Difference between revisions of "Andre Christian Batama"

From ccitonlinewiki
Jump to: navigation, search
(Final Project)
 
(4 intermediate revisions by the same user not shown)
Line 5: Line 5:
  
  
== Resume Pertemuan 1 ==
+
== Optimitization Assigment ==
  
 +
The design was to create an optimized prezzuried Hydrogen Storage with a capacity of one litre, pressure eight bar, and the cost of optimization should not exceed five hundred thousand rupiah.
  
[https://www.youtube.com/watch?v=W74y1RxN6BA]
+
Based on the journal of Minghe and friends (2021)[https://www.sciencedirect.com/science/article/abs/pii/S0360319920342634], there are several ways to increase the efficiency of the storage, which are :
 +
1.) System Composition
 +
Its a well known fact that the state of hydrogen could bring major improvement for the storage. for example the injection of liquid hidrogen into a tank using high pressure pump would actually lower the temprature while keeping the pressure high. this would actually benefitted the system as it increase the storage efficiency.
 +
2.) Improving the tank cooling process
 +
The tank of hydrogen storage usually a have high requirements of material. the material should be able to withstand a high range of temprature variation and pressure. the unsteady temprature of hydrogen liquid would be a huge consideration.
 +
3.) the diameter of design
 +
Considering the diameter of pipe during the cooling process actually would benefit the storage system itself. by changing the variable of diameter system it actually could increase the efficiency.
  
 +
Now moving on, the most plausible solution to be done according to the limited  budget is the second and third solution. the first solution would need a lot of resource to actually make the most perfect state of hydrogen to be keep in storage. a limtied budget of 500 thousand rupiah wouldn't be able to bring anything.
 +
The second solution could be done in small scale and based on the previous research that have been done by the the predecessor. Aluminium has a good thermal conductivty both for hot and cold temprature. adding extra layeer of insulation could be done to add a buffer zone to the system temprature. as we know that system temprature some times become a tricky variable  for thermal research especially in a storaged energy study. by adding a layer of thermal insulation we could minimize the lost of energy to the system.
 +
The third solution actually the most practical solution, the researcher just need to make a proper estimation of the progress and steps. then could optimize the design by actually cutting the budet. this actually very plausible for a mere five hundred thousand rupiah budget.
  
 
== Resume Pertemuan 26/5/22 ==
 
== Resume Pertemuan 26/5/22 ==
Pada hari ini saya pergi bersama-sama teman saya untuk mempelajari metnum yang asik.
+
Pada pertemuan pada hari jumat tanggal 26 mei 2023, saya menyadari bagaimana sebenarnya keterbatasan
[https://www.youtube.com/watch?v=1mB7z4g_A1k]
+
logika seorang individu. setiap individu  berusaha untuk mencari jawaban atas permasalahan-permasalahan yang ditemui.
 +
Jawaban dari permasalahan tersebut salah satunya berupa pendekatan matematika yang dianggap manusia sebagai
 +
sebuah metode eksak atau pasti. akan tetapi seiring dengan perkembangannya manusia menyadari bahwa
 +
penyelesaian sebuah masalah secara eksak tidak selalu dapat dilakukan bahkan jika dapat dilakukan hal tersebut
 +
membutuhkan waktu yang sangat panjang dan materi yang sedikit. oleh karenanya manusia mencoba melakukan
 +
pendekatan-pendekatan dalam menyelesaikan masalah-masalah tersebut. pendekatan tersebut dilakukan secara itiriner
 +
dimana hasil yang didapatkan semakin mendekati nilai yang paling sempurna seiring dengan jumlah pengulangan yang dilakukan.
 +
ini sama hal nya dengan bagaimana konsep kepercayaan, manusia dengan segala keterbatasannya cenderung sering kali mencoba
 +
menanyakan ketuhanan sendiri melalui standar kemanusiaannya sehingga sering kali melakukan pendekatan-pendekatan.
 +
 
 +
 
 +
 
 +
== Final Project ==
 +
The details about my project explanation can be watched on [https://www.youtube.com/watch?v=z1yO1knaj14]
 +
 
 +
[[File:SpoilerAndre.png]]
 +
 
 +
 
 +
class Material:
 +
    def __init__(self, name, cost, strength):
 +
        self.name = name
 +
        self.cost = cost  # Cost in rupiah
 +
        self.strength = strength  # Material strength in MPa
 +
 
