Difference between revisions of "Fadhlan Dindra"
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Pressurized hydrogen storage is a method of storing hydrogen gas by compressing it to high pressures inside storage vessels or tanks. Pressurized hydrogen storage plays a vital role in enabling the utilization of hydrogen as a clean energy carrier. By effectively storing hydrogen gas at high pressures, it becomes more viable for various applications, contributing to the advancement of hydrogen-based technologies and the transition to a sustainable energy future. Our goals in this class are to finalized the design and optimization for Pressurized Hydrogen Storage but with the specification of gas being pressurized at 8 bars and volume is 1 liter. | Pressurized hydrogen storage is a method of storing hydrogen gas by compressing it to high pressures inside storage vessels or tanks. Pressurized hydrogen storage plays a vital role in enabling the utilization of hydrogen as a clean energy carrier. By effectively storing hydrogen gas at high pressures, it becomes more viable for various applications, contributing to the advancement of hydrogen-based technologies and the transition to a sustainable energy future. Our goals in this class are to finalized the design and optimization for Pressurized Hydrogen Storage but with the specification of gas being pressurized at 8 bars and volume is 1 liter. | ||
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A hydrogen tank, also known as a hydrogen storage tank, is a container designed to store hydrogen gas for various applications. Hydrogen tanks are an essential component of hydrogen fuel cell vehicles, industrial processes, and energy storage systems. They provide a means to store hydrogen safely and efficiently until it is needed for use. | A hydrogen tank, also known as a hydrogen storage tank, is a container designed to store hydrogen gas for various applications. Hydrogen tanks are an essential component of hydrogen fuel cell vehicles, industrial processes, and energy storage systems. They provide a means to store hydrogen safely and efficiently until it is needed for use. | ||
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Hydrogen tanks are designed with safety features such as pressure relief valves, burst discs, and leak detection systems to ensure safe operation and prevent overpressure or leaks. The tank design, material selection, and construction adhere to specific standards and regulations to ensure the integrity and safety of the hydrogen storage system. | Hydrogen tanks are designed with safety features such as pressure relief valves, burst discs, and leak detection systems to ensure safe operation and prevent overpressure or leaks. The tank design, material selection, and construction adhere to specific standards and regulations to ensure the integrity and safety of the hydrogen storage system. | ||
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It's important to note that the choice of hydrogen tank depends on various factors, including the specific application requirements, storage capacity, weight considerations, safety considerations, and system efficiency. Different technologies and tank designs offer trade-offs in terms of cost, storage capacity, weight, and safety, and the selection should be made based on the specific needs of the application. | It's important to note that the choice of hydrogen tank depends on various factors, including the specific application requirements, storage capacity, weight considerations, safety considerations, and system efficiency. Different technologies and tank designs offer trade-offs in terms of cost, storage capacity, weight, and safety, and the selection should be made based on the specific needs of the application. | ||
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To design a hydrogen tank with a gas pressure of 8 bars and a volume of 1 liter within a maximum cost of 500,000 IDR, several factors need to be considered, such as material selection, manufacturing process, and safety requirements. | To design a hydrogen tank with a gas pressure of 8 bars and a volume of 1 liter within a maximum cost of 500,000 IDR, several factors need to be considered, such as material selection, manufacturing process, and safety requirements. | ||
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4130 steel, also known as chromoly steel or alloy steel, is a low-alloy steel that contains chromium and molybdenum. It is commonly used in various applications, including aerospace, automotive, and structural components. For the material properties, 4130 steel offers a good balance of strength, toughness, and cost-effectiveness. It has a tensile strength of around 560-700 MPa (81,000-101,000 psi) and a yield strength of approximately 460-590 MPa (67,000-85,000 psi), depending on the heat treatment and condition. The addition of chromium and molybdenum improves the steel's hardenability, strength, and corrosion resistance compared to standard carbon steels. | 4130 steel, also known as chromoly steel or alloy steel, is a low-alloy steel that contains chromium and molybdenum. It is commonly used in various applications, including aerospace, automotive, and structural components. For the material properties, 4130 steel offers a good balance of strength, toughness, and cost-effectiveness. It has a tensile strength of around 560-700 MPa (81,000-101,000 psi) and a yield strength of approximately 460-590 MPa (67,000-85,000 psi), depending on the heat treatment and condition. The addition of chromium and molybdenum improves the steel's hardenability, strength, and corrosion resistance compared to standard carbon steels. | ||
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4130 steel is generally compatible with hydrogen gas but may require appropriate surface treatment or coating to mitigate potential issues such as hydrogen embrittlement. Proper precautions should be taken during the manufacturing and handling processes to minimize hydrogen absorption and ensure long-term integrity. 4130 steel can be easily formed and welded, making it suitable for tank fabrication. Common manufacturing processes for 4130 steel tanks include seamless tube fabrication, welding (such as TIG or MIG welding), and heat treatment as needed. | 4130 steel is generally compatible with hydrogen gas but may require appropriate surface treatment or coating to mitigate potential issues such as hydrogen embrittlement. Proper precautions should be taken during the manufacturing and handling processes to minimize hydrogen absorption and ensure long-term integrity. 4130 steel can be easily formed and welded, making it suitable for tank fabrication. Common manufacturing processes for 4130 steel tanks include seamless tube fabrication, welding (such as TIG or MIG welding), and heat treatment as needed. | ||
Revision as of 08:59, 6 June 2023
Biodata
PAGI TEKNIKK!! My name is Fadhlan Kiska Anargya Dindra and my friends casually call me Dindra. Currently studying Mechanical Engineering at the University of Indonesia. Fast learner, well-organized, and responsible person. Always look forward to doing something new. Have an interest in sports, arts, and automotive.
