Water is the most abundant element on earth, yet it is the most valuable and most sought out. Water is absolute, the amount of water on the planet does not change, yet it seems to be scarce and is highly valued by all nations and societies all over the world. As urban growth is becoming more and more the norm in our world, we find that former green landscapes are replaced by concrete surfaces, this not only contributes to the rising temperatures of earth’s surface, but it is also a direct effector to the distribution of surface water or lack of. The fact is that water, although abundant, is not distributed evenly across the surface of our planet. As our societies grew and our civilization advance, the effect of this growth to nature have caused an imbalance of natural resources which led to regional and global changes, these changes have contributed directly and indirectly to extreme climate changes that led to draughts and floods in new areas; societies that started around abundant water sources are now struggling to keep demand or avoid constant floods and destruction. The idea in its core is aiming at reducing the effects of climate change on a global scale, by collecting the increasing amount of water in the atmosphere and collected it in areas where is needed and can be manages, such as deserted farmlands, draining reservoirs, and dried up streams and rivers. This will help redistribute surface water, manage flooding, create new agricultural lands, and support the eco system. A good example is the Jordan Valley, where Israeli pumps pull water off the Jordan River for agricultural and urban use in south of Israel, AquaSmart can replenish the Jordan River water levels and sustain its natural flow; thus, sustaining agricultural communities on both sides of the river, and saving the declining sea level of the Dead Sea, resulting preserving surrounding underground water levels from receding further. The impact AquaSmart can have on saving the planet is great, it will help balance natural resources, especially water, in our ever-growing society for a better future. What is it AquaSmart is a water harvesting machine that collects water from air's humidity, it is the most efficient product in the world and produces the most amount of water to kW in the market today. AquaSmart is designed to provide water to reservoirs and large-scale farming and forestry, it is aimed towards large scale terraforming that will change the world and balance water distribution on a global scale. There are 3 main versions of AquaSmart, depending on need and available infrastructure, it can produce water where it is needed and AquaSmart will help in easing the effects of climate change to communities across the world, and it will bring life to regions that has a dire need to easy access water sources that are self-sufficient and sustainable. Technology The atmosphere contains as much as 1.29 x 1016 L of water, in the form of clouds, fog, and water vapor. In global terms, that number is small, only 0.001% of the world’s total water. But in relative terms, it’s a deluge—six times as much water as what’s in the world’s rivers, a major source of drinking water. AquaSmart is nothing new, the idea/technology was invented by Willis Carrier in 1902, by cooling polished metal surfaces to the surrounding environment's dew point, water droplets can be collected on these surfaces, thus water can be harvested from air. Aqua smart utilizes this technology further and forces water droplets and ice crystals to form on a specially designed collection cell that ensures the harvesting of an abundance of water at low atmosphere humidity while using an economical amount of electricity to power the process. A simple explanation of the system includes using a gas pump that reduces the temperature of a specially designed sheets of aluminum cools a medium that run through a pipe system which in turn condensates moisture from the ambient air to very low temperatures, collecting water as droplets and ice crystals, a special collection method is used to speed up water flow, this results in large yield and productivity. The system components are grouped in cells and modules, this reduces power consumption and need, while increasing productivity. A single modular group produces approximately 500 liters of water per hour while consuming 1.4kw of electricity, making it the most efficient water generating machine on the planet. The AS-500 version produces 6000 liters of water per day, while consuming only 28.8 kw of electricity. Using single phase 110/220v, 50/60hz power supply means that AquaSmart can run on any outlet or power source, it can even be powered using a vehicle power supply. This makes it extremely useful for relief efforts, mobile operations, and remote area deployment. The system is designed to be a standalone operation with minimum or no human interference needed during running time, it is designed as a plug and play machine that can be connected to any power source available, it runs on 1 phase electricity and can run on solar power, it has a very low heat signature and a minimalist carbon footprint, making it suitable for solving current global challenges. Water produced by AquaSmart is considered raw water, it is not designed for drinking as the system does not have built-in filters, a filter system can be installed externally, AquaSmart will produce water to renourish streams, rivers, and reservoirs, and bring balance back to nature. Services Along with AquaSmart production, we also provide installation, relocation, and