World Academy of Science, Engineering and Technology

Authors: Xiang Liu, Cunxian Chen, Hao Zhou

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In the operation of large-scale molten salt storage tanks, foundation seepage due to rising groundwater levels or extreme rainfall can lead to uneven settlement and foundation instability. Coupled with thermal shock and thermal fatigue on the tank's bottom plate, such conditions may result in local cracking or even tank collapse, causing severe environmental pollution and economic loss. This study constructed a 1:100 scale molten salt storage tank foundation system in the laboratory to investigate the effects of floodwater, groundwater, and molten salt mixtures on the tank's bottom plate and foundation materials. High-temperature strain gauges and three-dimensional temperature sensors were used to capture the thermal shock patterns and specific thermal stress values (ranging from -200 to 150 MPa) experienced by the tank's bottom plate during accidents. The study confirmed that the thermal conductivity of the foundation materials could increase by 2 to 5 times their original values. Additionally, uniaxial compression tests revealed trends in changes to the foundation materials' elastic modulus and compressive strength. Finally, combining experimental results with numerical simulations, a systematic safety assessment method for complex accidents in large-scale molten salt storage tanks was proposed.

Keywords: thermal energy seorsge, tank, safety assessment, molten salt leakage

Procedia PDF Downloads 23

Authors: Silvio Carlos Anibal de Almeida

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Hydrogen stands out as a promising alternative to fossil fuels due to its significantly high energy density. The promise of a sustainable transportation system with fuel cell electric vehicles (FCEVs) depends on overcoming economic and infrastructure barriers. The high cost of hydrogen and the scarcity of refueling stations require innovative solutions for the widespread adoption of FCEVs. Although developments in fuel cell technology have reduced costs in recent years, FCEVs are still considerably more expensive than internal combustion vehicles. This study analyzes the prospects for cost reduction of FCEVs, hydrogen, and the investments needed to expand the hydrogen distribution network. Projections indicate that the cost of FCEVs will align with that of gasoline cars by 2050, driven by technological maturation and mass production. Reducing the production costs of green hydrogen by reducing renewable energy costs, developing more efficient electrolyzers, and leveraging economies of scale could bring the price down to less than $5/kgH₂ by 2030. Government investment and public-private partnerships are essential to build a robust infrastructure for production, transportation, storage, and refueling stations. The goal of a sustainable transportation future powered by FCEVs can only be achieved by converging these factors.

Keywords: alternative vehicles, fuel cell, fuel cell electric vehicles, green hydrogen

Procedia PDF Downloads 24

Authors: Amaro Olímpio Pereira Junior, Silvio Carlos Anibal de Almeida, Matheus Dias da Rocha

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Hydrogen plays an important role in transitioning to a low-carbon economy as an alternative to fossil fuels. However, to become competitive, hydrogen must overcome technical and economic barriers: production costs, storage, transportation, and large-scale production from renewable sources. Due to its low cost, steam reforming of natural gas is the most used route for hydrogen generation. However, besides not reducing the dependence on fossil fuels, the process presents the inconvenience of GHG emissions. This work evaluates the economic feasibility and emissions of different hydrogen production routes from methane, which can be obtained from biogas, a renewable fuel. Three routes for hydrogen production were compared: steam reforming, catalytic pyrolysis, and plasma pyrolysis. The results analyzed CO₂ emissions and hydrogen production costs. Steam reforming presented hydrogen production costs ranging from R$ 20.08 to R$ 22.70/kgH₂ and pyrolysis from R$ 34.18 to R$ 36.74/kgH₂. However, considering the commercialization of carbon black, a byproduct of pyrolysis, the hydrogen production cost can be reduced from R$ 25.26 to R$ 27.72/kgH₂. Regarding emissions, values for steam reforming range from 1.39 to 6.75 kg CO₂/kgH₂, considering CCS technologies, and those for pyrolysis range from 0.18 to 1.19 kg CO₂/kgH₂.

Keywords: hydrogen, pyrolysis, plasma reforming, methane, decarbonization

Procedia PDF Downloads 23

Authors: Afrah Bader Al Edan

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In the context of increasing global water scarcity, the reuse of produced water from oil production has emerged as a crucial strategy for sustainable water management. There is a feasibility of produced water reuse by using various treatments in different regions worldwide to show the potential applications of treated produced water, such as in agriculture and industrial processes. risk assessment framework can be employed to evaluate environmental, health, and operational risks associated with reuse. The findings underscore the importance of integrating advanced treatment technologies and stringent risk management practices to maximize the safe and effective reuse of produced water, providing reliable insights for the oil and gas industry.

Keywords: produced water, risk assessment, oil and gas, environmental impact

Procedia PDF Downloads 18

Authors: Shanshan Yang, Zhengfu Ning, Ying Kang

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The competitive adsorption between shale oil and CO₂ in kerogen is of great significance for CO₂ enhanced oil recovery (CO₂-EOR) and CO₂ storage. In this paper, molecular dynamics (MD) method is used to construct dry kerogen model, and grand canonical Monte Carlo (GCMC) method is used to construct shale reservoir kerogen model with different moisture content. Considering the influence of moisture content and shale oil composition, the competitive adsorption behavior of shale oil and CO₂ in kerogen is simulated, and the feasibility of CO₂ storage was evaluated. The results show that the presence of moisture content significantly reduces the ability of CO₂ to replace shale oil. With the increase of moisture content, the adsorption capacity of shale oil decreases, and the effect of CO₂ replacement of shale oil is improved. The adsorption capacity of long chain alkanes in shale oil decreases under moisture condition, and the competitive adsorption effect between short chain alkanes and CO₂ is more obvious. This study provides an effective guide to quantitatively reveal the competitive adsorption between CO₂ and shale oil from the microscopic perspective.

