Adriel Reuben Matthew

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Know Me More!

Adriel Reuben 2.jpeg

Halo semua, nama saya Adriel Reuben Matthew.. Biasa dipanggil Reuben atau Adriel.. Saya adalah Mahasiswa Teknik Mesin FTUI angkatan 2021 dan NPM saya adalah 2106732935 .. Saya adalah bagian dari Kelas METODE NUMERIK-03

My Motto is "Never Let Them Know Your Next Move!"

I. Chat with ChatGPT "What is Consciousness?"

Consciousness.png


WHAT IS CONSCIOUSNESS?


Consciousness refers to the state of being aware of and able to perceive both the external world and one's internal mental experiences. It is often described as the subjective experience of thoughts, sensations, emotions, and perceptions. While consciousness is a deeply complex and multifaceted phenomenon, it is generally characterized by qualities such as self-awareness, subjective experience, and the ability to process and integrate information.

The nature of consciousness has been a subject of philosophical inquiry and scientific study for centuries, and it remains a topic of ongoing debate and exploration. There are several theories and perspectives attempting to explain consciousness, and no single consensus has been reached thus far. Some prominent theories include:

Dualism: This perspective posits that consciousness is separate from the physical body and brain. According to dualism, there is a non-physical or spiritual aspect of consciousness that exists independently of the physical world.

Materialism: Materialistic theories argue that consciousness is solely a product of physical processes in the brain. According to this view, all mental experiences and phenomena can ultimately be explained in terms of the activity and interactions of neurons and other neural mechanisms.

Panpsychism: Panpsychism suggests that consciousness is a fundamental and ubiquitous feature of the universe. According to this view, consciousness is not solely confined to human or animal brains but is a property of all matter at some level, even inanimate objects.

Integrated Information Theory: Proposed by neuroscientist Giulio Tononi, this theory suggests that consciousness arises from the integrated and complex interactions among different brain regions. It emphasizes the generation of a unified, integrated experience rather than focusing on specific neural processes.

It's important to note that the scientific understanding of consciousness is still evolving, and researchers continue to explore various aspects of the phenomenon. While progress has been made in unraveling some of the mysteries surrounding consciousness, many questions remain unanswered.

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WHAT IS SELF CONSCIOUSNESS?


Self-consciousness refers to the awareness and recognition of oneself as a distinct individual with a unique identity, thoughts, beliefs, and experiences. It involves the ability to reflect on and have subjective knowledge of one's own mental states, actions, and characteristics. Self-consciousness is closely related to self-awareness and introspection.

There are two primary aspects of self-consciousness:

Objective self-consciousness: This aspect involves the ability to recognize oneself as an object of observation or evaluation by others. It involves being aware of how one appears to others, adhering to social norms, and experiencing self-evaluation and self-judgment. Objective self-consciousness often involves comparing oneself to others and feeling the pressure to meet societal expectations.

Subjective self-consciousness: This aspect involves the introspective awareness of one's thoughts, emotions, desires, and personal experiences. It includes having a sense of personal identity, continuity, and a narrative of one's life. Subjective self-consciousness allows individuals to reflect on their internal states, understand their own beliefs and values, and develop a sense of autonomy and self-reflection.

Self-consciousness plays a crucial role in shaping our social interactions, behavior, and self-perception. It enables us to navigate social situations, consider how others perceive us, and engage in self-reflection and self-improvement. However, excessive self-consciousness can lead to self-doubt, anxiety, and self-consciousness can also be influenced by cultural and societal factors, as different cultures may place varying emphasis on individualism, self-expression, and social conformity.

Overall, self-consciousness is a complex psychological phenomenon that contributes to our understanding of ourselves and our interactions with others.

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THE RELATIONSHIP BETWEEN SELF-CONSCIOUSNESS AND COLLEGE LIFE


Self-consciousness refers to the awareness and recognition of oneself as a distinct individual with unique thoughts, beliefs, and experiences. When it comes to college life, self-consciousness can have a significant impact on various aspects of a student's experience. Here are some ways in which self-consciousness can relate to college life:

Social Interactions: Self-consciousness can influence how students interact with their peers, professors, and other individuals in the college community. It may affect their confidence levels, social skills, and willingness to participate in discussions, group activities, or social events. Students who are more self-conscious may be more cautious about expressing themselves or seeking social connections.

