Drinking water purification

Around the world, home drinking water purification systems, which include a reverse osmosis stage, are commonly used to improve water for drinking and cooking.

These systems usually include a series of steps:

• - a sediment filter to trap particles, including rust and calcium carbonate.

• - optionally, a second sediment filter with smaller pores.

• - an activated carbon filter to trap organic chemicals and chlorine, which attack and degrade certain types of thin film composite membranes.

• - a reverse osmosis filter, which is a thin film composite membrane.

• - optionally, an ultraviolet lamp to sterilize microbes that may escape the filtration of the reverse osmosis membrane.

• - optionally, a second carbon filter to capture chemicals not removed by the reverse osmosis membrane.

In some systems, the carbon prefilter is omitted and a cellulose triacetate membrane is used. (Cellulose triacetate) is a paper by-product membrane bonded to a synthetic coating and is manufactured to allow contact with chlorine in water. These require a small amount of chlorine in the water source to prevent bacteria from forming in it. The typical rejection rate of these membranes is 85-95%.

The cellulose triacetate membrane is prone to rotting unless protected by chlorinated water, while the thin film composite membrane is prone to breaking down under the influence of chlorine. Thin film composite (TFC) membrane is made of synthetic material and requires chlorine removal before water enters the membrane. To protect the TFC membrane elements from chlorine damage, carbon filters are used as pretreatment in all residential reverse osmosis systems. TFC membranes have a higher rejection rate of 95-98% and longer life than cellulose triacetate membranes.

Portable reverse osmosis water processors are sold for personal water purification in various locations. To work effectively, the water feeding these units must be under a certain pressure (280 kPa (40 psi) or more is the norm).[9]​ Portable reverse osmosis water processors can be used by people living in rural areas without running water, far from city water mains. Rural residents filter river or ocean water themselves, as the device is easy to use (saline water may require special membranes). Some travelers taking long boat trips, fishing, or camping on islands, or in countries where the local water supply is contaminated or deficient, use reverse osmosis water processors combined with one or more ultraviolet sterilizers.

In the production of bottled mineral water, the water passes through a reverse osmosis water processor to remove contaminants and microorganisms. However, in European countries, this type of processing of natural mineral water (as defined by a European directive[10]​) is not permitted by European legislation. In practice, a fraction of live bacteria can and do pass through reverse osmosis membranes through small imperfections, or bypass the membrane entirely through small leaks in the surrounding joints. Therefore, complete reverse osmosis systems may include additional water treatment stages that use ultraviolet light or ozone to prevent microbiological contamination.

The pore size of the membranes can vary from 0.1 to 5,000 nm depending on the type of filter. Particle filtration removes particles 1 µm "Micrometer (unit of length)") or larger. Microfiltration removes particles 50 nm or larger. Ultrafiltration removes particles of approximately 3 nm or larger. Nanofiltration removes particles 1 nm or larger. Reverse osmosis belongs to the last category of membrane filtration, hyperfiltration, and removes particles larger than 0.1 nm.[11]​ For domestic water filtration when it is not necessary to remove excess dissolved minerals (soften the water), the alternative to reverse osmosis filtration is an activated carbon filter with a microfiltration membrane.

A solar desalination unit produces drinking water from saline water using a photovoltaic system that converts solar energy into that needed for reverse osmosis. Due to the high availability of sunlight in different geographic areas, solar reverse osmosis lends itself well to the purification of drinking water in remote locations that lack an electrical grid. Additionally, solar energy exceeds the operating costs and greenhouse emissions of conventional reverse osmosis systems, making it a sustainable freshwater solution compatible with developing contexts. For example, a solar-powered desalination unit designed for remote communities has been successfully trialled in the Northern Territory of Australia.[12]​.

