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Applicability of Hydrogen Fuel for a Cruise Ship
Jan 2025
Publication
Cruise ships function as a means of transport while simultaneously accommodating thousands of guests providing a holiday experience with various entertainment options. This translates to high energy requirements for propulsion and hotel operations typically covered by the combustion of fossil fuels. The operation of cruise vessels with fossil fuels contributes to carbon dioxide and also local harmful emissions in ports when shore power connections are not available. To enable cleaner and sustainable cruising alternative technologies and fuels must be adopted. The present study evaluated the applicability of hydrogen fuel in combustion engines in a Meraviglia-class cruise ship. The fuel consumption of the ship was based on a real operation in Europe. This study examined how fuel energy in the form of LH2 could be stored on the ship for a European cruise route and concludes that 3700 m3 of storage space would be needed to accommodate the liquid hydrogen. The mass of the LH2 would only be one-third of that of fossil fuels but the weight of the LH2 tanks would most likely increase the total weight of the hydrogen storage. Additional new technologies and combined power production could significantly reduce the amount of LH2 to be stored.
Potential of Hydrogen Fuel Cell Aircraft for Commercial Applications with Advanced Airframe and Propulsion Technologies
Jan 2025
Publication
The present work demonstrates a comparative study of hydrogen fuel cells and combustion aircraft to investigate the potential of fuel cells as a visionary propulsion system for radically more sustainable medium- to long-range commercial aircraft. The study which considered future airframe and propulsion technologies under the Se2A project was conducted to quantify potential emissions and costs associated with such aircraft and to determine the benefits and drawbacks of each energy system option for different market segments. Future technologies considered in the present work include laminar flow control active load alleviation new materials and structures ultra-high bypass ratio turbofan engines more efficient thermal management systems and superconducting electric motors. A multi-fidelity initial sizing framework with coupled constraint and mission analysis blocks was used for parametric airplane sizing and calculations of all necessary characteristics. Analyses performed for three reference aircraft of different sizes and ranges concluded that fuel-cell aircraft could have operating cost increases in the order of 30% compared to hydrogen combustion configurations and were caused by substantial weight and fuel burn increases. In-flight changes in emissions of fuel cell configurations at high altitudes were progressively reduced from medium-range to long-range segments from being similar to hydrogen combustion for medium-range to 24% for large long-range aircraft although fuel cell aircraft consume 22–30% more fuel than combustion aircraft. Results demonstrate a positive environmental impact of fuel cell propulsion for longrange applications the possibilities of being a more emission-universal solution if desired optimistic technology performance metrics are satisfied. The study also demonstrates progressively increasing technology requirements for larger aircraft making the long-range application’s feasibility more challenging. Therefore substantial development of fuel cell technologies for long-range aircraft is imperative. The article also emphasizes the importance of airframe and propulsion technologies and the necessity of green hydrogen production to achieve desired emissions.
Hydrogen Economy Index - A Comparative Assessment of the Political and Economic Perspective in the MENA Region for a Clean Hydrogen Economy
Jan 2025
Publication
The ongoing discourse on the transition to a hydrogen-based economy and the lessons learned from visions such as the Desertec concept emphasise the necessity for a nuanced approach to the development of metrics to assess a country’s hydrogen readiness. In addition to economic criteria such as investment incentives factors including law and order governance performance geography infrastructure and renewable energy production potential significantly impact a location’s attractiveness. To transparently evaluate sites using multiple criteria defined in the PESTEL framework this article aims to analyse quantify and compare the development of a sustainable hydrogen economy in 18 Middle East and North African states. The index-based assessment integrates criteria across three dimensions offering a comprehensive perspective on regional challenges and opportunities striking for policymakers and investors. The results show that the highest-ranked countries belong to the Gulf Cooperation Council followed by North African countries.
