Recycling Water Filtration Market - Global Industry Size, Share, Trends, Opportunity, and Forecast, Segmented By Technology (Membrane Filtration, Biological Filtration, Chemical Filtration, Mechanical Filtration), By Application (Municipal, Industrial, Commercial, Agriculture), By Component (Filtration Units, Pumps, Valves, Tanks, Others), By Region, and By Competition, 2020-2030F

Market Overview

The Global Recycling Water Filtration Market was valued at USD 2.38 Billion in 2024 and is expected to reach USD 3.71 Billion by 2030 with a CAGR of 7.53% during the forecast period.

The global Recycling Water Filtration Market is witnessing robust growth, driven by increasing water scarcity, stringent government regulations, and rising environmental consciousness. As the demand for clean and sustainable water sources escalates, industries and municipalities are turning to advanced water recycling solutions. These systems help reduce freshwater consumption by treating and reusing wastewater for industrial, agricultural, and domestic purposes. The growing urban population, coupled with industrial expansion, especially in emerging economies, is exerting immense pressure on freshwater resources, further fueling the need for water recycling technologies. Filtration plays a vital role in this process, ensuring that treated water meets stringent quality standards.

Technological advancements in membrane filtration systems such as reverse osmosis (RO), ultrafiltration (UF), and nanofiltration (NF) have significantly improved the efficiency and cost-effectiveness of water recycling. Additionally, the integration of IoT and automation in filtration systems has enhanced monitoring, maintenance, and overall operational performance. Governments across the globe are actively promoting the adoption of water recycling by offering subsidies, implementing regulatory mandates, and investing in infrastructure development. For instance, several regions in the Middle East, California in the U.S., and parts of Asia Pacific are aggressively adopting wastewater reuse as a strategic response to water stress.

Industrially, sectors such as food & beverage, pharmaceuticals, oil & gas, and power generation are increasingly deploying recycling water filtration systems to meet both regulatory compliance and sustainability targets. The commercial segment, including hotels, office buildings, and malls, is also becoming a significant adopter due to rising operational costs and eco-conscious consumers. Meanwhile, agriculture remains a promising area for recycled water use, particularly in drought-prone regions where irrigation demands are high.

The market remains competitive with the presence of global players such as Veolia, Xylem, Toray Industries, and DuPont, who are continuously innovating to offer scalable and efficient solutions. Strategic collaborations, mergers, and investments in R&D are key trends shaping the competitive landscape. Overall, the global Recycling Water Filtration Market is poised for continued expansion, supported by the urgent global need to secure sustainable water resources and ensure environmental resilience.

Key Market Drivers

Water Scarcity and Depleting Freshwater Resources

The growing scarcity of freshwater across various regions is a critical driver of the recycling water filtration market. With global water demand projected to increase by over 55% by 2050, many countries are facing acute water stress. Urban expansion, climate change, and erratic rainfall patterns have significantly reduced the availability of naturally replenished water sources.

Regions like the Middle East and North Africa receive less than 500 m³ of renewable freshwater per capita annually, far below the water scarcity threshold of 1,700 m³. In India, groundwater levels are declining by 0.5 to 1 meter per year in major agricultural belts. Meanwhile, California has experienced drought conditions in 8 of the last 10 years, pushing authorities toward mandatory water reuse programs.

Filtration technologies play a pivotal role in converting wastewater into usable water for irrigation, industrial operations, and even potable purposes. Around 80% of global wastewater is discharged untreated, and only 20% is currently reused. With rising awareness, this presents a vast opportunity for recycling.

Global water demand is expected to rise by 55% by 2050. Over 2 billion people currently live in countries under high water stress. By 2025, two-thirds of the world population may face water shortages. 70% of freshwater is consumed by agriculture, which is shifting toward recycled sources. Groundwater depletion affects more than 60% of global irrigated lands.

As water becomes increasingly precious, the deployment of filtration systems to recycle and conserve existing resources is not just an option—it’s an imperative.

Stringent Government Regulations and Wastewater Discharge Norms

Governments around the world are enforcing tighter regulations concerning wastewater discharge, effluent quality, and industrial water reuse. These policies are pushing industries and municipalities to adopt advanced water filtration technologies to comply with environmental mandates.

