Much More Water A/S
Much More Water A/S core business is to deliver compact, mobile, and robust water cleaning systems delivering clean drinking water in demanding areas primarily for disaster relief organisations, military, and NGO’s. During our many years of delivering our BlueBox systems we have learnt to understand the specific needs for organisations and deliver systems suitable for all types of needs and water types. Working in close partnership with these organisations, we have developed systems from the small carry on model to systems supplying cities with a wide range of technologies. Much More Water A/S is part of the Ellegaard Group employing over 100 people in three locations for more than 65 years.
Company details
Find locations served, office locations
- Business Type:
- Manufacturer
- Industry Type:
- Water and Wastewater - Water Filtration and Separation
- Market Focus:
- Globally (various continents)
- Year Founded:
- 2001
- Employees:
- 1-10
- Turnover:
- $1,000,000 US - $10,000,000 US
Much More Water A/S was established in 2001 and is...
Much More Water A/S was established in 2001 and is based in the greater Copenhagen area of Denmark. Over the years, and with substantial research and investment, we have developed our BlueBox water purification systems for multiple applications throughout the world in more than 35 countries. We have solid capability in research and development, manufacturing and sourcing. Beyond this, we have a strong commitment to supply parts and service from our headquarters to any location in the world.
- NATO NCAGE reference: R5235
- DUNS reference: 307487210
Clean water for everyone
Emergency Clean Water Solutions: Saving Lives When it Matters Most
In the aftermath of natural disasters like floods, hurricanes, war and earthquakes, the need for clean water becomes a matter of life and death. At MuchMoreWater we understand that in these critical moments, clean water is a lifeline. The equipment is manufactured from best-in-class quality components to obtain very compact, lightweight, and mobile water cleaning systems.
The Crucial Role of Clean Water
Clean water is indispensable for several reasons:
- Disease Prevention: Contaminated water can lead to deadly diseases. Clean water is the first defence against such threats.
- Hydration and Nourishment: Clean water is essential for drinking and food preparation, ensuring survivors' well-being.
- Medical Care: It's vital for patient treatment and sterilization of medical equipment.
- Hygiene: Enables personal hygiene, crucial for health and dignity.
- Recovery: Restores a sense of normalcy, aiding in the recovery process.
Clean water for everyone – are you in?
Join us in our mission to make a difference where it matters most, providing hope and healing through clean water in the toughest times.
Explore our solutions and be part of the life-saving journey.
Reliable Clean Water for Military Operations
In the field, easy access to safe, dependable clean water is mission critical. At MuchMoreWater we provide trusted water treatment solutions for military personnel. The equipment is manufactured from best-in-class quality components to obtain very compact, lightweight and mobile water cleaning systems.
The Significance of Clean Water in Military Operations
Clean water is essential for:
- Health and Readiness: It sustains performance and prevents waterborne illnesses needing up to 10 litres per day in hot areas.
- Logistical Efficiency: Our on-site water treatment reduces the need to transport bottled water.
- Operational Flexibility: Our portable systems support deployments in diverse environments from small teams to large camps.
Trusted Water Treatment Solutions
Choose MuchMoreWater for:
- Proven Performance: Our machines have a track record of reliability in challenging conditions from more than 35 countries.
- Rapid Deployment: Quickly transport and set up our portable systems in remote locations. We supply robust, easy to operate and compact solutions.
- Safety Assurance: We meet stringent safety standards for peace of mind from any water source.
Count on MuchMoreWater for clean water solutions that support mission success.
The Vital Significance of Clean Water: Key Statistics
Statistics related to the importance of clean water can be powerful arguments for emphasizing the critical role of access to safe and clean water. Here are some key statistics you can use:
- Waterborne Diseases: Millions of people worldwide suffer from waterborne diseases annually. For example, the World Health Organization (WHO) estimates that around 485,000 deaths occur each year due to diarrheal diseases caused by unsafe drinking water, sanitation, and hygiene practices.
- Child Mortality: Unsafe water and lack of sanitation and hygiene are major contributors to child mortality. According to UNICEF, approximately 1,000 children under the age of five die every day due to diarrhea linked to inadequate water, sanitation, and hygiene.
