower than those on the west side. Specifically, the ethane carbon isotope value in the Longgang Gas Field on the west side is higher than that in the Yuanba Gas Field, while the methane hydrogen isotope value is lower in the Longgang Gas Field compared to the Yuanba Gas Field. (3) The natural gas in the Dongyuezhai, Puguang, and Yuanba gas fields predominantly originates from sapropelic organic matter of the Wujiaping Formation, with kerogen types II1--I; in contrast, the Longgang Gas Field contains a mixture of coal-formed gas and oil-type gas, with a slightly higher content of coal-formed gas, originating from mixed organic matter of the Wujiaping Formation, with kerogen type II1--II2. (4) Multiple types of gas, such as coal rock gas, tight sandstone gas, and shale gas, can be formed within the Longtan Formation. The Suining--Luzhou and Langzhong--Guang'an--Fuling areas are identified as favorable zones for the exploration of coal rock gas and marine--continental transitional shale gas, respectively. Additionally, the reef and shoal development areas of the Changxing Formation in the Suining--Hechuan and Guang'an--Nanchong regions are also favorable exploration areas for coal-formed gas. [ABSTRACT FROM AUTHOR]

Published

2024

42. Hydrocarbon Generation Characteristics of Coal‐measure Source Rocks and their Contribution to Natural Gas: A Case Study of Middle and Lower Jurassic Targets from the Southern Junggar Basin Margin.

Author

YU, Miao, GAO, Gang, LIU, Miao, MA, Wanyun, TIAN, Anqi, FAN, Keting, GUO, Liulinbo, HE, Dan, and ZHANG, Youjin

Subjects

*NATURAL gas, *CARBON isotopes, *LIQUID hydrocarbons, *LIQUEFIED gases, *NATURAL resources

Abstract

In order to study the hydrocarbon generation (HCGE) characteristics of coal‐bearing basins, the coal‐measure source rocks of the Middle Jurassic–Lower Jurassic (MLJ) of the piedmont thrust belt in the southern margin of the Junggar Basin in Northwest China are taken as research objects. More than 60 MLJ samples were collected from outcrops and wells. Total organic carbon (TOC), rock pyrolysis (Rock–Eval), organic petrological, vitrinite reflectance (%Ro), and hydrous pyrolysis were performed to analyze the relevant samples. The pyrolysis gases and liquid products were measured, and then the chemical composition, as well as carbon isotopes of the gases, were analyzed. The results indicate that the MLJ source rocks have the capacity for large‐scale gas generation. In addition, for coal‐measure source rocks, the heavier the carbon isotope of kerogen (δ13Ckerogen), the lower the liquid hydrocarbon and hydrocarbon gas yield, and the easier it is to produce non‐hydrocarbon gas. It is worth noting that when the δ13Ckerogen in organic matter (OM) is relatively heavier, the fractionation of its products may become weaker in the evolutionary process. The vital contribution of the MLJ source rock to natural gas resources in the study area was further confirmed by comparing it with the Jurassic source gas. [ABSTRACT FROM AUTHOR]

Published

2024

43. Investigation into the Simulation and Mechanisms of Metal–Organic Framework Membrane for Natural Gas Dehydration.

Author

Song, Qingxiang, Liu, Pengxiao, Zhang, Congjian, Ning, Yao, Pi, Xingjian, and Zhang, Ying

Subjects

*NATURAL gas extraction, *NATURAL gas, *NATURAL gas transportation, *COMPOSITE membranes (Chemistry), *MOLECULAR theory

