Difference between revisions of "Putri Azzahra Khairunnisa"
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- menjelaskan teori CCIT (cara cerdas ingat tuhan) | - menjelaskan teori CCIT (cara cerdas ingat tuhan) | ||
- menjelaskan angka tak terhingga, “angka” yang dapat dioperasionalkan dalam penjumlahan, pengurangan, perkalian dan pembagian, namun hasilnya tidak berubah selain daripada dirinya sendiri. | - menjelaskan angka tak terhingga, “angka” yang dapat dioperasionalkan dalam penjumlahan, pengurangan, perkalian dan pembagian, namun hasilnya tidak berubah selain daripada dirinya sendiri. | ||
| + | |||
| + | |||
| + | == Tugas Pekan 1 == | ||
| + | |||
| + | The task for Week 1 is to design and optimize a 1-liter pressurized hydrogen storage tank with a maximum production cost of Rp. 500,000. To achieve this, various considerations and steps need to be taken: | ||
| + | |||
| + | 1. Tank Material: Use strong and lightweight materials such as aluminum or carbon fiber to meet strength requirements and minimize production costs. | ||
| + | |||
| + | 2. Tank Design and Size: The tank must be designed and sized to hold 1 liter of hydrogen and withstand a pressure of 8 bar. A smaller tank size reduces the amount of material needed and helps control production costs. | ||
| + | |||
| + | 3. Welding and Construction: Use welding techniques like Tungsten Inert Gas (TIG) or Metal Inert Gas (MIG) to join parts of the tank, ensuring strong and safe connections. | ||
| + | |||
| + | 4. Locking and Sealing System: Ensure an effective locking system is in place to prevent hydrogen leakage. Thoroughly check and test for leaks to ensure the desired pressure is maintained during use. | ||
| + | |||
| + | 5. Protection and Safety: Install safety features such as pressure relief valves to reduce the risk of failure and overpressure. Safety is critical when designing a hydrogen tank. | ||
| + | |||
| + | 6. Production Costs: Consider production costs throughout the design process to stay within the maximum budget of Rp. 500,000. Choose materials and construction methods efficiently to achieve this goal. Factor in material costs, labour costs, and other production expenses. | ||
| + | |||
| + | It's important to note that proper design of a hydrogen tank requires in-depth understanding of pressure vessel technology and safety. Therefore, risk management is also crucial and can be achieved by following the steps below: | ||
| + | |||
| + | 1. Risk Identification: Identify risks associated with the hydrogen tank, such as hydrogen leaks, structural failure, overpressure, or unwanted chemical reactions. Consider relevant environmental and safety factors as well. | ||
| + | |||
| + | 2. Risk Analysis: Systematically analyze the probability and impact of each identified risk. Prioritize risks based on severity and likelihood of occurrence. | ||
| + | |||
| + | 3. Risk Mitigation: Based on the risk analysis, develop an effective mitigation plan to reduce identified risks. For example, implement a sensitive hydrogen leak detection system, select materials with appropriate strength, and include reliable pressure relief devices. | ||
| + | |||
| + | 4. Tank Material: Choose suitable materials for the hydrogen tank while considering risk factors. Ensure that the material is resistant to corrosion and hydrogen embrittlement. Test materials thoroughly for suitability. | ||
| + | |||
| + | 5. Structural Design: Design the tank structure while considering strength, safety, and associated risks. Use structural analysis methods like Finite Element Analysis (FEA) to ensure adequate strength and structural integrity. | ||
| + | |||
| + | 6. Welding and Connections: Make sure tank welding and connections are performed carefully and in compliance with safety standards. Conduct non-destructive testing to ensure quality welds and connections. | ||
| + | |||
| + | 7. Leak and Pressure Testing: Routinely conduct pressure and leak testing to confirm tank integrity. Implement strict testing protocols and keep test records to track results. | ||
| + | |||
| + | 8. Emergency Pressure Relief System: Install an emergency pressure relief system, such as a pressure relief valve, which will activate when pressure exceeds safe limits. Ensure the system is designed correctly and tested regularly. | ||
| + | |||
| + | 9. Operator Training and Safety Procedures: Provide comprehensive operator training on handling, operation, and maintenance of the hydrogen tank. Establish clear safety procedures and ensure operators understand them well. | ||
| + | |||
| + | 10. Routine Monitoring and Maintenance: Regularly monitor and maintain the hydrogen tank to identify potential problems before they cause failure. Inspect and test periodically. | ||
Revision as of 13:16, 2 June 2023
Introduction
Perkenalkan saya Putri Azzahra Khairunnisa dengan NPM 2106731005. Saya adalah mahasiswa Fakultas Teknik Perkapalan.