- Hospitalizations: Many people are hospitalized due to water-related illnesses. The exact number can vary by region and year, but it often represents a substantial burden on healthcare systems. These hospitalizations include cases of severe diarrhea, cholera, and other waterborne diseases.
- Economic Impact: Lack of access to clean water has significant economic consequences. The United Nations estimates that the economic cost of inadequate water supply and sanitation can be as high as 2.5% of the gross domestic product (GDP) of some developing countries, mainly due to healthcare costs and lost productivity.
- Impact on Education and Gender Disparities: In many regions, children, especially girls, are responsible for collecting water for their families. The time spent on this task can limit their access to education, reinforcing the cycle of poverty.
- Water Scarcity: Beyond water quality, water scarcity is a growing global issue. Approximately 2.2 billion people lack access to safe drinking water, and by 2050, it's projected that almost half of the world's population will be living in water-stressed areas.
- Humanitarian Crises: In emergency situations like natural disasters and conflicts, the need for clean water becomes even more critical. Millions of people in crisis situations depend on humanitarian organizations for access to clean water.
- Global Goals: Access to clean water and sanitation is a key part of the United Nations Sustainable Development Goals (SDGs). Goal 6 aims to ensure availability and sustainable management of water and sanitation for all by 2030.
Transforming Challenging Water Sources into Potable Gold
At MuchMoreWater our cutting-edge Ultrafiltration (UF) and Reverse Osmosis (RO) technologies empower us to turn even the most challenging water sources into life-sustaining, potable water. Here's a glimpse of what we can achieve:
Lake Water: Lakes are invaluable natural water reservoirs, but they can often be contaminated by organic matter, sediments, and algae. Our UF and RO systems excel at removing impurities, ensuring that communities near lakes can have access to clean, safe drinking water.
- River Water: Rivers can be susceptible to pollution from industrial discharges, agricultural runoff, and human activity. Our advanced filtration and membrane technologies effectively remove pollutants, safeguarding the health of those relying on river water.
- Borehole Water: Borehole water often contains high mineral content, making it brackish or even saline. Our RO systems are designed to desalinate such water, making it suitable for consumption, irrigation, and industrial use.
- Brackish Water: Coastal regions frequently face the challenge of brackish water, which is neither entirely freshwater nor seawater. With our RO technology, we can desalinate brackish water, providing a reliable source of fresh water for coastal communities.
- Seawater: The vast oceans hold a potential reservoir of water, but their high salinity makes them undrinkable. Our RO technology can effectively desalinate seawater, opening new possibilities for coastal regions and islands to access freshwater resources.
- Groundwater: Groundwater is an important source of drinking water for many communities. However, it can contain contaminants such as arsenic, iron, and manganese that need to be removed to make it potable.
- Well Water: Well water is commonly used in rural and suburban areas. It can vary significantly in quality and may require treatment to meet drinking water standards.
- Rainwater: Rainwater harvesting systems collect rainwater for various uses, including drinking. Proper treatment is essential to ensure rainwater is safe for consumption.
- Spring Water: Springs often provide naturally sourced water, but the purity of spring water can vary. Filtration and treatment may be necessary to make it suitable for drinking.
- Urban Runoff: In some urban areas, rainwater runoff can be collected and treated for drinking purposes. This source can help alleviate water shortages in densely populated regions.
- Recycled Water: In regions with advanced water treatment infrastructure, treated wastewater can be purified to potable water standards and reused as a drinking water source.
- Industrial Effluent: In industrial areas, treated industrial effluent can be further purified to create a safe source of drinking water.
What We Remove and Why It Matters
Precision Filtration: Removing Molecules at the Molecular Level
Our Ultrafiltration (UF) and Reverse Osmosis (RO) technologies are masters of precision. They target and remove molecules at the molecular level, ensuring that only pure, clean water passes through.
Ultrafiltration (UF): With UF, we capture contaminants and particles that are larger than 0.01 microns in size. This includes bacteria, viruses, suspended solids, and even some large organic molecules. UF is like a molecular sieve, allowing only water and the tiniest of molecules to permeate.
Reverse Osmosis (RO): RO takes filtration to the next level, removing molecules as small as 0.0001 microns. It's the gold standard for desalination, effectively trapping salts, minerals, and virtually all impurities, leaving you with pristine, crystal-clear water.
