A Comprehensive Business Plan

Executive Summary

Real Estate Business Use Cases – An integrated approach

[x] Housing Capacity of 250,000 habitants/visitors
holding capacity of total infrastructure/minute
economies of scale for biogas generation
buildings/infrastructures equipped with low-cost solar panels
rooftops/window panels etc with flexible and non-transparent panels
adding aesthetics value
[x] Smart City
connected
internet of things
blockchain Infrastructure
central processing units/collations for biomass
support hydrogen storage and transportation
[x] Self Sufficiency
energy independence
agriculture and animal husbandry
central processing units/collations for biomass
[x] Biomass Generation Facilities
central processing units for biomass
biogas generation columns
scrubber facilities to clean biogas into methane
processing facilities for residues into fertilizer
fertilizer rich in nitrogen from human/animal urea
[x] Methane Pyrolysis Facilities
utilize solution design from Al’Maze Consulting
lowest cost possible
100 percent conversion rate of methane to carbon and hydrogen
utilize biogas from biomass generation facilities as methane
utilize energy from solar panels on buildings to generate 1200°C required
sequestration facilities to separate carbon from cold pre-moltened tin
hydrogen storage facilities
[x] A Unique Carbon Sequestration Technique
unit process design
premise for choice of process design
intellectual property @l'mazeC°
[x] Product Descriptions
organic carbonated gas for food and beverage industries – H2CO2_vs_H2CO3
synthetic wood H4CO3 for furniture industries
white charcoal – 2H4O
[x] Others, Product Design Equipment For 2H4O
Category – Griller
Usage Material – White Charcoal
2H4O + O2 --- 4H2O + Heat
Alternatively, C + O2 --- CO2

Housing Capacity and Economies of Scale

In order to achieve optimal quantity in biomass and a reduced cost per cubic meter of biogas in generation from facility, an integrated approach to a balanced eco-system is needed. Hence, the proposed business activity: A Self-Sustaining Estate of Ecosystem.

This self-sustaining estate of ecosystem integrates human, animal and plant activities as shown in the diagram below: screen shot 2018-08-16 at 01 00 15

[x] Humans

input

housing and living
feeding
education
healthcare
technology-in-use
mobility
entertainment and services

output

biodegradable household waste
sewage waste in form of urine and faeces
biomass
[x] Animals

input

space
feeding

output

food for humans
source of biogas
case_in_point: Cows and Cattles
https://bigthink.com/design-for-good/this-is-how-you-turn-cow-fart-gas-into-energy
biomass
[x] Plants

input

space
irrigation facilities
storage and processing facilities
quality seedlings

output

food for humans and animals
source of biogas
https://www.biooekonomie-bw.de/en/articles/dossiers/biogas-a-promising-source-of-renewable-energy/
biomass

real_estate_biz housing model in image

aloofers (richly)
highrise (elevators)_
face_me_i_faceyou (modernized)_

Biomass Generation Facilities

screen shot 2018-08-16 at 02 24 30

Biomass Pre-Treatment

Biogas Generations

[x] references in image below
[x] Premise
in the absence of Oxygen during fermentation
and with very reduced O2 present in wet biomass – via water,2H2O
therefore optimal Methane production possible @90%
with 10% water vapour composition in output
achieve equal distribution with excitation – mechanical spring bed, electric fan,
Otherwise, Carbon in biomass reacts further with O2 at stipulated 35%CO2
[x] Technical Description
biomass enters central processing unitA – whereby excitation,slurry,grading,smoothning
press and compress slurry to extract liquid Nitrogen before entering unitB
treat in unitB with H2O twice the mass-volume of biomass
reduced water content with pressure-induced equipment in unitC
perhaps osmostic-equipment in reverse osmotic pressure using membrane
reduce waterContent to 10% mass in treated biomass
[x] Calculations
determine mass of total biomass in reactor @x.kg
…………………………... water @x.kg*10% equals y.kg
………………………… biomassFibre @(x – y).kg equals z.kg
derived biomass reactor optimal high temperature equals t.optimal
derived biomass reactor optimal high pressure equals p.optimal
with mass kg.optimal known above
[x] Additives
source material for biodegradable in smart city totally Organic
introduction of external organic elements – algae, bacteria, prokaryotes etc
[x] reference in image_for_Membrane organic Sponge, fibre in abundance in SW Nigeria organic Sponge, fibre in abundance in SW Nigeria newLooks

