The Zetasizer Nano Z system is the perfect system for measuring zeta potential and electrophoretic mobility of colloids and nanoparticles in aqueous and non-aqueous dispersions using laser doppler micro-electrophoresis

Download free BIM objects of Watts for SketchUp, Autodesk, Revit, Vectorworks or ArchiCAD.

The major applications of nanotechnology in water treatment processes include silver, copper and zero-valent iron (ZVI) nanoparticles, nanostructured photocatalysts, nano-membranes, and nanoadsorbents. The large surface-to-volume ratio of nanoparticles enhances the adsorption of chemical and biological particles, while enabling the separation of contaminants at very low concentrations. Nanoadsorbents feature specific physical and chemical properties for the removal of metallic pollutants from water. Carbon nanotubes (CNTs) are considered to be one of the prominent nanomaterials used in water purification. CNT-based filtration systems can remove organic, inorganic and biological compounds from water. Global companies such as Alfa Laval, Applied Membranes, DowDuPont, GEA Group, Inopor, and Koch Membrane Systems are involved in the development of membranes that are made of nanomaterials to eliminate pollutants during the treatment. Acoustic nanotube technology NASA’s Johnson Space Center is the developer of the acoustic nanotube technology. Credit: Inna Bigun / Shutterstock. The acoustic nanotube technology was invented by scientists at Nasa’s Johnson Space Center. It employs acoustics in place of pressure to direct water through small-diameter carbon nanotubes. The technology is based on an acoustically driven molecular screen integrated with carbon nanotubes that allow the passage of water molecules while blocking any larger molecules and contaminants. It consumes less power than traditional filtration systems and drives water away from contaminants instead of removing pollutants from water. The process also eliminates the need for flushing the filter system. The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The ClearZone radiant snow melting system is also commonly used to provide snowmelt for brick and stone paver driveways and sidewalks. The cable is laid out in ...

Free shipping, great prices, and great customer service! Get the best deal on a Caleffi 535381HA. Place items in your cart to find the best deal.

Backflow Preventer LF009 Reduced Pressure Zone Assembly 1/2 Inch Lead Free Bronze Quarter Turn FNPT 0391002 (r,c,s)*

Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

power rating (nominal/program): according to IEC-60268-5 (long term/short term) power rating (peak); maximum SPL: peak, 20 ms with bandpass filtered pink noise signal according to IEC 60268-2 at one octave above the lower limit of the frequency range, with speaker preset weight: net weight without optional equipment cut-off frequency: -10 dB under anechoic halfspace-conditions with speaker preset

We offer solutions for fixed installations and mobile use sound systems for the global market. Acoustics, electronics, mechanics and software form an inseparable unit. The intelligent system amplifiers and digital tools are therefore just as important as the more than 100 types of loudspeakers. Every software and hardware component is engineered and made in the Fohhn company building in Nürtingen, Germany. Fohhn’s ambition goes beyond perfect sound. Because the visual integration of the system is also crucial in many projects. That’s why Fohhn offers numerous customizing options. From special colors, special enclosure lengths and special weather protection to complete custom-builds. The famous Fohhn Beam Steering Technology allows the control of the sound dispersion by mouse wheel. This allows systems to be mounted discreetly straight on the wall without having to be tilted or curved. They can also be optimally integrated into media controls and are designed to meet the needs of modern IT environments. Fohhn is a true partner during a project and supports with planning and simulation all the way to on-site system tuning - in the small conference room, in the cathedral as well as in Europe’s largest opera house.

Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

24 Feb 2022 — To avoid damage due to excess water pressure it is recommended to first check the water pressure at the premises before installing the water filter system.

Since our establishment in 1989, Yooil has built an excellent reputation by commissioning and supervising more than 200 custom-designed rubber dam projects.

The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The large surface-to-volume ratio of nanoparticles enhances the adsorption of chemical and biological particles, while enabling the separation of contaminants at very low concentrations. Nanoadsorbents feature specific physical and chemical properties for the removal of metallic pollutants from water. Carbon nanotubes (CNTs) are considered to be one of the prominent nanomaterials used in water purification. CNT-based filtration systems can remove organic, inorganic and biological compounds from water. Global companies such as Alfa Laval, Applied Membranes, DowDuPont, GEA Group, Inopor, and Koch Membrane Systems are involved in the development of membranes that are made of nanomaterials to eliminate pollutants during the treatment. Acoustic nanotube technology NASA’s Johnson Space Center is the developer of the acoustic nanotube technology. Credit: Inna Bigun / Shutterstock. The acoustic nanotube technology was invented by scientists at Nasa’s Johnson Space Center. It employs acoustics in place of pressure to direct water through small-diameter carbon nanotubes. The technology is based on an acoustically driven molecular screen integrated with carbon nanotubes that allow the passage of water molecules while blocking any larger molecules and contaminants. It consumes less power than traditional filtration systems and drives water away from contaminants instead of removing pollutants from water. The process also eliminates the need for flushing the filter system. The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

Malvern Panalytical provides water treatment solutions that analyse the qualities of dispersed systems, including industrial bulk powders, high-concentration slurries, and aerosols and sprays.