Abstract

Natural gas dehydration is a critical process in natural gas extraction and transportation, and the membrane separation method is the most suitable technology for gas dehydration. In this paper, based on molecular dynamics theory, we investigate the performance of a metal–organic composite membrane (ZIF-90 membrane) in natural gas dehydration. The paper elucidates the adsorption, diffusion, permeation, and separation mechanisms of water and methane with the ZIF-90 membrane, and clarifies the influence of temperature on gas separation. The results show that (1) the diffusion energy barrier and pore size are the primary factors in achieving the separation of water and methane. The diffusion energy barriers for the two molecules (CH4 and H2O) are ΔE(CH4) = 155.5 meV and ΔE(H2O) = 50.1 meV, respectively. (2) The ZIF-90 is more selective of H2O, which is mainly due to the strong interaction between the H2O molecule and the polar functional groups (such as aldehyde groups) within the ZIF-90. (3) A higher temperature accelerates the gas separation process. The higher the temperature is, the faster the separation process is. (4) The pore radius is identified as the intrinsic mechanism enabling the separation of water and methane in ZIF-90 membranes. [ABSTRACT FROM AUTHOR]

Published

2024

44. Investigating Changes in Natural Gas Demand across Great Britain for Domestic Heating Using Daily Data: 2018 to 2024.

Author

Phillips, Geraint and Wilson, Grant

Subjects

*HOT water heating, *SPACE heaters, *ENERGY consumption, *CONSUMPTION (Economics), *PRICE regulation

Abstract

This study analyses data from natural gas combination boilers across a 6-year timeframe, exploring how demand for space heating and hot water have both changed over time, and highlights the impact of factors such as external temperature and the UK energy price cap. The results show that there has been a significant decrease in annual space heating and hot water demand since 2021. Space heating typically contributes 88% of the total annual gas demand of the boilers, with hot water contributing the other 12%. For the same mean temperature across the fourth quarter (8.5 °C), 2018 had a daily mean energy demand of 50.4 kWh, whereas the 2022 value was 41.4 kWh. This 9.0 kWh (18%) difference of the daily mean for Q4 suggests a shift in consumer demand influenced by other factors such as the energy price cap. This analysis provides additional understanding of how consumer energy demand for heating continues to evolve and invites further studies to be completed on future trends of energy demand for both space heating and hot water. Here, we also highlight the benefit of considering space heating and hot water as separate demands, as this provides additional insights and is something the paper helps to advocate for. [ABSTRACT FROM AUTHOR]

Published

2024

45. Novel Recuperated Power Cycles for Cost-Effective Integration of Variable Renewable Energy.

Author

Arnaiz del Pozo, Carlos, Cloete, Schalk, Chiesa, Paolo, and Jiménez Álvaro, Ángel

Subjects

*COMBUSTION efficiency, *COMBINED cycle (Engines), *FUEL costs, *PLANT capacity, *HYDROGEN as fuel, *POWER plants

Abstract

The ongoing transition to energy systems with high shares of variable renewables motivates the development of novel thermal power cycles that operate economically at low capacity factors to accommodate wind and solar intermittency. This study presents two recuperated power cycles with low capital costs for this market segment: (1) the near-isothermal hydrogen turbine (NIHT) concept, capable of achieving combined cycle efficiencies without a bottoming cycle through fuel combustion in the expansion path, and (2) the intercooled recuperated water-injected (IRWI) power cycle that employs conventional combustion technology at an efficiency cost of only 4% points. The economic assessment carried out in this work reveals that the proposed cycles increasingly outperform combined cycle benchmarks with and without CO2 capture as the plant capacity factor reduces below 50%. When the cost of fuel storage and delivery by pipelines is included in the evaluation, however, plants fired by hydrogen lose competitiveness relative to natural gas-fired plants due to the high fuel delivery costs caused by the low volumetric energy density of hydrogen. This important but uncertain cost component could erode the business case for future hydrogen-fired power plants, in which case the IRWI concept powered by natural gas emerges as a promising solution. [ABSTRACT FROM AUTHOR]

Published

2024

46. Response surface prediction model of radon exhalation rate on beach surface of uranium tailings pond based on single factor law.