Keywords: competitive adsorption, kerogen, moisture content, shale oil, carbon dioxide, molecular simulation

Procedia PDF Downloads 18

Authors: Li Lu

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This work studies the processing of an all-solid-state sodium-ion battery (ASSB), utilizing sodium vanadium phosphate (NVP) as both the cathode and anode. The solid electrolyte is composed of a polymer matrix combined with nanoscale sodium zirconium phosphosilicate, Na₃Zr₂Si₂PO1₁₂ (NZSP) framework. To effectively enhance the desolvation of sodium salt, NaTFSI in the composite electrolyte, ferroelectric nano-ceramic particles are added to the electrolyte, achieving a high ionic conductivity in the range of 10⁻⁴ to 10⁻³ S/cm at room temperature. The full battery demonstrates impressive cycling performance, maintaining stability over 1000 charge/discharge cycles with minimal degradation. Atomic force microscopy (AFM) is employed to indirectly observe the ion transportation mechanisms within the battery, providing insights into the dynamics of sodium ion (Na⁺) movement. This study highlights the potential of polymer-NZSP composite electrolytes in enhancing the performance and longevity of ASSBs for next-generation energy storage applications.

Keywords: solid-state electrolyte, solid-state battery, composite electrolyte, impedance

Procedia PDF Downloads 27

Authors: Ranganatha Magadi, A. P. Achar

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Introduction: The urgent need to tackle climate change and environmental degradation highlights the significance of Renewable Energy Systems and Sources (RESSs). This paper explores the impactful roles of various RESSs—including wind, solar, hydropower, biomass, and geothermal energy—in mitigating greenhouse gas emissions and promoting sustainable development. It examines emerging technologies in energy storage and artificial intelligence to enhance renewable energy efficiency and reliability. The study also assesses essential policies for transitioning from conventional energy systems to renewables, focusing on grid interactivity and public awareness. Ultimately, this research aims to demonstrate how RESSs can drive climate resilience and contribute to a sustainable future. Objectives: The analysis aims to examine the contributions of various Renewable Energy Supply Systems (RESSs) in mitigating greenhouse gas emissions and promoting sustainable development while highlighting emerging trends and technologies such as advancements in energy storage, hybrid systems, and the integration of artificial intelligence and machine learning to enhance efficiency and reliability in renewable energy production. Additionally, it will assess the necessary policies and strategies for transitioning from conventional energy systems to renewable alternatives, focusing on aspects like grid interactivity, energy transformation, public awareness, and smart grid technologies. Methodology: This study employs a multi-faceted approach that includes a comprehensive literature review to gather insights on Renewable Energy Supply Systems (RESS) contributions to sustainability, quantitative data collection on energy production and greenhouse gas emissions from organizations like IRENA, and in-depth case studies of specific RESS projects across various geographical locations to illustrate practical applications. Additionally, it involves trend analysis through expert interviews and industry reports to identify emerging technologies, policy evaluation by analyzing existing policies with a focus on grid interactivity and public awareness, and the synthesis of findings by integrating insights from diverse sources to draw conclusions about the impact of RESSs. Contributions of the Paper: This research provides a comprehensive analysis of the impact of Renewable Energy Supply Systems (RESSs) in combating climate change while identifying emerging technologies, including current trends in energy storage and the integration of artificial intelligence in renewable energy systems. The paper offers actionable policy recommendations to facilitate the transition to renewable energy, illustrated through case studies that present best practices and real-world applications. Additionally, the findings highlight gaps in existing knowledge, encouraging further research into the sustainability impacts of RESSs. Overall, this study elucidates how RESSs can be instrumental in achieving climate resilience and environmental sustainability, ultimately contributing to a cleaner and greener future.

Keywords: renewable energy, sustainability, energy storage, artificial intelligence

