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RECOMMENDED by leading infection control experts worldwide.
EFFECTIVE against virtually all common bacteria, viruses and spores.
COMPACT AND SAFE to handle and store - reduce storage and transport costs.
LESS TOXIC AND LESS CORROSIVE than other chlorine compounds.
What´s included ?
A palletized customized for specific population size kit is available on demand, boxed and ready to ship.
Upon request, the customized kit can include salt, additional containers, pumps, flocculant,…
Request an offer ! info@bulane.com
Device
Method
Market
About chlorination
Device (answers)
Method (answers)
Market (answers)
About chlorination (answers)
RECOMMENDED by leading infection control experts worldwide.
EFFECTIVE against virtually all common bacteria, viruses and spores.
COMPACT AND SAFE to handle and store - reduce storage and transport costs.
LESS TOXIC AND LESS CORROSIVE than other chlorine compounds.
Safe water & efficient disinfection anytime, anywhere !
 Watalys is a point of use generation of sodium hypochlorite. It is a lightweight portable device (13.5 cm - 176 grams) designed for 12V field operations.Sodium hypochlorite is the solution provided by Watalys acting as a powerful disinfectant used for water potabilization and disinfection. One Watalys device provides safe water for 100 to 6,000 people everyday for several years. Besides, the innovative design enables simple and efficient upward scalability, pushing the upper capacity limit to a theoretical infinite population. Watalys use leading edge technology titan electrodes with sophisticated proprietary coating which provide an utmost Cl2 production yield. Under nominal conditions, one device generates up to 14 grams Cl2 per hour. It is robust and has been developed with the field constrains as key technical specifications. It operates on car battery, solar panel or any ad hoc 12V DC source. No maintenance is required other than rinsing with clear water. Watalys is well designed and well suited for NGO´s and institutions dealing with health, potabilization and sanitation. |
Downloads
Watalys® Flyer (English - 618KB)
Watalys® Flyer (French - 627KB)
Watalys® Flyer (Spain - 378KB)
Watalys® Flyer (Portuguese - 379KB)
Watalys® User Guide (English - 871KB)
Watalys® User Guide (French - 885KB)
Watalys® Datasheet (English - 178KB)
WHO - Guidelines for Drinking-water Quality (English - 5.2MB)
Frequently Asked Questions
Device
- How does WATALYS® work ?
- What is the operating cost? Power consumption?
- How is it brought to users? Physical properties?
- How can it be transported?
- Why not ship chlorine directly to the users?
- Capacity - how many grams of chlorine per hour/day?
- How much water can be treated per hour/day?
- How important is the production time? Can you leave overnight?
- How do you know when you have produced sufficient chlorine?
- In solar powered mode, what if there are cloudy conditions?
- Do you need batteries for solar operation?
Method
- Where is the device installed? Do you need cisterns for chlorinated water?
- What is the quantity of salt used? Weight versus HTH?
- Chlorine is sensitive to heat. Can it be operated in any temperature?
- Storage - how soon do you need to use the concentrate?
- How long can you store the treated water?
- Effectiveness - Can you guarantee that the water is safe after treatment
- What is the reliability of this device? People will depend on it!
- What is the reliability of this device in solar operation?
- Chlorine can be dangerous. Can anyone operate a WATALYS® without danger to water users? A tool in the hands of inexperienced?
- Can any water be treated? Turbidity, Chemicals, Toxins (As, Fl)
- What is the source of your recommendations for application and dosage?
- Do I have to test every batch for Chlorine concentration?
- Can you use WATALYS® with piped water networks?
- Other solutions? Filtration, UV treatment, microfiltration
- Method safety; Reference?
- How do you educate the users? (operation, test, dosage)
- Are there any (dangerous) bi-products from the process?
- How dangerous is overdosing chlorine in the drinking water?
- What if the concentrate leaks out in the environment?
Market
- Who are the end-users?
- Is WATALYS® targeting the poor?
- Is your target "less developed countries"?
- What epidemics and diseases can you cure with the WATALYS® method?
- Is the target user private individuals? Families?