Resume Kuliah Pertemuan 26/05/2023
Resume Perkuliahan:
Pak DAI memperkenalkan darimana asal nama beliau berasal, yaitu Dr. Ahmad Indra bisa disingkat DAI
- menjelaskan cara mengajarnya mengenai teori consciousness (kesadaran), Kesadaran bukanberlokasi dalam diri organisme, namunkesadaran adalah sebuah peristiwamenyangkut empat kuadran. Kesadaranterdistribusi kedalam semua kuadran,baik kuadran keperilakuan, sosial,intensional dan kultural. - menjelaskan teori CCIT (cara cerdas ingat tuhan) - menjelaskan angka tak terhingga, “angka” yang dapat dioperasionalkan dalam penjumlahan, pengurangan, perkalian dan pembagian, namun hasilnya tidak berubah selain daripada dirinya sendiri.
Tugas Pekan 1
The task for Week 1 is to design and optimize a 1-liter pressurized hydrogen storage tank with a maximum production cost of Rp. 500,000. To achieve this, various considerations and steps need to be taken:
1. Tank Material: Use strong and lightweight materials such as aluminum or carbon fiber to meet strength requirements and minimize production costs.
2. Tank Design and Size: The tank must be designed and sized to hold 1 liter of hydrogen and withstand a pressure of 8 bar. A smaller tank size reduces the amount of material needed and helps control production costs.
3. Welding and Construction: Use welding techniques like Tungsten Inert Gas (TIG) or Metal Inert Gas (MIG) to join parts of the tank, ensuring strong and safe connections.
4. Locking and Sealing System: Ensure an effective locking system is in place to prevent hydrogen leakage. Thoroughly check and test for leaks to ensure the desired pressure is maintained during use.
5. Protection and Safety: Install safety features such as pressure relief valves to reduce the risk of failure and overpressure. Safety is critical when designing a hydrogen tank.
6. Production Costs: Consider production costs throughout the design process to stay within the maximum budget of Rp. 500,000. Choose materials and construction methods efficiently to achieve this goal. Factor in material costs, labour costs, and other production expenses.
It's important to note that proper design of a hydrogen tank requires in-depth understanding of pressure vessel technology and safety. Therefore, risk management is also crucial and can be achieved by following the steps below:
1. Risk Identification: Identify risks associated with the hydrogen tank, such as hydrogen leaks, structural failure, overpressure, or unwanted chemical reactions. Consider relevant environmental and safety factors as well.
2. Risk Analysis: Systematically analyze the probability and impact of each identified risk. Prioritize risks based on severity and likelihood of occurrence.
3. Risk Mitigation: Based on the risk analysis, develop an effective mitigation plan to reduce identified risks. For example, implement a sensitive hydrogen leak detection system, select materials with appropriate strength, and include reliable pressure relief devices.
4. Tank Material: Choose suitable materials for the hydrogen tank while considering risk factors. Ensure that the material is resistant to corrosion and hydrogen embrittlement. Test materials thoroughly for suitability.
5. Structural Design: Design the tank structure while considering strength, safety, and associated risks. Use structural analysis methods like Finite Element Analysis (FEA) to ensure adequate strength and structural integrity.
6. Welding and Connections: Make sure tank welding and connections are performed carefully and in compliance with safety standards. Conduct non-destructive testing to ensure quality welds and connections.
7. Leak and Pressure Testing: Routinely conduct pressure and leak testing to confirm tank integrity. Implement strict testing protocols and keep test records to track results.
8. Emergency Pressure Relief System: Install an emergency pressure relief system, such as a pressure relief valve, which will activate when pressure exceeds safe limits. Ensure the system is designed correctly and tested regularly.
9. Operator Training and Safety Procedures: Provide comprehensive operator training on handling, operation, and maintenance of the hydrogen tank. Establish clear safety procedures and ensure operators understand them well.
10. Routine Monitoring and Maintenance: Regularly monitor and maintain the hydrogen tank to identify potential problems before they cause failure. Inspect and test periodically.