Procedia PDF Downloads 24

Authors: Sripad Gowda, Praveen Nail

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Introduction: The urgent need for sustainable development has propelled the exploration and implementation of renewable and alternative energy technologies. This paper presents a comprehensive study on energy systems design and thermoeconomic analysis, focusing on optimizing the integration of renewable energy sources into existing infrastructures. Various renewable technologies, including solar, wind, and biomass, are analyzed to assess their economic viability, efficiency, and environmental impacts. Objectives: This study adopts a comprehensive approach to assess the role of renewable energy supply systems (RESSs) in promoting sustainability. It begins with an extensive literature review, aggregating insights from existing research. Quantitative data on energy generation and greenhouse gas emissions is sourced from reputable entities like the International Renewable Energy Agency (IRENA). In-depth case studies of specific RESS projects across various regions highlight practical applications. Trend analysis identifies emerging technologies through expert interviews and industry reports. Additionally, the study evaluates current policies, focusing on crucial elements such as grid interactivity and public awareness. Ultimately, the findings synthesize diverse insights to evaluate RESSs' sustainability impact. Methodology: This study uses a multi-faceted approach to explore how renewable energy supply systems (RESSs) contribute to sustainability. First, it includes a literature review to gather information from existing studies about RESSs. Next, quantitative data on energy production and greenhouse gas emissions is collected from organizations like the International Renewable Energy Agency (IRENA). The study also examines specific RESS projects through case studies in different locations to show their practical use. Additionally, it identifies new technologies by conducting expert interviews and reviewing industry reports. The methodology assesses current policies, focusing on important aspects like grid interactivity and public awareness. Finally, the findings are combined to provide a clear understanding of the impact of RESSs on sustainability. Outcomes: The findings underscore the importance of developing innovative design strategies that enhance energy conversion processes while minimizing waste and emissions. The study reveals critical insights into the economic feasibility of integrating renewable energy technologies, demonstrating that careful consideration of initial investments, operational costs, and potential returns can lead to more sustainable energy solutions. Additionally, barriers to widespread adoption are identified, alongside suggested pathways to overcome these challenges, providing practical recommendations for policymakers and industry stakeholders. Ultimately, this research contributes valuable insights that facilitate informed decision-making aimed at achieving sustainable development goals, reducing dependence on fossil fuels, and addressing the pressing challenges of climate change and environmental degradation.

Keywords: sustainable development, renewable energy, thermoeconomic analysis, energy systems

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Authors: Emmanuel Ikegwuonu, Sixtus Afam, Godslove Uwumwonse, David Val-Izevbigie, Goodnews Imakpokpomwan

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The growing demand for electric vehicles has intensified the need for efficient battery thermal management systems to enhance performance, safety, and longevity. This study investigates the spatial efficiency and thermal performance of battery modules utilizing hexagonal cells integrated with a zig-zag liquid cooling channel and makes a comparative analysis with conventional cylindrical cells with serpentine cooling channels. The results revealed that the hexagonal cells offer superior spatial efficiency, occupying less area per cell due to their compact packing structure. This efficiency not only reduces the overall module footprint but also creates opportunities to incorporate additional batteries or enhance thermal management systems, potentially increasing battery capacity and thermal performance. Numerical analysis on ANSYS Fluent showed that the zig-zag cooling channel effectively minimized temperature gradients within the modules. Compared to cylindrical cells, hexagonal cells demonstrated improved thermal uniformity, with lower maximum and average cell temperatures due to their tighter packing and enhanced contact with the coolant. The findings emphasize the combined advantages of hexagonal cells and zig-zag cooling channels in optimizing battery performance for electric vehicles. This research provides valuable insights for the development of next-generation battery modules with enhanced spatial and thermal efficiency, contributing to the advancement of electric vehicle and renewable energy storage technology.

Keywords: battery module, cylindrical cells, electric vehicle, hexagonal cells, serpentine cooling channels, spatial efficiency, thermal management, zig-zag cooling channels

Procedia PDF Downloads 29

Authors: Rajini Murugesan, Anantharaj Sengeni, Arthanareeswari Maruthapillai

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The global transition to renewable energy hinges on breakthroughs in catalysis for the oxygen evolution reaction (OER) a bottleneck in fuel cell and water-splitting technologies. The 3D nanostructured Mn-doped CoFe-LDH catalyst merges high-performance engineering with next-generation material design. By leveraging the synergistic effects of Mn doping within the CoFe-LDH framework, this self-supported catalyst achieves a quantum leap in OER efficiency. The strategically tailored 3D architecture amplifies active surface areas and facilitates seamless electron transport, while Mn incorporation fine-tunes the electronic structure, unlocking new catalytic pathways. Synthesized through an accessible hydrothermal approach, the material redefines scalability in catalyst production. The Mn-doped CoFe-LDH delivers industry-leading performance, with an impressively low overpotential of 255 mV at 20 mA cm⁻², combined with enduring stability over 24 hours of rigorous operation in alkaline media. This remarkable performance not only rivals state-of-the-art alternatives but also offers a sustainable, cost-effective solution tailored for real-world energy applications. Our findings bridge the gap between material innovation and practical implementation, setting a benchmark for OER catalysis in the era of clean energy. The Mn-doped CoFe-LDH isn’t just a catalyst; it’s a vision for the future of sustainable energy technologies.

Keywords: clean energy, fuel cells, layered double hydroxides (LDH), oxygen evolution reaction (OER).

Procedia PDF Downloads 28

Authors: Emmanuel Nsengiyumva

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The complementary feature of batteries and supercapacitors (SC) in terms of energy density and power density makes the battery-supercapacitor hybrid energy storage system (HESS) an effective energy storage solution in application scenarios requiring a high power density and high energy density as it is for electric vehicle (EV). An appropriate topology and energy management strategy (EMS) for HESS is required to coordinate the power distribution among different power sources. Currently, commercial carbon-based supercapacitors are usually applied in HESS. However, the energy density of such supercapacitors is too low. On the other hand, new types of electrochemical capacitors, like hybrid supercapacitors, were reported to have increased energy density. This could lead to an improvement in the energy efficiency of a HESS. Thus, this study aims to build an adaptive EMS for battery/supercapacitor considering these new types of capacitors to increase the performance of the system. Effects of electrochemical capacitor model parameters on efficiency are studied after obtaining the model through parameter characterization of experimental data. Also, the charging mechanism's effect on energy efficiency is studied in this project. Firstly, a rule-based EMS with the aim of considering battery as a primary energy storage system is proposed. Then, dynamic programming (DP) is used with the purpose of minimizing the energy losses in the system, thereby improving energy efficiency. The DP optimization algorithm was chosen for our work to reach optimal global results. Since this optimization method can be used to refine rule-based methods or be considered as a tool to prepare training datasets for further usage in data-based EMSs, it will be used to refine the rule-based method for our case, which is a promising solution for real-time implementation.

