Structured water is an exciting new field in water science. It is water as nature intended it to be. The water is full of natural goodness & is known to boost the immune system. Discover healthy living with structured water.

Structured water is important to agriculture because it has the same energy and vitality as rainwater. Simple water vortex energizing devices attached to your irrigation system restore water’s negative charge making it more bioavailable to plants and soil microbes. With better water efficiency plant health improves and water bills are reduced. Farmers love structured water because the energy they seek for their crops is now available through their pivot instead of waiting for rain.

Structured water is important to agriculture because it has the same energy and vitality as rainwater. Simple water vortex energizing devices attached to your irrigation system restore water’s negative charge making it more bioavailable to plants and soil microbes. With better water efficiency plant health improves and water bills are reduced. Farmers love structured water because the energy they seek for their crops is now available through their pivot instead of waiting for rain.

Structured water is important to agriculture because it has the same energy and vitality as rainwater. Simple water vortex energizing devices attached to your irrigation system restore water’s negative charge making it more bioavailable to plants and soil microbes. With better water efficiency plant health improves and water bills are reduced. Farmers love structured water because the energy they seek for their crops is now available through their pivot instead of waiting for rain.

Ultrafiltration (UF) is a membrane filtration process similar to Reverse Osmosis, using hydrostatic pressure to force water through a semi-permeable membrane. The pore size of the ultrafiltration membrane is usually 103 - 106 Daltons. Ultrafiltration (UF) is a pressure-driven barrier to suspended solids, bacteria, viruses, endotoxins and other pathogens to produce water with very high purity and low silt density. Ultrafiltration (UF) is a variety of membrane filtration in which hydrostatic pressure forces a liquid against a semi permeable membrane. Suspended solids and solutes of high molecular weight are retained, while water and low molecular weight solutes pass through the membrane. Ultrafiltration is not fundamentally different from reverse osmosis, microfiltration or nanofiltration, except in terms of the size of the molecules it retains. A membrane or, more properly, a semi permeable membrane, is a thin layer of material capable of separating substances when a driving force is applied across the membrane. Once considered a viable technology only for desalination, membrane processes are increasingly employed for removal of bacteria and other microorganisms, particulate material, and natural organic material, which can impart color, tastes, and odors to the water and react with disinfectants to form disinfection byproducts (DBP). As advancements are made in membrane production and module design, capital and operating costs continue to decline. The pressure-driven membrane processes discussed in this fact sheet are microfiltration (MF), ultrafiltration (UF), nanofiltration (NF), and reverse osmosis (RO).

Discover the benefits of using structured water units in your industry. Structured water reduces hard water deposits & prevents scaling. This translates to better functioning of machinery & reduced downtime. In commercial boilers and RO units, there is a significant cost benefit to using our structured water devices. In the textile industry, structured water has yielded many benefits, from reduced clogging of water lines to lower consumption of detergent in washing machines. When used to cure concrete it has improved its impact strength

Structured water is important to agriculture because it has the same energy and vitality as rainwater. Simple water vortex energizing devices attached to your irrigation system restore water’s negative charge making it more bioavailable to plants and soil microbes. With better water efficiency plant health improves and water bills are reduced. Farmers love structured water because the energy they seek for their crops is now available through their pivot instead of waiting for rain.

An Air Source Heat Pump (ASHP) is an energy-efficient system that transfers heat from the outside air to either heat or cool indoor spaces. It operates on the principle of thermodynamics, using electricity to power a refrigerant cycle that absorbs heat from the air (even in cold temperatures) and transfers it into a building. Key Components Outdoor Unit: Contains a fan, evaporator coil, and compressor to absorb heat from the air. Indoor Unit: Distributes the heat into the building, often through ductwork or a fan coil. Refrigerant: Circulates between the outdoor and indoor units to transfer heat. Expansion Valve: Regulates refrigerant pressure for efficient operation. How It Works Heating Mode: The refrigerant absorbs heat from the outdoor air. The compressor increases the temperature and pressure of the refrigerant. Heat is released indoors via the condenser coil. Cooling Mode (Reversible Heat Pumps): The cycle is reversed, absorbing heat from inside the building and releasing it outdoors. Advantages Energy Efficiency: Provides more energy output compared to the electricity it consumes, often achieving efficiencies of 300% or higher. Lower Carbon Footprint: Reduces reliance on fossil fuels when powered by renewable electricity. Versatility: Can be used for heating, cooling, and sometimes water heating. Year-Round Operation: Works in a wide range of climates, though efficiency may decrease in extremely cold temperatures. Disadvantages Initial Cost: Higher upfront installation costs compared to traditional heating systems. Performance in Cold Climates: May require a supplemental heating source in extreme cold. Space Requirements: Needs an outdoor unit with good airflow. Applications Residential, commercial, and industrial heating and cooling. Often integrated with solar panels for further energy savings. ASHPs are a popular choice for eco-friendly heating and cooling, especially as part of efforts to reduce carbon emissions and reliance on fossil fuels.