 +
 
 +
class CoolingMechanism:
 +
    def __init__(self, name, cost, cooling_capacity):
 +
        self.name = name
 +
        self.cost = cost  # Cost in rupiah
 +
        self.cooling_capacity = cooling_capacity  # Cooling capacity in watts
 +
 
 +
 
 +
class HydrogenStorageSystem:
 +
    def __init__(self, capacity, operating_pressure):
 +
        self.capacity = capacity  # Hydrogen storage capacity in liters
 +
        self.operating_pressure = operating_pressure  # Operating pressure in bar
 +
 
 +
        self.materials = [
 +
            Material("Copper", 20000, 200),  # Copper material with cost and strength values
 +
            Material("Steel", 10000, 400),  # Steel material with cost and strength values
 +
        ]
 +
 
 +
        self.cooling_mechanisms = [
 +
            CoolingMechanism("Air Cooling", 50000, 100),  # Example cooling mechanisms with cost and cooling capacity
 +
            CoolingMechanism("Liquid Cooling", 100000, 200),
 +
            CoolingMechanism("Cryogenic Cooling", 200000, 300),
 +
        ]
 +
 
 +
        self.selected_material = None
 +
        self.selected_cooling_mechanism = None
 +
        self.selected_diameter = None
 +
 
 +
    def optimize_design(self):
 +
        optimized_designs = []
 +
        step_size = 50000
 +
        max_budget = 500000
 +
 
 +
        for i in range(10):
 +
            target_budget = (i + 1) * step_size
 +
            if target_budget > max_budget:
 +
                break
 +
 
 +
            best_cost = float('inf')
 +
            selected_diameter = None
 +
 
 +
            for material in self.materials:
 +
                for cooling_mechanism in self.cooling_mechanisms:
 +
                    # Calculate the cost of the tank based on material cost and required volume
 +
                    tank_volume = self.capacity / 1000  # Convert capacity from liters to m^3
 +
                    tank_cost = material.cost * tank_volume
 +
 
 +
                    # Calculate the required tank diameter based on material strength and operating pressure
 +
                    tank_diameter = (self.operating_pressure * self.capacity * 2) / (material.strength * 1000)
 +
 
 +
                    # Check if the calculated diameter matches the target diameter
 +
                    if tank_cost <= target_budget:
 +
                        # Calculate the total system cost including material cost and cooling mechanism cost
 +
                        total_cost = tank_cost + cooling_mechanism.cost
 +
 
 +
                        # Check if the cost is better than the current best cost
 +
                        if total_cost < best_cost:
 +
                            best_cost = total_cost
 +
                            self.selected_material = material
 +
                            self.selected_cooling_mechanism = cooling_mechanism
 +
                            selected_diameter = tank_diameter
 +
 
 +
            if self.selected_material is not None and self.selected_cooling_mechanism is not None and selected_diameter is not None:
 +
                optimized_designs.append(
 +
                    {"Material": self.selected_material.name,
 +
                    "Cooling Mechanism": self.selected_cooling_mechanism.name,
 +
                    "Diameter (mm)": selected_diameter,
 +
                    "Total Cost (rupiah)": best_cost})
 +
 
 +
        return optimized_designs
 +
 
 +
 
 +
# Example usage
 +
storage_system = HydrogenStorageSystem(capacity=1, operating_pressure=8)
 +
optimized_designs = storage_system.optimize_design()
 +
 
 +
# Print the optimized designs for each budget
 +
 
 +
This code estimating the budget of the optimization with considering the aspect of cooling progress, design, and material thickness (diameter).
 +
from this coding printing its proven that material did have effect on lowering the budget. material such as composite which is more expensive will cost more money than cheaper material such as steel, aluminium, an copper.
 +
Steel, Aluminium, and Copper also have advatange compared to the composite which is the thermal conductivity. but the composite is proven to be more resilince and adapt to pressure.
 +
Among all materials, aluminium was proven to be the most cost effective and efficient as its could meet the requirements to withstand 8 bar pressure and has good conductivity.
 +
The thickness of the tube also being considered as the thinner the tube meaning the lower cost of materials would be spent.
 +
To estimate the real cost we need to first calculate the total of materials spend.
 +
 