Keywords: energy management strategy, hybrid energy storage system, battery, supercapacitor

Procedia PDF Downloads 29

Authors: HyeSuk Ri, HyonChol Kim, NamChol Yu

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The FTO thin films were deposited on 15 cm × 15 cm glass substrates by ultrasonic spray pyrolysis, and the influence of process parameters on the film properties was investigated. This paper is the first report on the design of a uniform nozzle and simulating the carrier gas flow characteristics in an ultrasonic spray pyrolysis process. The uniformity of FTO films was evaluated by surface resistivity. The structure, surface morphology and optical properties of FTO films were investigated using scanning electron microscopy, X-ray diffraction, and UV-Vis spectroscopy. The process conditions for film preparation were SnCl₄ concentration of 1.34 mol, NH₄F concentration of 0.08 mol, temperature of 500 °C, deposition time of 15 min, carrier gas flow rate of 3 m/s, distance between nozzle and substrate of 0.7 cm. The transmittance of the fabricated FTO films was 80%, the surface resistance showed a uniform behavior at 14-15Ω/cm² and the X-ray analysis showed a high orientation of SnO₂ crystals in the 200-plane. SEM analysis showed that the crystallite size was constant.

Keywords: nozzle design, FTO film, simulation, ultrasonic spray pyrolysis

Procedia PDF Downloads 32

Authors: Foozhan Gharehkhani

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The use of solar energy as a sustainable renewable energy source has gained significant attention in recent years. Solar concentrating systems (CSP), which direct solar radiation onto a receiver, are an effective means of producing high-temperature thermal energy. Cavity receivers, known for their high thermal efficiency and reduced heat losses, are particularly noteworthy in these systems. Optimizing their design can enhance energy efficiency and reduce costs. This study leverages the genetic algorithm, a powerful optimization tool inspired by natural evolution, to optimize the performance of a solar concentrator system with a cavity receiver, aiming for a more efficient and cost-effective design. In this study, a system consisting of a solar concentrator and a cavity receiver was analyzed. The concentrator was designed as a parabolic dish, and the receiver had a cylindrical cavity with a helical structure. The primary parameters were defined as the cavity diameter (D), the receiver height (h), and the helical pipe diameter (d). Initially, the system was optimized to achieve the maximum heat flux, and the optimal parameter values along with the maximum heat flux were obtained. Subsequently, a multi-objective optimization approach was applied, aiming to maximize the heat flux while minimizing the system construction cost. The optimization process was conducted using the genetic algorithm implemented in MATLAB with precise execution. The results of this study revealed that the optimal dimensions of the receiver, including the cavity diameter (D), receiver height (h), and helical pipe diameter (d), were determined to be 0.142 m, 0.1385 m, and 0.011 m, respectively. This optimization resulted in improvements of 3% in the cavity diameter, 8% in the height, and 5% in the helical pipe diameter. Furthermore, the results indicated that the primary focus of this research was the accurate thermal modeling of the solar collection system. The simulations and the obtained results demonstrated that the optimization applied to this system maximized its thermal performance and elevated its energy efficiency to a desirable level. Moreover, this study successfully modeled and controlled effective temperature variations at different angles of solar irradiation, highlighting significant improvements in system efficiency. The significance of this research lies in leveraging solar energy as one of the prominent renewable energy sources, playing a key role in replacing fossil fuels. Considering the environmental and economic challenges associated with the excessive use of fossil resources—such as increased greenhouse gas emissions, environmental degradation, and the depletion of fossil energy reserves—developing technologies related to renewable energy has become a vital priority. Among these, solar concentrating systems, capable of achieving high temperatures, are particularly important for industrial and heating applications. This research aims to optimize the performance of such systems through precise design and simulation, making a significant contribution to the advancement of advanced technologies and the efficient utilization of solar energy in Iran, thereby addressing the country's future energy needs effectively.

Keywords: cavity receiver, genetic algorithm, optimization, solar concentrator system performance

Procedia PDF Downloads 34

Authors: Tao Lin, Hongzhi Song, Zhongtao Yuan, Shanshan Lin, Chunyue Tong

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Offshore heavy oil in the production of thick oil fields, old wells of low production and low efficiency are mainly caused by plugging, heavy oil, insufficient stratigraphic energy, etc., the use of heat - gas - chemical and other composite production enhancement role, can be better to achieve the purpose of unblocking and increase the efficiency of the production. Through indoor physical simulation experiments, comprehensive grey correlation analysis, combined with theoretical methods to analyze the composite production enhancement effect of heat-gas-chemical and other factors was in the order of heat>gas>chemical agent; and quantitative analysis of the data shows that the contribution of heat is the highest in the range of 68.5%-82.8%, the gas role in the range of 9.3%-11.3%, and the contribution of the chemical agent in the range of 6.0%-22.2%. Combined with indoor physical simulation experiments and reservoir engineering calculations, it shows that the production capacity is restored and increased by about 50%, and numerical simulation calculations show that the cumulative increase in production by using thermal-gas-chemical decongestion process measures can be up to 40%. Through the optimization of this kind of compound production enhancement technology, it can meet the requirements of original production string operation, and this technology has the advantages of short, flat and fast operation and has good application prospects.

