EnergyInfrastructure

Bryan Espinoza

GREATLY OBSERVED OBJECTIVES DEFINED

ARCHITECTURE DESIGN URBANISM

(631) 702 0232 GreatlyObserved.com

ObjectivesDefined@GreatlyObserved.com

New York, New York

The objective ofthisletterisfora proposal.Anyinformation disclosed in thisletterisforthe ownerofthe

companytoinitiate anagreementforan architectural/design scope ofwork.Anyquestionsorconcernsshouldalwaysbe communicated to the information above.

CARBON-CAPTURE TECHNOLOGIES

Type: Schematic Concept

Status: Unbuilt Commission: Proposal

On our path towards a Carbon NetZero Society, within our Global Effort, are the goals to reduce Carbon Emissions, prevent Climate Change, counteract Water Sea-Levels, & protect our lasting Natural Resources. The development of these kinds of Technologies within Carbon Capture & Absorption of Solar Energies become imperative. The path towards Carbon NetZero develops an Environmental Doctrine, a promise to our Global Community, promoted within the Sustainable Development Goals of 2030/2050, invested in by the prestigious organizations such as the United Nations within International Affairs. Nevertheless, it is the hope of this Research, Innovation, Infrastructure & Technology, for which we depend on our days of tomorrow.

From Data-Analysis to the Abstractions of “Working-Mechanisms”, the operating Eco-System, the functions of the Earth’s Stratosphere, the Development of Human-Life exprience as Innovation in Technology continues to evolve; this is the motivation for the future projects of tomorrow. Projects that will determine the life span of Human Creation & Existence as we know it, but also develop the Job Market, Material Research, as well as, Socio-Economic & Socio-Racial Structures from hereinafter.

Nevertheless, to the Sustainable Development Goals of 2030, Climate Change, is of the greater feat to conquer, combatting alot of the issues in Energy-Efficiency, Poverty, Clean-Water & Sustainability. Within that experience is controlling Carbon Emissions, for which need to really decrease by almost (45) percent from the 2010 analysis, & finally deplete to NetZero by 2050. Today, that measured analysis, according to the International Energy Agency, shows that we have not really done to well in the Carbon NetZero report card. In the last (10) years, the Global Energy is up about (2) to (3) Gigatons in Carbon Dioxide, relatively, about (3) times the mass of the human population in the world.

Since 1994, as the internet was introduced, Carbon Dioxide has soared almost (60) percent in (13) Gigatons. Today, the goal is to develop Technology & Infrastructure that sequesters, depletes & reproduces Carbon Emissions into more efficient material in Fuel Energies, Power-Supply & systems of working in better Air-Filteration for a Carbon NetZero Environment. Accordingly, the following Technologies in Carbon-Capture develop an answer to Carbon Emissions through Clean Efficient Techno-Systems which alter our Human Interactive & Inhabitable Experience.

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks

according to the International Energy Agency (IEA), in regards of Global Energy-Related CO2 emissions, as of Spring 2021, we are at a rate of 32 to 33 Gigatons per year, the Sustainable Development Goals require an interest of reaching 20 Gigatons per year by 2030 and Carbon Net-Zero by 2050 the innovation in the designed Carbon-Capture Technologies is within the amount of Carbon Sequestration in relative time, the chart and data show projections of sequestration for each Carbon-Capture Technology presented, displaying the possibilities of overcoming the requirements and reaching Carbon Net-Zero by at least 2032

each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

Carbon Sequestration Projection (2021-2050)

Hybridity - Sub-Floor Mechanical Level

Schematic Concept - Chart & Data Analysis (Competitive Proposal 2021)

Conceptual Proposal - Waterfall Remediation Tank (Competitive Proposal 2021)

Carbon-Capture Technologies

Carbon Capture Technologies

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks

a diagram from the International Energy Agency (IEA) regarding Factors in CO2 Emissions from Generated Electricity was analyzed and reinterpreted for an understanding in projection of Electricity Production and CO2 Sequestration by the new Carbon Capture Technologies being presented from 2021-2050

each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

since 1990-2018, there has been a tight relationship between Carbon Emissions and Electric production, in 2010, that changed as more sustainable fixtures were invented and used, but in order to reach NetZero in Carbon Emissions, Technologies in Carbon-Capture of which are able to sequester and produce at a gigaton-level must be developed as shown