About chlorination
- Why chlorination ?
- What makes chlorination more interesting than other techniques ?
- What about chlorination byproducts ?
Device (answers)
How does WATALYS® work ?
The WATALYS® cell is immersed in a brine solution (water with salt or sea water). A 12V power supply is connected to the cell. Current flows through the electrodes electrolyzes the solution of sodium chloride, transforming it in sodium-hypochlorite, a strong disinfectant.
A 1 to 1.5 liter batch is achieved within an hour. A 10 liter batch is achieved within 6 hours of continuous run.
The solution will then be dissolved with water as follows :
Watalys is powered by any 12V source, such car batteries, mains with adapters or solar panels, allowing a full range of possibilities and offering complete autonomy.
What is the operating cost? Power consumption?
The operating cost for a 10L disinfectant batch is the cost of 250g of NaCl plus the cost of 0.25 kWh of (solar) power. The equivalent cost per kg chlorine, including depreciation of the device, is lower by far than any other form of commercial chlorine on local markets.
How is it brought to users? Physical properties?
A "bare" WATALYS® weighs less than 350 grams incl. manual and packaging. The device + solar equipment is shipped to organization or the user. Its size and weight allows an easy and cheap shipment.
How can it be transported?
The bare WATALYS® can be transported by car, plane, or brought in your pocket. Its design, size and weight along with the fact that it is shock and corrosion proof makes the WATALYS® very easy to handle and transport.
Why not ship chlorine directly to the users?
The WATALYS® "point of use production" proposal is an advantage compared to other solutions: Commonly used calcium hypochlorite (HTH) tablets, are not allowed in air transport. All forms of concentrated chlorine is hazardous to handle and transport, making it more difficult to access remote areas and increasing the price at final destination.
Capacity - how many grams of chlorine per hour/day?
The WATALYS® (Std) can produce max. 14g/hour equivalent (100%) chlorine. Ideal production quantity is a "bucket at a time" or typically 10L containing 60g chlorine in 5-6 hours.
How much water can be treated per hour/day?
A bucket, 10L will treat up to 40,000L or 40 cubic meters.
How important is the production time? Can you leave overnight?
It is important to respect the 1 hour/ L. If not under solar power, you could consider producing the solution at night. Ideal production quantity is a "bucket at a time" or 10L. While "shut-off" time is not critical, leaving the process under power generates heat which will negatively affect the chlorine concentration.
How do you know when you have produced sufficient chlorine?
Time and current (Ah passed) should give you a good indication. DPD tablets and Pool-colorimetric chlorine testers can tell you in a minute if the chlorine concentration is sufficient.
In SOLAR powered mode, what if there are cloudy conditions?
Solar panel size needs to be selected for the available average sun-hours on site. In addition it is advisable to produce a stock of concentrate for the days without no direct sunlight.
Do you need batteries for solar operation?
WATALYS® is designed for direct power by solar panels. We do not recommend batteries for reasons of cost, reliability, maintenance and ecological reasons. Also, battery mode requires charge controllers adding to the cost of the system and reducing reliability in hot climates. It is however vital that the solar panel can deliver the required current also in realistic local meteorological conditions. Consult the WATALYS® team for solar panel sizing.
The WATALYS® cell is immersed in a brine solution (water with salt or sea water). A 12V power supply is connected to the cell. Current flows through the electrodes electrolyzes the solution of sodium chloride, transforming it in sodium-hypochlorite, a strong disinfectant.
A 1 to 1.5 liter batch is achieved within an hour. A 10 liter batch is achieved within 6 hours of continuous run.
The solution will then be dissolved with water as follows :
- 2 to 5 times for a disinfectant solution
- 4000 times for water potabilization
Watalys is powered by any 12V source, such car batteries, mains with adapters or solar panels, allowing a full range of possibilities and offering complete autonomy.
What is the operating cost? Power consumption?
The operating cost for a 10L disinfectant batch is the cost of 250g of NaCl plus the cost of 0.25 kWh of (solar) power. The equivalent cost per kg chlorine, including depreciation of the device, is lower by far than any other form of commercial chlorine on local markets.