Keywords: MCTF, old heavy oil wells, low production and low efficiency, immobile tubular column, composite production increase

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Authors: Abdelaziz Nasr

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This work conducted numerical simulations to examine the impact of the static electric field on a falling-film evaporation system. A constant electric field can alter the dynamics of a liquid film by modifying the heat and mass transfer properties of the system. The geometry problem consists of two parallel plates in a vertical channel, with the left plate experiencing a constant heat flux and the liquid flowing downward over it, while the right plate remains dry and maintains a constant temperature. The gaseous component consists of dry air and water vapor, whilst the liquid component comprises a thin coating of water. The results suggest that the electric field's impact on heat and mass transport, as well as the evaporation of the liquid sheet, is minimal. Experimental evidence demonstrates that the electric field exerts a minor influence on heat, mass transport, and liquid film evaporation at elevated electric field intensities.

Keywords: electric field, evaporation, liquid film, heat and mass transfer

Procedia PDF Downloads 30

Authors: Luzie Krings, Sven Liebehentze, Maximilian Gehring, Uwe Rüppel

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The integration of renewable energy into the energy grid is essential for decarbonization, and leveraging electrified vehicles (EVs) as mobile storage units offers a pathway to address grid challenges. The decentralized nature of EVs and the intermittency of renewable energy sources, such as photovoltaic (PV) and wind power, complicate grid stability. Vehicle-to-Grid (V2G) technology presents a promising solution, enabling EVs to support grid stability through services like redispatch, congestion mitigation, and enhanced renewable energy utilization. Freight transport, contributing 38% of transport emissions, holds significant potential as its aggregated energy storage capacity can stabilize the grid and optimize renewable energy integration. This study introduces a risk-averse optimization model for marketing EV flexibilities in Germany’s energy markets, with a strong focus on improving grid stability and maximizing renewable energy potential. Using a linear optimization framework, the model incorporates technical, regulatory, and operational constraints to simulate EV fleets as scalable energy storage solutions. The integration of proprietary PV and wind energy systems is also modeled to evaluate benefits. Benchmarks compare bidirectional charging with unidirectional charging under dynamic tariffs. The methodology employs the Python-based energypilot tool to optimize participation in Day-Ahead, Intraday, and Redispatch markets, accounting for trading conditions and temporal offsets. Results demonstrate that redispatch utilization substantially supports grid stability, while bidirectional charging increased renewable energy integration by 15% and economic benefits by 20%. Longer charging cycles offered greater financial returns compared to fragmented cycles, emphasizing the potential of fleets with extended idle periods for storing renewable energy. This research highlights the critical role of EVs in stabilizing the grid and utilizing renewable energy effectively by expanding storage capacity. The optimization framework addresses key challenges in energy trading, offering a transferable methodology for broader energy storage applications. This supports the transition to a sustainable energy system by improving environmental outcomes and economic incentives.

Keywords: Electric Vehicles, Energy Grid, Energy Storages, Redispatch

Procedia PDF Downloads 23

Authors: Salar Ahmed Ali

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Hydraulic fracturing has revolutionized the extraction of unconventional oil and gas resources, significantly increasing global energy reserves. This paper explores recent advancements in hydraulic fracturing technologies, focusing on the integration of real-time monitoring systems, environmentally friendly fracturing fluids, and nanotechnology applications. Case studies demonstrate how innovative approaches have enhanced resource recovery while minimizing environmental impact and operational costs. Additionally, the paper addresses challenges such as induced seismicity and regulatory constraints, proposing solutions to ensure sustainable development. These advancements promise to make hydraulic fracturing more efficient, sustainable, and adaptable to the evolving energy landscape.