Accumulated

Generated Electricity & CO2 Sequestration

Schematic Concept - Chart & Data Analysis (Competitive Proposal 2021)

Carbon-Capture Technologies

Oi Demand After COVID (mb/d)

following interests in the Oil Demand Forecast, for the Sustainable Future, considering Sustainable Goals of 2030 in Fossil and Energy Fuels, through this analysis the existing and projected data of Global Demand is recollected and compared to the accumulation of Generated Energy with new technologies

each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

since 2010, the Demand for Oil has been progressively growing at the Millions of Barrels per day, although a minor drop through COVID, it continues to be consistent, in order to reach these demands we must develop a very efficient and considerable technology, hence, alongside a data-chart showing what these prospective prototypes are and the economic infrastructure they are to produce

(tb/d) (tb/d) (tb/d) (tb/d) Hybridity 7-Story Building dfiHydroPurifier (12-Stor y Tower) y HydroPurifier The Cascades

801,360 6.3 1.6M 12.6

Accumulated Generated

Energy in Methane Fuel tb/d & Cost-Value ($127.2/b

Hybridity (7-Story Building HydroPurifier 12-Story Tower HydroPurifier The Cascades

7.80 992 160 15.6 1.98M 23.4 2.98M 31.2 3.97M 39 0 4 96M

SDG2030 SDG 2030 Carbon Neutrality y Cbl ra Pre Pandemic Post Pandemic

PROJECTION CT

Hybridity - Sub-Floor Mechanical Level

(Competitive Proposal

2025 (tb/d)($/d) 0.9 W ater f all Cascades @ 5 gpm/.5 d a y

228 960 1.8 12.6 3.2M 25.2 1.6M 349,440 2.7 18 9 4.8M 37.8 2.4M 457,920 3 6 25.2 6.4M 50.4 3.2M 572,400 4 5 31.5 8.0M 63 0 4.0M 1.56 198,432 3.12 396,864 4.68 595,296 6.24 793,728 7 80 992,160 2026 2027 2028 Projection (Time) Hybdbridity (49-Story Building) bd Hybridity (98 -Stor y Building)

2030 9.36 1.19M 10.9 12.5 14.0 15.6 1.98M 1.39M 1.59M 1.79M 46.8 5.95M 54 5 62.5 70.0 78.0 9.90M 6.95M 7.95M 8.95M

Oil Demand & Generated Energy Cost-Value

Schematic Concept - Chart & Data Analysis (Competitive Proposal 2021)

801 360 6.3 44.1 11.2M 88.2 5.6M 915 840 7 2 50.4 12.8M 101 6.4M 1.03M 8.1 56.7 14 4M 113 7.2M 1.15M 9.0 63.0 16M 126 8.0M

2029 (tb/d)($/d)(tb/d)($/d) (tb/d)($/d) (tb/d)($/d) (tb/d)($/d) 686 880 5 4 4.8M 37.8 9.6M 75.6

(tb LO b b/

(tb/d)

OBJECTIVES DEFINED

Conceptual Proposal - Waterfall Remediation Tank

Carbon-Capture Technologies

Carbon Capture Technologies

© All Rights Reserved.

COMPETITIVE PROPOSALS 19 OBJECTIVES DEFINED

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks

each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

the main technology that is innovated through this project is the cascade waterfall, which works through the mechanisms of a sprinkler system designed through the vertical columns and mullions

the main technology that is innovated through this project is the cascade waterfall which works through the mechanisms of a sprinkler system designed through the vertical columns and mullions

whilepanelsofalgaeand

metal zinc are parallel to the cascade waterfall, structured through vertical columns, which allow air to be absorbed and cleansed before being filtered in or out of the building, as well as, allows water to be harvested along the chemical properties of the panels creating carbon acid, later used for grey water and energy fuel

