S.B.G & CIG Tier 1 Housing of 3-4+ / 3 & 1-2
S.B.G & CIG Tier 1 Housing of 3-4+ / 3 & 1-2
TIER 1 HOUSING PROJECT
Capsules + TinyStackable with a protected steel - composite frame designed in a modern look for safety & security meeting basic needs living with available parking & controlled sized storage
Wi-Fi & mobile phones + space for a television & in-capsule lounge separate from exterior entrance lounge lobby
In-suite washer - dryer + washroom - shower combination then fridge - stove & microwave with fire extinguisher
Computer living & a mailing address
SOLUTIONS FOR THE HOMELESS
As reviewed throughout the H.I.3 Case by Dr Sydney Nicola Bennett
SUBSIDIED LIVING
A Tier is a category in the perspective of S.B.G & CIG
The 1-2 Tiered living creates a foundation which beenfits the economy & investments rather than creating a burden to cater to that acts as a financial straining leech on other areas of the economy through taxation & investments for such
POTENTIAL
Public Sdctor reclaims land for & considers multiple land use claims for
Shelters for the homeless transition to then become resources catering to Tier 1 housing projects
Shelters for the homeless transition to then become resources catering to Tier 1 housing projects
WHAT THIS IS NOT
Temporary vacation housing
Locals capped pr hybrid capped housing
Locals affordable Tiered housing
Locals upper middle or upper class housing
WHAT THIS IS
Safe, security based foundational housing replacing homelessness with a turn key blockage secured home
$25-50 per month or higher or subsided at $0-25 geared to income below a tiny house (Tier 2) or Tier 2-3+ housing
Security surveillance. Anti-bed bug heaters & minimal staff connected to another resource with automation then controlled storage & food - drink storage + preparation rules
HOW THIS BEENFITS SOCIETY
A break even for-profit system voiding homelessness so people meet basic needs
This lowers crime rates & offers a basic universal quality of life for all citizens
HOMELESSNESS ERADICATED
Separate from other forms if housing above. A foundational program that voids homelessness permanently
Public Sector Social Foundation
Private Sdctor For-Profit Foundation
EARTH HALO. MAY NOT BURN UP
We cannot attach moon to halo + harness earth's rotation so it's Piston-Punch Wind-Tunnel & Perpetual Battery or other options
A business that uses lake water & no return in cycle depleats the lake of water. No home for the homeless & they remain homeless.
The Earth has enormous rotational kinetic energy (about 2.14 x 10²⁹ Joules), but extracting it is extremely difficult due to the slow speed and need for a stationary frame of reference. While traditional methods like gyroscopes face challenges, a recent experiment generated a tiny voltage by manipulating the Earth's magnetic field, though it's a controversial, nascent concept not yet practical for power generation.
The Energy of Earth's Rotation
Separate from other forms if housing above. A foundational program that voids homelessness permanently
Public Sector Social Foundation
Private Sdctor For-Profit Foundation
EARTH HALO. MAY NOT BURN UP
We cannot attach moon to halo + harness earth's rotation so it's Piston-Punch Wind-Tunnel & Perpetual Battery or other options
A business that uses lake water & no return in cycle depleats the lake of water. No home for the homeless & they remain homeless.
The Earth has enormous rotational kinetic energy (about 2.14 x 10²⁹ Joules), but extracting it is extremely difficult due to the slow speed and need for a stationary frame of reference. While traditional methods like gyroscopes face challenges, a recent experiment generated a tiny voltage by manipulating the Earth's magnetic field, though it's a controversial, nascent concept not yet practical for power generation.
The Energy of Earth's Rotation
• Immense Energy:
The Earth has a vast amount of rotational kinetic energy, but it's very slow.
• The Challenge:
To extract this energy, you need a system that is stationary relative to the Earth's rotation.
Methods Explored
To extract this energy, you need a system that is stationary relative to the Earth's rotation.
Methods Explored
• Gyroscopes:
Early concepts used gyroscopes that, if spinning fast enough and frictionless, would appear to turn as the Earth rotates. Theoretically, the points of the gyroscope could act as generators, but applying any resistance to slow the gyroscope would cause it to fall, making it difficult to extract sustained power.
• Magnetic Field Interaction:
A more recent idea is to use the Earth's magnetic field, which is influenced by its rotation.
• How it works: A conductor moving through a magnetic field generates an electrical current. A specially designed device, like a magnetic cylinder, could potentially interact with the Earth's magnetic field as the planet turns, creating an imbalance in electrostatic force and generating a small current.
• Current Status: This method is highly controversial, as traditional physics says a conductor static to Earth shouldn't produce electricity from a static field. However, a recent experiment by Princeton University researchers did measure a tiny voltage (microvolts) under specific conditions, suggesting a potential, though unproven, loophole.