Academic Performance: Self-consciousness can also impact a student's academic performance. Excessive self-consciousness may lead to anxiety or self-doubt, which can hinder concentration, information processing, and the ability to express ideas effectively. On the other hand, a healthy level of self-consciousness can motivate students to strive for excellence and take responsibility for their learning.

Identity Development: College is a time when many students explore and develop their identities. Self-consciousness plays a role in this process as students reflect on their values, beliefs, and goals. It can influence decision-making, career choices, and the exploration of personal interests and passions. Developing a positive and authentic self-consciousness can contribute to a sense of purpose and direction in college life.

Personal Growth: College provides opportunities for personal growth and self-discovery. Self-consciousness allows students to reflect on their strengths, weaknesses, and areas for improvement. It can drive self-reflection, self-evaluation, and the pursuit of personal development. By becoming more self-conscious, students can gain a better understanding of themselves, their values, and their aspirations.

Well-being and Mental Health: Self-consciousness can impact a student's well-being and mental health. Excessive self-consciousness, especially in the form of self-criticism or negative self-judgment, can contribute to stress, anxiety, and low self-esteem. Developing a healthy self-consciousness that includes self-acceptance, self-care, and self-compassion is important for maintaining mental well-being throughout college life.

In summary, self-consciousness has a multifaceted relationship with college life. It affects social interactions, academic performance, identity development, personal growth, and overall well-being. Striking a balance between self-awareness and self-acceptance can contribute to a fulfilling and successful college experience.

II. Design & Optimization of Pressurized Hydrogen Storage

Contoh Gambaran Tanki Hidrogen

Berikut adalah konsep desain dan optimasi untuk penyimpanan hidrogen bertekanan 8 bar dengan kapasitas 1 liter dan budget maksimal Rp500.000:

Pemilihan Wadah Penyimpanan:

Pilih wadah yang terbuat dari bahan yang kuat dan tahan tekanan, seperti aluminium atau baja. Pastikan wadah memiliki kapasitas minimal 1 liter dan mampu menahan tekanan hingga 8 bar. Pertimbangkan penggunaan wadah penyimpanan yang telah tersedia di pasaran untuk mengoptimalkan penggunaan budget.

Sistem Pengunci dan Segel:

Pastikan wadah dilengkapi dengan sistem pengunci yang aman dan tahan tekanan. Gunakan segel yang berkualitas tinggi untuk mencegah kebocoran hidrogen. Perhatikan biaya pengadaan sistem pengunci dan segel agar sesuai dengan budget.

Sistem Pengisi:

Perhatikan sistem pengisi yang sederhana namun efektif dengan memperhatikan budget. Gunakan katup pengisi yang kompatibel dengan wadah penyimpanan dan mampu menangani tekanan 8 bar. Pastikan sistem pengisi memiliki mekanisme pengaman dan kontrol tekanan yang memadai.

Pengujian dan Sertifikasi:

Lakukan pengujian pada wadah penyimpanan untuk memastikan keamanan dan kebocoran hidrogen yang minimal. Pastikan wadah memenuhi standar keamanan dan sertifikasi yang berlaku. Cari tahu apakah ada laboratorium atau lembaga yang dapat melakukan pengujian dengan biaya yang terjangkau.

Efisiensi Biaya:

Pertimbangkan penggunaan material yang ekonomis namun tetap memenuhi kebutuhan desain dan tekanan yang diinginkan. Cari pemasok yang menawarkan harga yang kompetitif untuk material dan komponen yang dibutuhkan. Perhatikan kemungkinan menggunakan komponen bekas yang masih dalam kondisi baik untuk mengoptimalkan budget.

Perencanaan Anggaran: Rencanakan anggaran dengan cermat untuk memastikan semua komponen, material, dan biaya pengujian tercakup dalam budget maksimal Rp500.000. Prioritaskan elemen desain yang kritis dan tetap mengutamakan keamanan. Jika diperlukan, pertimbangkan mencari alternatif sumber dana atau pendanaan tambahan untuk memastikan ketersediaan budget yang mencukupi. Perlu diingat bahwa dengan budget yang terbatas, desain yang sangat kompleks atau material yang khusus mungkin sulit untuk dicapai. Namun, dengan konsep di atas, Anda dapat menghasilkan desain penyimpanan hidrogen yang sederhana namun sesuai dengan persyaratan dasar, seperti kapasitas 1 liter dengan tekanan 8 bar, dan tetap memperhatikan faktor keamanan dan keandalan dalam penggunaan hidrogen.