Gaseous Separation and Methane Pyrolysis

separationmethaneandwater separation of water vapour from methane using Chillers lens_and_wavefronts Optics lens convert solar energy to heat energy screen shot 2018-08-19 at 04 48 11 premise screen shot 2018-08-20 at 01 36 42 premise screen shot 2018-08-19 at 23 25 28 premise screen shot 2018-08-20 at 02 35 09 solar collectors for both Electricity and Heat references in link below http://news.mit.edu/2017/mit-researchers-develop-graphene-based-transparent-flexible-solar-cells-0728 http://www.dailymail.co.uk/sciencetech/article-5505627/Miracle-material-graphene-used-create-ultimate-hair-dye.html https://www.youtube.com/watch?v=ZMJnBx117-E&t=8s http://www.wikiwand.com/en/Physics https://wernerantweiler.ca/blog.php?item=2016-10-30 design_methane_cracking

Methane Pyrolysis, intellectual property@l'mazeC°

[x] Methane Pyrolysis: technical description
an integrated process production facilities
bioMethane, CH4 as raw material mass feed-input
gaseous at temperature as low as 10°C
lighter than air, hence upward pressure in design, with assisted gas-pump
inlet into molten slurry tin at 1200°C, assisted with gravitational force field
molten tin and ch4 inlet A higher elevation than outlet B lower elevation
hence drag force in parallel direction as in design
Sun provides heat-transfer dynamics as energy material feed-input
temperature as high as 1200°C provides needed energy for Bond Breaking
bond breaking for CH4 at 74.85KJ/mol https://wernerantweiler.ca/blog.php?item=2016-10-30
Optic lens to convert solar energy ---- heat energy (concave, convese lens)
focus Sun-Ray to optimal concave-convese optimal point
Tin as raw material mass feed-input, separative catalyst
tin melts at a temperature of 1200°C into molten slurry (solid-liquid)
hydrogen boils out of methane as Gas, collected in upward direction
carbon floats on molten tin, as carbon is lighter than tin in periodic-reaction table
carbon is a Metalloid, while tin is a Metal
separate floating carbon from cold Tin during sequestration, carbon as powder
reuse energy from Sun as heat, to continue same process or other industrial usage
remove residue fibre rich in Nitrogen in a batch process
[x] references in images below KIT_PI_2015_139_Crack it Energy from a Fossil Fuel without carbon di-oxide.pdf

Hydrogen Storage and Distribution

[x] Examine Hydrogen Distribution Concept From GasPlas
develop own concept perhaps
partner with GasPlas on H2 transport: storage and distribution
compressor to compress H2 to liquid, or cryogenic freezing
buffer tank for storage pre-Dispenser
coat interior buffer tank with graphite or grapheneOil
aforementioned carbon-isotopes inert to liquid or frozen hydrogen
cost in considerations to develop own or in-partnership
Cost Accounting

distributed_hydrogenc integration hydrogen distribution concept - methane pyrolysis+gasplas distribution concept

screen shot 2018-08-16 at 16 22 58 original hydrogen distribution concept - GasPlas

Carbon Sequestration Design Facilities

[x] references in image below
[x] premise,technical descriptions, and products
in literal terms – sequestering could mean one of followings: isolate, segregate, remove
mission: to remove carbon from molten tin
cool molten tin carbon mixture to room temperature
tin is solid @25°C and so is pure carbon solid powder @25°C
Carbon@(6) is metalloid and Tin@(50) is metal using atomic number comparisons
carbon lighter than tin
carbon stays on tin as suspended power
apply blow-pump
blow-pump applies wind to blow carbon powder off solid tin
grade carbon into product needs
products (carbon, biochar, carbon-fibre, graphite, graphene, diamonds) amongst others Sequestering Carbon from Molten Tin, a unique unit process at Al’Maze Consulting