Hybridity - Cascade Waterfall Diagram

Hybridity - Sub-Floor Mechanical Level

OBJECTIVES DEFINED

Schematic Conceptual Proposal - Partial Elevation

Schematic Conceptual Waterfall Remediation Tank

(Competitive Proposal 2021)

Carbon Capture Technologies

(Competitive Proposal Technologies

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks

alongside, is the material cost analysis of the Hydro-Purifying Cascade technology, to be promoted and commercialized into the market by identifying the costs of the primary materials at a wholesale level for a custom design

the data of the costs present the primary materials used by weight and work-application to prepare for the construction and building phase, a total product-cost for the technology is developed and identified with breakdowns in cost definitions as shown

the second technology that is innovated through this project is the custom designed facade panel using the materials of algae, metal zinc and metal oxide film which is layered on a panel that also hosts around a 4”-8” air gap and provides the transfer of solar energy for electricity of the panel’s self-sufficiency the air gap allows the filtration, insulation and daily manipulation of temperatures through the building skinfor the complete year, while providing the adequate applications for the exhaustion and rain harvesting of the custom drainage system on the bottom of the panel

Hydro-Purifying Water fall Cascade (10-Stor y)

Hydro-Purifying Water fall Cascade (10-Stor y)

Hybridity - Sub-Floor Mechanical Level

Hybridity - Sustainability Diagrams

$131,852.91 the cost of 123,003 06 lbs-wt o Steel w/ work

3$13,024.7 the cost o 3,183.93 bs-wt of Steel w/ work

$45,297.63 the cost o 50,343.55 lbs-wt of Aluminum Oxide Film w work

5$38,141.5 the cost o 14,983.20 lbs-wt o Zinc w work

$2 94 50 083 9 the cost of 42 029 26 lbs-wt o Steel or Vent & Sprinkler System w/ work

60,$438,258. G azing-Vent Tube w/work

$330,000.00, the cost o 4 Air-Fan Turbines w/work

00,$410,000.0 the cost o (4) Fuel Tanks & (8) Water Tanks w Wo k

$2 94 50 083 9 the cost of 42,029.26 bs-wt of Steel for Vent & Sprinkler System w/ work

of Algae w/ work

$38,141.55, the cost of 14,983.20 lbs-wt of Zinc w/ work

$45,297.63 the cost o 50,343.55 lbs-wt of A uminum Oxide Fi m w/ work

$13,024.73 the cost of 3,183.93 lbs-wt of Steel w/ work

Schematic Conceptual Proposal - Partial Elevation (Competitive Proposal 2021)

Schematic Conceptual Proposal - Waterfall Remediation Tank (Competitive Proposal 2021)

Hydro-Purifying Cascade Material Cost Schematic Concept - Cost & Data Analysis (Competitive Proposal 2021)

Carbon Capture Technologies

Carbon-Capture Technologies

© All Rights Reserved.

834.70 $2 166 5M$2.5-5. $3M

ost Per Cascade l Co (10-Stor y, 120’) : $7-10M 166,834.70 , 2.5-5.5M 3M

- Primar y Material Cost - Building/Secondary Materia Cost - Design/Analysis Cost

- Primar y Materia Cost - Building/Secondary Materia Cost - Design/Analysis Cost

Important Material Cost of I : A gae

Important Material

- $1,137 per 2,000 lbs

- $1,900 per 2,000 lbs

Coppe

- $8,880 per 2,000 lbs

Glazin

- $7,800 per 2,000 lbs

- $3,089 per 2,000 lbs

num Oxide A umin

- $1,005 per 2,000 lbs

- $1,005 per 2,000 lbs

OBJECTIVES DEFINED

COMPETITIVE PROPOSALS 19 OBJECTIVES DEFINED

13

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks

in order to sequester and filter large amounts of carbon dioxide at the gigaton level, eliminating large quantities of carbon emissions from the existing natural environment, the hydro-purifying tower is developed to maximize that workload at a greater efficiency

each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

amidst the waterfall cascade technlogy and material science(s) in different matters of substance, water is also harvested and turned into carbon acid for fuel energies, supplying the turbine for acceleration of clean air flow to exhaust back out into to the environment

Formula :

) Direct Air Capture - Carbon Dioxide Intake (ft ) x 1000 (fpm x (Min. Intake/Return)