How is it brought to users? Physical properties?
A "bare" WATALYS® weighs less than 350 grams incl. manual and packaging. The device + solar equipment is shipped to organization or the user. Its size and weight allows an easy and cheap shipment.
How can it be transported?
The bare WATALYS® can be transported by car, plane, or brought in your pocket. Its design, size and weight along with the fact that it is shock and corrosion proof makes the WATALYS® very easy to handle and transport.
Why not ship chlorine directly to the users?
The WATALYS® "point of use production" proposal is an advantage compared to other solutions: Commonly used calcium hypochlorite (HTH) tablets, are not allowed in air transport. All forms of concentrated chlorine is hazardous to handle and transport, making it more difficult to access remote areas and increasing the price at final destination.
Capacity - how many grams of chlorine per hour/day?
The WATALYS® (Std) can produce max. 14g/hour equivalent (100%) chlorine. Ideal production quantity is a "bucket at a time" or typically 10L containing 60g chlorine in 5-6 hours.
How much water can be treated per hour/day?
A bucket, 10L will treat up to 40,000L or 40 cubic meters.
How important is the production time? Can you leave overnight?
It is important to respect the 1 hour/ L. If not under solar power, you could consider producing the solution at night. Ideal production quantity is a "bucket at a time" or 10L. While "shut-off" time is not critical, leaving the process under power generates heat which will negatively affect the chlorine concentration.
How do you know when you have produced sufficient chlorine?
Time and current (Ah passed) should give you a good indication. DPD tablets and Pool-colorimetric chlorine testers can tell you in a minute if the chlorine concentration is sufficient.
In SOLAR powered mode, what if there are cloudy conditions?
Solar panel size needs to be selected for the available average sun-hours on site. In addition it is advisable to produce a stock of concentrate for the days without no direct sunlight.
Do you need batteries for solar operation?
WATALYS® is designed for direct power by solar panels. We do not recommend batteries for reasons of cost, reliability, maintenance and ecological reasons. Also, battery mode requires charge controllers adding to the cost of the system and reducing reliability in hot climates. It is however vital that the solar panel can deliver the required current also in realistic local meteorological conditions. Consult the WATALYS® team for solar panel sizing.
Method (answers)
Where is the device installed? Do you need
cisterns for chlorinated water?
With WATALYS® you can treat the water at the POINT OF USE i.e. where water is sourced; well, source, sea, river or where it is consumed. The production process is separate from the water distribution system. It is important to keep the process and the concentrate out of direct sunlight. Once dosage is determined, the chlorinator can just add "a shot" of concentrate (typically. 2.5 - 5ml) in each pot, bucket or other container at the source or well. Wait 30 mins (Min. contact time, CT) before consumption.
What is the quantity of salt used? Weight versus HTH?
25kg of salt yields 6kg chlorine, equivalent to 8.5kg HTH
Chlorine is sensitive to heat. Can it be operated in any temperature?
It is important to have as low starting temperature as possible, as the electrolyte heats up in the process. The yield of the process actually increases up to 38°C. Keep the process in the shade to avoid UV radiation and excessive heat.
Storage How soon do you need to use the concentrate?
Store the concentrate in a dark place. Under good storage conditions, 80% of the free chlorine remains after 2 months. The solution cannot by stored in metal or metallic container.
How long can you store the treated water?
This depends on the conditions of storage and cleanliness of the vessels. Where there is a risk of contamination e.g. in open cisterns, it is a good practice to retest residual chlorine (FCR) and if necessary add concentrate.
Effectiveness - Can you guarantee that the water is safe after treatment
Free chlorine residual (FCR) and contact time (CT) are critical to safety. Follow the guidelines in the manual or those issued by WHO. If after disinfection and allowing for sufficient contact time (CT) there is a minimum of 0.5mg/L free chlorine residual (FCR) the disinfection has been successful and pathogens are deactivated.
What is the reliability of this device? People will depend on it!
WATALYS® is extremely reliable due to its robust design and no moving parts. The operating life is guaranteed to 10,000 hours. Do not scratch or replace the electrodes. They are protected by a special coating, vital to product life. Cleaning is done by occasionally reversing the polarity.