 +
First count the diameter and height of the tube
 +
 
 +
h = V / (π * r^2)
 +
h = (1 * 10^-3) / (π * (0.1)^2)
 +
 
 +
import math
 +
 
 +
diameter = 20  # cm
 +
radius = diameter / 2 / 100  # Convert to meters
 +
volume = 1 / 1000  # Convert to cubic meters
 +
 
 +
height = volume / (math.pi * radius ** 2)
 +
 
 +
print("Estimated tube height: {:.2f} meters".format(height))
 +
 
 +
Estimated tube height: 0.16 meters
 +
 
 +
After got the estimation of the height and diamater now estimate the thickness of the diameter
 +
 
 +
desired_stress = 50  # MPa
 +
yield_strength = 200  # MPa
 +
pressure = 8  # bar
 +
radius = 0.1  # meters
 +
 
 +
thickness = pressure * radius / (desired_stress * 10**6 / yield_strength)
 +
 
 +
print("Estimated thickness: {:.2f} meters".format(thickness))
 +
 
 +
Estimated thickness: 0.02 meters
 +
 
 +
 
 +
Now we got the estimation of the thickness we can start counting the money we are going to spend by making iteration
 +
 
 +
 
 +
import math
 +
 
 +
class Material:
 +
    def __init__(self, name, price_per_kg):
 +
        self.name = name
 +
        self.price_per_kg = price_per_kg  # Price in rupiah per kg
 +
 
 +
 
 +
class HydrogenStorageSystem:
 +
    def __init__(self, capacity, operating_pressure, initial_thickness, iterations):
 +
        self.capacity = capacity  # Hydrogen storage capacity in liters
 +
        self.operating_pressure = operating_pressure  # Operating pressure in bar
 +
        self.initial_thickness = initial_thickness  # Initial thickness of the tube in cm
 +
        self.iterations = iterations  # Number of iterations
 +
        self.materials = [
 +
            Material("Copper", 200000),  # Copper material with price per kg
 +
            Material("Steel", 100000),  # Steel material with price per kg
 +
        ]
 +
 
 +
        self.selected_material = None
 +
        self.selected_diameter = None
 +
 
 +
    def estimate_cost(self):
 +
        best_cost = float('inf')
 +
 
 +
        for material in self.materials:
 +
            thickness = self.initial_thickness
 +
 
 +
            for _ in range(self.iterations):
 +
                # Calculate the weight of the tube
 +
                tube_volume = math.pi * (self.selected_diameter ** 2) * thickness / 4  # Volume in cubic cm
 +
                tube_weight = tube_volume * material_density / 1000  # Weight in kg
 +
 
 +
                # Calculate the material cost
 +
                material_cost = tube_weight * material.price_per_kg
 +
 
 +
                # Calculate the total cost (material cost + labor cost + other costs)
 +
                total_cost = material_cost
 +
 
 +
                # Check if the cost is better than the current best cost
 +
                if total_cost < best_cost:
 +
                    best_cost = total_cost
 +
                    self.selected_material = material
 +
 
 +
                # Increase the thickness for the next iteration
 +
                thickness += 0.1
 +
 
 +
        return best_cost
 +
 
 +
 
 +
# Example usage
 +
storage_system = HydrogenStorageSystem(capacity=1, operating_pressure=8, initial_thickness=0.2, iterations=25)
 +
cost = storage_system.estimate_cost()
 +
 
 +
print("Estimated cost: {:.2f} rupiah".format(cost))
 +
print("Selected material: {}".format(storage_system.selected_material.name))
 +
 
 +
[[File:ITERATED.png]]

Latest revision as of 23:32, 15 June 2023

Introduction Saya andre lahir di batam



Optimitization Assigment

The design was to create an optimized prezzuried Hydrogen Storage with a capacity of one litre, pressure eight bar, and the cost of optimization should not exceed five hundred thousand rupiah.

Based on the journal of Minghe and friends (2021)[1], there are several ways to increase the efficiency of the storage, which are :

1.) System Composition

Its a well known fact that the state of hydrogen could bring major improvement for the storage. for example the injection of liquid hidrogen into a tank using high pressure pump would actually lower the temprature while keeping the pressure high. this would actually benefitted the system as it increase the storage efficiency.

2.) Improving the tank cooling process

The tank of hydrogen storage usually a have high requirements of material. the material should be able to withstand a high range of temprature variation and pressure. the unsteady temprature of hydrogen liquid would be a huge consideration.