(discussed with chatGPT)


HOW TO UTILIZE HYDROGEN AS A VEHICLE FUEL

Fuel Cell EV Diagram


Hydrogen Production: Hydrogen can be produced through various methods, such as electrolysis of water, reforming natural gas, or biomass gasification. Electrolysis is a common method that uses electricity to split water into hydrogen and oxygen. It's important to ensure that the hydrogen production process is efficient and environmentally friendly.

Hydrogen Storage: Hydrogen is a lightweight gas, so it needs to be stored in a suitable manner. There are a few options for hydrogen storage, including compressed gas, liquid hydrogen, and solid-state storage. Compressed gas storage involves compressing hydrogen gas and storing it in high-pressure tanks. Liquid hydrogen storage requires cooling hydrogen to very low temperatures. Solid-state storage involves storing hydrogen within a solid material, such as metal hydrides.

Vehicle Fueling Infrastructure: Establishing a hydrogen fueling infrastructure is crucial for widespread adoption of hydrogen as a vehicle fuel. This infrastructure includes hydrogen production facilities, storage facilities, and hydrogen refueling stations. Building a network of refueling stations is essential to ensure that hydrogen-powered vehicles have access to fuel during their journeys.

Hydrogen Fuel Cell Vehicles (FCVs): Hydrogen fuel cell vehicles are one of the main ways to utilize hydrogen as a vehicle fuel. FCVs use hydrogen to generate electricity through a chemical reaction in the fuel cell. This electricity powers an electric motor, propelling the vehicle. FCVs produce only water vapor as a byproduct, making them environmentally friendly.

Hydrogen Internal Combustion Engine (ICE) Vehicles: Another way to utilize hydrogen as a vehicle fuel is by using hydrogen in internal combustion engines designed specifically for hydrogen. These engines combust hydrogen to generate mechanical energy, which drives the vehicle. Hydrogen ICE vehicles may require modifications to the engine and fueling systems compared to traditional gasoline or diesel engines.

Safety Considerations: Hydrogen is highly flammable and requires careful handling to ensure safety. Safety measures should be implemented throughout the hydrogen production, storage, and refueling processes. It's essential to follow regulations, industry standards, and best practices to mitigate risks associated with hydrogen.

Advancing Hydrogen Technologies: Ongoing research and development are crucial to improve hydrogen production, storage, and utilization technologies. This includes enhancing the efficiency of electrolysis processes, developing advanced hydrogen storage methods, and improving the performance and durability of fuel cells and hydrogen engines.

It's worth noting that transitioning to hydrogen as a vehicle fuel involves challenges such as infrastructure development, cost considerations, and mass production of hydrogen vehicles. However, as technology advances and the infrastructure expands, hydrogen has the potential to play a significant role in a sustainable transportation future.

Toyota Mirai Fuel Cell EV


HOW TO UTILIZE HYDROGEN TANK AS A STORAGE OF THE SOURCE OF VEHICLE FUEL


Tank Selection: Choose a suitable hydrogen tank for storage. There are different types of tanks available, including high-pressure gas tanks, liquid hydrogen tanks, and solid-state storage systems. Consider factors such as the required range, weight, cost, and safety when selecting a tank.

Tank Installation: Install the hydrogen tank in the vehicle according to the manufacturer's guidelines and safety standards. The tank should be securely mounted and properly integrated into the vehicle's fuel system.

Hydrogen Filling: Refuel the hydrogen tank using a compatible refueling system. Ensure that the refueling process follows safety protocols and guidelines. It's essential to use dedicated hydrogen refueling stations that are equipped to handle hydrogen fueling.

Safety Measures: Implement safety measures for handling hydrogen. This includes proper sealing and venting systems, leak detection, and adherence to safety regulations and standards. Regular inspections and maintenance of the tank and fueling system are important to ensure safe operation.

Pressure Regulation: Hydrogen tanks store the gas under high pressure. It's necessary to regulate the pressure before supplying the hydrogen to the vehicle's engine or fuel cell system. Pressure regulators or control valves are typically used for this purpose.

Fuel Delivery System: Ensure that the vehicle's fuel delivery system is compatible with hydrogen. Hydrogen fuel cell vehicles require a fuel cell stack to convert hydrogen into electricity, while hydrogen internal combustion engine vehicles may require modifications to accommodate hydrogen as a fuel source.