Purified Air - Clean Air Exhaust (t

Total Height (ft) x Width of Facade (ft) x Depth of Panels (ft) 3

Direct Air Capture (ft ) + (Air Flow Velocity 1500 (fpm) x (A 3 2 3

Area of PurifierTube (ft ))

Hybridity - Sub-Floor Mechanical Level

Hydro-Purifier (The Tower)

Schematic Concept - Diagram & Render (Competitive Proposal 2021)

Carbon Capture Technologies

Carbon-Capture Technologies

Conceptual Proposal - Waterfall Remediation Tank

f the tower is an Exhaust Vent At the top of e amount o Purified Air filters where a larg environment. the existing

n elevations, you find the On the ro Pane s which work with the Materia ized Rain-Harvesting filering Air process of R process o well as, producing Grey Water s Quality, a Acid fo Methane Fuel on and Carbo pane s, are the Intake Vents, he p Behind ugh a Mechanical-Pull System hro working h nute or Carbon Capture. M at Feet Pe

levations, a System of Exhaust de e On the si large amounts of PurifiedAir ere Vents, wh ut to the environment. k ou Fi ter bac

m of the Tower Technology you to At the bo hanical Turbine pushing up the Mech findthe M ters through the Tower Tube fi t Air which environment he e out into th

the Mechanical Area, Water of Outside o Rain-Harvested Partic es and ere Tanks, wh of the cascade is amassed o fall the Water bon Acid for Methane Fuel Car produce C batier Reaction, providing the Sa through a uel Energies or the Turbine. y F neccessar

© All Rights Reserved.

OBJECTIVES DEFINED

OBJECTIVES DEFINED

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks

through this proto-type, ‘the hydropurifier’, develops into a self-sufficient system of air filtering and purifying waterfall cascades, in where the ‘waterfall cascade’ technology is implemented and explored through a five-step process, beginning with the absorption of carbon dioxide an active process of rain harvesting filters air particles through a sprinkler system, then amassed in a moment of hydro-electricity and water mitigationallowingthedevelopmentofnewfuelenergies for a mechanical system to exhaust clean filtered air back out, while influencing Ocean Thermal EnergyConversions,

each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

Hydro-Purifier (The Cascades)

Hybridity - Sub-Floor Mechanical Level

Schematic Concept - Diagram & Render

Schematic Conceptual Proposal - Waterfall Remediation Tank

(Competitive Proposal 2021)

(Competitive Proposal

Carbon-Capture Technologies

Carbon Capture Technologies

OBJECTIVES DEFINED

OBJECTIVES DEFINED

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks

the second technology that is innovated through this project is the custom designed facade panel using the materials of algae, metal zinc and metal oxide film which is layered on a panel that also hosts around a 4”-8” air gap and provides the transfer of solar energy for electricity of the panel’s self-sufficiency the air gap allows the filtration, insulation and daily manipulation of temperatures through the building skinfor the complete year, while providing the adequate applications for the exhaustion and rain harvesting of the custom drainage system on the bottom of the panel

each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

Hybridity - Sustainability Diagrams

Hybridity - Sub-Floor Mechanical Level

Schematic Conceptual Proposal - Partial Elevation

OBJECTIVES DEFINED

OBJECTIVES DEFINED

(Competitive Proposal 2021)

Schematic Conceptual Proposal - Waterfall Remediation Tank (Competitive Proposal 2021)

Carbon Capture Technologies

Carbon Capture Technologies

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks

alongside, is the material cost analysis of the Electro-Purifying Facade Panel, developed to promote and commercialize the technology into the market by identifying the costs of the primary materials at a wholesale level for a custom design

each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

the data of the costs present the primary materials used by weight and work-application to prepare for the construction and building phase, a total product-cost for the technology is developed and identified with breakdowns in cost definitions as shown

the second technology that is innovated through this project is the custom designed facade panel using the materials of algae, metal zinc and metal oxide film which is layered on a panel that also hosts around a 4”-8” air gap and provides the transfer of solar energy for electricity of the panel’s self-sufficiency the air gap allows the filtration, insulation and daily manipulation of temperatures through the building skinfor the complete year, while providing the adequate applications for the exhaustion and rain harvesting of the custom drainage system on the bottom of the panel