Although the intermittent nature of sunlight and its varying intensity throughout the day make it difficult to predict PV efficiency and desalination at night, several solutions exist. For example, batteries, which provide the energy needed for desalination during non-sunny hours, can be used to store solar energy during the day. Apart from the use of conventional batteries, there are alternative methods to store solar energy. For example, thermal energy storage systems solve this storage problem and ensure consistent performance even during hours without sunlight and cloudy days, improving overall efficiency.[13]​.

A reverse osmosis water purification unit (ROWPU) is a portable, self-contained water treatment plant. Designed for military use, it can provide drinking water from almost any water source. The armed forces of some states use many models. Some models are containers, some are trailers, and some are vehicles themselves.

Each branch of the military has its own model series of reverse osmosis water purification units, but they are all similar. Water is pumped from its raw source to the reverse osmosis water purification unit module, where it is treated with a polymer to initiate coagulation. It then passes through a multi-media filter where it undergoes primary treatment to remove turbidity. It is then pumped through a cartridge filter which is usually spirally wound cotton. This process clarifies the water of any particles larger than 5 µm and eliminates almost all turbidity.

The clarified water is then introduced via a high-pressure piston pump into a series of containers where it undergoes reverse osmosis. The produced water is free of 90.00-99.98% of the total dissolved solids of the raw water and, according to military standards, should be no more than 1000-1500 parts per million depending on the measurement of electrical conductivity. It is then disinfected with chlorine and stored for later use.

Water and wastewater purification

Rainwater collected from storm drains is purified by reverse osmosis water processors and used for landscape irrigation and industrial cooling in Los Angeles and other cities, as a solution to the problem of water scarcity.

In industry, reverse osmosis removes minerals from power plant boiler water.[14] The water is distilled several times. It must be as pure as possible so that it does not leave deposits on the machinery or cause corrosion. Deposits on the inside or outside of the boiler tubes can cause poor boiler performance, reducing its efficiency and leading to poor steam production and therefore poor power production in the turbine.

It is also used to clean effluents and brackish groundwater. Larger volume effluents (more than 500 m/day) must be treated first in an effluent treatment plant and then the cleaned effluent is subjected to the reverse osmosis system. The cost of treatment is considerably reduced and the useful life of the reverse osmosis system membrane is increased.

The reverse osmosis process can be used for the production of deionized water.[15]​.

The reverse osmosis process for water purification does not require thermal energy. Continuous flow reverse osmosis systems can be regulated by high pressure pumps. The recovery of purified water depends on several factors such as membrane size, membrane pore size, temperature, operating pressure and membrane surface area.

In 2002, Singapore announced that a process called NEWater would be an important part of its future water plans. It involves using reverse osmosis to treat domestic wastewater before discharging NEWater back into reservoirs.

Food industry

In addition to desalination, reverse osmosis is a more economical operation for concentrating food liquids (such as fruit juices) than conventional heat treatment processes. Research has been carried out on the concentration of orange and tomato juice. Its advantages include lower running costs and the ability to avoid heat treatment processes, making it suitable for heat-sensitive substances such as proteins and enzymes found in most food products.

Reverse osmosis is widely used in the dairy industry for the production of whey protein powder and for milk concentration to reduce shipping costs. In whey applications, whey (liquid left after cheese making) is concentrated with reverse osmosis from 6% total solids to 10-20% total solids before processing by ultrafiltration. The ultrafiltration retentate can then be used to manufacture various whey powders, including whey protein isolate. Additionally, the ultrafiltration permeate, which contains lactose, is concentrated by reverse osmosis from 5% total solids to 18-22% total solids to reduce the costs of crystallization and drying of lactose powder.

Although the use of this process was once avoided in the wine industry, it is now widely known and used. In 2002, it is estimated that there were 60 reverse osmosis machines in Bordeaux, France. Known users include many of the elite (Kramer) wines, such as Château Léoville-Las Cases from Bordeaux.

Maple syrup production

In 1946, some maple syrup producers began using reverse osmosis to remove water from the sap before boiling it into syrup. The use of reverse osmosis allows removing around 75-90% of the water from the sap, reducing energy consumption and exposure of the syrup to high temperatures. Microbial contamination and membrane degradation must be monitored.