Monitoring and Maintenance: Regularly monitor the hydrogen tank's pressure, integrity, and performance. Implement a maintenance schedule to ensure the tank remains in optimal condition. Follow the manufacturer's guidelines for maintenance, inspection, and replacement of components.

Safety Training: Provide appropriate safety training to vehicle owners, operators, and maintenance personnel. It's important to educate individuals about the properties of hydrogen, safe handling practices, and emergency procedures.

Hydrogen Availability: Consider the availability of hydrogen refueling infrastructure in your area. Ensure that there are adequate hydrogen refueling stations along your planned routes to support your vehicle's fueling needs.

Remember that utilizing hydrogen as a vehicle fuel requires careful consideration of safety, infrastructure, and technological requirements. Always adhere to safety guidelines and regulations to ensure the safe and efficient use of hydrogen as a fuel source.

III. Hydrogen Storage Designing Operation

CUSTOMER REQUIREMENTS

Seperti yang sudah dijelaskan sebelumnya, customer requirement yang harus diperhatikan dalam designing and optimizing hydrogen storage tank adalah sebagai berikut :

1. Volume tangki yang dibutuhkan adalah 1000 ml atau 1 liter

2. Tekanan hydrogen sebesar 8 bar

3. Biaya maximal yang diberikan adalah Rp500.000

4. Nantinya tangki ini akan diletakkan pada suhu ruang normal (23°C)

5. Terdapat port input dan port output untuk mengisi dan mengeluarkan hydrogen yang ada dalam tangki

6. Tambahkan regulator tekanan dan sensor tekanan pada port output tangki



PERHITUNGAN VOLUME TANGKI

Rumus Volume Tabung

Sesuai dengan Customer Requirement yang ditulis diatas, volume yang diinginkan adalah 1 Liter atau 1000 cm^3

untuk diameter awal tabung, saya menggunakan acuan dimensi bagasi honda beat :

Bagasi Honda Beat 2023

"Honda BeAT 125cc 2023 memiliki kapasitas bagasi sebesar 12 liter. Bagasi ini terletak di bawah jok dan memiliki dimensi L’300 x W180 x H 200 mm. Kapasitas ini cukup untuk membawa barang-barang pribadi seperti tas, jaket, dan peralatan elektronik"

maka dari itu, diameter yang di-set untuk perancangan tangki ini adalah sebesar 90 mm setelah diameter tangkinya sudah diketahui, maka akan dilakukan perhitungan untuk mendapatkan tinggi tangki

h = 1.000.000 / 3,14 x 45 x 45 = 157,26 mm

Maka tinggi tabung yang akan dibuat adalah sebesar 157,26 mm




MENDEFINISIKAN FASA HYDROGEN (23°C)

Diagram P-T Hydrogen


Berdasarkan diagram fasa tekanan vs suhu (diagram PT) disamping,dapat diketahui bahwa hidrogen dengan tekanan 8 bar pada suhu 23°C berada pada gaseous phase atau fase gas











PERHITUNGAN DESIGN TANGKI BERDASARKAN BAHAN DAN MATERIAL

ASME VII Pressure Vessels Standarization

ASME Section VIII

ASME Section VIII adalah bagian dari American Society of Mechanical Engineers (ASME) Boiler and Pressure Vessel Code (BPVC). Bagian ini mengatur desain dan konstruksi bejana tekan atau pressure vessels. Pressure vessel merupakan wadah yang dirancang untuk menahan tekanan internal yang lebih tinggi daripada tekanan atmosfer sekitarnya. Mereka digunakan dalam berbagai industri seperti petrokimia, industri makanan dan minuman, energi, dan sektor lainnya.

ASME Section VIII memiliki beberapa divisi yang mencakup persyaratan yang berbeda untuk pressure vessels dengan berbagai jenis dan ukuran. Beberapa divisi yang umum ditemui adalah:

Division 1: Divisi ini berlaku untuk pressure vessels dengan tekanan desain yang relatif rendah dan ukuran yang kecil hingga menengah. Divisi 1 memberikan pedoman untuk desain, bahan, fabrikasi, inspeksi, pengujian, dan sertifikasi pressure vessels. Persyaratan ini mencakup batas kekuatan, ketebalan dinding, penyambungan, pengelasan, pengujian kebocoran, dan faktor keamanan.