maintenance service. We can design and install appropriate setup for your needs Investor invitation AquaSmart is seeking investors and partners to establish manufacturing and assembly facility for the product line, to take over a global commercial share of this growing market, there is a need for our product and a low-risk market and growth opportunities. Existing market A simple Google search will show that the idea is popular nowadays and gaining momentum, it is in the news, there are many innovations that are focused on this technology and are aiming to improve output of this technology. By simple comparison, AquaSmart produce the highest rate of water production per kW of power. Potential customers Our product lineup reflects our target base customers, we offer AquaSmart to: Small farms and villas Businesses and industries Large Scale Farming Forestry and land rehabilitation Governments Global organizations We offer medium capacity commercial capability, and large-scale projects, AquaSmart is not meant for small skill individual use at is produces a large amount of water that is best used for commercial and industrial large-scale use. Projects To increase value and showcase the product, we offer our customers with a project template that we implement, operate, and maintain. Mountain Valley As the name suggests this project template offers a sustainable resource generating setup, requiring only mountainous terrain, it operates simply by using elevation to generate electricity and water This concept works anywhere on earth where there is an elevation, it uses the earth’s gravity and water pressure to create kinetic energy that is utilized by using power turbines; generating electricity to run AquaSmart, and an excess to support community, providing electricity and water. This project can be implemented anywhere on earth and has a base infrastructure cost that pays off quickly in community development, and sustainable long term economic advantages. It also has a minimalist carbon footprint and reduces CO2 build-up and greenhouse effects. Target Customers are local governments and large-scale farming industries. Oasis The oasis template is designed to terraform and rehabilitate deserts and barren regions, it reclaims land for farming and wild forestry, which improves the natural resources of the project’s region. This template does require a large area to meet its full potential, but the results are rewarding. The oasis template is implemented on 4 main phases. Phase 1: setting up solar farm and AquaSmart, where solar panels will occupy the flat areas of the project, AquaSmart to be placed on high terrain to reduce need of pumping system. Phase 2: water is collected in reservoir, either natural or constructed lake, this will improve ground water saturation and water distribution at later stages. Phase 3: cultivating of land and select high yield farming, this can either be developed by large scale agricultural development or by a community outreach programs. Phase 4: development of wild forestry, this will provide sustainability and is crucial for land terraforming. These charts show the first operating hour, as the system goes through the first couple of cycles, the average productivity stabilizes. Power consumption chart shows the cycle as controlled by a thermostat, it will shut down the main cooling compressor once a certain temperature is reached in the medium and start again once it warms up as part of the system function. Note that the medium pump runs continuously that’s why the system will not reach zero power consumption while in use. Temperature chart shows the temperature cycle, as the condensation pipes gets colder, water start to form ice crystals after a few cycles which brings the water productivity to zero, it starts by generating dew, that turn into solid ice layer covering the pipes. Once the temperature rises again due to cooling idle stage, the ice layer melts, and dew is formed again. Once dew formation and ice melting on the condensation pipes gains rhythm, an infinite cycle of water production while AquaSmart is running, until restart or shutdown, water will be produced at the same level even in dry weather as the condensation and pipe system operates will below dew point of anywhere on the planet. The design of a cycle operation allows AquaSmart to produce stable sustainable amounts of water. While consuming stable low amounts of energy, if the system is powered by solar panel, this allows for battery recharge and low power system load. AquaSmart is the result of an actual experiment and prototype, this resulted on actual data proving the efficiency of the system which gives it heads start in R&D and product development. One of the interesting finding is that while calculating water productivity on the condensation pipes, water droplets covered a certain percentage of pipes and did not form a surrounding layer while in liquid form, water droplets covered 30% of the pipe surface in best cases, once the pipe was cold enough, those water droplets turned into solid ice layer that did cover the entire area of the pipe and eventually both solid ice layer and powdered ice crystals where covering the pipes in the entire system. The cycle method proved that by having the water droplets while the cooling system is in idle state, it allowed for more productivity as solid ice and water crystals did form on the condensation pipes. This resulted in a much better water production that other models that rely only on high humidity and dew point temperature design.