3.) the diameter of design

Considering the diameter of pipe during the cooling process actually would benefit the storage system itself. by changing the variable of diameter system it actually could increase the efficiency.

Now moving on, the most plausible solution to be done according to the limited budget is the second and third solution. the first solution would need a lot of resource to actually make the most perfect state of hydrogen to be keep in storage. a limtied budget of 500 thousand rupiah wouldn't be able to bring anything. The second solution could be done in small scale and based on the previous research that have been done by the the predecessor. Aluminium has a good thermal conductivty both for hot and cold temprature. adding extra layeer of insulation could be done to add a buffer zone to the system temprature. as we know that system temprature some times become a tricky variable for thermal research especially in a storaged energy study. by adding a layer of thermal insulation we could minimize the lost of energy to the system. The third solution actually the most practical solution, the researcher just need to make a proper estimation of the progress and steps. then could optimize the design by actually cutting the budet. this actually very plausible for a mere five hundred thousand rupiah budget.

Resume Pertemuan 26/5/22

Pada pertemuan pada hari jumat tanggal 26 mei 2023, saya menyadari bagaimana sebenarnya keterbatasan logika seorang individu. setiap individu berusaha untuk mencari jawaban atas permasalahan-permasalahan yang ditemui. Jawaban dari permasalahan tersebut salah satunya berupa pendekatan matematika yang dianggap manusia sebagai sebuah metode eksak atau pasti. akan tetapi seiring dengan perkembangannya manusia menyadari bahwa penyelesaian sebuah masalah secara eksak tidak selalu dapat dilakukan bahkan jika dapat dilakukan hal tersebut membutuhkan waktu yang sangat panjang dan materi yang sedikit. oleh karenanya manusia mencoba melakukan pendekatan-pendekatan dalam menyelesaikan masalah-masalah tersebut. pendekatan tersebut dilakukan secara itiriner dimana hasil yang didapatkan semakin mendekati nilai yang paling sempurna seiring dengan jumlah pengulangan yang dilakukan. ini sama hal nya dengan bagaimana konsep kepercayaan, manusia dengan segala keterbatasannya cenderung sering kali mencoba menanyakan ketuhanan sendiri melalui standar kemanusiaannya sehingga sering kali melakukan pendekatan-pendekatan.


Final Project

The details about my project explanation can be watched on [2]

SpoilerAndre.png


class Material:

   def __init__(self, name, cost, strength):
       self.name = name
       self.cost = cost  # Cost in rupiah
       self.strength = strength  # Material strength in MPa


class CoolingMechanism:

   def __init__(self, name, cost, cooling_capacity):
       self.name = name
       self.cost = cost  # Cost in rupiah
       self.cooling_capacity = cooling_capacity  # Cooling capacity in watts


class HydrogenStorageSystem:

   def __init__(self, capacity, operating_pressure):
       self.capacity = capacity  # Hydrogen storage capacity in liters
       self.operating_pressure = operating_pressure  # Operating pressure in bar
       self.materials = [
           Material("Copper", 20000, 200),  # Copper material with cost and strength values
           Material("Steel", 10000, 400),  # Steel material with cost and strength values
       ]
       self.cooling_mechanisms = [
           CoolingMechanism("Air Cooling", 50000, 100),  # Example cooling mechanisms with cost and cooling capacity
           CoolingMechanism("Liquid Cooling", 100000, 200),
           CoolingMechanism("Cryogenic Cooling", 200000, 300),
       ]
       self.selected_material = None
       self.selected_cooling_mechanism = None
       self.selected_diameter = None
   def optimize_design(self):
       optimized_designs = []
       step_size = 50000
       max_budget = 500000
       for i in range(10):
           target_budget = (i + 1) * step_size
           if target_budget > max_budget:
               break
           best_cost = float('inf')
           selected_diameter = None
           for material in self.materials:
               for cooling_mechanism in self.cooling_mechanisms:
                   # Calculate the cost of the tank based on material cost and required volume
                   tank_volume = self.capacity / 1000  # Convert capacity from liters to m^3
                   tank_cost = material.cost * tank_volume
                   # Calculate the required tank diameter based on material strength and operating pressure
                   tank_diameter = (self.operating_pressure * self.capacity * 2) / (material.strength * 1000)
                   # Check if the calculated diameter matches the target diameter
                   if tank_cost <= target_budget:
                       # Calculate the total system cost including material cost and cooling mechanism cost
                       total_cost = tank_cost + cooling_mechanism.cost
                       # Check if the cost is better than the current best cost
                       if total_cost < best_cost:
                           best_cost = total_cost
                           self.selected_material = material
                           self.selected_cooling_mechanism = cooling_mechanism
                           selected_diameter = tank_diameter
           if self.selected_material is not None and self.selected_cooling_mechanism is not None and selected_diameter is not None:
               optimized_designs.append(
                   {"Material": self.selected_material.name,
                    "Cooling Mechanism": self.selected_cooling_mechanism.name,
                    "Diameter (mm)": selected_diameter,
                    "Total Cost (rupiah)": best_cost})
       return optimized_designs