Low alcohol beer

When beer with a normal alcohol concentration is subjected to reverse osmosis, both water and alcohol pass through the membrane more easily than the other components, leaving a "beer concentrate." The concentrate is then diluted with fresh water to return the non-volatile components to their original intensity.[16]​.

Hydrogen production

For small-scale hydrogen production, reverse osmosis is sometimes used to prevent the formation of mineral deposits on the surface of the electrodes.

Contenido

Muchos acuariófilos de arrecife utilizan sistemas de ósmosis inversa para su mezcla artificial de agua de mar. El agua corriente del grifo puede contener un exceso de cloro, cloraminas, cobre, nitratos, nitritos, fosfatos, silicatos "Silicato (mineral)") o muchas otras sustancias químicas perjudiciales para los organismos sensibles de un entorno de arrecife. Contaminantes como los compuestos nitrogenados y los fosfatos pueden provocar un crecimiento excesivo e indeseado de algas. Una combinación eficaz de ósmosis inversa y desionización es la más popular entre los acuariófilos de arrecife, y se prefiere a otros procesos de purificación del agua debido al bajo coste de propiedad y los mínimos gastos de funcionamiento. Cuando hay cloro y cloraminas en el agua, es necesaria la filtración por carbono antes de la membrana, ya que la membrana residencial común utilizada por los acuariófilos de arrecife no puede con estos compuestos.

Los acuaristas de agua dulce también utilizan sistemas de ósmosis inversa para replicar las aguas muy blandas de muchas masas de agua tropicales. Aunque muchos peces tropicales pueden sobrevivir en agua del grifo convenientemente tratada, la cría puede resultar imposible. Muchas tiendas de acuariofilia venden contenedores de agua de ósmosis inversa para este fin.

Window cleaning

An increasingly popular method of window cleaning is the so-called "water-fed pole" system. Instead of washing windows with detergent in the conventional way, they are scrubbed with highly purified water, usually containing less than 10 ppm dissolved solids, using a brush on the end of a long pole operated from ground level. Reverse osmosis is usually used to purify water.

Reverse osmosis membranes have the potential to become clogged and damaged over time, which can lead to reduced lifespan and effectiveness. For this reason, their recycling is essential to reduce the amount of waste that goes to landfills, as well as reducing pollution, the exploitation of natural resources, costs and energy.

Before addressing the recycling process, the first step is to identify the main parts of RO membranes and their composition. The structure and its corresponding composition are explained below.[17]​.

Therefore, taking all this data into account, the recycling of these units is carried out through the following processes: mechanical recycling, chemical recycling and energy recovery.

Mechanical recycling.

Mechanical recycling is the technique that recovers waste materials and transforms them into new goods through the action of mechanical forces. This recycling method consists of 5 stages. First, the unit is collected. Secondly, the first classification is carried out, which consists of classifying the waste by type of material (manually) and then by type of polymer using a spectrophotometer. Subsequently, they are washed to remove any dust or dirt in the washing phase. This cleaning procedure is essential to guarantee the quality of recycled products, as well as to prevent damage to machinery. Subsequently, crushing occurs, which involves crushing through the action of a crusher. Finally, the extrusion stage takes place. The latter a continuous plastic conversion technology that involves the plastic deformation of crushed plastic through the action of a screw rotating in a heated barrel. In this way, the molten plastic is pushed through a matrix and the resulting product is characterized by having a constant cross section.[1].

Regarding RO membranes, this technique is used for ABS, PET and PP components, i.e. the center tube, end caps and spacers.

Chemical recycling.

Chemical recycling in reverse osmosis membranes is any recycling or reuse process using chemical compounds. This type of recycling has the greatest potential to overcome the limitations of mechanical recycling. However, its technology has not yet been developed enough, so its use is less. This is due to the complexity and price of the process.

So, depending on the conditions of the RO membrane, two types of recycling can be distinguished:[18]​.