Keywords: oil, gas, fracture, hydraulic

Procedia PDF Downloads 27

Authors: Danlei Yang, Luofeng Huang

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The integration of digital twin technology with renewable energy systems offers an innovative approach to predicting and optimising performance throughout the entire lifecycle. A digital twin is a continuously updated virtual replica of a real-world entity, synchronised with data from its physical counterpart and environment. Many digital twin companies today claim to have mature digital twin products, but their focus is primarily on equipment visualisation. However, the core of a digital twin should be its model, which can mirror, shadow, and thread with the real-world entity, which is still underdeveloped. For a floating solar energy system, a digital twin model can be defined in three aspects: (a) the physical floating solar energy system along with environmental factors such as solar irradiance and wave dynamics, (b) a digital model powered by artificial intelligence (AI) algorithms, and (c) the integration of real system data with the AI-driven model and a user interface. The experimental setup for the floating solar energy system, is designed to replicate real-ocean conditions of floating solar installations within a controlled laboratory environment. The system consists of a water tank that simulates an aquatic surface, where a floating catamaran structure supports a solar panel. The solar simulator is set up in three positions: one directly above and two inclined at a 45° angle in front and behind the solar panel. This arrangement allows the simulation of different sun angles, such as sunrise, midday, and sunset. The solar simulator is positioned 400 mm away from the solar panel to maintain consistent solar irradiance on its surface. Stability for the floating structure is achieved through ropes attached to anchors at the bottom of the tank, which simulates the mooring systems used in real-world floating solar applications. The floating solar energy system's sensor setup includes various devices to monitor environmental and operational parameters. An irradiance sensor measures solar irradiance on the photovoltaic (PV) panel. Temperature sensors monitor ambient air and water temperatures, as well as the PV panel temperature. Wave gauges measure wave height, while load cells capture mooring force. Inclinometers and ultrasonic sensors record heave and pitch amplitudes of the floating system’s motions. An electric load measures the voltage and current output from the solar panel. All sensors collect data simultaneously. Artificial neural network (ANN) algorithms are central to developing the digital model, which processes historical and real-time data, identifies patterns, and predicts the system’s performance in real time. The data collected from various sensors are partly used to train the digital model, with the remaining data reserved for validation and testing. The digital twin model combines the experimental setup with the ANN model, enabling monitoring, analysis, and prediction of the floating solar energy system's operation. The digital model mirrors the functionality of the physical setup, running in sync with the experiment to provide real-time insights and predictions. It provides useful industrial benefits, such as informing maintenance plans as well as design and control strategies for optimal energy efficiency. In long term, this digital twin will help improve overall solar energy yield whilst minimising the operational costs and risks.

Keywords: digital twin, floating solar energy system, experiment setup, artificial intelligence

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Authors: Alexandra Papagianni, George Filis, Panagiotis Papadopoulos

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This paper evaluates the effectiveness of different forecasting strategies for the day-ahead electricity prices, using benchmark and state-of-the-art modelling frameworks. The literature is currently using two types of forecasting strategies, namely, the direct, and the iterated forecasts. Even though there is a tendency toward iterated approaches, there are no studies to assess whether the choice of alternative forecasting strategies could improve predictions. We do so in the present study, by entering into a “beauty” contest these standard approaches, in an effort to test whether the choice of the forecast strategy can impact the quality of the forecasts. We use hourly day-ahead electricity prices, evaluating the period surrounding the onset of the RussiaUkraine conflict in February 2022. Based on the findings of this study, forecasters can substantially improve their predictions by adjusting a range of forecasting strategies to fit specific concepts and timeframes with each forecast.

Keywords: short-term electricity price forecast, forecast strategies, forecast horizons, iterated strategy, direct strategy

Procedia PDF Downloads 25

Authors: Bahamin Bazooyar, Xinyan Wang, Hua Zhao

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As a zero-carbon fuel, hydrogen can be used in combustion engines to avoid carbon emissions. This paper numerically investigates the engine performance of a two-stroke opposed piston hydrogen engine by using three-dimensional (3D) Computational Fluid Dynamics (CFD) simulations. The engine displacement is 12.2 cm, and the compression ratio of 39. RANS simulations with the k-ε turbulence model and coupled chemistry combustion models are performed at an engine speed of 4500 rpm and hydrogen flow rate of up to 100 gr/s. In order to model the hydrogen injection process, the hydrogen nozzle was meshed with refined mesh, and injection pressure varied between 100 and 200 bars. In order to optimize the hydrogen combustion process, the injection timing was optimized between 15 before the top dead center and 10. The results showed that the combustion efficiency was mostly influenced by the injection pressures due to its impact on the fuel/air mixing and charge inhomogeneity. Nitrogen oxide (NOₓ) emissions are well correlated with engine peak temperatures, demonstrating that the thermal NO mechanism is dominant under engine conditions. Through the optimization of hydrogen injection timing and pressure, the peak thermal efficiency of 45 and NOx emission of 15 ppm/kWh can be achieved at an injection timing of 350 CA and pressure of 160 bars.

Keywords: engine, hydrogen, diesel, two-stroke, opposed-piston, decarbonisation

Procedia PDF Downloads 32

Authors: Zaid H. Yaseen, Jamel A. Orfi, Zeyad A. Alsuhaibani

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Solar power has a huge potential to be employed in the fields of electricity production, water desalination, and multi-generation. There are various types of solar collectors, and parabolic trough collectors (PTCs) are common among these types. In PTCs, a mirror is used to direct the incident radiation on an absorber tube to utilize the heat in power generation. In this work, a PTC covered with a glass tube is presented and analyzed. Results showed that temperatures of 510℃ for steam can be reached for certain parameters. The work also showed the viability of using Benzene as the working fluid in the absorber tube. Also, some analysis regarding changing the absorber’s tube diameter and the efficiency of the solar collector was demonstrated in this work. The effect of changing the heat transfer correlations for the convection phenomena of the working fluid was illustrated. In fact, two heat transfer correlations, the Dittus-Boelter and Gnielinski correlations, were used, and the outcomes showed a resemblance in the results for the maximum attainable temperature in the working fluid.

Keywords: absorber tube, glass tube, incident radiation, parabolic trough collector

Procedia PDF Downloads 30

Authors: Jiaojiao Zhang

Abstract:

Boar sperm quality, as an important indicator of reproductive efficiency, directly affects the efficiency of livestock production. Here, this study was conducted to improve the boar sperm quality by using a non-thermal dielectric barrier discharge (DBD) plasma. Our results showed that DBD plasma exposure at 2.1 W for 15 s could improve boar sperm quality by increasing the exon methylation level of adenosine monophosphate-activated protein kinase (AMPK) and thus improving the glycolytic flux, mitochondrial function, and antioxidant capacity without damaging the integrity of sperm DNA and acrosome. In addition, DBD plasma could rescue DNA methyltransferase inhibitor decitabine-caused low sperm quality by reducing oxidative stress and mitochondrial damage. Therefore, the application of non-thermal plasma provides a new strategy for reducing sperm oxidative damage and improving sperm quality, which shows great potential in assisted reproduction to solve the problem of male infertility.