These technologies don't just clean water; they transform it into a pure elixir of life. Whether it's providing safe drinking water from challenging sources or ensuring the highest quality for industrial processes, our UF and RO systems deliver precision you can trust.
Our UF and RO systems are engineered to remove a wide range of impurities, including:
Pathogens: Bacteria, viruses, and protozoa that can cause waterborne diseases are effectively eliminated, protecting public health.
Suspended Solids: Sediments, debris, and particulate matter are filtered out, improving water clarity and taste.
Salts and Minerals: High levels of salts and minerals can render water undrinkable and harm plumbing systems. RO removes these impurities, ensuring the water is safe and non-corrosive.
Chemical Contaminants: Pesticides, heavy metals, and industrial chemicals are effectively reduced or eliminated, minimizing health risks.
Access to clean water is a basic human right, and with our UF and RO systems, we are committed to making this right a reality for communities around the world. Clean water isn't just a convenience; it's a lifeline, promoting health, well-being, and prosperity.
Rigorous Standards for Safe Drinking Water
Around the world, stringent water quality standards are in place to ensure the safety of drinking water. Both for regions, countries, and organisations. Using our systems, we can secure you will follow these standards too. Let us know which standard you want to follow. The are some key standards used.
World Health Organization (WHO): Globally, the WHO sets international standards and guidelines for drinking water quality. These standards provide a framework for countries to assess and maintain the safety of their water supplies. Explore the [WHO's Guidelines for Drinking-water Quality]
NATO: The North Atlantic Treaty Organization (NATO) also establishes water quality standards for its members. These standards ensure that water used by NATO forces, including for drinking, meets stringent quality requirements. For further details on NATO water quality standards, please refer to [NATO's official resources].
United States: The Environmental Protection Agency (EPA) administers the Safe Drinking Water Act (SDWA), which sets Maximum Contaminant Levels (MCLs) for various contaminants. This ensures that public water systems adhere to rigorous testing and treatment requirements. You can learn more about the SDWA on the [EPA's Safe Drinking Water Act webpage].
Europe: The European Union (EU) regulates water quality through the EU Drinking Water Directive. It establishes comprehensive standards covering microbiological, chemical, and indicator parameters, guaranteeing safe and clean water for citizens. For detailed information on EU water quality standards, visit the [European Commission's page on Drinking Water Quality]
For further details on these standards and parameters, we recommend visiting the provided webpages of the respective regulatory authorities.
Our construction philosophy
Mobile, some portable, robust, simple, high quality materials and well-known brands, spare parts all over the world, easy maintenance, and repair
The technologies
Selecting the right technology for emergency water purification is crucial for ensuring the health and well-being of individuals and communities in crisis situations. Our page is divided into three key sections:
- Prefiltration: Discover various prefiltration technologies that remove larger particles and impurities, setting the stage for effective water treatment.
- UV and RO Filtration. Explore how Ultraviolet (UV) and Reverse Osmosis (RO) filtration systems work to eliminate contaminants, highlighting their importance in emergency water purification.
- Post-Treatment: Learn about essential steps to optimize water quality after UV and RO filtration, ensuring safe and clean drinking water.
Choose the right tools and strategies to turn contaminated water into a source of hope and resilience during emergencies.
Prefiltration
Prefiltration is a critical step in water treatment processes, particularly before employing advanced technologies like Ultrafiltration (UF) and Reverse Osmosis (RO). This preliminary stage serves as the initial line of defense against contaminants present in the water source. By effectively removing larger particles, debris, and impurities, prefiltration not only extends the lifespan of UF and RO membranes but also enhances the efficiency and reliability of the entire water cleaning system. In the following sections, we will delve into various prefiltration technologies and their significance in achieving cleaner, safer water for a multitude of applications.
Here is a list of the most popular prefiltration technologies. The optimal prefiltration can be decided based on a test of the intake water. If this is not available assumptions are considered.
Media Filters
Media filters use layers of granular materials like sand, anthracite, or multimedia to trap particles and impurities in water through physical filtration.