HYDRIDE4MOBILITY: An EU Project on Hydrogen Powered Forklift using Metal Hydrides for Hydrogen Storage and H2 Compression
Jan 2025
Publication
Volodymyr A. Yartys,
Mykhaylo V. Lototskyy,
Ivan Tolj,
José Bellosta von Colbe,
Roman V. Denys,
Moegamat Wafeeq Davids,
S. Nyallang Nyamsi,
Dana Swanepoel,
V.V. Berezovets,
I.Yu. Zavaliy,
Suwarno Suwarno,
I.J. Puszkiel,
Julian Jepsen,
Inês Abreu Ferreira,
Claudio Pistidda,
Yuanyuan Shang,
Sivakumar Pasupathi and
Vladimir Linkov
The EU Horizon2020 RISE project 778307 “Hydrogen fuelled utility and their support systems utilising metal hydrides” (HYDRIDE4MOBILITY) worked on the commercialization of hydrogen powered forklifts using metal hydride (MH) based hydrogen stores. The project consortium joined forces of 9 academic and industrial partners from 4 countries. The work program included a) Development of the materials for hydrogen storage and compression; b) Theoretical modelling and optimisation of the materials performance and system integration; c) Advanced fibre reinforced composite cylinder systems for H2 storage and compression; d) System validation. Materials development was focused on i) Zr/Ti-based Laves type high entropy alloys; ii) Mg-rich composite materials; iii) REMNiSn intermetallics; iv) Mg based materials for the hydrolysis process; v) Cost-efficient alloys. For the optimized AB2±x alloys the Zr/Ti content was optimized at A = Zr78-88Ti12–22 while B=Ni10Mn5.83VFe. These alloys provided a) Low hysteresis of hydrogen absorption-desorption; b) Excellent kinetics of charge and discharge; c) Tailored thermodynamics; d) Long cycle life. Zr0.85Ti0.15TM2 alloy provided a reversible H storage and electrochemical capacity of 1.6 wt% H and 450 mAh/g. The tanks development targeted: i) High efficiency of heat and hydrogen exchange; ii) Reduction of the weight and increasing the working H2 pressure; iii) Modelling testing and optimizing the H2 stores with fast performance. The system for power generation was validated at the Implats plant in a fuel cell powered forklift with on-board MH hydrogen storage and on-site H2 refuelling. The outcome on the HYDRIDE4MOBILITY project (2017–2024) (http://hydride4mobility.fesb.unist. hr) was presented in 58 publications.
Lifecycle Management of Hydrogen Pipelines: Design, Maintenance, and Rehabilitation Strategies for Canada’s Clean Energy Transition
Jan 2025
Publication
This paper examines the crucial elements of pipeline-based hydrogen transportation highlighting the particular difficulties and technical developments required to guarantee the sustainable effective and safe supply of hydrogen. This study lists the essential phases of hydrogen pipeline management from design to repair as the relevance of hydrogen infrastructure in the worldwide energy transition continues to rise. It discusses the upkeep monitoring operation and rehabilitation procedures for aged pipelines with an emphasis on the cutting-edge techniques and technology used to mitigate the dangers related to hydrogen’s unique features such as leakage and embrittlement. Together with highlighting the legislative and regulatory frameworks that enable the infrastructure this paper also discusses the material economic and environmental difficulties related to hydrogen pipelines. Lastly it emphasizes how crucial it is to fund research create cutting-edge materials and implement sophisticated monitoring systems to guarantee the long-term dependability and safety of hydrogen pipelines. These initiatives will be crucial in allowing hydrogen’s contribution to the future of renewable energy together with international collaboration on regulatory standards.
Network Evolutionary Game Analysis of Coal-to-Hydrogen CCUS Technology Dissemination in Carbon Trading Market
Jan 2025
Publication
Integrating coal-to-hydrogen production with Carbon Capture Utilization and Storage (CCUS) is essential for reducing greenhouse gas emissions and facilitating a shift towards a more sustainable energy paradigm. This paper explores the diffusion of CCUS technology within the coal-to-hydrogen sector against the dynamic backdrop of the carbon trading market. An evolutionary game-theoretic approach is utilized within a smallworld network framework to analyze the spread of CCUS technology among coal-tohydrogen enterprises. The simulation reveals that current market dynamics along with technological market and policy-related uncertainties do not robustly encourage the adoption of CCUS. As the carbon trading market continues to mature carbon prices become a significant factor influencing the diffusion of CCUS technology in coal-to-hydrogen processes. Furthermore investment costs hydrogen market prices and governmental policies are identified as pivotal elements in the propagation of CCUS technology. This study contributes valuable insights into the sustainable development of the hydrogen industry and the broader implications for low-carbon energy transition strategies.