What is the reliability of this device in solar operation?
Extremely good. We recommend powering the WATALYS® device directly (in some cases with regulating electronics) from solar panels. Manufacturers of solar panels usually guarantee their products and the power output for 10-20 years. The WATALYS® device has an operating life of 10000 hours and should be replaced every 4 1/2 years in normal daily operation. Avoiding batteries reduces material- and maintenance cost. It increases system reliability and results in an ecologically clean system.
CHLORINE can be dangerous. Can anyone operate a WATALYS® without danger to water users? A tool in the hands of inexperienced?
The chlorine concentration level achieved with WATALYS® is 0.6%, which is just below the recommendations issued by WHO for field use of chlorine. The advantage of WATALYS® is that there is no need to handle highly concentrated products like HTH or bleach.
Can any water be treated? Turbidity, Chemicals, Toxins (As, Fl)
Chlorination is only effective for organic contaminations and killing pathogens. A requirement for the process is reasonably clear water (turbidity less than 5 NTU). Pre-treatment by simple filtration or sedimentation is necessary for turbid waters.
What is the source of your recommendations for application and dosage?
The methods and recommendations are derived from WHO Guidelines for drinking water quality Volume1, 3rd edition. They are verified by field use with local water boards and help organizations. Go to our download page for details.
Do I have to test every batch for Chlorine concentration?
What is key is to monitor the current in the process, the number of Ampere hours passed. Once the production method is mastered and the operating conditions are stable, the production yield has good repeatability. However, in the case of solar operation and varying insolation conditions, it is good practice to verify that enough chlorine has been released.
Can you use WATALYS® with piped water networks?
The concentrate can be added, like other forms of chlorine, to a storage cistern or basin. It is however vital to continuously monitor chlorine levels (FCR) both at storage and point of use. Where necessary additional chlorine should be added. There are also dosage pumps available on the market for simple urban installations.
Other solution? Filtration, Sodis, UV treatment, microfiltration
Each method has its advantages and shortcomings. Use of ultraviolet light or ozone in water purification does not continue to protect drinking water throughout the distribution system as chlorine does. Capacity in rural applications is usually a drawback with alternative methods. WATALYS® is designed to meet the WHO recommendation of 20L/day/person. - "Disinfection of water at the point of use is consistently the most cost-effective intervention" UN World Water Development Report
Method safety; Reference?
Measuring the free residual chlorine (FCR) is considered a good indicator that disinfection has been successful. The process of dosage and test is well described in the publications of the Intl. Organizations. Our instructions for WATALYS® are based on Guidelines for Drinking-water Quality 3rd ed. WHO 2004.
How do you educate the users? (operation, test, dosage)
Collaboration with competent locals is the preferred way. We collaborate with local water boards, NGOs, health centers, volunteers and Intl. Organizations.
Are there any bi-products from the process?
There is a minimal release of hydrogen gas, which dissolves into surrounding air. It is important to operate in ventilated premises.
How dangerous is overdosing chlorine in the drinking water?
The smell and taste of chlorine prevents excessive concentration levels in drinking water long before harmful levels are achieved.
What if the concentrate leaks out in the environment?
Sodium hypochlorite products with less than 5% active chlorine are not classified as hazardous (EU norms). Products with higher than 1% active chlorine may react with other substances to form dangerous gases. WATALYS® concentrate contains 0.6% active chlorine and is subsequently not subject to any restrictions.
With WATALYS® you can treat the water at the POINT OF USE i.e. where water is sourced; well, source, sea, river or where it is consumed. The production process is separate from the water distribution system. It is important to keep the process and the concentrate out of direct sunlight. Once dosage is determined, the chlorinator can just add "a shot" of concentrate (typically. 2.5 - 5ml) in each pot, bucket or other container at the source or well. Wait 30 mins (Min. contact time, CT) before consumption.
What is the quantity of salt used? Weight versus HTH?
25kg of salt yields 6kg chlorine, equivalent to 8.5kg HTH
Chlorine is sensitive to heat. Can it be operated in any temperature?