  1. Example usage

storage_system = HydrogenStorageSystem(capacity=1, operating_pressure=8) optimized_designs = storage_system.optimize_design()

  1. Print the optimized designs for each budget

This code estimating the budget of the optimization with considering the aspect of cooling progress, design, and material thickness (diameter). from this coding printing its proven that material did have effect on lowering the budget. material such as composite which is more expensive will cost more money than cheaper material such as steel, aluminium, an copper. Steel, Aluminium, and Copper also have advatange compared to the composite which is the thermal conductivity. but the composite is proven to be more resilince and adapt to pressure. Among all materials, aluminium was proven to be the most cost effective and efficient as its could meet the requirements to withstand 8 bar pressure and has good conductivity. The thickness of the tube also being considered as the thinner the tube meaning the lower cost of materials would be spent. To estimate the real cost we need to first calculate the total of materials spend.

First count the diameter and height of the tube

h = V / (π * r^2) h = (1 * 10^-3) / (π * (0.1)^2)

import math

diameter = 20 # cm radius = diameter / 2 / 100 # Convert to meters volume = 1 / 1000 # Convert to cubic meters

height = volume / (math.pi * radius ** 2)

print("Estimated tube height: {:.2f} meters".format(height))

Estimated tube height: 0.16 meters

After got the estimation of the height and diamater now estimate the thickness of the diameter

desired_stress = 50 # MPa yield_strength = 200 # MPa pressure = 8 # bar radius = 0.1 # meters

thickness = pressure * radius / (desired_stress * 10**6 / yield_strength)

print("Estimated thickness: {:.2f} meters".format(thickness))

Estimated thickness: 0.02 meters


Now we got the estimation of the thickness we can start counting the money we are going to spend by making iteration


import math

class Material:

   def __init__(self, name, price_per_kg):
       self.name = name
       self.price_per_kg = price_per_kg  # Price in rupiah per kg


class HydrogenStorageSystem:

   def __init__(self, capacity, operating_pressure, initial_thickness, iterations):
       self.capacity = capacity  # Hydrogen storage capacity in liters
       self.operating_pressure = operating_pressure  # Operating pressure in bar
       self.initial_thickness = initial_thickness  # Initial thickness of the tube in cm
       self.iterations = iterations  # Number of iterations
       self.materials = [
           Material("Copper", 200000),  # Copper material with price per kg
           Material("Steel", 100000),  # Steel material with price per kg
       ]
       self.selected_material = None
       self.selected_diameter = None
   def estimate_cost(self):
       best_cost = float('inf')
       for material in self.materials:
           thickness = self.initial_thickness
           for _ in range(self.iterations):
               # Calculate the weight of the tube
               tube_volume = math.pi * (self.selected_diameter ** 2) * thickness / 4  # Volume in cubic cm
               tube_weight = tube_volume * material_density / 1000  # Weight in kg
               # Calculate the material cost
               material_cost = tube_weight * material.price_per_kg
               # Calculate the total cost (material cost + labor cost + other costs)
               total_cost = material_cost
               # Check if the cost is better than the current best cost
               if total_cost < best_cost:
                   best_cost = total_cost
                   self.selected_material = material
               # Increase the thickness for the next iteration
               thickness += 0.1
       return best_cost


  1. Example usage

storage_system = HydrogenStorageSystem(capacity=1, operating_pressure=8, initial_thickness=0.2, iterations=25) cost = storage_system.estimate_cost()

print("Estimated cost: {:.2f} rupiah".format(cost)) print("Selected material: {}".format(storage_system.selected_material.name))

ITERATED.png