A swimming pool heat pump is a device used to efficiently heat pool water by transferring heat from the surrounding air to the pool water. It operates on the principle of heat exchange, making it a cost-effective and environmentally friendly way to maintain a comfortable swimming temperature. How It Works: Air Intake: The heat pump draws in ambient air through a fan. Heat Absorption: The air passes over an evaporator coil containing a refrigerant. This refrigerant absorbs the heat from the air and turns into a gas. Compression: The warm gas is compressed by a compressor, increasing its temperature significantly. Heat Transfer: The hot gas passes through a heat exchanger where it transfers its heat to the pool water. Recycling: The refrigerant cools down, returns to liquid form, and the cycle repeats. Features: Energy Efficiency: Heat pumps use electricity to operate but rely on extracting heat from the air, making them more energy-efficient than traditional electric or gas heaters. Temperature Control: They typically come with thermostats for precise temperature adjustments. Durability: Designed to withstand outdoor conditions and prolonged use. Eco-Friendly: Lower carbon footprint compared to fossil fuel-based heaters. Advantages: Lower Operating Costs: Despite the initial investment, they save money in the long run due to lower energy consumption. Consistent Heating: They provide steady and reliable heating, especially in moderate climates. Longevity: Can last for 10–20 years with proper maintenance. Disadvantages: Dependent on Air Temperature: Their efficiency decreases in very cold weather since they rely on heat from the air. Slower Heating: It takes longer to heat the pool compared to gas heaters. Ideal Use: A swimming pool heat pump is best suited for regions with mild to warm climates where outdoor temperatures remain above 50°F (10°C). It's an excellent choice for residential and commercial pools, offering an economical way to extend the swimming season.

Ambient air is drawn in by the fan and passed over the evaporator. The evaporator cools the air, i.e. it extracts the heat it contains. In the evaporator, the heat removed is transferred to the working fluid (refrigerant). With the aid of an electrically driven compressor, the absorbed heat is “pumped” to a higher temperature level through an increase in pressure and given off to the heating water via the condenser (heat exchanger). In so doing, the electrical energy is used to raise the heat of the environment to a higher temperature level. Due to the fact that the heat energy extracted from the air is transferred to the heating water, this type of appliance is referred to as an air source heat pump. The air source heat pump consists of the following main components: Evaporator, fan and expansion valve as well as the low-noise compressor, the condenser and the electric control unit consisting of branded equipment for controlling and safety devices for protection of Compressor, pump etc. against any variations in voltage, current. Also consists of trip devices, if any parameters not available for smooth running of Heat Pump. The Heat Pump is connected to a Hot Water Storage Tank which is made of 4 mm M.S. Sheet, is insulated with rock wool, for maximum temperature sustenance.. Once the temperature in Tank reaches 55°C the machine automatically shuts down and again re-starts when the temperature reduces to 52°C. There is 24 x 7 uninterrupted Hot Water for the whole year, unconditional to any seasons or weather, unlike solar heaters which are completely dependent on Weather conditions.

Enviro Brine+ Hard Water Brine inhibits Calcium formation because of Hard Bore Water used in Houses for Utility Purpose (Like Taking Bath, Washing, etc). Because of Hard Water Taps, Tiles, Geyser Rods all become white and also hard to operate. Same with our Hair too. They become dry and stiff. The looks of the House also deteriorate. Appliances using Bore water like Geyser, Washing Machine, etc also deteriorate because of internal damage and corrosion thus reducing their life. This also prevents corrosion of your house Piping System. All this can be eliminated by using our Revolutionary Hard Water Conditioner. The Product media is Odourless, Tasteless and PH neutral. The system masks the calcium ions to become inert by using proprietary technology

A reverse osmosis (RO) plant is a water treatment facility that uses reverse osmosis technology to purify water by removing contaminants, dissolved salts, and impurities. Below are different aspects and descriptions of an RO plant based on its components, applications, and operations: General Description Definition: A reverse osmosis plant is a water purification system that applies pressure to force water through a semi-permeable membrane, effectively removing impurities, salts, and microorganisms. Purpose: It is designed to provide high-quality water for drinking, industrial processes, irrigation, or specific uses like medical applications. Components Pretreatment System: Includes filters, water softeners, and dosing systems to remove large particles, chlorine, and other contaminants that could damage the RO membranes. High-Pressure Pump: Generates the necessary pressure to push water through the semi-permeable membranes, overcoming the natural osmotic pressure. RO Membranes: The core of the plant, designed to allow only water molecules to pass while blocking salts, minerals, and impurities. Post-Treatment System: May include UV sterilization, pH adjustment, or remineralization to make the purified water suitable for its intended use. Control System: Automates the operation, monitors parameters, and ensures the plant functions efficiently and safely. Applications Drinking Water Production: Supplies potable water in urban, rural, or disaster-relief settings. Industrial Use: Produces ultrapure water for pharmaceuticals, electronics manufacturing, and power plants. Desalination: Converts seawater into fresh water in arid regions or areas with limited freshwater resources. Irrigation: Provides purified water for agriculture, ensuring crop health by reducing salinity. Wastewater Treatment: Recycles wastewater by removing contaminants for reuse. Advantages Produces high-quality water with minimal impurities. Removes a wide range of contaminants, including heavy metals, dissolved salts, and bacteria. Energy-efficient compared to thermal desalination processes. Scalable, from small household units to large industrial plants. Limitations Requires a significant amount of feed water, as some is rejected as waste. Regular maintenance and replacement of membranes are necessary. Energy-intensive, especially for high-pressure systems. Pretreatment is critical to avoid fouling and scaling of membranes. Environmental Impact Positive: Provides clean drinking water, supports sustainable water management, and reduces dependency on groundwater. Negative: Brine disposal from the plant can harm the environment if not managed properly.