It is important to have as low starting temperature as possible, as the electrolyte heats up in the process. The yield of the process actually increases up to 38°C. Keep the process in the shade to avoid UV radiation and excessive heat.
Storage How soon do you need to use the concentrate?
Store the concentrate in a dark place. Under good storage conditions, 80% of the free chlorine remains after 2 months. The solution cannot by stored in metal or metallic container.
How long can you store the treated water?
This depends on the conditions of storage and cleanliness of the vessels. Where there is a risk of contamination e.g. in open cisterns, it is a good practice to retest residual chlorine (FCR) and if necessary add concentrate.
Effectiveness - Can you guarantee that the water is safe after treatment
Free chlorine residual (FCR) and contact time (CT) are critical to safety. Follow the guidelines in the manual or those issued by WHO. If after disinfection and allowing for sufficient contact time (CT) there is a minimum of 0.5mg/L free chlorine residual (FCR) the disinfection has been successful and pathogens are deactivated.
What is the reliability of this device? People will depend on it!
WATALYS® is extremely reliable due to its robust design and no moving parts. The operating life is guaranteed to 10,000 hours. Do not scratch or replace the electrodes. They are protected by a special coating, vital to product life. Cleaning is done by occasionally reversing the polarity.
What is the reliability of this device in solar operation?
Extremely good. We recommend powering the WATALYS® device directly (in some cases with regulating electronics) from solar panels. Manufacturers of solar panels usually guarantee their products and the power output for 10-20 years. The WATALYS® device has an operating life of 10000 hours and should be replaced every 4 1/2 years in normal daily operation. Avoiding batteries reduces material- and maintenance cost. It increases system reliability and results in an ecologically clean system.
CHLORINE can be dangerous. Can anyone operate a WATALYS® without danger to water users? A tool in the hands of inexperienced?
The chlorine concentration level achieved with WATALYS® is 0.6%, which is just below the recommendations issued by WHO for field use of chlorine. The advantage of WATALYS® is that there is no need to handle highly concentrated products like HTH or bleach.
Can any water be treated? Turbidity, Chemicals, Toxins (As, Fl)
Chlorination is only effective for organic contaminations and killing pathogens. A requirement for the process is reasonably clear water (turbidity less than 5 NTU). Pre-treatment by simple filtration or sedimentation is necessary for turbid waters.
What is the source of your recommendations for application and dosage?
The methods and recommendations are derived from WHO Guidelines for drinking water quality Volume1, 3rd edition. They are verified by field use with local water boards and help organizations. Go to our download page for details.
Do I have to test every batch for Chlorine concentration?
What is key is to monitor the current in the process, the number of Ampere hours passed. Once the production method is mastered and the operating conditions are stable, the production yield has good repeatability. However, in the case of solar operation and varying insolation conditions, it is good practice to verify that enough chlorine has been released.
Can you use WATALYS® with piped water networks?
The concentrate can be added, like other forms of chlorine, to a storage cistern or basin. It is however vital to continuously monitor chlorine levels (FCR) both at storage and point of use. Where necessary additional chlorine should be added. There are also dosage pumps available on the market for simple urban installations.
Other solution? Filtration, Sodis, UV treatment, microfiltration
Each method has its advantages and shortcomings. Use of ultraviolet light or ozone in water purification does not continue to protect drinking water throughout the distribution system as chlorine does. Capacity in rural applications is usually a drawback with alternative methods. WATALYS® is designed to meet the WHO recommendation of 20L/day/person. - "Disinfection of water at the point of use is consistently the most cost-effective intervention" UN World Water Development Report
Method safety; Reference?
Measuring the free residual chlorine (FCR) is considered a good indicator that disinfection has been successful. The process of dosage and test is well described in the publications of the Intl. Organizations. Our instructions for WATALYS® are based on Guidelines for Drinking-water Quality 3rd ed. WHO 2004.
How do you educate the users? (operation, test, dosage)
Collaboration with competent locals is the preferred way. We collaborate with local water boards, NGOs, health centers, volunteers and Intl. Organizations.