For instance, the European Union’s Water Framework Directive and U.S. Clean Water Act impose strict penalties for non-compliance with discharge limits. In China, the government aims to recycle over 25% of its total treated wastewater by 2030. Similar efforts are being seen in India, where industries in highly polluted zones are mandated to set up zero-liquid-discharge systems.

Industries are now required to treat their effluents before release or reuse them internally to reduce their water footprint. Municipal authorities are increasingly pushing for decentralized filtration systems in urban infrastructure projects. This regulatory push has created an urgent demand for robust, reliable, and scalable water recycling systems.

China targets 25% reuse of treated wastewater by 2030. EU mandates near-zero discharge for select industrial categories. India’s CPCB classifies 22 major cities under severe wastewater risk. 95% of OECD countries have adopted policies promoting water reuse. Over 60% of Fortune 500 companies face water-related compliance audits annually.

As compliance becomes more complex and expensive, recycling water through efficient filtration is emerging as the most viable strategy for both risk mitigation and operational efficiency.

Industrialization and Growing Water Demand in Manufacturing

With industrial water demand increasing rapidly, particularly in developing economies, manufacturers are looking for cost-effective solutions to reduce freshwater dependence. Sectors like textiles, food & beverage, chemicals, and pharmaceuticals consume vast quantities of water and generate equally large volumes of wastewater.

Industrial water withdrawals account for over 20% of global freshwater use, and this figure is expected to grow with rapid urban and economic development. Recycling and treating this water with filtration systems offer dual benefits—cost savings on input water and reduction in wastewater treatment liabilities.

Many companies are now investing in membrane-based systems like reverse osmosis and ultrafiltration to create closed-loop water usage systems. For example, the textile industry can recycle up to 90% of its water, significantly cutting down on freshwater procurement costs.

Industrial sector accounts for 22% of global freshwater withdrawals. A mid-sized brewery uses around 4–7 liters of water per liter of beer produced. Textile dyeing generates 20% of the world’s industrial wastewater. Treating and reusing water can reduce industrial operational costs by up to 35%. Chemical industries discharge more than 300 billion liters of wastewater annually.

As industrial water tariffs rise and freshwater sources dwindle, companies are increasingly turning to recycling as a strategic operational shift.

Technological Advancements in Filtration and Treatment Systems

Innovations in membrane technology, real-time monitoring, and automation are transforming water recycling systems, making them more efficient, compact, and cost-effective. Advancements like nanofiltration (NF), ceramic membranes, and smart filtration units with IoT sensors are enabling highly customized and energy-efficient water treatment solutions.

New filtration systems now require 30–40% less energy and offer longer membrane life due to fouling-resistant designs. Smart controls enable predictive maintenance, which reduces system downtime and improves filtration accuracy. Additionally, modular and containerized systems allow easier scalability for decentralized installations in remote or urban applications.

Filtration manufacturers are also exploring hybrid systems combining biological and membrane-based treatments to optimize reuse performance. These developments are making recycling water filtration more attractive, especially for sectors with high water variability and stringent reuse demands.

Modern UF membranes can achieve 99.9% removal of pathogens. IoT-enabled systems can reduce maintenance costs by up to 25%. Ceramic membranes last 2–3 times longer than polymeric ones. Smart automation can cut operational expenses by 15–20%. Energy-efficient systems consume up to 40% less electricity per liter filtered.

Such technological strides not only reduce operational costs but also enable compliance with increasingly stringent discharge and reuse standards.

Rising Public Awareness and Corporate Sustainability Initiatives

There is a growing awareness among consumers, corporations, and policymakers regarding water sustainability and the environmental impact of untreated wastewater. Public pressure and ESG (Environmental, Social, Governance) commitments are compelling companies to adopt greener practices, including water recycling.

Over 80% of Fortune 500 companies now publish sustainability reports that include water usage metrics. Many of them have set targets to reduce water consumption by 30–50% in the next decade. This momentum is accelerating the deployment of recycling water filtration systems as an integral part of corporate sustainability strategies.