Keywords: non-thermal DBD plasma, sperm quality, AMPK methylation, energy metabolism, antioxidant capacity

Procedia PDF Downloads 28

Authors: Gwani M., Umar M. Kangiwa, Bello A. Umar, Gado A. Abubakar

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The increasing demand for sustainable energy solutions has driven significant interest in the development of innovative designs of wind turbines. The horizontal axis wind turbine (HAWT) and the vertical axis wind turbine (VAWT) are the dominant type of wind turbine used for power generation. However, these turbines have their respective merits and demerits, which affect their performance. This study introduces a Hybrid Cross Axis Wind Turbine (HCAWT), which integrates the blades of both horizontal axis wind turbines (HAWTs) and vertical axis wind turbines (VAWTs) in a cross-axis configuration with a Savonius rotor to form a hybrid system. The HCAWT combines the self-starting capabilities of Savonius rotors with the high-efficiency characteristics of Darrieus rotors and HAWT, aiming to optimize performance across a range of wind conditions. The performance of the HCAWT was tested and evaluated against a cross-axis wind turbine (CAWT) and a conventional VAWT under similar experimental conditions. The study’s results indicate that the HCAWT outperformed both the CAWT and the conventional VAWT. The power coefficient (Cp) of the HCAWT increases by 83% and 132% compared to that of the CAWT and conventional VAWT, respectively. The findings show that the HCAWT offers better start-up performance and maintains higher efficiency at lower wind speeds compared to CAWT and conventional VAWT. The findings suggest that the HCAWT offers significant improvements in energy capture, particularly in turbulent wind conditions, and greater adaptability to changing wind conditions, making it a viable option for both urban and rural energy applications.

Keywords: renewable energy, hybrid, cross axis wind turbine, energy efficiency

Procedia PDF Downloads 28

Authors: Nadia Bachir (Dahmani), Fatima Zohra Otmani

Abstract:

Due to its interesting optoelectronic properties, methylammonium perovskite CH3NH3PbI3 is used as the active layer in the development of several solar cells. In this work, the hybrid (organic-inorganic) cell with the architecture FTO/pedotpss/CH3NH3PbI3/pcdtbt/Al is simulated using the Organic and Hybrid Material Nano Simulation Tool (OghmaNano). We studied the influence of certain parameters, such as thickness, on the characteristics of the solar cell. The effect of the device temperature was also investigated. The photovoltaic characteristic curves, such as current-voltage (j-V), are presented in this work. The optimized final parameters are Voc = 0.947 V, FF = 0.8034%, and PCE = 23.16%.

Keywords: OghmaNano software, hybrid perovskite cell, CH3NH3PbI3, conversion efficiency

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Authors: Sarita Sindhu, Vinay Kumar

Abstract:

The growing demand for efficient energy storage in applications such as portable electronics, electric vehicles, and renewable energy systems has emphasized the need for advanced energy storage materials. This study addresses the pressing need for efficient energy storage materials by exploring the synthesis and application of a composite of activated carbon (AC) and nickel sulfide (NiS) for supercapacitors. Activated carbon, possessing high surface area and excellent electrochemical stability, was combined with nickel sulfide, a transition metal sulfide with high theoretical capacitance, to enhance the electrochemical performance of the composite material. Characterization techniques, including scanning electron microscopy (SEM), X-ray diffraction (XRD), and Fourier-transform infrared spectroscopy (FTIR), were employed to analyze the morphology, crystalline structure, and bonding characteristics, confirming the successful formation of a uniformly distributed AC/NiS composite. Electrochemical evaluations revealed that the AC/NiS composite exhibited superior capacitance, excellent rate capability, and enhanced cycling stability compared to pure AC and NiS. The synergistic effect of the large surface area from activated carbon and redox-active sites of nickel sulfide provided an improved energy storage capacity, making this composite a promising electrode material for high-performance supercapacitors.

Keywords: activated carbon, energy storage, sulfide, surface area

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Authors: Annu Sheokand, Vinay Kumar

Abstract:

Hydrogen sulfide (H₂S) detection is essential for environmental monitoring and industrial safety due to its high toxicity, even at low concentrations. This study explores the H₂S gas sensing properties of Cu-doped Fe₂O₃ materials derived from metal-organic frameworks (MOFs), which offer high surface area and controlled porosity for optimized gas sensing. The structural and morphological characteristics of the synthesized material were thoroughly analyzed using techniques such as X-ray Diffraction (XRD), Field Emission Scanning Electron Microscopy (FE-SEM), and UV-Vis Spectroscopy. The resulting sensor exhibited remarkable sensitivity and selectivity, achieving a detection limit at the ppb level for H₂S. The study indicates that Cu doping significantly enhances the gas sensing performance of Fe₂O₃ by introducing abundant active sites within the material. These enhanced sensing properties emphasize the potential of MOF-derived Cu-doped Fe₂O₃ as a highly effective material for H₂S gas sensors in various applications.