Nanotechnology involves several approaches and processes of applying materials on the atomic or molecular scale. Nanotech-based water purification processes are considered to be modular, highly efficient and cost-effective when compared to conventional water purification methods. The major applications of nanotechnology in water treatment processes include silver, copper and zero-valent iron (ZVI) nanoparticles, nanostructured photocatalysts, nano-membranes, and nanoadsorbents. The large surface-to-volume ratio of nanoparticles enhances the adsorption of chemical and biological particles, while enabling the separation of contaminants at very low concentrations. Nanoadsorbents feature specific physical and chemical properties for the removal of metallic pollutants from water. Carbon nanotubes (CNTs) are considered to be one of the prominent nanomaterials used in water purification. CNT-based filtration systems can remove organic, inorganic and biological compounds from water. Global companies such as Alfa Laval, Applied Membranes, DowDuPont, GEA Group, Inopor, and Koch Membrane Systems are involved in the development of membranes that are made of nanomaterials to eliminate pollutants during the treatment. Acoustic nanotube technology NASA’s Johnson Space Center is the developer of the acoustic nanotube technology. Credit: Inna Bigun / Shutterstock. The acoustic nanotube technology was invented by scientists at Nasa’s Johnson Space Center. It employs acoustics in place of pressure to direct water through small-diameter carbon nanotubes. The technology is based on an acoustically driven molecular screen integrated with carbon nanotubes that allow the passage of water molecules while blocking any larger molecules and contaminants. It consumes less power than traditional filtration systems and drives water away from contaminants instead of removing pollutants from water. The process also eliminates the need for flushing the filter system. The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

Water Technology lists five of the latest water purification technologies that are likely to serve as alternatives to existing water purification processes. Nanotechnology The nanotechnology-based purification processes are considered to be highly efficient and cost-effective. Credit: cybrain / Shutterstock. Nanotechnology involves several approaches and processes of applying materials on the atomic or molecular scale. Nanotech-based water purification processes are considered to be modular, highly efficient and cost-effective when compared to conventional water purification methods. The major applications of nanotechnology in water treatment processes include silver, copper and zero-valent iron (ZVI) nanoparticles, nanostructured photocatalysts, nano-membranes, and nanoadsorbents. The large surface-to-volume ratio of nanoparticles enhances the adsorption of chemical and biological particles, while enabling the separation of contaminants at very low concentrations. Nanoadsorbents feature specific physical and chemical properties for the removal of metallic pollutants from water. Carbon nanotubes (CNTs) are considered to be one of the prominent nanomaterials used in water purification. CNT-based filtration systems can remove organic, inorganic and biological compounds from water. Global companies such as Alfa Laval, Applied Membranes, DowDuPont, GEA Group, Inopor, and Koch Membrane Systems are involved in the development of membranes that are made of nanomaterials to eliminate pollutants during the treatment. Acoustic nanotube technology NASA’s Johnson Space Center is the developer of the acoustic nanotube technology. Credit: Inna Bigun / Shutterstock. The acoustic nanotube technology was invented by scientists at Nasa’s Johnson Space Center. It employs acoustics in place of pressure to direct water through small-diameter carbon nanotubes. The technology is based on an acoustically driven molecular screen integrated with carbon nanotubes that allow the passage of water molecules while blocking any larger molecules and contaminants. It consumes less power than traditional filtration systems and drives water away from contaminants instead of removing pollutants from water. The process also eliminates the need for flushing the filter system. The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

Global companies such as Alfa Laval, Applied Membranes, DowDuPont, GEA Group, Inopor, and Koch Membrane Systems are involved in the development of membranes that are made of nanomaterials to eliminate pollutants during the treatment. Acoustic nanotube technology NASA’s Johnson Space Center is the developer of the acoustic nanotube technology. Credit: Inna Bigun / Shutterstock. The acoustic nanotube technology was invented by scientists at Nasa’s Johnson Space Center. It employs acoustics in place of pressure to direct water through small-diameter carbon nanotubes. The technology is based on an acoustically driven molecular screen integrated with carbon nanotubes that allow the passage of water molecules while blocking any larger molecules and contaminants. It consumes less power than traditional filtration systems and drives water away from contaminants instead of removing pollutants from water. The process also eliminates the need for flushing the filter system. The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The acoustic nanotube technology was invented by scientists at Nasa’s Johnson Space Center. It employs acoustics in place of pressure to direct water through small-diameter carbon nanotubes. The technology is based on an acoustically driven molecular screen integrated with carbon nanotubes that allow the passage of water molecules while blocking any larger molecules and contaminants. It consumes less power than traditional filtration systems and drives water away from contaminants instead of removing pollutants from water. The process also eliminates the need for flushing the filter system. The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

