ENVIRONMENTAL CHALLENGE
Ecological concerns
The main challenge Human kind is facing for coming years is CO2 reduction.
CO2 is present in the 3 core elements of Life: FOOD, ENERGY & ENVIRONMENT.
Each content Carbon.
CO2 is present in the 3 core elements of Life: FOOD, ENERGY & ENVIRONMENT.
Each content Carbon.
FOOD : Carbon is in all animal and vegetal tissus
ENERGY : 85% of fossil fuels are made of Carbon
ENVIRONMENT : During the last 50 years the natural balancing of CO2 has been jeopardized. Anthropogenic emissions of CO2 have increased faster than the absorbtion capacity of Nature.
Impacts
Waste from food consumption and fossil fuels consumption generate tons of CO2 rejections.
The disrupted equilibrium of CO2 is changing thermodynamics of Climate, causing:
The disrupted equilibrium of CO2 is changing thermodynamics of Climate, causing:
Hurricanes
Typhons
Flood
OUR MISSION: BRING INNOVATION TO MARKET
CCN Environment is a new singaporean company specialized in Clean Tech Biotechnologies with the mission to build bridges between the laboratory expertise of scientists from Universities and the industrial marketplace. CCN Environment primary focus is to attract investments to turn the demonstration production facility plant and Patents currently existing, into an industrial technology for environmental remediation of CO2 and commercialization of premium ingredients for human and animal health and nutrition in aquaculture and agriculture.
Autotrophs versus Heterotrophs
Autotrophs, store chemical energy in carbohydrate food molecules they build themselves.
Only plants, ALGAE, and some bacteria are capable of this life-giving energy transformation. Autotrophs are the beginning of food chains which feed all life. Autotrophs produce food, using photosynthesis with the energy of the sun.
Only plants, ALGAE, and some bacteria are capable of this life-giving energy transformation. Autotrophs are the beginning of food chains which feed all life. Autotrophs produce food, using photosynthesis with the energy of the sun.
Heterotrophs cannot make their own food. They must eat or absorb it.
They are known as consumers. This includes all animals. Heterotrophs have an absolute dependancy on autotrophs that originally create food.
They are known as consumers. This includes all animals. Heterotrophs have an absolute dependancy on autotrophs that originally create food.
Recycling CO2 is the KEY
Natural recycling of CO2 is done within our biosphere by Photosynthesis :
It is the ability of Nature to absorb CO2.
99% of the energy of Life is coming from this Photosynthesis.
But this Photosynthesis capacity of Nature does not cope with the increasing industrial emissions of CO2.
Our project is based on accelerating natural photosynthesis to transform CO2 from industrial emissions into highly valuable products used in:
It is the ability of Nature to absorb CO2.
99% of the energy of Life is coming from this Photosynthesis.
But this Photosynthesis capacity of Nature does not cope with the increasing industrial emissions of CO2.
Our project is based on accelerating natural photosynthesis to transform CO2 from industrial emissions into highly valuable products used in:
- Feed and Food
- Cosmetic
- Pharmaceutical
UNLOCK THE POWER OF ALGAE
As such, CCN Environment is working on unlocking the extraordinary potential of microalgae with a technology based on the natural Photosynthesis capacity of Nature to transform CO2. CCN Environment patented technology is based on the capture and accelerated conversion of CO2 using solar energy and photosynthesis from autotrophic microalgae to neutralize pollution and cultivate Biomass Algae from which premium nutrients like Omega 3 & 6 are extracted.
How autotrophs create energy
This diagram illustrates how Autotrophs Algae transform CO2 into carbonhydrates (energy)
An innovative technology available in mother Nature
Autotrophic microalgae culture in farms of Bioreactors exposed to sunlight (or sunlamps).
Production of energy-rich Biomass with high lipid load
The process is fully automated and under aseptic atmosphere to avoid contamination.
Microalgae use nutrients (from recycling water: like nitrates) and CO2 from industrial emissions.
Through Photosynthesis, the Biomass volume doubles (strong Mitosis capacity) every 24 hours.
Every day half of the pipe is captured and down streamed to extract high value products
Leaving a negative carbon footprint
Production of energy-rich Biomass with high lipid load
The process is fully automated and under aseptic atmosphere to avoid contamination.
Microalgae use nutrients (from recycling water: like nitrates) and CO2 from industrial emissions.
Through Photosynthesis, the Biomass volume doubles (strong Mitosis capacity) every 24 hours.
Every day half of the pipe is captured and down streamed to extract high value products
Leaving a negative carbon footprint
Our process to extract the products
How autotrophs create energy
This diagram illustrates how Autotrophs Algae transform CO2 into carbonhydrates (energy)
An innovative technology available in mother Nature
Autotrophic microalgae culture in farms of Bioreactors exposed to sunlight (or sunlamps).
Production of energy-rich Biomass with high lipid load
The process is fully automated and under aseptic atmosphere to avoid contamination.
Microalgae use nutrients (from recycling water: like nitrates) and CO2 from industrial emissions.
Through Photosynthesis, the Biomass volume doubles (strong Mitosis capacity) every 24 hours.
Every day half of the pipe is captured and down streamed to extract high value products
Leaving a negative carbon footprint
Production of energy-rich Biomass with high lipid load
The process is fully automated and under aseptic atmosphere to avoid contamination.
Microalgae use nutrients (from recycling water: like nitrates) and CO2 from industrial emissions.
Through Photosynthesis, the Biomass volume doubles (strong Mitosis capacity) every 24 hours.
Every day half of the pipe is captured and down streamed to extract high value products
Leaving a negative carbon footprint
Our process to extract the products
CO2 Processing
Negative carbon footprint
1.86 tons of CO2 absorption ratio per ton of Biomass production
170 tons of CO2 capture per 1ha plant
1.86 tons of CO2 absorption ratio per ton of Biomass production
170 tons of CO2 capture per 1ha plant
PRODUCTS
Acqualift Sulphated Polysaccharides (SPs)
Natural sulfated polysaccharide compound isolated from marine phytoplankton
NaturCarotene
The best source of natural mixed carotenes, xanthophylls and 9-cis β-carotene
LICENSING AND PARTNERSHIP
This unique patented technology kills 2 birds with one stone: reduce C02 pollution and provide sustainable low cost source of nutrition for a growing population. CCN Environment seeks and welcomes any opportunities to collaborate with research and industry groups whenever the project is aligned with our mission; or to explore mutually beneficial technology licensing opportunities.
CONTACT US