Keywords: detection limit, doping, MOF, sensitivity, sensor

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Authors: Mamta Bulla, Vinay Kumar

Abstract:

The transition to renewable energy sources is essential due to the finite limitations of conventional fossil fuels, which contribute significantly to environmental pollution and greenhouse gas emissions. Traditional energy storage solutions, such as batteries and capacitors, are also hindered by limitations, particularly in capacity, cycle life, and energy density. Conventional supercapacitors, while able to deliver high power, often suffer from low energy density, limiting their efficiency in storing and providing renewable energy consistently. Renewable energy sources, such as solar and wind, produce power intermittently, so efficient energy storage solutions are required to manage this variability. Advanced materials, particularly those with high capacity and long cycle life, are critical to developing supercapacitors capable of effectively storing renewable energy. Among various electrode materials, vanadium pentoxide (V₂O₅) offers high theoretical capacitance, but its poor conductivity and cycling stability limit practical applications. This study explores the hydrothermal synthesis of a V₂O₅-carbon nanotube (CNT) composite to overcome these drawbacks, combining the high capacitance of V₂O₅ with the exceptional conductivity and mechanical stability of CNTs. The resulting V₂O₅-CNT composite demonstrates enhanced electrochemical performance, showing high specific capacitance of 890 F g⁻¹ at 0.1 A g⁻¹ current density, excellent rate capability, and improved cycling stability, making it a promising candidate for next-generation supercapacitors, with significant improvements in energy storage efficiency and durability.

Keywords: cyclability, energy density, nanocomposite, renewable energy, supercapacitor

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Authors: Sunil Kumar, Vinay Kumar, Mamta Bulla, Rita Dahiya

Abstract:

Supercapacitors have emerged as a leading energy storage technology, gaining popularity in applications like digital telecommunications, memory backup, and hybrid electric vehicles. Their appeal lies in a long cycle life, high power density, and rapid recharge capabilities. These exceptional traits attract researchers aiming to develop advanced, cost-effective, and high-energy-density electrode materials for next-generation energy storage solutions. Two-dimensional (2D) nanostructures are highly attractive for fabricating nanodevices due to their high surface-to-volume ratio and good compatibility with device design. In the current study, a composite was synthesized by combining MoS2 with reduced graphene oxide (rGO) under optimal conditions and characterized using various techniques, including XRD, FTIR, SEM and XPS. The electrochemical properties of the composite material were assessed through cyclic voltammetry, galvanostatic charging-discharging and electrochemical impedance spectroscopy. The supercapacitor device demonstrated a specific capacitance of 153 F g-1 at a current density of 1 Ag-1, achieving an excellent energy density of 30.5 Wh kg-1 and a power density of 600 W kg-1. Additionally, it maintained excellent cyclic stability over 5000 cycles, establishing it as a promising candidate for efficient and durable energy storage solutions. These findings highlight the dynamic relationship between electrode materials and offer valuable insights for the development and enhancement of high-performance symmetric devices.

Keywords: 2D material, energy density, galvanostatic charge-discharge, hydrothermal reactor, specific capacitance

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Authors: Basheer Idrees Balarabe, Aminu Hamisu Kura, Nabila Shehu

Abstract:

As the power demand rapidly increases, the generation and transmission systems are affected because of inadequate resources, environmental restrictions and other losses. The role of transient stability control in maintaining the steady-state operation in the occurrence of large disturbance and fault is to describe the ability of the power system to survive serious contingency in time. The application of a Unified power flow controller (UPFC) plays a vital role in controlling the active and reactive power flows in a transmission line. In this research, a genetic algorithm (GA) method is applied to determine the optimal location of the UPFC device in a power system network for the enhancement of the power-system Transient Stability. Optimal location of UPFC has Significantly Improved the transient stability, the damping oscillation and reduced the peak over shoot. The GA optimization Technique proposed was iteratively searches the optimal location of UPFC and maintains the unusual bus voltages within the satisfy limits. The result indicated that transient stability is improved and achieved the faster steady state. Simulations were performed on the IEEE 14 Bus test systems using the MATLAB/Simulink platform.

Keywords: UPFC, transient stability, GA, IEEE, MATLAB and SIMULINK

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Authors: Waleed Alsaidy, Mourad Mbarki

Abstract:

In this work, it have investigated the effect of electron irradiation on the output characteristics of n+/p GaAs solar cell. The studied solar cell is exposed to an electron beam with kinetic energy of 1 MeV under AM0 illumination. In this work, it have used our own software to calculate the damage caused by these energetic particles. Indeed, these particles produce severe degradation on the performances of the solar cells. The aim of this work is to investigate the effect of electronic irradiation on the J(V) characteristics upon the fluence of particles φ (electron/cm2). Thereafter, we have evaluated the degradation of its performances such as the short circuit current J_sc, the open circuit voltage V_oc the efficiency η with respect to the fluence φ of electrons. it have shown that the variation of these parameters decrease linearly with the logarithm of the fluence φ, and their degradation begins from a threshold value φ_m. To validate our calculation, we have compared our results with other theoretical and experimental results available in the literature and we have found a good agreement between them.

Keywords: solar cells, GaAs, short circuit current, open circuit voltage, fluence, degradation

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