Public-private partnerships and certifications like LEED and ISO 14046 (water footprint) are further reinforcing the importance of water reuse. In urban areas, housing societies and commercial buildings are installing recycling systems as part of green building compliance.

Over 75% of global companies report water-related financial risks. 83% of Fortune 500 firms now track water performance in sustainability goals. Buildings with green certifications save 15–20% more water annually. 60% of millennials consider a company’s water policy when making purchases. Urban housing projects in India must include greywater recycling under new codes. With sustainability no longer optional, organizations are embracing water filtration not just as a compliance measure but as a brand-building and risk-mitigation strategy.

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Key Market Challenges

High Initial Investment and Operating Costs

One of the major hurdles in the adoption of recycling water filtration systems is the high capital and operational expenditure. Setting up advanced filtration infrastructure—especially those involving technologies like reverse osmosis (RO), ultrafiltration (UF), and nanofiltration (NF)—requires significant investment. The cost of membranes, high-pressure pumps, automation systems, and energy requirements make the initial cost barrier particularly steep for small to mid-sized companies and municipalities.

Operational costs further burden adoption, as regular membrane replacement, energy consumption, maintenance, and skilled labor are needed to keep systems running efficiently. In particular, energy usage for RO can account for up to 50% of total operating expenses. While cost savings are realized over time via reduced freshwater intake and compliance avoidance, the long payback period often deters investment.

Moreover, many developing nations lack the financial capability or government incentives to support widespread infrastructure upgrades. This creates a disparity in adoption rates between industrialized and emerging markets. Even in urban commercial buildings, small developers often shy away from installing recycling systems due to upfront costs.

The need for reliable pre-treatment to reduce fouling and scaling in filters adds another layer of complexity and cost. If not properly designed or maintained, these systems become inefficient, increasing operational costs further.

Thus, despite the long-term economic and environmental benefits, the initial financial burden remains a significant barrier to entry, especially in price-sensitive markets. Without effective funding mechanisms, incentives, or shared infrastructure solutions, many potential end users delay or abandon implementation.

Limited Public Awareness and Misconceptions About Recycled Water

Despite technological advances in water treatment, public perception and awareness around recycled water remain major challenges. A considerable portion of the population still associates recycled water with poor quality or health risks, especially when it comes to potable reuse. The "yuck factor" persists across both developed and developing regions, which hampers widespread acceptance.

In many municipalities, even when regulations allow for the use of treated water in irrigation or toilet flushing, residents resist such practices due to lack of education on the safety and efficacy of filtration systems. This limits the implementation of decentralized recycling units in residential complexes, schools, and commercial buildings.

Additionally, misinformation around the maintenance, cost, and environmental impact of filtration systems often circulates unchecked. Some believe these systems consume more energy than they save or are overly complex for smaller users, discouraging adoption. Even in industries, middle-management decision-makers sometimes lack adequate knowledge of recycling benefits, resulting in missed sustainability opportunities.

Furthermore, in regions where water is still perceived as abundant or cheap, there is little urgency to invest in recycling infrastructure. Governments and NGOs have made efforts to raise awareness, but educational outreach often fails to translate into tangible behavioral change.

In the absence of large-scale awareness campaigns, social proof, or demonstration projects, these misconceptions continue to impede progress. Bridging this knowledge gap will require stronger public-private partnerships, school-level programs, and transparent communication on the safety, economics, and environmental benefits of water recycling through effective filtration.

Technological Complexity and Maintenance Challenges

Another major obstacle in the recycling water filtration market is the complexity of filtration systems and their ongoing maintenance requirements. While technologies like RO, UF, and membrane bioreactors offer high efficiency, they demand consistent technical oversight to ensure optimal performance. Membranes are sensitive to fouling, scaling, and microbial growth, which can degrade efficiency over time if not properly maintained.

Users often struggle with selecting the right filtration technology for their specific water characteristics, leading to mismatches between system design and operational requirements. This results in frequent system breakdowns, higher downtime, and elevated maintenance costs. Additionally, many regions lack the skilled labor needed to operate and troubleshoot these systems, particularly in rural or semi-urban areas.