- Pros: Effective at removing sediment, silt, and larger particles. Simple operation and maintenance.
- Cons: May not effectively remove dissolved contaminants or very fine particles.
Filter houses
Filter houses are used with either cartridges or bags inside that can be replaced:
Filter cartridges consist of porous materials, such as pleated paper, fabric, or ceramic, which capture particles as water passes through.
- Pros: Easy to install, replace, and maintain. Can target specific contaminants using different cartridge types.
- Cons: Limited capacity and may require frequent replacement.
Filter bags are fabric-based filtration systems that capture larger particles and solids from water.
- Pros: Cost-effective, easy to change, and capable of handling high flow rates, can be cleaned, and reused.
- Cons: Limited to coarse filtration and may not effectively remove fine particles or dissolved substances.
Antiscalants
Antiscalants are chemical additives that prevent the formation of scale deposits, such as calcium and magnesium, on UF and RO membranes. Antiscalants are dosed into the water with a dosing pump.
- Pros: Protect membranes from scaling, improving their lifespan and efficiency.
- Cons: Need proper dosing and monitoring to be effective. Chemical handling and disposal considerations.
Activated Carbon Filters
Activated carbon filters use porous carbon, either granulate of solid, to adsorb organic compounds, chlorine, and certain chemicals from water. Important to have chlorine removed before using RO membranes as chlorine will destroy the membranes and some UF technology.
Pros: Effective at removing taste, odour, and many organic contaminants. Enhances overall water quality.
Cons: Limited to specific contaminants and may require periodic replacement or reactivation.
Sedimentation Tanks or Basins
Sedimentation tanks allow particles and solids in water to settle out under the influence of gravity before further treatment.
Pros: Cost-effective for large volumes of water. Removes larger particles and allows for simpler subsequent treatment.
Cons: May require significant space, and the efficiency depends on the settling characteristics of the particles.
Chlorine
Chlorin is sometimes used as part of prefiltration as this will both kill some organics like bacterial before reaching the RO and UF filters and will keep the prefiltration equipment clean from bacteria’s settling. You do however need to have the chlorine removed if you use RO membranes. This is done by either using activated carbon as described, or by adding chemicals like Bisulfide.
Some prefiltration technologies, like media filters and certain filter housings, offer an additional advantage – they can be backflushed.
Backflushing is a process where the flow of water is temporarily reversed to clean and unclog the filter media. This maintenance technique helps extend the lifespan of the filtration system and ensures consistent performance.
Pros of Backflushing:
- Extended Filter Lifespan: Backflushing removes accumulated debris, preventing clogs and prolonging the life of the filter media.
- Improved Efficiency: Regular backflushing maintains optimal filtration rates, ensuring effective contaminant removal.
- Cost Savings: Longer-lasting filter media reduces replacement and maintenance costs.
Cons of Backflushing:
- Water Usage: Backflushing requires additional water, which can be a concern in water-scarce regions.
- Energy Consumption: The reversal of flow may require energy to operate valves and pumps.
- Complexity: Backflushing systems can be more complex and may require regular monitoring and maintenance.
Each prefiltration method has its own advantages and limitations, and the choice depends on the specific water source, contaminants, and treatment objectives. Careful consideration of these factors is crucial in designing an effective water treatment system incorporating UF and RO technologies.
Main treatment – Reverse Osmosis and Ultrafiltration
This brief introduction serves as an initial exploration into the realms of Reverse Osmosis (RO) and Ultrafiltration (UF). The world of membranes and filtration is extensive, encompassing a rich tapestry of specialized technologies, each designed to yield unique outcomes. This introductory overview offers a general glimpse into the transformative potential of RO and UF processes, while acknowledging the intricacies of specialized membrane applications that yield diverse results.
Ultrafiltration (UF)
Ultrafiltration is a physical filtration process that uses semi-permeable membranes with relatively large pores, typically in the range of 0.01 to 0.1 micrometres. Water is forced through these membranes, which act like fine sieves, blocking particles, colloids, bacteria, and some large molecules from passing through. However, UF allows smaller molecules and ions to permeate, making it effective for separating suspended solids and microorganisms from water. UF typically clean 80-100% of the intake water into potable water and is not too sensitive to different water temperatures. UF production typically working with 3-4 bar pressure using less power than RO production.