Practical Considerations
• Scale:
The voltage generated in these experiments is minuscule, and the devices are not currently practical for generating significant amounts of power.
• Skepticism:
The findings have been met with skepticism from other physicists, and independent confirmation is needed before this concept can be considered a viable energy source.
The findings have been met with skepticism from other physicists, and independent confirmation is needed before this concept can be considered a viable energy source.
• Indirect Methods:
The Earth's rotation also influences other renewable energy sources, such as wind and tides, making these more practical methods of harnessing the planet's movement.
The Earth Halo could offset Earth's main then heat & cold age rotations separate from solar flares & other concerns including meteror or gallatic federation return & exits in the Milky Way or outside as we have mapped
OSMOTIC POWER FOR DESALINATION
The Earth's rotation also influences other renewable energy sources, such as wind and tides, making these more practical methods of harnessing the planet's movement.
The Earth Halo could offset Earth's main then heat & cold age rotations separate from solar flares & other concerns including meteror or gallatic federation return & exits in the Milky Way or outside as we have mapped
OSMOTIC POWER FOR DESALINATION
Ocean - Sea to then bring extraction shallow or deep water for use in Batteries + other then desalination from lakes or streams & rivers creating safer marine biology "ecosystems" creating a break even Energy to operations effort or met positive
Osmotic power is a renewable energy technology that generates electricity from the natural salinity difference between fresh water and salt water, often at river mouths. It uses a semipermeable membrane to allow water to move from the less concentrated fresh water to the more concentrated salt water, creating a pressure buildup. This pressurized flow can then drive a turbine to produce electricity, similar to how other hydroelectric power sources work.
How it works (Pressure Retarded Osmosis - PRO)
Osmotic power is a renewable energy technology that generates electricity from the natural salinity difference between fresh water and salt water, often at river mouths. It uses a semipermeable membrane to allow water to move from the less concentrated fresh water to the more concentrated salt water, creating a pressure buildup. This pressurized flow can then drive a turbine to produce electricity, similar to how other hydroelectric power sources work.
How it works (Pressure Retarded Osmosis - PRO)
• 1. Semipermeable Membrane:
A special membrane separates a chamber of fresh water from a chamber of salt water.
• 2. Osmosis:
The natural process of osmosis occurs, where water molecules move from the freshwater side to the saltwater side to equalize the salt concentration.
• 3. Pressure Build-up:
As water enters the closed saltwater chamber, it increases the pressure inside.
• 4. Turbine and Generator:
This pressurized water is then directed to a turbine, which spins a generator to create electricity.
Key Characteristics
• Continuous Power:
Unlike some other renewable sources, osmotic power can generate electricity 24/7, regardless of weather conditions.
• Reliable:
It offers a steady and reliable source of power.
• Environmental Benefits:
It is a renewable energy source with low environmental impact and no emissions.
• Location-Specific:
Osmotic power plants are most feasible in locations where fresh water, such as rivers, meets the ocean.
Challenges and Future Potential
• Membrane Technology:
Historically, the main challenge has been the development of efficient, durable, and cost-effective membranes for energy conversion
Historically, the main challenge has been the development of efficient, durable, and cost-effective membranes for energy conversion
• Commercialization:
While prototypes have been built, large-scale commercial application is still limited by challenges such as membrane efficiency and system costs.
• Integration:
Osmotic power could potentially be integrated into existing coastal and water treatment infrastructure, offering additional benefits.
https://www.theguardian.com/world/2025/aug/25/japan-osmotic-power-plant-fukuoka
Osmotic power could potentially be integrated into existing coastal and water treatment infrastructure, offering additional benefits.
https://www.theguardian.com/world/2025/aug/25/japan-osmotic-power-plant-fukuoka
OCEAN WATER USES
Processed Salt Water versus As Is encapsuled Salt Water for non-flamable Heating - Cooling insulators for buildings & specifics
Imagine Seawater in a rectangular wall sealed. Heating - cooling + insulation properties then Emergency drainage & anti-corrosion efforts with an anti-flammable Emergency Safety System integrated to arrive at a non-toxic readily available vast resource
Ocean water is heated by the sun and by greenhouse gases, leading to global sea-level rise due to thermal expansion. The ocean also facilitates both heating and cooling via systems like Seawater Air Conditioning (SWAC) and seawater heat pumps, which use the stable temperatures of deep water to cool buildings in the summer and heat them in the winter. These are effective sustainable energy sources where deep, cold water is readily available.
Ocean Heating
• Solar Radiation:
The sun's energy is absorbed by the ocean's surface, leading to increased water temperatures.
