Review on modern ways of insulation of reservoirs for liquid hydrogen storage

Yatsenko, E. A.; Гольцман, Б. М.; Novikov, Yu. V.; Izvarin, A.I.; Rusakevich, I.V.

doi:10.1016/j.ijhydene.2022.09.211

Cited by 33 publications

(7 citation statements)

References 76 publications

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“…However, the large amount of energy required to liquefy the hydrogen and the special low-temperature heat-insulated container required by this technology result in high energy loss and high cost. This indicates that from a long-term and economic perspective, liquid hydrogen storage method is not suitable for multi-rotor drones that require frequent operations [104].…”

Section: Liquid Hydrogen Storage Methodsmentioning

confidence: 99%

A Review on Key Technologies and Developments of Hydrogen Fuel Cell Multi-rotor Drones

Shen,

Liu,

Zhu

et al. 2024

Preprint

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Multi-rotor drones, a kind of unmanned equipment which is widely used in military, commercial consumption and other fields, has been developed very rapidly in recent years. However, their short flight time has hindered the expansion of their application range. This can be addressed by utilizing hydrogen fuel cells, which exhibit high energy density, strong adaptability to ambient temperature, and no pollution emissions, as the power source. Accordingly, the application of hydrogen fuel cells as the power source in multi-rotor drones is a promising technology that has attracted significant research attention. This paper summarizes the development process of hydrogen fuel cell mul-ti-rotor drones and analyzes the key obstacles that need to be addressed for the further development of hydrogen fuel cell multi-rotor drones, including structural lightweight, hydrogen storage methods, energy management strategies. Additionally, prospects for the future development of hydrogen fuel cell multi-rotor drones are presented.

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Section: Liquid Hydrogen Storage Methodsmentioning

confidence: 99%

A Review on Key Technologies and Developments of Hydrogen Fuel Cell Multi-rotor Drones

Shen,

Liu,

Zhu

et al. 2024

Preprint

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“…Innovative designs, such as double-walled tanks with inner and outer insulation layers, have improved insulation performance and minimized heat loss during LNG storage (Yin, 2024). Additionally, advanced materials and construction techniques have enhanced the structural integrity and reliability of LNG storage facilities, reducing the risk of leaks and spills LNG Propulsion for Marine Vessels, The adoption of LNG as a marine fuel represents a significant advancement in the transportation sector, offering a cleaner and more sustainable alternative to traditional marine fuels such as heavy fuel oil and marine diesel.…”

Section: Technological Advancements In Lngmentioning

confidence: 99%

Assessing the role of LNG in global carbon neutrality efforts: A project management review

Ifeanyi Onyedika Ekemezie,

Wags Numoipiri Digitemie

2024

GSC Adv. Res. Rev.

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This paper review explores the role of LNG in the context of global carbon neutrality efforts. It examines various aspects such as the current state of LNG usage, its environmental impacts, technological advancements, regulatory frameworks, and the challenges and opportunities associated with its integration into the energy mix. Through a comprehensive analysis, this review aims to provide insights into how project management principles can facilitate the effective implementation of LNG projects to support the transition towards a carbon-neutral future. The transition to a carbon-neutral global economy is an imperative challenge of the 21st century, necessitating a profound shift in energy systems and practices. At the forefront of this transition, liquefied natural gas (LNG) has emerged as a potential bridge fuel, offering a pathway towards decarburization. This project management review delves into the multifaceted role of LNG within the context of global carbon neutrality efforts, examining its current usage, environmental implications, technological advancements, regulatory frameworks, and the associated challenges and opportunities. Through a comprehensive analysis, this review aims to shed light on how project management principles can effectively facilitate the implementation of LNG projects to support the transition towards a carbon-neutral future. LNG's emergence as a potential bridge fuel stems from its relatively lower carbon intensity compared to other fossil fuels. As nations strive to reduce greenhouse gas emissions and meet their commitments under the Paris Agreement, LNG presents an opportunity to mitigate climate change while addressing energy security and economic development objectives. However, a nuanced understanding of LNG's role requires a thorough examination of various dimensions. Firstly, the current state of LNG usage underscores its growing significance in the global energy landscape. With LNG trade reaching record highs in recent years, countries are increasingly turning to LNG to meet their energy needs. Major LNG-producing nations such as Qatar, Australia, and the United States have invested in liquefaction infrastructure, enabling the export of LNG to markets around the world. Additionally, LNG is utilized across diverse sectors, including power generation, industrial processes, transportation, and residential heating, highlighting its versatility and applicability. Despite its potential benefits, LNG is not without environmental impacts. The extraction, production, and transportation of natural gas, the primary component of LNG, can result in methane emissions, a potent greenhouse gas. In conclusion, LNG has emerged as a potential bridge fuel in the transition towards a carbon-neutral global economy. Its relatively lower carbon intensity, versatility, and scalability make it a viable option for reducing greenhouse gas emissions while meeting energy demand. However, realizing the full potential of LNG requires careful consideration of its environmental impacts, technological advancements, regulatory frameworks, and associated challenges. By applying project management principles, stakeholders can effectively navigate the complexities of LNG projects and contribute to the achievement of global carbon neutrality goals.

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“…As such, the primary objective in the utilization of hydrogen energy is to pursue safe, efficient, cost-effective, and more energy-efficient hydrogen storage technologies [11]. At present, high-pressure gaseous hydrogen storage [12], cryogenic liquid hydrogen storage [13], solid-state hydrogen storage [14], and organic liquid hydrogen storage [15] represent the main methods for storing hydrogen through compression, liquefaction, physical absorption, and chemical binding. Compared to the other options, high-pressure gaseous hydrogen storage boasts several advantages, including a simple equipment structure, low energy consumption during compressed hydrogen preparation, fast charging and discharging of hydrogen, and a good adaptability to a wide range of temperatures.…”

Section: Technical Indexmentioning

confidence: 99%

Small-Scale High-Pressure Hydrogen Storage Vessels: A Review

Li,

Chai,

et al. 2024

Materials

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Nowadays, high-pressure hydrogen storage is the most commercially used technology owing to its high hydrogen purity, rapid charging/discharging of hydrogen, and low-cost manufacturing. Despite numerous reviews on hydrogen storage technologies, there is a relative scarcity of comprehensive examinations specifically focused on high-pressure gaseous hydrogen storage and its associated materials. This article systematically presents the manufacturing processes and materials used for a variety of high-pressure hydrogen storage containers, including metal cylinders, carbon fiber composite cylinders, and emerging glass material-based hydrogen storage containers. Furthermore, it introduces the relevant principles and theoretical studies, showcasing their advantages and disadvantages compared to conventional high-pressure hydrogen storage containers. Finally, this article provides an outlook on the future development of high-pressure hydrogen storage containers.

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Review on modern ways of insulation of reservoirs for liquid hydrogen storage

Cited by 33 publications

References 76 publications

A Review on Key Technologies and Developments of Hydrogen Fuel Cell Multi-rotor Drones

A Review on Key Technologies and Developments of Hydrogen Fuel Cell Multi-rotor Drones

Assessing the role of LNG in global carbon neutrality efforts: A project management review

Small-Scale High-Pressure Hydrogen Storage Vessels: A Review

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