Assessing the Feasibility of a Green Hydrogen Economy in Selected African Regions with Composite Indicators
Jan 2025
Publication
This study offers a comprehensive analysis of the feasibility of green hydrogen economies in Western and Southern African regions focusing on the ECOWAS and SADC countries. Utilizing a novel approach based on composite indicators the research evaluates the potential readiness and overall feasibility of green hydrogen production and export across these regions. The study incorporates various factors including the technical potential of renewable energy sources water resource availability energy security and existing infrastructure for transport and export. Country-specific analyses reveal unique insights into the diverse potential of nations like South Africa Lesotho Ghana Nigeria Angola and Namibia each with its unique strengths and challenges in the context of green hydrogen. The research findings underscore the complexity of developing green hydrogen economies highlighting the need for nuanced region-specific approaches that consider technical socioeconomic geopolitical and environmental factors. The paper concludes that cooperation and integration between countries in the regions may be crucial for the success of a future green hydrogen economy
Hydrogen Risk Assessment Studies: A Review Toward Environmental Sustainability
Jan 2025
Publication
The transition to hydrogen as a clean energy source is critical for addressing climate change and supporting environmental sustainability. This review provides an accessible summary of general research trends in hydrogen risk assessment methodologies enabling diverse stakeholders including researchers policymakers and industry professionals to gain insights into this field. By examining representative studies across theoretical experimental and simulation-based approaches the review highlights prominent trends and applications within academia and industry. The key focus is on evaluating risks in stationary and transportation applications paying particular attention to hydrogen storage systems transportation infrastructures and energy systems. By offering a concise yet informative summary of hydrogen risk assessment trends this paper aims to serve as a foundational resource for fostering safer and more sustainable hydrogen systems.
A Comparative Science-Based Viability Assessment Among Current and Emerging Hydrogen Production Technologies
Jan 2025
Publication
This research undertakes a comparative analysis of current and emerging hydrogen (H2) production technologies evaluating them based on quantitative and qualitative decision criteria. The quantitative criteria include cost of H2 production (USD/kg H2) energy consumption (MJ/kg H2) global warming potential (kg CO2-eq/kg H2) and technology energy efficiency (%). The qualitative criteria encompass technology readiness level (TRL) and availability of supply chain materials (classified as low medium or high). To achieve these objectives an extensive literature review has been conducted systematically assessing the selected H2 production technologies against the aforementioned criteria. The insights synthesized from the literature provide a foundation for an informed science-based evaluation of the potentials and techno-economic challenges that these technologies face in achieving the 1-1-1 goal set by the U.S. Department of Energy (DOE) in 2021. This target aims for a H2 production cost of USD 1/kg H2 within one decade (by 2031) including costs associated with production delivery and dispensing at H2 fueling stations (HRSs). Also the DOE established an interim goal of USD 2/kg H2 by 2026. This research concludes that among the examined H2 production technologies water electrolysis and biomass waste valorization emerge as the most promising near-term solutions to meet the DOE’s goal.
Water Requirements for Hydrogen Production: Assessing Future Demand and Impacts on Texas Water Resources
Jan 2025
Publication
Hydrogen is emerging as a critical component in the global energy transition providing a low-carbon alternative for sectors such as industry and transportation. This paper aims to comprehensively address water usage in hydrogen production by exploring the water demands of different production methods and their implications for water management particularly in Texas. Key variables influencing water consumption are identified and potential water demands under different hydrogen market scenarios are estimated. Using spatial analysis regions where hydrogen production may stress local water resources are identified alongside policy recommendations for sustainable water use.
