Difference between revisions of "Muhamad Azkhariandra Aryaputra"
(→Hydrogen Storage Optimization) |
|||
Line 19: | Line 19: | ||
== Hydrogen Storage Optimization == | == Hydrogen Storage Optimization == | ||
− | Hydrogen storage optimization entails enhancing hydrogen storage technologies' efficiency, capacity, safety, and cost-effectiveness. Because hydrogen has a low energy density, efficient storage is essential for its broad use as an energy carrier. Improving the efficiency, safety, and cost-effectiveness of storing and consuming hydrogen under high-pressure circumstances is referred to as optimizing pressurized hydrogen. Pressurized hydrogen storage is a typical approach for increasing energy density and making hydrogen feasible as an energy carrier. | + | Hydrogen storage optimization entails enhancing hydrogen storage technologies' efficiency, capacity, safety, and cost-effectiveness. Because hydrogen has a low energy density, efficient storage is essential for its broad use as an energy carrier. Improving the efficiency, safety, and cost-effectiveness of storing and consuming hydrogen under high-pressure circumstances is referred to as optimizing pressurized hydrogen. Pressurized hydrogen storage is a typical approach for increasing energy density and making hydrogen feasible as an energy carrier. The key aspects of the optimization of hydrogen storage are : |
+ | |||
+ | Storage Tank Design: Optimizing pressurised hydrogen storage entails creating storage tanks that can bear high pressures safely. The materials used in the tank must be sturdy, lightweight, and resistant to hydrogen embrittlement. To attain the appropriate strength-to-weight ratio, advanced composite materials such as carbon fiber composites are frequently used. | ||
+ | |||
+ | Safety Measures: In pressurized hydrogen storage, safety is a vital factor. Implementing safety precautions to prevent leaks, ruptures, or explosions is part of the optimization process. This incorporates pressure release systems, burst discs, and stringent testing and inspection methods to assure the storage tanks' integrity. | ||
+ | |||
+ | |||
+ | Mitigation of Hydrogen Leakage: Minimizing hydrogen leakage is critical for ensuring the safety and efficiency of pressurised hydrogen systems. To reduce leaks, optimization efforts include the use of modern sealing technologies such as metal-to-metal seals or elastomeric seals. Regular maintenance, inspection, and leak detection procedures are also necessary to detect and rectify any potential leaks as soon as possible. | ||
+ | |||
+ | Material Compatibility: Optimizing pressurized hydrogen storage necessitates examining the hydrogen compatibility of storage tank materials. Hydrogen can induce embrittlement or penetration in some materials, resulting in decreased strength or hydrogen loss. To increase the longevity and performance of pressurised hydrogen storage systems, researchers are designing materials that are resistant to hydrogen embrittlement and penetration. |
Revision as of 21:39, 5 June 2023
Introduction
Name: Muhamad Azkhariandra Aryaputra
NPM: 2106657765
Major: Mechanical Engineering KKI
DoB: 1 January 2003
E-mail: azkha.aryaputra@gmail.com
Hello everyone !
My name is Muhamad Azkhariandra Aryaputra, you can call me Azkha. Right now I'm a Mechanical Engineering student at University of Indonesia and taking Numerical Method class with Pak DAI as the lecturer.
Hydrogen Storage Optimization
Hydrogen storage optimization entails enhancing hydrogen storage technologies' efficiency, capacity, safety, and cost-effectiveness. Because hydrogen has a low energy density, efficient storage is essential for its broad use as an energy carrier. Improving the efficiency, safety, and cost-effectiveness of storing and consuming hydrogen under high-pressure circumstances is referred to as optimizing pressurized hydrogen. Pressurized hydrogen storage is a typical approach for increasing energy density and making hydrogen feasible as an energy carrier. The key aspects of the optimization of hydrogen storage are :
Storage Tank Design: Optimizing pressurised hydrogen storage entails creating storage tanks that can bear high pressures safely. The materials used in the tank must be sturdy, lightweight, and resistant to hydrogen embrittlement. To attain the appropriate strength-to-weight ratio, advanced composite materials such as carbon fiber composites are frequently used.
Safety Measures: In pressurized hydrogen storage, safety is a vital factor. Implementing safety precautions to prevent leaks, ruptures, or explosions is part of the optimization process. This incorporates pressure release systems, burst discs, and stringent testing and inspection methods to assure the storage tanks' integrity.
Mitigation of Hydrogen Leakage: Minimizing hydrogen leakage is critical for ensuring the safety and efficiency of pressurised hydrogen systems. To reduce leaks, optimization efforts include the use of modern sealing technologies such as metal-to-metal seals or elastomeric seals. Regular maintenance, inspection, and leak detection procedures are also necessary to detect and rectify any potential leaks as soon as possible.
Material Compatibility: Optimizing pressurized hydrogen storage necessitates examining the hydrogen compatibility of storage tank materials. Hydrogen can induce embrittlement or penetration in some materials, resulting in decreased strength or hydrogen loss. To increase the longevity and performance of pressurised hydrogen storage systems, researchers are designing materials that are resistant to hydrogen embrittlement and penetration.