Ocean water is heated by the sun and by greenhouse gases, leading to global sea-level rise due to thermal expansion. The ocean also facilitates both heating and cooling via systems like Seawater Air Conditioning (SWAC) and seawater heat pumps, which use the stable temperatures of deep water to cool buildings in the summer and heat them in the winter. These are effective sustainable energy sources where deep, cold water is readily available.
Ocean Heating
• Solar Radiation:
The sun's energy is absorbed by the ocean's surface, leading to increased water temperatures.
• Climate Change:
An increase in greenhouse gases traps more heat in the atmosphere, and the ocean acts as a massive heat sink, absorbing much of this excess heat.
• Thermal Expansion:
As ocean water warms, it expands, a phenomenon that contributes significantly to rising sea levels.
Ocean Cooling & Heating Systems
These systems leverage the ocean's stable, deep-water temperatures for climate control in buildings.
• Seawater Air Conditioning (SWAC) (Deep Water Source Cooling):
• How it works: Cold seawater from deep ocean levels is pumped through a heat exchanger, where it cools freshwater circulating in a closed-loop system.
• Application: This cooled freshwater is then used in conventional air conditioning systems to cool buildings.
• Benefits: Reduces electricity consumption for air conditioning systems.
• Seawater Heat Pumps:
• How it works: A heat pump transfers thermal energy from one place to another, using seawater as the energy source.
• In Winter: It extracts heat from the ocean to warm buildings.
• In Summer: It uses the colder seawater to absorb heat from buildings, providing cooling.
• Benefits: Offers emission-free and reliable heating and cooling energy.
Challenges & Considerations
• Location: These systems require deep, cold water, which is not available in all coastal locations.
• Corrosion: Seawater is highly corrosive, requiring the use of corrosion-resistant piping and materials.
• Marine Growth: Systems must control marine growth in pipes to maintain efficiency.
• High Initial Costs: The installation of deep water cooling systems can be very expensive.
SNOW AS A RESOURCE
If we capture & encapsule snow then preserve in state of snow or ice for production with break even Energy sources that are low cost or at a break even then the perpetual factor considers the variable
If we do so. The melt is smaller in yields for repercipitation which could affect the cloud system & rising ocean waters versus storms & drought patterns
Snow is untapped like Ocean Water
Lake. River & stream cannot be done without a cycle replenish & preservation factor against aquifiers
ETHANOL VERSUS EV & PRODUCTION CYCLES
Lake. River & stream cannot be done without a cycle replenish & preservation factor against aquifiers
ETHANOL VERSUS EV & PRODUCTION CYCLES
A zero emissions effort from Point A - B in full cucle design + sourcing of raw & repurposed materials then manufacturing + assembly then maintenance before repurposing
Ethanol emissions are complex, but can be broken down into tailpipe, production, and life cycle impacts, with overall lifecycle emissions being lower than gasoline but dependent on feedstock. Ethanol combustion is cleaner than gasoline, reducing certain pollutants like carbon monoxide and particulates. However, growing corn for ethanol can release greenhouse gases, which can offset some benefits, though cellulosic ethanol from wood or crop residues offers a greater potential for emission reduction.
Ethanol emissions are complex, but can be broken down into tailpipe, production, and life cycle impacts, with overall lifecycle emissions being lower than gasoline but dependent on feedstock. Ethanol combustion is cleaner than gasoline, reducing certain pollutants like carbon monoxide and particulates. However, growing corn for ethanol can release greenhouse gases, which can offset some benefits, though cellulosic ethanol from wood or crop residues offers a greater potential for emission reduction.
Combustion Emissions
• Reduced Pollutants:
The oxygen in ethanol leads to more complete combustion, which can significantly reduce tailpipe emissions of pollutants like carbon monoxide (CO) and particulate matter (PM).
• Increased CO2:
Ethanol combustion releases carbon dioxide (CO2). However, the carbon released was absorbed from the atmosphere by the biomass (like corn) during its growth, making it a closed carbon cycle for the fuel itself.
• Similar NOx Emissions:
Nitrogen oxide (NOx) emissions from ethanol and gasoline are often comparable.
Life Cycle Emissions
• Corn-Based Ethanol:
The overall greenhouse gas (GHG) emissions for corn-based ethanol can be 3-4% lower than gasoline over its entire lifecycle. This benefit is reduced by factors like the fertilizer and tilling used in corn cultivation
• Cellulosic Ethanol:
Ethanol produced from cellulosic materials (like wood or agricultural waste) can result in substantially lower life cycle emissions compared to gasoline, though this technology is still developing.