Name: Fadhlan Kiska Anargya Dindra
Date of Birth: September 7th, 2003
NPM: 2106658414
Major: Mechanical Engineering
E-mail: fadhlan.kiska@ui.ac.id
I made this blog for the purposes of Numerical Method KKI that i took this semester. Special appreciation to Mr. DAI for creating this website to open new opportunities for us in learning through digital media. I will use this blog as my personal space to create my creativity in learning Numerical Method lectures.
Pressurized Hydrogen Storage
Pressurized hydrogen storage is a method of storing hydrogen gas by compressing it to high pressures inside storage vessels or tanks. Pressurized hydrogen storage plays a vital role in enabling the utilization of hydrogen as a clean energy carrier. By effectively storing hydrogen gas at high pressures, it becomes more viable for various applications, contributing to the advancement of hydrogen-based technologies and the transition to a sustainable energy future. Our goals in this class are to finalized the design and optimization for Pressurized Hydrogen Storage but with the specification of gas being pressurized at 8 bars and volume is 1 liter.
A hydrogen tank, also known as a hydrogen storage tank, is a container designed to store hydrogen gas for various applications. Hydrogen tanks are an essential component of hydrogen fuel cell vehicles, industrial processes, and energy storage systems. They provide a means to store hydrogen safely and efficiently until it is needed for use.
Hydrogen tanks are designed with safety features such as pressure relief valves, burst discs, and leak detection systems to ensure safe operation and prevent overpressure or leaks. The tank design, material selection, and construction adhere to specific standards and regulations to ensure the integrity and safety of the hydrogen storage system.
It's important to note that the choice of hydrogen tank depends on various factors, including the specific application requirements, storage capacity, weight considerations, safety considerations, and system efficiency. Different technologies and tank designs offer trade-offs in terms of cost, storage capacity, weight, and safety, and the selection should be made based on the specific needs of the application.
Material Selection
To design a hydrogen tank with a gas pressure of 8 bars and a volume of 1 liter within a maximum cost of 500,000 IDR, several factors need to be considered, such as material selection, manufacturing process, and safety requirements.
4130 steel, also known as chromoly steel or alloy steel, is a low-alloy steel that contains chromium and molybdenum. It is commonly used in various applications, including aerospace, automotive, and structural components. For the material properties, 4130 steel offers a good balance of strength, toughness, and cost-effectiveness. It has a tensile strength of around 560-700 MPa (81,000-101,000 psi) and a yield strength of approximately 460-590 MPa (67,000-85,000 psi), depending on the heat treatment and condition. The addition of chromium and molybdenum improves the steel's hardenability, strength, and corrosion resistance compared to standard carbon steels.
4130 steel is generally compatible with hydrogen gas but may require appropriate surface treatment or coating to mitigate potential issues such as hydrogen embrittlement. Proper precautions should be taken during the manufacturing and handling processes to minimize hydrogen absorption and ensure long-term integrity. 4130 steel can be easily formed and welded, making it suitable for tank fabrication. Common manufacturing processes for 4130 steel tanks include seamless tube fabrication, welding (such as TIG or MIG welding), and heat treatment as needed.
Geometrical Constraint
In this case, i choose a Cylindrical Shape as the geometry of the tank because cylindrical tanks can maximize the use of available volume and allowing for efficient storage of hydrogen. Moreover, the cylindrical shape provides a larger internal volume compared to other shapes with the same external dimensions. For the structural, cylindrical tanks distribute stress uniformly along the walls, resulting in a structurally efficient design. The cylindrical shape inherently provides good resistance against internal pressure, making it suitable for high-pressure hydrogen storage.