Are there any bi-products from the process?
There is a minimal release of hydrogen gas, which dissolves into surrounding air. It is important to operate in ventilated premises.
How dangerous is overdosing chlorine in the drinking water?
The smell and taste of chlorine prevents excessive concentration levels in drinking water long before harmful levels are achieved.
What if the concentrate leaks out in the environment?
Sodium hypochlorite products with less than 5% active chlorine are not classified as hazardous (EU norms). Products with higher than 1% active chlorine may react with other substances to form dangerous gases. WATALYS® concentrate contains 0.6% active chlorine and is subsequently not subject to any restrictions.
Market (answers)
Who are the end-users?
The end-users are groups of people in need of potabilized water and/or disinfection methods and who cannot be reached by the "classical" means of water potabilization or sanitation brought by health programs (such as Veolia or WHO). Usually, potabilization programs especially in emergency contexts do provide potable water in areas safe and easy to reach and were there is a relevant concentration of people (like towns or big villages). On the other end, there are potabilization methods available today on the market, suitable for individuals or very small groups (3 to 6 people) in this segment we do find water filters or chlorination tabs from different vendors.
Is WATALYS® targeting the poor?
The price of the device should also enable small communities even in the poorest areas to get their own potabilization device. Also WATALYS® is a sustainable development method supporting WHO´s recommendation of 20L/person/day at the lowest operating cost. The WATALYS® method can be installed at a cost lower than EUR 0.10 per inhabitant. "Disinfection of water at the point of use is consistently the most cost-effective intervention." UN World Water Development Report
Is your target "less developed countries"?
The price of the device should enable small communities even in the poorest areas to get their own potabilization device WATALYS®. However, the WATALYS® should be powerful enough for NGOs, health departments and organizations to be considered for sustainable safe water programs.
What epidemics and diseases can you cure with the WATALYS® method?
Chlorination is not meant to cure any disease. WATALYS® does provide a way of eliminating pathogens from water used for drinking, cooking or personal hygiene.
Is the target user private individuals? Families?
The target is communities between 10 to 6000 people per device. For solar powered installations, limited by the available sun-hours, the target is up to 2000 people.
The end-users are groups of people in need of potabilized water and/or disinfection methods and who cannot be reached by the "classical" means of water potabilization or sanitation brought by health programs (such as Veolia or WHO). Usually, potabilization programs especially in emergency contexts do provide potable water in areas safe and easy to reach and were there is a relevant concentration of people (like towns or big villages). On the other end, there are potabilization methods available today on the market, suitable for individuals or very small groups (3 to 6 people) in this segment we do find water filters or chlorination tabs from different vendors.
Is WATALYS® targeting the poor?
The price of the device should also enable small communities even in the poorest areas to get their own potabilization device. Also WATALYS® is a sustainable development method supporting WHO´s recommendation of 20L/person/day at the lowest operating cost. The WATALYS® method can be installed at a cost lower than EUR 0.10 per inhabitant. "Disinfection of water at the point of use is consistently the most cost-effective intervention." UN World Water Development Report
Is your target "less developed countries"?
The price of the device should enable small communities even in the poorest areas to get their own potabilization device WATALYS®. However, the WATALYS® should be powerful enough for NGOs, health departments and organizations to be considered for sustainable safe water programs.
What epidemics and diseases can you cure with the WATALYS® method?
Chlorination is not meant to cure any disease. WATALYS® does provide a way of eliminating pathogens from water used for drinking, cooking or personal hygiene.
Is the target user private individuals? Families?
The target is communities between 10 to 6000 people per device. For solar powered installations, limited by the available sun-hours, the target is up to 2000 people.
About chlorination (answers)
Why chlorination ?
Probably one of the most widely recognized uses of chlorine in everyday life is disinfection of drinking water. Chlorine was first used to make water safe in the late 19th century. At that time, it proved invaluable to control the spread of water-borne diseases such as typhoid, cholera, dysentery and gastro-enteritis.