Regulator Repair Kit for 2" Diaphragm, CO2 Regulators, with Diaphragm, Capsule, and Flat Tank Seal. $14.51

Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

Since our establishment in 1989, Yooil has built an excellent reputation by commissioning and supervising more than 200 custom-designed rubber dam projects.

Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The technology is based on an acoustically driven molecular screen integrated with carbon nanotubes that allow the passage of water molecules while blocking any larger molecules and contaminants. It consumes less power than traditional filtration systems and drives water away from contaminants instead of removing pollutants from water. The process also eliminates the need for flushing the filter system. The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The high-stability Viscotek UV detector is ideally suited for multi-detection GPC/SEC. Accurate measurement of the polymer or protein concentration profile is essential to good molecular weight or structure data.

Global water treatment product manufacturers are exploring state-of-the-art water filtration technologies such as carbon nanotubes and advanced membrane systems to better serve their customers.

Global water treatment product manufacturers are exploring state-of-the-art water filtration technologies such as carbon nanotubes and advanced membrane systems to better serve their customers. Water Technology lists five of the latest water purification technologies that are likely to serve as alternatives to existing water purification processes. Nanotechnology The nanotechnology-based purification processes are considered to be highly efficient and cost-effective. Credit: cybrain / Shutterstock. Nanotechnology involves several approaches and processes of applying materials on the atomic or molecular scale. Nanotech-based water purification processes are considered to be modular, highly efficient and cost-effective when compared to conventional water purification methods. The major applications of nanotechnology in water treatment processes include silver, copper and zero-valent iron (ZVI) nanoparticles, nanostructured photocatalysts, nano-membranes, and nanoadsorbents. The large surface-to-volume ratio of nanoparticles enhances the adsorption of chemical and biological particles, while enabling the separation of contaminants at very low concentrations. Nanoadsorbents feature specific physical and chemical properties for the removal of metallic pollutants from water. Carbon nanotubes (CNTs) are considered to be one of the prominent nanomaterials used in water purification. CNT-based filtration systems can remove organic, inorganic and biological compounds from water. Global companies such as Alfa Laval, Applied Membranes, DowDuPont, GEA Group, Inopor, and Koch Membrane Systems are involved in the development of membranes that are made of nanomaterials to eliminate pollutants during the treatment. Acoustic nanotube technology NASA’s Johnson Space Center is the developer of the acoustic nanotube technology. Credit: Inna Bigun / Shutterstock. The acoustic nanotube technology was invented by scientists at Nasa’s Johnson Space Center. It employs acoustics in place of pressure to direct water through small-diameter carbon nanotubes. The technology is based on an acoustically driven molecular screen integrated with carbon nanotubes that allow the passage of water molecules while blocking any larger molecules and contaminants. It consumes less power than traditional filtration systems and drives water away from contaminants instead of removing pollutants from water. The process also eliminates the need for flushing the filter system. The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The PS-850 is a powerful and flexible double 18" subwoofer from the Perform series. The passive sub with direct dispersion and vented enclosure is the perfect complement to the Focus Venue modules and the PT-70 speaker. In conjunction with the DSP-driven DI amplifiers, it provides precise and powerful sound for concert halls, clubs, stadiums and open-air events. The PS-850 is perfectly suitable for horizontal, vertical or end fired sub-arrays, but also for cardioid setups.