Ethanol produced from cellulosic materials (like wood or agricultural waste) can result in substantially lower life cycle emissions compared to gasoline, though this technology is still developing.
• Land-Use Change:
Expanding land for growing feedstock, particularly corn, can lead to emissions from soil and affect carbon sequestration, which can negatively impact the net climate benefit of ethanol, according to some studies.
Factors Influencing Emissions
• Feedstock:
The type of biomass used for ethanol production (e.g., corn, wood) greatly influences its lifecycle emissions.
• Production Methods:
The efficiency of the ethanol production process and farming practices for the feedstock are critical in determining the overall carbon footprint.
• Transportation:
The distance ethanol travels from production to consumption can also impact its lifecycle emissions.
About the lifecycle CO2 emissions associated with using an electric vehicle (EV)?
Well, that’s where things get more complicated. If an EV is using 100 percent nuclear or renewable electricity (like wind or solar), and if the minerals in that EV’s battery were mined using low-energy and non-invasive practices, then the full lifecycle carbon emissions tied to using electricity in that EV could be as low as 2 or 3 g/MJ. If, on the other hand, the EV uses electricity generated by coal, natural gas, or other fossil fuels (which provide 60 percent of U.S. electricity today), and if the minerals used in the battery were mined using typical (i.e., more intensive) practices, then this EV could have a carbon footprint well over 100 g/MJ—making it a worse option for the climate than petroleum.
Notably, these carbon intensity estimates are adjusted to account for the fact that EV drivetrains are generally three times more efficient per unit of energy than internal combustion engines using liquid fuels. In other words, a normal EV drives three times further per megajoule of electricity than a conventional vehicle drives using one megajoule of liquid fuel.
Zero-carbon corn ethanol isn’t an idealistic aspiration or a far-fetched concept. The members of the Renewable Fuels Association have pledged to achieve a net-zero carbon footprint by 2050 or sooner and they are already making strides toward fulfilling that commitment. However, reaching net-zero emissions will require fairness and integrity in lifecycle analysis and honesty in discussions—and reporting—about the carbon impacts of different fuels.
https://ethanolrfa.org/media-and-news/category/blog/article/2022/10/the-truth-about-ethanol-and-carbon-emissions
The distance ethanol travels from production to consumption can also impact its lifecycle emissions.
About the lifecycle CO2 emissions associated with using an electric vehicle (EV)?
Well, that’s where things get more complicated. If an EV is using 100 percent nuclear or renewable electricity (like wind or solar), and if the minerals in that EV’s battery were mined using low-energy and non-invasive practices, then the full lifecycle carbon emissions tied to using electricity in that EV could be as low as 2 or 3 g/MJ. If, on the other hand, the EV uses electricity generated by coal, natural gas, or other fossil fuels (which provide 60 percent of U.S. electricity today), and if the minerals used in the battery were mined using typical (i.e., more intensive) practices, then this EV could have a carbon footprint well over 100 g/MJ—making it a worse option for the climate than petroleum.
Notably, these carbon intensity estimates are adjusted to account for the fact that EV drivetrains are generally three times more efficient per unit of energy than internal combustion engines using liquid fuels. In other words, a normal EV drives three times further per megajoule of electricity than a conventional vehicle drives using one megajoule of liquid fuel.
Zero-carbon corn ethanol isn’t an idealistic aspiration or a far-fetched concept. The members of the Renewable Fuels Association have pledged to achieve a net-zero carbon footprint by 2050 or sooner and they are already making strides toward fulfilling that commitment. However, reaching net-zero emissions will require fairness and integrity in lifecycle analysis and honesty in discussions—and reporting—about the carbon impacts of different fuels.
https://ethanolrfa.org/media-and-news/category/blog/article/2022/10/the-truth-about-ethanol-and-carbon-emissions
M.D.E - C/M PERFORMANCE COMPARE
Our full-scale vehicles compare to X-Ray Brushless 1/10 Scale in all sizes
Enthusiast Racer reference:
https://youtu.be/dDR9mDASeLk?si=N4_OyQxwSsRtk5y_
Acceleration & Speed Govenors... because & smart digital - physical features
FU*K A YOU! JAPAN CHOP STICK
Acceleration & Speed Govenors... because & smart digital - physical features
FU*K A YOU! JAPAN CHOP STICK
Wrap Chop-Sticks in Re-Usable Napkin for hinges (half way or quarter way down)
Easy to clean
https://youtube.com/shorts/8jqyHShmLUI?si=0R9tlf3a957iRlVX
Snap in - lock in construction techniques
S.B.G & CIG
https://youtube.com/shorts/8jqyHShmLUI?si=0R9tlf3a957iRlVX
Snap in - lock in construction techniques
S.B.G & CIG
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