Difference between revisions of "Ariq Dhifan"

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== Case Study of Pressurized Hydrogen Storage ==
 
== Case Study of Pressurized Hydrogen Storage ==
  
In order to improve the density of hydrogen gas and make it suitable for use as a fuel or energy carrier, pressurized hydrogen storage is a technique. Since hydrogen is a light and low-density gas, it must be compressed to reach usable storage levels.
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The effectiveness, security, and utility of the storage system are all improved as part of the process of optimizing pressurized hydrogen storage. Here are several essential factors for pressurized hydrogen storage optimization:
  
Greater amounts of hydrogen may be kept in a given volume by being stored at high pressures. Its transportation and usage in several applications, including fuel cell cars, business operations, and power production, are made easier by the greater density.
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Tank Design and Materials: The storage tanks' design and materials are crucial to optimization. The tanks may be made out of strong, lightweight materials like high-strength metals or innovative composites while yet preserving structural integrity. Tank shapes that have been optimized can increase storage capacity while still fitting into the available area.
  
The following are some essentials of pressurized hydrogen storage:
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Safety precautions: When dealing with compressed hydrogen, safety is of the highest importance. Leaks may be avoided and the integrity of the storage tanks can be guaranteed by putting strong safety measures into place, such as strict manufacturing standards, quality control processes, and routine inspections. Effective pressure release and venting
  
Storage Tanks: High-strength storage tanks that are specially made to resist the high pressure are often used for pressurized hydrogen storage. The materials used to construct these tanks are able to endure the tensions
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Storage Pressure: The energy density and usability of the storage system are influenced by the pressure level at which hydrogen is kept in storage. A greater storage pressure makes it possible to store more hydrogen in a given container, but it also creates issues with tank weight, cost, and safety. Finding the ideal balance between storage pressure, energy density, and pragmatic concerns for the particular application is the goal of optimization.
  
Pressure Levels: Depending on the purpose, several pressure levels may be used for pressurized hydrogen storage. 350 bar (5,076 psi) and 700 bar (10,152 psi) are typical pressure ranges, with the latter being more frequently employed in vehicle fuel cell systems.
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Systems for Filling and Dispensing: Systems for filling and dispensing are essential for pressurized hydrogen storage. Systems that are optimized should reduce fill time, guarantee precise pressure control during filling, and enable safe and regulated hydrogen dispensing.
  
Safety considerations: Because hydrogen storage is high-pressure, safety precautions must be taken with great care. To guarantee their integrity and stop leaks or failures, storage tanks must be designed, produced, and inspected in accordance with strict safety regulations. To reduce the dangers connected with storing high-pressure hydrogen, proper handling, transportation, and maintenance procedures are essential.
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Thermal management: Controlling the storage tanks' temperature is crucial for achieving peak performance. Thermal insulation can minimize energy losses and keep the pressure within the appropriate range by reducing heat transfer to the hydrogen that has been stored. As needed, active cooling or heating systems can be used to control the temperature.
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System Integration: When optimizing pressurized hydrogen storage, the transportation and end-use systems as well as the storage tanks must all be taken into account. To guarantee effective and flawless operation, integration with fuel cell systems or other hydrogen consumption technologies may be enhanced.
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Cost Factors: When doing optimization, it is important to take into account all associated costs, such as those related to materials, production methods, and infrastructure needs. Pressurized hydrogen storage must be widely used, and this depends on finding affordable options that nevertheless retain performance and safety.

Revision as of 11:03, 30 May 2023

Introduction

Ariq 081290260277 4x6.jpg

Name: Ariq Dhifan

NPM: 2106657323

Major: Mechanical Engineering KKI

DoB: 22 June 2003

E-mail: ariqdhifan7@gmail.com

Assalamualaikum Hello Everyone! My name is Ariq Dhifan, an undergradute student majoring in Mechanical Engineering at Universitas Indonesia. Currently I am taking Numerical Method class with Pak DAI as my lecturer.

Case Study of Pressurized Hydrogen Storage

The effectiveness, security, and utility of the storage system are all improved as part of the process of optimizing pressurized hydrogen storage. Here are several essential factors for pressurized hydrogen storage optimization:

Tank Design and Materials: The storage tanks' design and materials are crucial to optimization. The tanks may be made out of strong, lightweight materials like high-strength metals or innovative composites while yet preserving structural integrity. Tank shapes that have been optimized can increase storage capacity while still fitting into the available area.

Safety precautions: When dealing with compressed hydrogen, safety is of the highest importance. Leaks may be avoided and the integrity of the storage tanks can be guaranteed by putting strong safety measures into place, such as strict manufacturing standards, quality control processes, and routine inspections. Effective pressure release and venting

Storage Pressure: The energy density and usability of the storage system are influenced by the pressure level at which hydrogen is kept in storage. A greater storage pressure makes it possible to store more hydrogen in a given container, but it also creates issues with tank weight, cost, and safety. Finding the ideal balance between storage pressure, energy density, and pragmatic concerns for the particular application is the goal of optimization.

Systems for Filling and Dispensing: Systems for filling and dispensing are essential for pressurized hydrogen storage. Systems that are optimized should reduce fill time, guarantee precise pressure control during filling, and enable safe and regulated hydrogen dispensing.

Thermal management: Controlling the storage tanks' temperature is crucial for achieving peak performance. Thermal insulation can minimize energy losses and keep the pressure within the appropriate range by reducing heat transfer to the hydrogen that has been stored. As needed, active cooling or heating systems can be used to control the temperature.

System Integration: When optimizing pressurized hydrogen storage, the transportation and end-use systems as well as the storage tanks must all be taken into account. To guarantee effective and flawless operation, integration with fuel cell systems or other hydrogen consumption technologies may be enhanced.

Cost Factors: When doing optimization, it is important to take into account all associated costs, such as those related to materials, production methods, and infrastructure needs. Pressurized hydrogen storage must be widely used, and this depends on finding affordable options that nevertheless retain performance and safety.