Author

Chen, Yifan, Chen, Zhangkai, Wu, Xianwei, Huang, Juntao, and Liu, Yong

Subjects

*METAHEURISTIC algorithms, *VIBRATION tests, *RADON, *NATURAL gas, *PREDICTION models, *URANIUM

Abstract

Radon is a natural radioactive gas, which has great radiation hazards. Mastering the radon exhalation law under complex conditions is of great significance to the safety and stability of uranium tailings pond. Based on the self-developed artificial microclimate chamber, the single factor influence of water content, temperature and crack rate of overburden soil on radon exhalation rate of uranium tailings pond was explored through simulation experiments, and the corresponding single factor mathematical model was obtained. The response surface model of radon exhalation rate was constructed by combining whale optimization algorithm to achieve accurate prediction of radon exhalation rate. The test results of simulated seismic station vibration test also confirm the scientificity of the model. The results of this study can be used not only to guide the prediction and prevention of radon, but also to guide the early warning of uranium tailings pond instability. [ABSTRACT FROM AUTHOR]

Published

2024

47. Trajectory planning and automatic docking of LNG five-axis loading arm.

Author

Jiang, FaGuang, Chen, Kebing, Chen, Yang, and Tian, Cheng

Subjects

*COMPUTER vision, *CHARACTERISTIC functions, *NATURAL gas, *LIQUEFIED gases, *FLANGES

Abstract

Purpose: In response to the challenges posed by the conventional manual flange docking method in the LNG (Liquefied Natural Gas) loading process, such as low positioning accuracy, constraints on production efficiency and safety hazards, this study analyzed the LNG five-axis loading arm's main functions and structural characteristics. Design/methodology/approach: An automated solution for the joints of the LNG loading arm was designed. The forward kinematic model of the LNG loading arm was established using the Denavit–Hartenberg (D-H) parameter method, and its workspace was analyzed. The Newton–Raphson iteration method was employed to solve the inverse kinematics of the LNG loading arm, facilitating trajectory planning. The relationship between the target position and the joint variables was established to verify the stability of the arm's motion. Flange center identification was achieved using the Hough transform function. Based on the ROS platform, combined with Gazebo and Rviz, an experimental simulation of automatic docking of the LNG loading arm was conducted. Findings: The docking errors in the XYZ directions were all less than 0.8 mm, meeting the required docking accuracy. Moreover, the motion performance of the loading arm during docking was smooth and free of abrupt changes, validating its capability to accomplish the automatic docking task. Originality/value: The proposed trajectory planning and automatic docking scheme can be used for the rapid filling of LNG filling arms and LNG tankers to improve the efficiency of LNG transportation. In guiding the docking, the proposed automatic docking scheme is an accurate and efficient way to improve safety. [ABSTRACT FROM AUTHOR]

Published

2024

48. The effects of an abundance of natural resources on the healthcare industry: The global evidence.

Author

Katircioglu, Setareh

Subjects

*NATURAL resources, *HEALTH care industry, *NATURAL gas, *RESOURCE management, *COAL

Abstract

The current study investigates the effects of an abundance of natural resources on the healthcare industry worldwide. Various natural resources proxies such as rents for coal, mineral, natural gas, and oil are used and analyzed by using a quarterly datasets for the period 2000:Q1–2020:Q4. Results from regional and income group datasets show that various forms of natural resources abundance around the globe exert statistically significant, but a mix of positive and adverse effects on the healthcare sector. Results also reveal that changes in and shocks given to natural resources precede significant changes in the healthcare sector in general. This study advises that countries need to achieve careful resource management, open governance, and economic diversification top priority in order to lessen reliance on a single resource and mitigate any negative effects. Further implications are provided at the end of this study. [ABSTRACT FROM AUTHOR]

Published

2024

49. The greenhouse gas footprint of liquefied natural gas (LNG) exported from the United States.

Author

Howarth, Robert W.