UF Applications
UF is effective at removing suspended solids, turbidity, bacteria, viruses, and larger molecules from water. It is used for producing high-quality drinking water from various sources, including surface water and groundwater, by removing particulate matter and microorganisms. UF is also applied in industrial processes, and wastewater treatment.
Reverse Osmosis (RO) – low salination:
Reverse Osmosis is a membrane-based process that employs a semi-permeable membrane with extremely fine pores, typically in the range of 0.0001 to 0.001 micrometres. Water is pressurized and forced through the RO membrane. This process is designed to reject the passage of dissolved salts, ions, molecules, and particles, producing highly purified water by removing almost all contaminants. Reverse Osmosis is the only technology which can remove heavy metals such as lead, copper, barium, chrome, mercury, cadmium, nitrates, selenium, and other unwanted elements. In addition, dangerous poisons such as arsenic, fluoride and pesticides will be removed.
The pores in the Membranes are smaller than bacteria such as E. coli and the parasites Giardia and Cryptosporidium. This stops them from being transported along with the rest of your drinking water.
RO typically clean 50-70% of the intake water into potable water. RO membranes are sensitive to water temperature are normally measured for their productivity at 25 Celsius. Decreases in water temperature decrease the production level due to the size of molecules, and by 7-8 Celsius you generally do not have any production. RO production typically working with 8-12 bar pressure.
RO Applications
RO is used for a wide range of applications, including desalination of seawater and brackish water to produce freshwater. It's employed in industrial processes, such as the production of ultrapure water for electronics and pharmaceutical industries. RO is a key technology for producing high-quality drinking water from various sources, including groundwater and municipal supplies. Ro water is clean enough for hospitals to use it to clean wounds.
Desalination with Reverse Osmosis (RO):
RO desalination is a game-changer for regions grappling with water scarcity, providing a lifeline of freshwater from seemingly endless oceans. Its applications extend beyond drinking water, encompassing industrial processes, agriculture, and even spacecraft hydration systems. With the ability to produce highly purified water from the most saline of sources, RO desalination is a beacon of hope in the face of global water challenges. RO desalination typically clean 10-30% of the intake water into potable water. RO membranes are sensitive to water temperature are normally measured for their productivity at 25 Celcius. Decreases in water temperature decrease the production level due to the size of molecules, and by 7-8 Celcius you generally do not have any production. RO desalination production typically working with 50-60 bar pressure.
Key Advantages of RO Desalination:
- High Purity Output: RO desalination can yield potable water with purity levels exceeding 99%, making it suitable for various applications.
- Sustainable Water Supply: It offers a sustainable and reliable source of freshwater, vital for arid coastal regions.
- Versatility: RO desalination can adapt to different saline water sources, from seawater to brackish water.
Considerations:
- Energy Intensity: RO desalination demands substantial energy input, which can impact operational costs and environmental considerations.
- Concentrated Brine: The process generates concentrated brine as a byproduct, requiring proper disposal or treatment to minimize environmental impact.
In essence, RO desalination stands as a technological marvel, unlocking the potential of vast saline water reserves to meet the ever-growing global demand for freshwater. It represents an innovative solution to the intricate challenges posed by water scarcity, offering a pathway towards a more sustainable and hydrated world.
Key Differences in technologies
Pore Size: The main difference between UF and RO lies in the size of their pores. UF membranes have larger pores that allow the passage of certain ions and small molecules, while RO membranes have much smaller pores that reject virtually all solutes, including salts and ions.
Water Quality: RO produces extremely pure water, suitable for a wide range of applications, including drinking water. UF, while effective at removing microorganisms and suspended solids, does not remove dissolved salts and ions to the same extent as RO. Knowing your water source and the aim of your water production decides the technology.
In summary, UF and RO are both membrane-based water treatment technologies, but they differ in pore size, applications, and the level of water purification they achieve.
Post treatment and measurements
In the realm of water purification, achieving pristine quality goes beyond initial filtration techniques like RO and UF. Post-treatment methods are the final steps in refining water quality, making it safe, palatable, and in line with regulatory standards. This essential stage includes options such as UV disinfection, chlorination, pH adjustment, and remineralization, each with unique benefits to tailor water quality to meet specific needs, ensuring that the water you consume is not only pure but also tastes and feels just right.