• - Direct chemical recycling: This branch of chemical recycling consists of the total elimination of accumulated fouling using an oxidizing agent, with a partial or total degradation of the polyamide layer as a consequence. In this type of recycling, the entire membrane unit is treated and it cannot be soiled by more than 25 kg or physically damaged. This process consists of 3 stages:[19]​

1. Membrane autopsy and cleaning: The membrane is stored in humid conditions and an autopsy of the membrane is performed before cleaning procedures. In standard membrane system cleaning procedures, membranes are gently brushed for exactly 5 minutes while immersed in a series of different pH solutions, as follows: 7.0 (HO), 11 (NaOH), 7.4 (HNO), and 7.0 (HO).

2. Membrane oxidation: Different chemical compounds have historically been tested for the oxidation stage. Among them, NaClO treatment achieved the highest permeability in recycled membranes. Furthermore, the NaClO solution had better chemical stability and reusability, allowing the production of a lower volume of effluent in a large-scale application. Exposure to a concentrated free chlorine solution eliminates membrane fouling, while the dense polyamide layer is intentionally degraded, either partially, achieving NF properties, or completely, achieving UF properties.

3. Investigation of the performance of the new membrane: Finally, the membrane is tested based on the new application.

• - Indirect chemical recycling: In indirect chemical recycling, the pieces of the RO membrane are treated individually. This is because the membrane is already soiled by more than 25 kg and/or may be physically damaged, so the reuse method cannot be applied. The objective is the decomposition of these synthetic materials through chemical reactions to obtain the constituent compounds and reuse them. So, each component has its respective recycling process, therefore, it depends only on the material that that piece is made of. These processes typically use the principle of depolymerization of the substance, but there may also be other types of processes such as devulcanization of rubber.[18]​.

• - reverse osmosis (RO).

• - Spanish stroke database Archived May 8, 2016 at the Wayback Machine.

• - Communicate Science UPF Archived July 27, 2018 at the Wayback Machine.

• - What is reverse osmosis?

Drinking water purification

Around the world, home drinking water purification systems, which include a reverse osmosis stage, are commonly used to improve water for drinking and cooking.

These systems usually include a series of steps:

• - a sediment filter to trap particles, including rust and calcium carbonate.

• - optionally, a second sediment filter with smaller pores.

• - an activated carbon filter to trap organic chemicals and chlorine, which attack and degrade certain types of thin film composite membranes.

• - a reverse osmosis filter, which is a thin film composite membrane.

• - optionally, an ultraviolet lamp to sterilize microbes that may escape the filtration of the reverse osmosis membrane.

• - optionally, a second carbon filter to capture chemicals not removed by the reverse osmosis membrane.

In some systems, the carbon prefilter is omitted and a cellulose triacetate membrane is used. (Cellulose triacetate) is a paper by-product membrane bonded to a synthetic coating and is manufactured to allow contact with chlorine in water. These require a small amount of chlorine in the water source to prevent bacteria from forming in it. The typical rejection rate of these membranes is 85-95%.

The cellulose triacetate membrane is prone to rotting unless protected by chlorinated water, while the thin film composite membrane is prone to breaking down under the influence of chlorine. Thin film composite (TFC) membrane is made of synthetic material and requires chlorine removal before water enters the membrane. To protect the TFC membrane elements from chlorine damage, carbon filters are used as pretreatment in all residential reverse osmosis systems. TFC membranes have a higher rejection rate of 95-98% and longer life than cellulose triacetate membranes.

Portable reverse osmosis water processors are sold for personal water purification in various locations. To work effectively, the water feeding these units must be under a certain pressure (280 kPa (40 psi) or more is the norm).[9]​ Portable reverse osmosis water processors can be used by people living in rural areas without running water, far from city water mains. Rural residents filter river or ocean water themselves, as the device is easy to use (saline water may require special membranes). Some travelers taking long boat trips, fishing, or camping on islands, or in countries where the local water supply is contaminated or deficient, use reverse osmosis water processors combined with one or more ultraviolet sterilizers.