Fighting such diseases, which have killed more people than all the wars in history, remains vital today. For example, according to the World Health Organization (WHO) "3.4 million people in developing countries, most of them children, die every year from diseases associated with lack of safe drinking water, inadequate sanitation and poor hygiene[1]".
A powerful disinfection agent, elemental chlorine and its derivatives, sodium hypochlorite and chorine dioxide, quickly kill bacteria and other micro-organisms when added to water in minute quantities. Chlorine has the major advantage of ensuring clean water right to the tap , whereas the action of other disinfection techniques - such as ozone, ultraviolet light and ultrafiltration - is much more temporary. In addition to purifying water, chlorine not only helps to remove unpleasant tastes or odors, but also helps eliminate unwanted nitrogenous contaminants, and control the growth of slime and algae in distribution pipes and storage tanks.
Today, most of world's drinking water is made safe with the help of chlorine. It is an essential part of the purification processes used by water companies to supply our homes, industry and ensure that discharges of wastewater to rivers and seas are safe.
What makes chlorination more interesting than other techniques ?
There are other processes designed to purify drinking water, such as ozone, ultraviolet irradiation, and ultrafiltration. However, the principal advantage over alternative disinfection processes is that chlorination is the only method that persists long enough to keep water germ-free right up to the tap "the remanence effect".
Pathogens can easily enter the distribution system downstream of a water treatment plant especially in older or poorly-maintained pipeline networks. Chlorine also prevents the growth of biofilm (for example: algae in pipes and slime formation in storage tanks). Another distinct advantage is that it can be used with relatively simple techniques and at low costs, which makes chlorination a particularly appropriate disinfection technique for lesser-developed countries.
What about chlorination byproducts ?
During the water treatment process, chlorine reacts with organic matter such as decomposing leaves or soil to create what are called disinfection by-products (DBPs). The most common class of DBPs is trihalomethanes (THMs).
Toxicological studies suggested that some THMs are carcinogenic to laboratory animals, but only at levels many thousands of times greater than those found in drinking water. Recent studies on chloroform (the main type of THMs) show that it is unlikely to cause cancer at the extremely low levels found in drinking water.
The World Health Organization's (WHO) International Programme on Chemical Safety recently concluded that "There is insufficient epidemiological evidence to support a causal relationship between bladder cancers and exposures to chlorinated drinking water."[2] EPA and Health Canada have also reached similar conclusions.[3]
Based on these findings, the WHO maintains that the "Risks to health from DBPs are extremely small in comparison with inadequate disinfection."[4]
In addition to concerns about carcinogenicity attention has also focused on possible relationships between DBPs and adverse reproductive and developmental effects. Overall however, evidence for such effects are sparse and the findings inconsistent.
Based on available research, WHO concluded that the "risks to health from DBPs are extremely small in comparison with inadequate disinfection" and urged that disinfection not be compromised in attempts to control DBPs (N.B. In 1993, WHO issued Guidelines for drinking water quality[5]).
This sets values for various DBPs on the basis of a single excess case of cancer in a given large population of people each drinking two liters of water per day for 70 years).
It is essential to remember that the primary purpose of chlorination is the protection of public health and that any minimal or hypothetical adverse effects have to be balanced against the benefits gained from chlorination. This is well illustrated by the tragic consequences of a misinterpretation of US Regulations in 1991 by the Peruvian Government that led to suspension of the chlorination of that country's water supplies. The resulting cholera epidemic, which also spread to neighboring countries in Latin America, caused about 800,000 cases of cholera and more than 6,000 deaths.[6]
Probably one of the most widely recognized uses of chlorine in everyday life is disinfection of drinking water. Chlorine was first used to make water safe in the late 19th century. At that time, it proved invaluable to control the spread of water-borne diseases such as typhoid, cholera, dysentery and gastro-enteritis.
Fighting such diseases, which have killed more people than all the wars in history, remains vital today. For example, according to the World Health Organization (WHO) "3.4 million people in developing countries, most of them children, die every year from diseases associated with lack of safe drinking water, inadequate sanitation and poor hygiene[1]".