Moreover, filtration systems must often be customized based on the source of wastewater—industrial, municipal, or domestic—which complicates procurement and installation. For example, effluent from the textile industry may require a different pre-treatment and membrane configuration than that from food processing.

Regular replacement of cartridges, membranes, and chemical inputs adds further to the maintenance burden. In areas with inconsistent electricity supply or poor water quality, system components wear out faster, reducing equipment lifespan and increasing total cost of ownership.

The lack of centralized technical support and limited access to spare parts in many developing countries also slows repairs and raises costs. As a result, even entities that invest in water recycling infrastructure often fail to operate systems effectively over the long term.

Unless manufacturers develop more resilient, user-friendly, and self-monitoring systems, and governments invest in technical training, the technological complexity will remain a roadblock to broader market adoption.

Inconsistent Regulatory Frameworks Across Regions

Despite the global emphasis on sustainable water management, regulations governing recycled water usage and filtration systems vary significantly across countries—and even within regions of the same country. This inconsistency complicates market development and creates uncertainty for investors and technology providers.

In some developed nations, well-established guidelines clearly define water quality parameters, reuse applications, and operational procedures. However, in many emerging markets, regulations are vague, outdated, or entirely absent. For instance, while Singapore and parts of the U.S. allow potable reuse under strict controls, most countries prohibit it, even when treated water meets or exceeds drinking standards.

Industries operating in multiple jurisdictions must adapt to different compliance requirements, adding cost and complexity. In some cases, filtration systems approved in one region may not qualify under another’s standards, delaying projects and reducing investor confidence.

Moreover, enforcement of existing regulations is often weak due to limited institutional capacity. This allows untreated or partially treated wastewater to be discharged without consequences, reducing the incentive to invest in proper recycling infrastructure. Lack of coordination between local, regional, and national agencies further exacerbates the issue.

In regions without clear quality benchmarks or discharge rules, customers hesitate to invest in filtration systems, fearing future legal changes or unrecognized certifications. This stifles innovation and adoption, especially among small- and medium-sized enterprises.

Standardization and harmonization of water recycling laws, combined with strong enforcement mechanisms, are necessary to unlock the full potential of the recycling water filtration market on a global scale.

Limited Infrastructure in Emerging Economies

Many developing nations face infrastructural limitations that hinder the deployment of advanced recycling water filtration systems. Poor sewage networks, unreliable electricity, insufficient water treatment plants, and lack of waste segregation at source all contribute to challenges in implementing effective water reuse solutions.

Urban areas in low- and middle-income countries often rely on decentralized and overburdened water systems. Without access to stable water flow or reliable wastewater collection, filtration systems cannot operate efficiently or continuously. In rural regions, the lack of even basic sanitation infrastructure renders modern recycling technology impractical without foundational investment.

Additionally, the absence of proper waste management systems means that recycled water may be contaminated due to inadequate pre-treatment or illegal dumping. This limits both the quality and safety of recycled water, undermining public trust and potential use in agriculture, industry, or municipalities.

Transporting and installing equipment in remote areas also adds cost and complexity. Many areas lack trained technicians, logistical access, or parts supply chains necessary for system maintenance and troubleshooting. Even when governments announce ambitious water recycling programs, weak infrastructure and limited budgets often derail execution.

In these regions, donor agencies or multilateral institutions typically finance pilot projects. However, without long-term financial and technical sustainability plans, these initiatives often fail to scale. This has created a perception that water recycling is only viable in urban or industrial hubs, further delaying broader adoption.

Addressing infrastructure gaps will require massive coordinated investment, capacity building, and inclusive policy design to ensure that even underserved regions can benefit from recycled water filtration technologies.

Key Market Trends

Growing Adoption of Decentralized and Modular Filtration Systems

The rising preference for decentralized and modular water filtration systems is another significant trend transforming the recycling water filtration market. Traditional centralized water treatment plants are often expensive, inflexible, and slow to deploy—especially in remote, underserved, or fast-growing urban areas. Modular systems offer a scalable, transportable, and cost-effective alternative.

Decentralized filtration units can be deployed at the source—residential complexes, industrial facilities, commercial buildings, and construction sites—where wastewater is generated. This allows for on-site treatment and reuse, reducing the need for long-distance water transport and complex sewage infrastructure.