UV Disinfection
UV (Ultraviolet) light disinfection is a chemical-free method that effectively destroys microorganisms like bacteria, viruses, and protozoa in water by damaging their DNA and RNA. Technically the water pass through a tube with UV light in the right frequency and dimension.
Advantages
- It does not alter the taste, odour, or colour of the water.
- It is a sustainable and eco-friendly process as it doesn't involve the use of chemicals.
- UV treatment is highly effective against a wide range of waterborne pathogens.
Chlorination
Chlorination is a widely used method for water disinfection and pathogen removal. Technically chlorine is dosed into the water, typically to the level of 2ppm.
Advantages
- Chlorine effectively eliminates bacteria, viruses, and other pathogens.
- It offers residual protection to the clean water, helping to maintain water quality as it travels through the distribution system and into often dirty water bottles.
- Chlorine is a cost-effective and well-established method.
Remineralization
Remineralization is a process of restoring essential minerals, such as calcium and magnesium, to the purified water. This is typically used for RO water as the RO membranes removes all minerals from the water. Technically is it done by dosing minerals into the water or more ideally leaving water in a tank for 8-10 minutes with mineral granulates.
Advantages
- It enhances the taste and quality of the water, making it more palatable.
- Remineralization helps increase the pH value and maintain the pH balance of the water, reducing its corrosive properties.
- It provides important minerals that may be removed during the purification process, improving overall water health.
pH Adjustment
Adjusting the pH level of water can improve its taste and reduce corrosiveness. This is typically used for RO water as the RO process lower the pH level typically to 5-6 pH value. Technically you can dose chemicals like Bisulfide into the water or remineralize with a Calcium product.
Advantages
- pH adjustment helps prevent damage to plumbing systems caused by acidic water.
- It can enhance the overall aesthetic quality of the water for consumers.
These post-treatment options are essential to ensure that purified water is not only safe but also meets quality standards and is pleasant to drink. The choice of post-treatment methods may depend on the specific needs and characteristics of the water source and the preferences of consumers.
Further many chose to measure the quality of the potable water after the processes depending on preferences. This can be: pH level, TDS, conductivity, chloride among others.
Mission, Vision and Values
Vision
A world population with access to clean, safe and drinkable water – anytime and anywhere.
Mission
Design, manufacture and market compact and mobile water purification systems that will serve as the purpose to meet our vision – clean water for everyone.
Values
- Credibility – we honor our commitment
- Reliability – we ensure high standards and quality
- Mobility – we make deliveries in any part of the world – including parts
Our commitment includes working towards the UNs SDG goal no. 6:
References
The collaboration with MuchMoreWater is excellent. They accept challenging changes in the configuration of their applications. Their technical capabilities and know-how is big. They are passionate about their solutions, and they deliver on follow-up and attention, which make them a desirable partner.
Directorate for Civil Protection and Emergency Planning, Norway
BlueBox deployments worldwide
Our BlueBox water purification systems have been sucessfully installed worldwide for more than two decades and include deployment of over 650 units for a broad range of emergency, military and humanitarian applications. A few select references are listed below – for further details please contact info@muchmorewater.com
The BlueBox equipment has been field tested and approved by experts and is currently used by a large number of aid organizations, NGO’s disaster relief and military organisations around the world including:
- UNICEF,
- World Health Organisation (WHO)
- DANIDA
- Red Cross
- FMV (Swedish Defence Materiel Administration)
- DEMA (Danish Emergency Management Agency)
- DSB (Norwegian Directorate for Civil Protection)
- Swedish Armed Forces
- Norwegian Armed Forces
- British Army
- And many more in the Middle East, Asia and North America
NORWAY
Complete water purification systems including BlueBox water storage units for the Norwegian Civil Defence Division For Emergency Deployment. The Norwegian Armed Forces also had BlueBox units supplied for their international missions.
PAKISTAN
A number of BlueBox 1200 units were supplied and put in action during and after a major flooding event which occurred in Pakistan. This provided immediate access to clean water for thousands of locals in the area.