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== Design & Optimization of Pressurized Hydrogen Storage == | == Design & Optimization of Pressurized Hydrogen Storage == | ||
| + | the study case is for determine the most efficient design of pressurized hydrogen storage at minimal cost, this are some step recommended by me based on my research | ||
'''Design Optimization and Material Choosing''' | '''Design Optimization and Material Choosing''' | ||
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To maximize the performance of the storage, we can use 2 layer of material, those material are 8 mm thickness of alumunium and GFRP(Glass Fiber Reinforced Plastic) Composite with 6 mm thickness, this study is based on numerical method using Finite Element Method to investigate the mechanical behavior of the storage | To maximize the performance of the storage, we can use 2 layer of material, those material are 8 mm thickness of alumunium and GFRP(Glass Fiber Reinforced Plastic) Composite with 6 mm thickness, this study is based on numerical method using Finite Element Method to investigate the mechanical behavior of the storage | ||
'''Using Sorption - Based Storage''' | '''Using Sorption - Based Storage''' | ||
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The timing between supply and energy demand cause calls for reliable storage system. In this current years, energy storage system become further significant with the widespread implementation of renewable energy. Hydrogen is being a renewable energy with the most demands past the current years, that makes hydrogen storage keep being upgraded to provide the most efficient storage at minimum price, with the research I did from reading many sources, that one journal says that hydrogen storage with sorption based storage system exibit huge potential due to a high energy density. | The timing between supply and energy demand cause calls for reliable storage system. In this current years, energy storage system become further significant with the widespread implementation of renewable energy. Hydrogen is being a renewable energy with the most demands past the current years, that makes hydrogen storage keep being upgraded to provide the most efficient storage at minimum price, with the research I did from reading many sources, that one journal says that hydrogen storage with sorption based storage system exibit huge potential due to a high energy density. | ||
An average temperature lift of 25 °C, energy density of 40 kWh/m3 , and '''energy efficiency of 73% were obtained.''' | An average temperature lift of 25 °C, energy density of 40 kWh/m3 , and '''energy efficiency of 73% were obtained.''' | ||
'''Do the Life Cycle Assessment method''' | '''Do the Life Cycle Assessment method''' | ||
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Life cycle assessment method for determine the tube life cycle from the storage material until it’s not being used anymore, the main factor from this method is knowing whether this storage are toxic to the nature around. | Life cycle assessment method for determine the tube life cycle from the storage material until it’s not being used anymore, the main factor from this method is knowing whether this storage are toxic to the nature around. | ||
Revision as of 22:18, 1 June 2023
INTRODUCTION Saya Rawhul Ihsan Setyoko dengan NPM 2106639371, mahasiswa Teknik Perkapalan 2021, saya lahir di jakarta 13 Agustus 2003
Resume 26/05/2023
pada hari ini saya belajar untuk bagaimana kita saling mengenal dengan bapak Ahmad Indra, pak DAI berharap bahwa mahasiswa memanfaatkan waktu untuk berinteraksi dengan dosen,belajar mandiri juga penting dan tidak hanya mengandalkan belajar di kelas, pak DAI menjelaskan bagaimana individual study case yang harus dikerjakan, belajar apapun harus melihat realitas, conciesness adalah kondisi dimana kesadaran tidak hanya fisik saja,
Design & Optimization of Pressurized Hydrogen Storage
the study case is for determine the most efficient design of pressurized hydrogen storage at minimal cost, this are some step recommended by me based on my research
Design Optimization and Material Choosing
To maximize the performance of the storage, we can use 2 layer of material, those material are 8 mm thickness of alumunium and GFRP(Glass Fiber Reinforced Plastic) Composite with 6 mm thickness, this study is based on numerical method using Finite Element Method to investigate the mechanical behavior of the storage
Using Sorption - Based Storage
The timing between supply and energy demand cause calls for reliable storage system. In this current years, energy storage system become further significant with the widespread implementation of renewable energy. Hydrogen is being a renewable energy with the most demands past the current years, that makes hydrogen storage keep being upgraded to provide the most efficient storage at minimum price, with the research I did from reading many sources, that one journal says that hydrogen storage with sorption based storage system exibit huge potential due to a high energy density. An average temperature lift of 25 °C, energy density of 40 kWh/m3 , and energy efficiency of 73% were obtained.
Do the Life Cycle Assessment method
Life cycle assessment method for determine the tube life cycle from the storage material until it’s not being used anymore, the main factor from this method is knowing whether this storage are toxic to the nature around.