EllfdS ectro-Purifying Facade System (4x12 Panel)

Electro-Purifier Panel Material Cost

Hybridity - Sub-Floor Mechanical Level

Hybridity - Sustainability Diagrams

OBJECTIVES DEFINED

Schematic Conceptual Proposal - Waterfall Remediation Tank (Competitive Proposal 2021)

Schematic Conceptual Proposal - Partial Elevation (Competitive Proposal 2021)

Schematic Concept - Cost & Data Analysis (Competitive Proposal 2021)

Carbon Capture Technologies

Carbon-Capture Technologies

Carbon Capture Technologies

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks

here the electro-purifier technology is used through its facade panel system, developing a purifying wall, which produces a new circuit and system of power supply, filtering the existing environment with purified and processed clean air at large quantities

each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

the electro-purifying system is designed through facade panel types in different articulations of material science, with algae, copper and metal qualities, for a process of solar energy absorption and sequestration of carbon dioxide, producing work-energy for a mechanical vent to reduce Carbon Emissions

Electro-Purifying Wall

Hybridity - Sub-Floor Mechanical Level

Schematic Concept - Diagram & Render (Competitive Proposal 2021)

Conceptual Proposal - Waterfall Remediation Tank

Carbon-Capture Technologies

Carbon Capture Technologies

OBJECTIVES DEFINED

OBJECTIVES DEFINED

on the bottom sub-floor level you find the mechanical room, where the waterfall cascade meets its remediation process through the two tanks each tank has its own purpose of interest, one through the use of algae which allows the water filtration for grey water, while the other prepares for the carbon acid harvested towards a sabatier process to produce methane energy feul

here the electro-purifier technology is used through its facade panel system, developing a purifying tower, which produces a new circuit and system of power supply, filtering the existing environment with purified and processed clean air at a gigaton level

the electro-purifier technology through its facade panel system, rises in modules, developing a purifying tower, and producing a large of power supply, while filtering the existing environment with processed clean air

the electro-purifying tower is designed through a facade system of panels rising in modules articulating processes of material science, with algae, copper and metal qualities, a process for solar energy absorption and sequestration of carbon dioxide, producing new electricity for a vent system of work-energy eliminating carbon emissions

the rising modules in panels articulate a process of material science, with algae, copper and metal qualities, expanding on the notion of direct-capture sequestering Carbon Dioxide at a gigaton level and absoring solar energy for a suitable work-energy at a gigawatt level

Formula :

Direct Air Capture Carbon Dioxide Intake (ft x 1000 (fpm)

Total Height (ft) x Width of Facade (ft) x Depth of Panels (ft) x (Min. Intake/Return) 3

Purified Air - Clean Air Exhaust (t )

Amount of Wattage/Hr

3 2 3

(2 Panels)(4)(4.5Ft)(5Ft)(321 Watts/HR)(Height of Panels (Ft))

Direct Air Capture (ft ) + (Air Flow Velocity - 1500 (fpm) x (Area of PurifierTube (ft ))

At the top of the tower is an Exhaust Vent where a large amount of Purified Air Filters within the existing environment.

On the ront elevations, you find the Materia ized Pane s which work with the process of Natural Direct Capture

Behind the pane s, are the Intake Vents, working through a Mechanical-Pull System at Feet Per Minute or Carbon Capture Sequestration

At the bottom o the Tower Technology you find the Mechanical Turbine pushing up the Air, which Fi ters through the Tower Tube out into the environment

*** Avg. Solar Pane at 5.4Ft x 3.25Ft provides around 250 Watts/Hr

*** Each Module is of (8) Panels at 4.5Ft x 5Ft

Electro-Purifier (The Tower)

Hybridity - Sub-Floor Mechanical Level

OBJECTIVES DEFINED

Schematic Conceptual Proposal - Waterfall Remediation Tank

(Competitive Proposal

Schematic Concept - Diagram & Render (Competitive Proposal 2021)

Carbon-Capture Technologies

Carbon Capture