Subjects

*GREENHOUSE gases, *SHALE gas, *ENERGY consumption, *OIL shales, *CARBON dioxide, *LIQUEFIED natural gas, *NATURAL gas, *TANKERS

Abstract

Liquefied natural gas (LNG) exports from the United States have risen dramatically since the LNG‐export ban was lifted in 2016, and the United States is now the world's largest exporter. This LNG is produced largely from shale gas. Production of shale gas, as well as liquefaction to make LNG and LNG transport by tanker, is energy‐intensive, which contributes significantly to the LNG greenhouse gas footprint. The production and transport of shale gas emits a substantial amount of methane as well, and liquefaction and tanker transport of LNG can further increase methane emissions. Consequently, carbon dioxide (CO2) from end‐use combustion of LNG contributes only 34% of the total LNG greenhouse gas footprint, when CO2 and methane are compared over 20 years global warming potential (GWP20) following emission. Upstream and midstream methane emissions are the largest contributors to the LNG footprint (38% of total LNG emissions, based on GWP20). Adding CO2 emissions from the energy used to produce LNG, total upstream and midstream emissions make up on average 47% of the total greenhouse gas footprint of LNG. Other significant emissions are the liquefaction process (8.8% of the total, on average, using GWP20) and tanker transport (5.5% of the total, on average, using GWP20). Emissions from tankers vary from 3.9% to 8.1% depending upon the type of tanker. Surprisingly, the most modern tankers propelled by two‐ and four‐stroke engines have higher total greenhouse gas emissions than steam‐powered tankers, despite their greater fuel efficiency and lower CO2 emissions, due to methane slippage in their exhaust. Overall, the greenhouse gas footprint for LNG as a fuel source is 33% greater than that for coal when analyzed using GWP20 (160 g CO2‐equivalent/MJ vs. 120 g CO2‐equivalent/MJ). Even considered on the time frame of 100 years after emission (GWP100), which severely understates the climatic damage of methane, the LNG footprint equals or exceeds that of coal. [ABSTRACT FROM AUTHOR]

Published

2024

50. Differential evolution of pore fluid pressure in the Sinian carbonate reservoirs of the central and eastern Sichuan Basin, China: Implication for gas preservation and destruction.

Author

Chen, Jiaxu, Chen, Changwei, He, Zhiliang, Guo, Xiaowen, Zhu, Huahui, Tao, Ze, Luo, Tao, Zhang, Dianwei, and Sun, Ziming

Subjects

*PORE fluids, *FLUID pressure, *NATURAL gas reserves, *CARBONATE reservoirs, *GAS reservoirs, *NATURAL gas

Abstract

Trillions of cubic meters of gas reserve have been found in the Sinian Dengying carbonate reservoirs with normal pressure in the central Sichuan Basin, while no industrial gas reservoir have been detected in the Sinian Dengying reservoir with normal pressure in the eastern Sichuan Basin. The pore fluid pressure of gas reservoir is usually closely related to total gas content. To investigate the pore fluid pressure evolution and its implication for gas reserve preservation in the Sinian Dengying reservoir of the central and eastern Sichuan Basin, we conducted a comprehensive analysis including fluid inclusion petrography, microthermometry and Raman spectroscopy. The timings of gas inclusions captured in the central and eastern Sichuan Basin occurred from 175 to 92 Ma and 191 to 183 Ma, respectively. The presence of two‐phase vapour‐solid bitumen inclusions with similar phase proportions in a single fluid inclusion assemblage of fluorite provides direct evidence of in situ oil cracking to gas. The widespread solid bitumen from the Sinian Dengying reservoir in the central Sichuan Basin indicates the existence of massive oil cracking, which results in the formation of overpressure in the reservoir. Pore fluid pressure evolution of the Sinian Dengying reservoir of the central Sichuan Basin experiences normal pressure stage (200–155 Ma), overpressure development stage (155–90 Ma) and overpressure release stage (90–0 Ma). The maximum pore fluid pressure and its corresponding pressure coefficient of the Sinian Dengying reservoir of the central Sichuan Basin are approximately 141.4 MPa and 1.95, respectively. The overpressure development stage reflects the processes of oil cracking and gas accumulation, and the overpressure release stage reflects the dissipation of some natural gas in the Sinian Dengying reservoir of the central Sichuan Basin. The pore fluid pressure of the Sinian Dengying reservoir in the eastern Sichuan Basin has maintained at normal pressure since 200 Ma, indicating that the gas reservoir was small during the oil cracking stage and natural gas completely leaked due to tectonic uplift. [ABSTRACT FROM AUTHOR]

Published

2024