These modular units are often skid-mounted or containerized, pre-assembled with all necessary components (filters, pumps, membranes, control units) and are plug-and-play, requiring minimal civil work. Their flexible design makes them ideal for temporary operations or rapidly growing regions that need scalable infrastructure.

Such systems are gaining popularity in countries like India, Kenya, and Indonesia, where water scarcity coincides with limited infrastructure investment. Industries such as mining, oil & gas, and food processing are also investing in mobile modular units to meet fluctuating operational demands.

In urban areas, local governments and private developers are using decentralized systems to comply with green building regulations and reduce water consumption. These systems are also favored in disaster relief or humanitarian operations where rapid deployment is crucial.

This trend aligns with the broader push toward distributed infrastructure that is more resilient, sustainable, and adaptive to local conditions, helping bridge the water treatment gap in both developed and emerging markets.

Rise of Membrane-Based Advanced Filtration Technologies

The global water recycling industry is witnessing a growing shift toward membrane-based filtration systems, such as reverse osmosis (RO), ultrafiltration (UF), nanofiltration (NF), and microfiltration (MF). These technologies are rapidly gaining traction due to their high filtration accuracy, efficiency, and ability to remove contaminants at the molecular level.

Membrane technologies can remove bacteria, viruses, dissolved salts, organic compounds, and even microplastics, making them ideal for applications ranging from industrial reuse to potable water reclamation. RO systems, for instance, are widely used in the beverage and electronics industries where ultrapure water is essential.

Recent innovations have improved membrane durability, reduced fouling, and lowered energy consumption—historically major challenges in membrane adoption. Energy-efficient designs now reduce operational costs by 30–40%, while new anti-fouling coatings extend membrane life by up to 60%. Hybrid systems combining membranes with biological or chemical treatments are also gaining popularity.

Membrane technologies are also being miniaturized and modularized, allowing them to be integrated into decentralized setups or compact installations. This flexibility is encouraging broader adoption across residential, commercial, and industrial applications.

In water-scarce regions like the Middle East, Southern Europe, and parts of the U.S., membrane systems are forming the backbone of large-scale water reuse projects. Additionally, municipal agencies are leveraging these systems to achieve higher treatment standards for wastewater discharge.

As the cost of membranes continues to decrease and their efficiency improves, membrane-based filtration is expected to dominate the future of water recycling technologies worldwide, offering both environmental and economic advantages.

Emphasis on Zero Liquid Discharge (ZLD) Solutions

A significant trend influencing the recycling water filtration market is the increasing focus on Zero Liquid Discharge (ZLD) systems, particularly in highly regulated industrial sectors. ZLD is a treatment process that eliminates all liquid waste, ensuring that no water leaves the facility as effluent. Instead, the water is recovered and reused, and solids are safely disposed of or reused.

Industries such as textiles, chemicals, pharmaceuticals, and power generation are being mandated to adopt ZLD to minimize environmental pollution. ZLD systems combine multiple filtration and treatment stages—such as pre-treatment, membrane filtration, evaporators, and crystallizers—to achieve complete water recovery.

The push for ZLD is being driven by regulatory pressures, rising environmental liabilities, and growing corporate sustainability goals. In India and China, government policies now require ZLD compliance in certain industrial zones, driving significant investment in advanced filtration infrastructure.

While ZLD systems are capital-intensive and energy-demanding, advancements in membrane distillation, thermal energy recovery, and automation are helping lower costs and improve feasibility. Modular ZLD solutions are also becoming available for mid-sized industrial units, further expanding the addressable market.

Adopting ZLD not only helps companies reduce freshwater intake but also shields them from the risks associated with regulatory fines, shutdowns, or reputational damage due to illegal discharge. The trend is likely to intensify as global environmental regulations tighten and industries look for long-term solutions to their water-related sustainability challenges.

As more regions adopt stricter wastewater discharge norms, ZLD solutions—powered by efficient filtration systems—are poised to become the gold standard in industrial water management.