In the production of bottled mineral water, the water passes through a reverse osmosis water processor to remove contaminants and microorganisms. However, in European countries, this type of processing of natural mineral water (as defined by a European directive[10]​) is not permitted by European legislation. In practice, a fraction of live bacteria can and do pass through reverse osmosis membranes through small imperfections, or bypass the membrane entirely through small leaks in the surrounding joints. Therefore, complete reverse osmosis systems may include additional water treatment stages that use ultraviolet light or ozone to prevent microbiological contamination.

The pore size of the membranes can vary from 0.1 to 5,000 nm depending on the type of filter. Particle filtration removes particles 1 µm "Micrometer (unit of length)") or larger. Microfiltration removes particles 50 nm or larger. Ultrafiltration removes particles of approximately 3 nm or larger. Nanofiltration removes particles 1 nm or larger. Reverse osmosis belongs to the last category of membrane filtration, hyperfiltration, and removes particles larger than 0.1 nm.[11]​ For domestic water filtration when it is not necessary to remove excess dissolved minerals (soften the water), the alternative to reverse osmosis filtration is an activated carbon filter with a microfiltration membrane.

A solar desalination unit produces drinking water from saline water using a photovoltaic system that converts solar energy into that needed for reverse osmosis. Due to the high availability of sunlight in different geographic areas, solar reverse osmosis lends itself well to the purification of drinking water in remote locations that lack an electrical grid. Additionally, solar energy exceeds the operating costs and greenhouse emissions of conventional reverse osmosis systems, making it a sustainable freshwater solution compatible with developing contexts. For example, a solar-powered desalination unit designed for remote communities has been successfully trialled in the Northern Territory of Australia.[12]​.

Although the intermittent nature of sunlight and its varying intensity throughout the day make it difficult to predict PV efficiency and desalination at night, several solutions exist. For example, batteries, which provide the energy needed for desalination during non-sunny hours, can be used to store solar energy during the day. Apart from the use of conventional batteries, there are alternative methods to store solar energy. For example, thermal energy storage systems solve this storage problem and ensure consistent performance even during hours without sunlight and cloudy days, improving overall efficiency.[13]​.

A reverse osmosis water purification unit (ROWPU) is a portable, self-contained water treatment plant. Designed for military use, it can provide drinking water from almost any water source. The armed forces of some states use many models. Some models are containers, some are trailers, and some are vehicles themselves.

Each branch of the military has its own model series of reverse osmosis water purification units, but they are all similar. Water is pumped from its raw source to the reverse osmosis water purification unit module, where it is treated with a polymer to initiate coagulation. It then passes through a multi-media filter where it undergoes primary treatment to remove turbidity. It is then pumped through a cartridge filter which is usually spirally wound cotton. This process clarifies the water of any particles larger than 5 µm and eliminates almost all turbidity.

The clarified water is then introduced via a high-pressure piston pump into a series of containers where it undergoes reverse osmosis. The produced water is free of 90.00-99.98% of the total dissolved solids of the raw water and, according to military standards, should be no more than 1000-1500 parts per million depending on the measurement of electrical conductivity. It is then disinfected with chlorine and stored for later use.

Water and wastewater purification

Rainwater collected from storm drains is purified by reverse osmosis water processors and used for landscape irrigation and industrial cooling in Los Angeles and other cities, as a solution to the problem of water scarcity.

In industry, reverse osmosis removes minerals from power plant boiler water.[14] The water is distilled several times. It must be as pure as possible so that it does not leave deposits on the machinery or cause corrosion. Deposits on the inside or outside of the boiler tubes can cause poor boiler performance, reducing its efficiency and leading to poor steam production and therefore poor power production in the turbine.

It is also used to clean effluents and brackish groundwater. Larger volume effluents (more than 500 m/day) must be treated first in an effluent treatment plant and then the cleaned effluent is subjected to the reverse osmosis system. The cost of treatment is considerably reduced and the useful life of the reverse osmosis system membrane is increased.