Hydrogen Leakage Location Prediction in a Fuel Cell System of Skid-Mounted Hydrogen Refueling Stations
Jan 2025
Publication
Hydrogen safety is a critical issue during the construction and development of the hydrogen energy industry. Hydrogen refueling stations play a pivotal role in the hydrogen energy chain. In the event of an accidental hydrogen leak at a hydrogen refueling station the ability to quickly predict the leakage location is crucial for taking immediate and effective measures to prevent disastrous consequences. Therefore the development of precise and efficient technologies to predict leakage locations is vital for the safe and stable operation of hydrogen refueling stations. This paper studied the localization technology of high-risk leakage locations in the fuel cell system of a skid-mounted hydrogen refueling station. The hydrogen leakage and diffusion processes in the fuel cell system were predicted using CFD simulations and the hydrogen concentration data at various monitoring points were obtained. Then a multilayer feedforward neural network was developed to predict leakage locations using simulated concentration data as training samples. After multiple adjustments to the network structure and hyperparameters a final model with two hidden layers was selected. Each hidden layer consisted of 10 neurons. The hyperparameters included a learning rate of 0.0001 a batch size of 32 and 10-fold cross-validation. The Softmax classifier and Adam optimizer were used with a training set for 1500 epochs. The results show that the algorithm can predict leakage locations not included in the training set. The accuracy achieved by the model was 95%. This approach addresses the limitations of sensor detection in accurately locating leaks and mitigates the risks associated with manual inspections. This paper provides a feasible method for locating hydrogen leakage in hydrogen energy application scenarios.
Simulation of PEM Electrolyzer Power Management with Renewable Generation in Owerri, Nigeria
Jan 2025
Publication
Proton exchange membrane electrolyzers are an attractive technology for hydrogen production due to their high efficiency low maintenance cost and scalability. To receive these benefits however electrolyzers require high power reliability and have relatively high demand. Due to their intermittent nature integrating renewable energy sources like solar and wind has traditionally resulted in a supply too sporadic to consistently power a proton exchange membrane electrolyzer. This study develops an electrolyzer model operating with renewable energy sources at a highly instrumented university site. The simulation uses dynamic models of photovoltaic solar and wind systems to develop models capable of responding to changing climatic and seasonal conditions. The aim therefore is to observe the feasibility of operating a proton exchange membrane system fuel cell yearround at optimal efficiency. To address the problem of feasibility with dynamic renewable generation a case study demonstrates the proposed energy management system. A site with a river onsite is chosen to ensure sufficient wind resources. Aside from assessing the feasibility of pairing renewable generation with proton exchange membrane systems this project shows a reduction in the intermittency plaguing previous designs. Finally the study quantifies the performance and effectiveness of the PEM energy management system design. Overall this study highlights the potential of proton exchange membrane electrolysis as a critical technology for sustainable hydrogen production and the importance of modeling and simulation techniques in achieving its full potential.
Influence of Safety Culture on Safety Outcomes of a Hydrogen–CCS Plant
Jan 2025
Publication
: This article investigates how safety culture impacts the safety performance of blue hydrogen projects. Blue hydrogen refers to decarbonized hydrogen produced through natural gas reforming with carbon capture and storage (CCS) technology. It is crucial to decide on a suitable safety policy to avoid potential injuries financial losses and loss of public goodwill. The system dynamics approach is a suitable tool for studying the impact of factors controlling safety culture. This study examines the interactions between influencing factors and implications of various strategies using what-if analyses. The conventional risk and safety assessments fail to consider the interconnectedness between the technical system and its social envelope. After identifying the key factors influencing safety culture a system dynamics model will be developed to evaluate the impact of those factors on the safety performance of the facility. The emphasis on safety culture is directed by the necessity to prevent major disasters that could threaten a company’s survival as well as to prevent minor yet disruptive incidents that may occur during day-to-day operations. Enhanced focus on safety culture is essential for maintaining an organization’s long-term viability. H2-CCS is a complex socio-technical system comprising interconnected subsystems and sub-subsystems. This study focuses on the safety culture sub-subsystem illustrating how human factors within the system contribute to the occurrence of incidents. The findings from this research study can assist in creating effective strategies to improve the sustainability of the operation. By doing so strategies can be formulated that not only enhance the integrity and reliability of an installation as well as its availability within the energy networks but also contribute to earning a good reputation in the community that it serves.