Division 2: Divisi ini berlaku untuk pressure vessels dengan tekanan desain yang lebih tinggi dan lebih kompleks. Division 2 memberikan pedoman yang lebih rinci untuk analisis kekuatan dan desain pressure vessels yang lebih kompleks. Divisi ini memperhitungkan faktor-faktor seperti deformasi, kelelahan, kriogenik, dan perlakuan panas.

Division 3: Divisi ini berfokus pada desain dan konstruksi pressure vessels yang digunakan dalam industri nuklir. Persyaratan di Division 3 meliputi bahan, desain, konstruksi, pengujian, dan inspeksi pressure vessels yang tahan radiasi dan tekanan yang tinggi.

ASME Section VIII memastikan bahwa pressure vessels yang dibuat sesuai dengan standar ini memenuhi persyaratan keamanan yang ketat untuk melindungi manusia, lingkungan, dan properti. Desain dan fabrikasi pressure vessels yang mematuhi ASME Section VIII harus disertifikasi oleh inspektur berwenang sebelum digunakan.

Penting untuk dicatat bahwa penjelasan di atas hanya memberikan gambaran umum tentang ASME Section VIII Pressure Vessels. Jika Anda memiliki pertanyaan atau perlu informasi lebih lanjut, direkomendasikan untuk merujuk ke dokumen asli ASME BPVC atau berkonsultasi dengan ahli yang berpengalaman dalam desain dan fabrikasi pressure vessels.

Untuk membuat tangki hydrogen dengan tekanan 8 bar, Anda perlu menggunakan jenis mild steel yang memenuhi persyaratan kekuatan dan keamanan yang sesuai. Dalam kasus ini, material yang biasa digunakan adalah mild steel dengan kualitas terbaik yang disebut sebagai "pressure vessel quality" atau kualitas tangki tekanan.

Salah satu jenis mild steel yang sering digunakan untuk pressure vessel adalah ASTM A516 Grade 70. Baja ini memiliki sifat mekanik dan kekuatan yang baik, serta mampu menahan tekanan yang relatif tinggi. ASTM A516 Grade 70 adalah baja karbon dengan kandungan karbon rendah, yang biasanya dipilih untuk aplikasi pressure vessel karena ketangguhannya yang baik dan kemampuannya menahan tekanan tinggi.


ASTM A36 VS ASTM A516 GRADE 70

ASTM A516 Grade 70

ASTM A36 dan ASTM A516 Grade 70 adalah dua jenis baja yang umum digunakan dalam berbagai aplikasi industri. Meskipun keduanya memiliki beberapa kesamaan, terdapat perbedaan signifikan dalam komposisi kimia, kekuatan, dan penggunaan yang disarankan. Berikut ini adalah perbandingan antara ASTM A36 dan ASTM A516 Grade 70:

Komposisi Kimia:

ASTM A36: ASTM A36 merupakan baja karbon rendah yang umumnya mengandung karbon sekitar 0,25% hingga 0,29%, dengan sedikit tambahan elemen lain seperti mangan, silikon, dan fosfor. ASTM A516 Grade 70: ASTM A516 Grade 70 juga merupakan baja karbon rendah, tetapi memiliki kandungan karbon yang sedikit lebih tinggi, yaitu sekitar 0,27% hingga 0,31%. Selain itu, ASTM A516 Grade 70 biasanya memiliki tambahan elemen seperti mangan, fosfor, silikon, dan sulfur dalam jumlah terbatas.

Kekuatan Mekanik:

ASTM A36: ASTM A36 memiliki kekuatan tarik minimum sekitar 400 hingga 550 MPa dan kekuatan luluh minimum sekitar 250 MPa. Baja ini biasanya digunakan dalam struktur yang tidak mengalami tekanan yang signifikan. ASTM A516 Grade 70: ASTM A516 Grade 70 memiliki kekuatan tarik minimum sekitar 485 hingga 620 MPa dan kekuatan luluh minimum sekitar 260 MPa. Baja ini dirancang khusus untuk digunakan dalam pressure vessel dengan tekanan yang tinggi dan suhu yang rendah hingga sedang.

Penggunaan yang Disarankan:

ASTM A36: ASTM A36 umumnya digunakan dalam struktur bangunan, jembatan, platform, dan komponen lain yang tidak memerlukan ketahanan terhadap tekanan atau suhu tinggi. ASTM A516 Grade 70: ASTM A516 Grade 70 digunakan khusus dalam pembuatan pressure vessel yang bekerja pada tekanan dan suhu tinggi, seperti tangki penyimpanan gas, boiler, dan peralatan industri lainnya.