A powerful disinfection agent, elemental chlorine and its derivatives, sodium hypochlorite and chorine dioxide, quickly kill bacteria and other micro-organisms when added to water in minute quantities. Chlorine has the major advantage of ensuring clean water right to the tap , whereas the action of other disinfection techniques - such as ozone, ultraviolet light and ultrafiltration - is much more temporary. In addition to purifying water, chlorine not only helps to remove unpleasant tastes or odors, but also helps eliminate unwanted nitrogenous contaminants, and control the growth of slime and algae in distribution pipes and storage tanks.
Today, most of world's drinking water is made safe with the help of chlorine. It is an essential part of the purification processes used by water companies to supply our homes, industry and ensure that discharges of wastewater to rivers and seas are safe.
What makes chlorination more interesting than other techniques ?
There are other processes designed to purify drinking water, such as ozone, ultraviolet irradiation, and ultrafiltration. However, the principal advantage over alternative disinfection processes is that chlorination is the only method that persists long enough to keep water germ-free right up to the tap "the remanence effect".
Pathogens can easily enter the distribution system downstream of a water treatment plant especially in older or poorly-maintained pipeline networks. Chlorine also prevents the growth of biofilm (for example: algae in pipes and slime formation in storage tanks). Another distinct advantage is that it can be used with relatively simple techniques and at low costs, which makes chlorination a particularly appropriate disinfection technique for lesser-developed countries.
What about chlorination byproducts ?
During the water treatment process, chlorine reacts with organic matter such as decomposing leaves or soil to create what are called disinfection by-products (DBPs). The most common class of DBPs is trihalomethanes (THMs).
Toxicological studies suggested that some THMs are carcinogenic to laboratory animals, but only at levels many thousands of times greater than those found in drinking water. Recent studies on chloroform (the main type of THMs) show that it is unlikely to cause cancer at the extremely low levels found in drinking water.
The World Health Organization's (WHO) International Programme on Chemical Safety recently concluded that "There is insufficient epidemiological evidence to support a causal relationship between bladder cancers and exposures to chlorinated drinking water."[2] EPA and Health Canada have also reached similar conclusions.[3]
Based on these findings, the WHO maintains that the "Risks to health from DBPs are extremely small in comparison with inadequate disinfection."[4]
In addition to concerns about carcinogenicity attention has also focused on possible relationships between DBPs and adverse reproductive and developmental effects. Overall however, evidence for such effects are sparse and the findings inconsistent.
Based on available research, WHO concluded that the "risks to health from DBPs are extremely small in comparison with inadequate disinfection" and urged that disinfection not be compromised in attempts to control DBPs (N.B. In 1993, WHO issued Guidelines for drinking water quality[5]).
This sets values for various DBPs on the basis of a single excess case of cancer in a given large population of people each drinking two liters of water per day for 70 years).
It is essential to remember that the primary purpose of chlorination is the protection of public health and that any minimal or hypothetical adverse effects have to be balanced against the benefits gained from chlorination. This is well illustrated by the tragic consequences of a misinterpretation of US Regulations in 1991 by the Peruvian Government that led to suspension of the chlorination of that country's water supplies. The resulting cholera epidemic, which also spread to neighboring countries in Latin America, caused about 800,000 cases of cholera and more than 6,000 deaths.[6]
[1] Water for Life Decade, Published by the
United Nations Dep. For Public Information,
Sept. 2005.
[2] International Programme on
Chemical Safety. World Health Organization.
Environmental Health Criteria
216: Disinfectants and Disinfection Byproducts.
2000.
[3] U.S. Environmental Protection
Agency. "National Primary Drinking Water
Regulations: Disinfectants and Disinfection
Byproducts (final rule)."
Federal Register.
December 1998.
[4] Guidelines for Drinking Water
Quality, Volume 1.
1993.
[5] See " Guidelines for Drinking Water Quality
2004 ", 3rd edition, WHO: http://www.who.int/water_sanitation_health/dwq/gdwq3/en
[6] Otterstetter, Horst and Craun,
Gunther. "Disinfection in the Americas: A
Necessity."Journal of the American Water
Works Association.
September 1997.
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