The reverse osmosis process can be used for the production of deionized water.[15]​.

The reverse osmosis process for water purification does not require thermal energy. Continuous flow reverse osmosis systems can be regulated by high pressure pumps. The recovery of purified water depends on several factors such as membrane size, membrane pore size, temperature, operating pressure and membrane surface area.

In 2002, Singapore announced that a process called NEWater would be an important part of its future water plans. It involves using reverse osmosis to treat domestic wastewater before discharging NEWater back into reservoirs.

Food industry

In addition to desalination, reverse osmosis is a more economical operation for concentrating food liquids (such as fruit juices) than conventional heat treatment processes. Research has been carried out on the concentration of orange and tomato juice. Its advantages include lower running costs and the ability to avoid heat treatment processes, making it suitable for heat-sensitive substances such as proteins and enzymes found in most food products.

Reverse osmosis is widely used in the dairy industry for the production of whey protein powder and for milk concentration to reduce shipping costs. In whey applications, whey (liquid left after cheese making) is concentrated with reverse osmosis from 6% total solids to 10-20% total solids before processing by ultrafiltration. The ultrafiltration retentate can then be used to manufacture various whey powders, including whey protein isolate. Additionally, the ultrafiltration permeate, which contains lactose, is concentrated by reverse osmosis from 5% total solids to 18-22% total solids to reduce the costs of crystallization and drying of lactose powder.

Although the use of this process was once avoided in the wine industry, it is now widely known and used. In 2002, it is estimated that there were 60 reverse osmosis machines in Bordeaux, France. Known users include many of the elite (Kramer) wines, such as Château Léoville-Las Cases from Bordeaux.

Maple syrup production

In 1946, some maple syrup producers began using reverse osmosis to remove water from the sap before boiling it into syrup. The use of reverse osmosis allows removing around 75-90% of the water from the sap, reducing energy consumption and exposure of the syrup to high temperatures. Microbial contamination and membrane degradation must be monitored.

Low alcohol beer

When beer with a normal alcohol concentration is subjected to reverse osmosis, both water and alcohol pass through the membrane more easily than the other components, leaving a "beer concentrate." The concentrate is then diluted with fresh water to return the non-volatile components to their original intensity.[16]​.

Hydrogen production

For small-scale hydrogen production, reverse osmosis is sometimes used to prevent the formation of mineral deposits on the surface of the electrodes.

Contenido

Muchos acuariófilos de arrecife utilizan sistemas de ósmosis inversa para su mezcla artificial de agua de mar. El agua corriente del grifo puede contener un exceso de cloro, cloraminas, cobre, nitratos, nitritos, fosfatos, silicatos "Silicato (mineral)") o muchas otras sustancias químicas perjudiciales para los organismos sensibles de un entorno de arrecife. Contaminantes como los compuestos nitrogenados y los fosfatos pueden provocar un crecimiento excesivo e indeseado de algas. Una combinación eficaz de ósmosis inversa y desionización es la más popular entre los acuariófilos de arrecife, y se prefiere a otros procesos de purificación del agua debido al bajo coste de propiedad y los mínimos gastos de funcionamiento. Cuando hay cloro y cloraminas en el agua, es necesaria la filtración por carbono antes de la membrana, ya que la membrana residencial común utilizada por los acuariófilos de arrecife no puede con estos compuestos.

Los acuaristas de agua dulce también utilizan sistemas de ósmosis inversa para replicar las aguas muy blandas de muchas masas de agua tropicales. Aunque muchos peces tropicales pueden sobrevivir en agua del grifo convenientemente tratada, la cría puede resultar imposible. Muchas tiendas de acuariofilia venden contenedores de agua de ósmosis inversa para este fin.

Window cleaning

An increasingly popular method of window cleaning is the so-called "water-fed pole" system. Instead of washing windows with detergent in the conventional way, they are scrubbed with highly purified water, usually containing less than 10 ppm dissolved solids, using a brush on the end of a long pole operated from ground level. Reverse osmosis is usually used to purify water.

