Aspects Regarding the Use of 3D Printing Technology and Composite Materials for Testing and Manufacturing Vertical Axis Wind Turbines

Chirita, Alexandru-Polifron; Bere, Paul-Petru; Rdoi, Radu Iulian; Dumitrescu, Liliana

doi:10.37358/mp.19.4.5283

Cited by 7 publications

(4 citation statements)

References 16 publications

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“…The traditional aerial and aerospace photogrammetry technique is mainly used to measure the top of topographic features, but the description of the sides and geometric structure of features is very limited. As a new and high technology developed internationally in recent years, oblique photogrammetric technology can obtain images from different angles of ground objects and provide rich textures for the construction of the city three-dimensional model, which can solve the above problems well [ 12 , 13 ]. Oblique photogrammetry, as a multi-angle photogrammetry technology, carries multiple sensors on the flight platform and shoots images from five different angles, such as vertical tilt, to obtain more complete and accurate information of ground objects [ 14 ].…”

Section: Methodsmentioning

confidence: 99%

Application of Realistic 3D Model in Building Prefabricated Nanomaterial Structure

2022

International Journal of Analytical Chemistry

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In order to solve the problem of 3D modeling in building assembly, an application of a 3D model based on the real scene in the building assembly structure is proposed. This method, based on the current BIM technology in nanomaterial design research, analyzes the problems existing in the traditional assembly structure design scheme and analyzes the feasibility of BIM technology in the forward design of assembly buildings from the perspective of theory and practical application. The experimental results show that the urban building model established by the 3D model has high precision and a good real-scene effect. The accuracy of the building model meets the requirements of 1 : 1000 mapping, has measurable accuracy, and elevation accuracy is better than 30 cm. The 3D model promotes the development of informatization.

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Section: Methodsmentioning

confidence: 99%

Application of Realistic 3D Model in Building Prefabricated Nanomaterial Structure

2022

International Journal of Analytical Chemistry

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“…The use of carbon fiber-reinforced polymers (CFRP) and glass fiber-reinforced polymers (GFRP) has proven to remarkably improve wind turbine blade manufacturing, leading to a high strength-to-weight ratio and excellent fatigue resistance [28,31,[33][34][35][36][37][38][39]. Continuous fiber reinforcement or chopped fibers are used to enhance the ink material properties to enable the production of complex geometries.…”

Section: Fiber-reinforced Polymers (Frps)mentioning

confidence: 99%

3D Printing for wind turbine blade manufacturing: a review of materials, design optimization, and challenges

Zarzoor,

Jaber,

Shandookh

2024

ETJ

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3D printing optimizes wind turbine blades for greater cost-effectiveness and durability.• The review emphasizes design optimization to enhance aerodynamics and structural efficiency. • Challenges such as material limitations and the need for structural integrity are identified. • AI and hybrid manufacturing are proposed to address these limitations and reduce costs.Wind energy has become an easy-to-harness source by converting captured wind currents into electrical energy. Powerful and customizable wind turbines are used to convert wind energy efficiently. However, wind turbine development in terms of structure is still an active area of research aiming at efficiently building capable and long-lasting turbines. Additive manufacturing technology, particularly 3D printing, has revolutionized multiple industries, including its potential to create wind turbine blades with high cost-effectiveness and optimizable shapes and rigid structures. In this review, various 3D printing-based techniques, including Fused Deposition Modelling (FDM), Continuous Fiber Reinforcement (CFR), Stereolithography (SLA), and 3D Printing-enhanced Large-Scale Additive Manufacturing (LSAM), are examined in detail for complex and large-scale wind turbine blade production. Materials used in 3D printing wind turbine blades, such as thermoplastic composites, epoxy resins, and fiber-reinforced polymers, are assessed with a focus on their mechanical strength, durability, and environmental considerations. Furthermore, the importance of design optimization and customization for wind turbine blades, including aerodynamic and structural design optimization, is emphasized. Customization for site-specific conditions, infill structural optimization, and infill printing speed and cost are also discussed.The review highlights the importance of structural optimization in developing efficient and cost-effective 3D-printed wind turbine blades, customization for sitespecific conditions, and infill structure. The review also mentions these technologies' challenges, such as material limitations, surface finish quality, size limitations, and structural integrity. Therefore, addressing these challenges to utilize these technologies' potential fully is crucial.

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“…For example, researchers have developed 3D-printed nickel foam catalysts for the electrolysis of water to produce hydrogen. These catalysts have shown higher activity and durability compared to traditional catalysts, which could lead to more efficient and cost-effective hydrogen production [147]. Additive manufacturing can also be used to fabricate components for renewable energy systems, such as wind turbines and solar panels, which can provide the electricity needed for green hydrogen and ammonia production.…”

Section: Am's Role In the Production Of Green Hydrogen And Ammoniamentioning

confidence: 99%

How Green Hydrogen and Ammonia Are Revolutionizing the Future of Energy Production: A Comprehensive Review of the Latest Developments and Future Prospects

Adeli,

Nachtane,

Faik

et al. 2023

Applied Sciences

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As the need for clean and sustainable energy sources grows rapidly, green hydrogen and ammonia have become promising sources of low-carbon energy and important key players in the transition to green energy. However, production and storage problems make it hard to use them widely. The goal of this review paper is to give a complete overview of the latest technology for the manufacture and storage of hydrogen and ammonia. This paper deals with hydrogen and ammonia synthesis and storage. It examines the most recent technological breakthroughs in areas such as electrolysis, reforming, C-ZEROS, HYSATA, DAE, sulfide, and SRBW, as well as novel storage techniques, such as solid-state storage, plasma kinetics, and POWERPASTE. This article examines the history of ammonia production and discusses some of the newer and more sustainable techniques for producing ammonia, such as electrochemical and biological approaches. This study also looks at how artificial intelligence (AI) and additive manufacturing (AM) could be used to revolutionize the way green hydrogen and ammonia are produced, with an emphasis on recent breakthroughs in AI-assisted catalyst design and 3D-printed reactors, as well as considering major investments in the shift to green energy, such as Moroccan government programs, and how they may affect future hydrogen and ammonia production.

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Aspects Regarding the Use of 3D Printing Technology and Composite Materials for Testing and Manufacturing Vertical Axis Wind Turbines

Cited by 7 publications

References 16 publications

Application of Realistic 3D Model in Building Prefabricated Nanomaterial Structure

Application of Realistic 3D Model in Building Prefabricated Nanomaterial Structure

3D Printing for wind turbine blade manufacturing: a review of materials, design optimization, and challenges

How Green Hydrogen and Ammonia Are Revolutionizing the Future of Energy Production: A Comprehensive Review of the Latest Developments and Future Prospects

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