Carbon nanotubes (CNTs) are considered to be one of the prominent nanomaterials used in water purification. CNT-based filtration systems can remove organic, inorganic and biological compounds from water. Global companies such as Alfa Laval, Applied Membranes, DowDuPont, GEA Group, Inopor, and Koch Membrane Systems are involved in the development of membranes that are made of nanomaterials to eliminate pollutants during the treatment. Acoustic nanotube technology NASA’s Johnson Space Center is the developer of the acoustic nanotube technology. Credit: Inna Bigun / Shutterstock. The acoustic nanotube technology was invented by scientists at Nasa’s Johnson Space Center. It employs acoustics in place of pressure to direct water through small-diameter carbon nanotubes. The technology is based on an acoustically driven molecular screen integrated with carbon nanotubes that allow the passage of water molecules while blocking any larger molecules and contaminants. It consumes less power than traditional filtration systems and drives water away from contaminants instead of removing pollutants from water. The process also eliminates the need for flushing the filter system. The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The primary applications of acoustic nanotube technology are municipal water plants, medical facilities, laboratories, distilleries, desalination plants, industrial facilities, wastewater treatment plants, and consumer segment. The innovation is scalable with the integration of multiple filters, according to the filtration needs of users. Nasa’s patented acoustic nanotube technology is available for the firms to license and evolve into a commercial water purification product offering. Photocatalytic water purification technology A demonstration machine of photocatalytic water purification technology developed by Panasonic. Credit: Panasonic Corporation. Water treatment using photocatalysis has gained prominence in recent years due to its efficiency in treating contaminated water. The technology utilises photocatalyst and ultraviolet (UV) rays to remove toxic substances from water. Panasonic developed a technology that binds the photocatalyst (titanium dioxide) to a commercial adsorbent and a catalyst called zeolite, ensuring effective separation and recovery of photocatalysts from the water for reuse. Titanium dioxide can mineralise a range of organic compounds into safe end products. The catalyst uses UV radiation either from sunlight or artificial light to separate substances. Photocatalysis can break down a range of organic materials, estrogens, pesticides, dyes, crude oil, and microbes such as viruses and chlorine-resistant pathogens, as well as inorganic compounds such as nitrous oxides. Photocatalytic water treatment systems are suitable for use in water and wastewater treatment facilities and can treat industrial wastewater polluted with high loads of organic substances or metals. Aquaporin Inside™ technology The unique architecture of aquaporins enable rapid, highly selective water transfer across the cell membrane. Credit: Art of Science / Shutterstock. Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

The T304 Tank Pressure and Vacuum Relief Valve will open at pressures exceeding 15 psi to prevent over pressurizing. Great for beer & wine.

The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

Montagna offers UV water disinfection systems that can be used in any application where water requires cleaning or treatment.

825Y Product Image. FRK 825Y-RT 1 1/2-2. UPC: 643925003703. Ordering Code: 905112. Complete Rubber Parts Kit For 1 1/2 and 2 IN Reduced Pressure Zone Assembly.

Aquaporin Inside™ technology from Danish cleantech company Aquaporin is based on the bio-mimetic water treatment membrane design. Aquaporins enable quick and highly selective water transfer across the cell membrane. They allow the cell to regularise its volume and internal osmotic pressure in line with the hydrostatic and osmotic pressure differences. The aquaporin channel’s distinct architecture allows the passage of water molecules and blocks all other compounds. The natural bio-mimetic membranes also serve as a basis for the development of artificial bio-mimetic membrane systems. The technology is being used in industrial and household water filtration and purification systems. The Aquaporin Inside membranes are the only membranes in the market to employ aquaporins to purify drinking water. The membranes are available for both forward osmosis (FO) and reverse osmosis (RO) applications. The Aquaporin Space Alliance (ASA), a joint venture between Aquaporin and Danish Aerospace Company (DAS) is commercialising the patented Aquaporin Inside™ technology in space applications and space programmes, in collaboration with European and US-based firms. Automatic Variable Filtration (AVF) technology The automated variable filtration (AVF) systems can be used in municipal drinking water and wastewater treatment facilities. Credit: Dmitri Ma / Shutterstock. Automated Variable Filtration (AVF) technology involves a simple process where upward flow of influent is cleaned by downward flow of filter media. It eliminates the need for any additional process or freshwater for filter media cleaning. The AVF method employs continuously cleaned descending bed filters embedded in a variable array. The two-stage configuration of the system integrates two sets of media filters that can function either in serial or parallel mode. The process delivers water with quality equivalent to that of micro-filtration technology and at a fraction of the cost of low-pressure membranes. It features no moving parts and consumes less power, offerings savings on reduced operating and maintenance costs. AVF systems are suitable for municipal drinking water and wastewater treatment, wastewater recycling and reuse, pre-filtration for membrane processes and desalination applications. R2O Water Technologies, Process Research ORTECH (PRO), and Eureka Forbes are some of the major companies involved in the development of AVF technology-based products and services.

Nobody likes spam - neither do we. From time to time you will instead receive news, announcements and knowledge tranfser relevant to you from our pro audio experts.

Malvern Panalytical provides water treatment solutions that analyse the qualities of dispersed systems, including industrial bulk powders, high-concentration slurries, and aerosols and sprays.

11 Oct 2024 — Water heater installation usually requires a plumbing permit, so you'll find out about any expansion tank requirements when you file for your ...

A pressure regulating valve reduces the pressure in a mains supply to a safe level, while relief valves offer an easy way for excess pressure to escape ...

Montagna offers UV water disinfection systems that can be used in any application where water requires cleaning or treatment.