Reverse osmosis membranes have the potential to become clogged and damaged over time, which can lead to reduced lifespan and effectiveness. For this reason, their recycling is essential to reduce the amount of waste that goes to landfills, as well as reducing pollution, the exploitation of natural resources, costs and energy.

Before addressing the recycling process, the first step is to identify the main parts of RO membranes and their composition. The structure and its corresponding composition are explained below.[17]​.

Therefore, taking all this data into account, the recycling of these units is carried out through the following processes: mechanical recycling, chemical recycling and energy recovery.

Mechanical recycling.

Mechanical recycling is the technique that recovers waste materials and transforms them into new goods through the action of mechanical forces. This recycling method consists of 5 stages. First, the unit is collected. Secondly, the first classification is carried out, which consists of classifying the waste by type of material (manually) and then by type of polymer using a spectrophotometer. Subsequently, they are washed to remove any dust or dirt in the washing phase. This cleaning procedure is essential to guarantee the quality of recycled products, as well as to prevent damage to machinery. Subsequently, crushing occurs, which involves crushing through the action of a crusher. Finally, the extrusion stage takes place. The latter a continuous plastic conversion technology that involves the plastic deformation of crushed plastic through the action of a screw rotating in a heated barrel. In this way, the molten plastic is pushed through a matrix and the resulting product is characterized by having a constant cross section.[1].

Regarding RO membranes, this technique is used for ABS, PET and PP components, i.e. the center tube, end caps and spacers.

Chemical recycling.

Chemical recycling in reverse osmosis membranes is any recycling or reuse process using chemical compounds. This type of recycling has the greatest potential to overcome the limitations of mechanical recycling. However, its technology has not yet been developed enough, so its use is less. This is due to the complexity and price of the process.

So, depending on the conditions of the RO membrane, two types of recycling can be distinguished:[18]​.

• - Direct chemical recycling: This branch of chemical recycling consists of the total elimination of accumulated fouling using an oxidizing agent, with a partial or total degradation of the polyamide layer as a consequence. In this type of recycling, the entire membrane unit is treated and it cannot be soiled by more than 25 kg or physically damaged. This process consists of 3 stages:[19]​

1. Membrane autopsy and cleaning: The membrane is stored in humid conditions and an autopsy of the membrane is performed before cleaning procedures. In standard membrane system cleaning procedures, membranes are gently brushed for exactly 5 minutes while immersed in a series of different pH solutions, as follows: 7.0 (HO), 11 (NaOH), 7.4 (HNO), and 7.0 (HO).

2. Membrane oxidation: Different chemical compounds have historically been tested for the oxidation stage. Among them, NaClO treatment achieved the highest permeability in recycled membranes. Furthermore, the NaClO solution had better chemical stability and reusability, allowing the production of a lower volume of effluent in a large-scale application. Exposure to a concentrated free chlorine solution eliminates membrane fouling, while the dense polyamide layer is intentionally degraded, either partially, achieving NF properties, or completely, achieving UF properties.

3. Investigation of the performance of the new membrane: Finally, the membrane is tested based on the new application.

• - Indirect chemical recycling: In indirect chemical recycling, the pieces of the RO membrane are treated individually. This is because the membrane is already soiled by more than 25 kg and/or may be physically damaged, so the reuse method cannot be applied. The objective is the decomposition of these synthetic materials through chemical reactions to obtain the constituent compounds and reuse them. So, each component has its respective recycling process, therefore, it depends only on the material that that piece is made of. These processes typically use the principle of depolymerization of the substance, but there may also be other types of processes such as devulcanization of rubber.[18]​.

• - reverse osmosis (RO).

• - Spanish stroke database Archived May 8, 2016 at the Wayback Machine.

• - Communicate Science UPF Archived July 27, 2018 at the Wayback Machine.

• - What is reverse osmosis?