Electrochemical Sensor for Hydrogen Leakage Detection at Room Temperature
Jan 2025
Publication
The use of hydrogen as fuel presents many safety challenges due to its flammability and explosive nature combined with its lack of color taste and odor. The purpose of this paper is to present an electrochemical sensor that can achieve rapid and accurate detection of hydrogen leakage. This paper presents both the component elements of the sensor like sensing material sensing element and signal conditioning as well as the electronic protection and signaling module of the critical concentrations of H2. The sensing material consists of a catalyst type Vulcan XC72 40% Pt from FuelCellStore (Bryan TX USA). The sensing element is based on a membrane electrode assembly (MEA) system that includes a cathode electrode an ion-conducting membrane type Nafion 117 from FuelCellStore (Bryan TX USA). and an anode electrode mounted in a coin cell type CR2016 from Xiamen Tob New Energy Technology Co. Ltd (Xiamen City Fujian Province China). The electronic block for electrical signal conditioning which is delivered by the sensing element uses an INA111 from Burr-Brown by Texas Instruments Corporation (Dallas TX USA). instrumentation operational amplifier. The main characteristics of the electrochemical sensor for hydrogen leakage detection are operation at room temperature so it does not require a heater maximum amperometric response time of 1 s fast recovery time of maximum 1 s and extended range of hydrogen concentrations detection in a range of up to 20%.
New Development Paths through Green Hydrogen? An Ex-ante Assessment of Structure and Agency in Chile and Namibia
Jan 2025
Publication
Many developing countries seek to participate in the emerging global green hydrogen industry not only as exporters of green hydrogen and its derivatives to Europe and the Far East but also to use it for their own energy security and green transition. They hope that new development paths will lead to late-comer industrialisation. This article assesses corresponding prospects in Chile and Namibia two countries that pursue particularly ambitious plans on green hydrogen. To better understand the chances for path creation ex ante the authors draft an innovative framework that refers to context factors – that is structure – and three types of transformative agency. Against the backdrop of information from secondary sources and a series of expert interviews they uncover sound institutional reforms and initiatives of place-based leadership to promote the green hydrogen industry. However Chile and Namibia lack Schumpeterian entrepreneurship. It therefore remains to be seen whether new development paths will be inclusive contributing to in-country development. Typical downsides of extractive industries in resource peripheries might occur.
Bridging the Gap: Public Perception and Acceptance of Hydrogen Technology in the Philippines
Jan 2025
Publication
This study examines the effects of transitioning to hydrogen production in the National Capital Region (NCR) and Palawan Province Philippines focusing on technology environment and stakeholder impact. This research conducted through a July 2022 survey aimed to assess public awareness knowledge risk perception and acceptance of hydrogen and its environmentally friendly variant green hydrogen infrastructure. Disparities were found between urban NCR and rural Palawan with lower awareness in Palawan. Safety concerns were highlighted with NCR respondents generally considering hydrogen production safe while Palawan respondents had mixed feelings particularly regarding nuclear-based hydrogen generation. This report emphasizes the potential ecological advantages of hydrogen technology but highlights potential issues concerning water usage and land impacts. It suggests targeted public awareness campaigns robust safety assurance programs regional pilot projects and integrated environmental plans to facilitate the seamless integration of hydrogen technology into the Philippines’ energy portfolio. This collective effort aims to help the country meet climate action obligations foster sustainable development and enhance energy resilience.
Breakthrough Position and Trajectory of Sustainable Energy Technology
Jan 2025
Publication
This research aims to determine the position and the breakthrough trajectory of sustainable energy technologies. Fine-grained insights into these breakthrough positions and trajectories are limited. This research seeks to fill this gap by analyzing sustainable energy technologies’ breakthrough positions and trajectories in terms of development application and upscaling. To this end the breakthrough positions and trajectories of seven sustainable energy technologies i.e. hydrogen from seawater electrolysis hydrogen airplanes inland floating photovoltaics redox flow batteries hydrogen energy for grid balancing hydrogen fuel cell electric vehicles and smart sustainable energy houses are analyzed. This is guided by an extensively researched and literature-based model that visualizes and describes these technologies’ experimentation and demonstration stages. This research identifies where these technologies are located in their breakthrough trajectory in terms of the development phase (prototyping production process and organization and niche market creation and sales) experiment and demonstration stage (technical organizational and market) the form of collaboration (public–private private–public and private) physical location (university and company laboratories production sites and marketplaces) and scale-up type (demonstrative and first-order and second-order transformative). For scientists this research offers the opportunity to further refine the features of sustainable energy technologies’ developmental positions and trajectories at a detailed level. For practitioners it provides insights that help to determine investments in various sustainable energy technologies.
Offshore Wind Power—Seawater Electrolysis—Salt Cavern Hydrogen Storage Coupling System: Potential and Challenges
Jan 2025
Publication
Offshore wind power construction has seen significant development due to the high density of offshore wind energy and the minimal terrain restrictions for offshore wind farms. However integrating this energy into the grid remains a challenge. The scientific community is increasingly focusing on hydrogen as a means to enhance the integration of these fluctuating renewable energy sources. This paper reviews the research on renewable energy power generation water electrolysis for hydrogen production and large-scale hydrogen storage. By integrating the latest advancements we propose a system that couples offshore wind power generation seawater electrolysis (SWE) for hydrogen production and salt cavern hydrogen storage. This coupling system aims to address practical issues such as the grid integration of offshore wind power and large-scale hydrogen storage. Regarding the application potential of this coupling system this paper details the advantages of developing renewable energy and hydrogen energy in Jiangsu using this system. While there are still some challenges in the application of this system it undeniably offers a new pathway for coastal cities to advance renewable energy development and sets a new direction for hydrogen energy progress.
Techno-economic and Environmental Assessment of Green Hydrogen Production via Biogas Reforming with Membrane-based CO2 Capture
Jan 2025
Publication
Reduction of the carbon dioxide emissions is a vital important environmental element in achieving the global climate neutrality. The integration of renewables and the Carbon Capture Utilization and Storage (CCUS) technologies is seen as an important pillar for overall decarbonization. This work presents several innovative concepts in which the biogas reforming process in integrated with pre- and post-combustion CO2 capture using membranes for green hydrogen production. The assessment evaluates the most relevant techno-economic and environmental performances for 100 MWth green hydrogen plant capacity. Several biogas reforming designs with and without CO2 capture capability were evaluated. In respect to the CO2 capture rate several pre- and postcombustion systems provided decarbonization yields between 55% up to 99%. The results show that the decarbonized membrane-based green hydrogen production shows attractive performances such as high energy efficiency (55–60%) reduced energy and cost penalties for CO2 capture (3.6–15.5 net efficiency points depending on the carbon capture rate) low specific CO2 emissions at system level (down to 2 kg/MWh green hydrogen) and overall negative carbon emission for whole biogas value chain (up to − 468 kg/MWh green hydrogen). This analysis clearly shows how the integration of renewables with CCUS technologies can deliver applications with negative CO2 emissions for climate neutrality.
Essentials of Hydrogen Storage and Power Systems for Green Shipping
Jan 2025
Publication
This paper establishes a framework of boundary conditions for implementing hydrogen energy systems in ships identifying what is feasible within maritime constraints. To support a comprehensive understanding of hydrogen systems onboard vessels an extensive technical review of hydrogen storage and power systems is provided covering the entire power value chain. Key aspects include equipment arrangement integration of fuel cell powertrain and presentation of the complete storage system in compliance with regulations. Engineering considerations such as material selection and insulation equipment specifications (e.g. pressure relief valves and hydrogen purity) and system configurations are analysed. Key findings reveal that fuel cells must achieve operational lifespans exceeding 46000 h to be viable for maritime applications. Additionally reliance solely on volumetric energy density underestimates storage needs necessitating provisions for cofferdams ullage space tank heels and hydrogen conditioning areas. Regulatory gaps are identified including inadequate safety provisions and inappropriate material guidelines.
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