Segmental Insights

Technology Insights

Membrane Filtration segment dominates in the Global Recycling Water Filtration market in 2024 due to its superior efficiency, adaptability, and scalability across various end-use sectors. Membrane filtration technologies—including reverse osmosis (RO), ultrafiltration (UF), nanofiltration (NF), and microfiltration (MF)—offer precise separation of contaminants, enabling the production of high-purity recycled water suitable for industrial, municipal, and even potable applications. One of the key drivers behind this dominance is the high removal efficiency of suspended solids, pathogens, heavy metals, dissolved salts, and organic compounds. This makes membrane systems particularly suitable for industries like food & beverage, pharmaceuticals, and power generation, where water quality is critical. In fact, membrane systems can remove up to 99% of bacteria and viruses, making them ideal for high-risk environments.

Technological advancements have made membrane systems more energy-efficient and less prone to fouling, with newer materials offering extended life cycles and self-cleaning capabilities. For example, the introduction of anti-fouling coatings and hybrid membrane systems has reduced cleaning frequency by 30–40%, lowering operational costs. The modular design of membrane systems also allows for decentralized deployment, making them attractive for small-scale residential, commercial, and industrial users. These systems are often pre-fabricated, easy to install, and require less civil infrastructure, which speeds up deployment and reduces costs. Environmental regulations mandating high-quality wastewater discharge and water reuse have further fueled adoption. In many countries, regulatory bodies now encourage or mandate the use of membrane technology in water recycling projects, boosting the segment’s growth.

Additionally, the membrane filtration segment benefits from rising ESG commitments by corporations, with many investing in closed-loop water systems that rely on advanced membrane technology to minimize freshwater usage and wastewater discharge. Due to these advantages, membrane filtration continues to be the preferred and dominant solution in the global recycling water filtration market.

Application Insights

Municipal segment dominated the Global Recycling Water Filtration market in 2024 due to increasing urbanization, rising water demand, and stringent wastewater discharge regulations. Cities are investing heavily in advanced filtration systems to reclaim and reuse water for non-potable purposes such as landscaping, toilet flushing, and industrial supply. Government initiatives promoting sustainable water management, along with funding for smart city infrastructure, are accelerating adoption. Municipal utilities prefer membrane-based and biological filtration technologies for their high efficiency and scalability. With growing water scarcity concerns, municipalities are prioritizing closed-loop systems to ensure long-term water security and environmental compliance.

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Regional Insights

Largest Region

North America dominated the Global Recycling Water Filtration market in 2024 due to a combination of advanced infrastructure, strong regulatory frameworks, high environmental awareness, and significant investment from both public and private sectors. The region—especially the United States and Canada—has long prioritized water sustainability, driven by increasing water scarcity, aging water infrastructure, and the need to meet stringent discharge and reuse standards.

One of the key factors is the stringent environmental regulations enforced by agencies like the U.S. Environmental Protection Agency (EPA), which mandate proper wastewater treatment and promote water reuse in municipalities and industries. Compliance with these regulations has encouraged the widespread adoption of advanced filtration technologies, including membrane bioreactors (MBRs), ultrafiltration (UF), and reverse osmosis (RO).

The municipal sector in North America is leading the shift toward recycling treated wastewater for non-potable and indirect potable applications. Cities like Los Angeles, San Diego, and Phoenix have implemented large-scale water recycling programs to address long-term drought and groundwater depletion challenges. These initiatives are heavily reliant on filtration systems that ensure water safety and regulatory compliance.

Industrially, sectors such as pharmaceuticals, food & beverage, oil & gas, and semiconductors are investing in water recycling to meet internal sustainability goals and reduce operational costs. The region’s strong focus on ESG (Environmental, Social, and Governance) compliance further accelerates adoption of high-efficiency filtration systems.

Technological advancement also plays a critical role. North American companies are at the forefront of developing smart, IoT-enabled water filtration systems, allowing real-time monitoring, predictive maintenance, and performance optimization. This improves reliability and encourages broader deployment.

Government funding, private investment, and rising consumer awareness around water conservation all reinforce North America’s leadership. As water stress intensifies and sustainability targets tighten, the region continues to drive innovation and market growth in the global recycling water filtration sector.

Emerging Region

Europe was the emerging region in the Global Recycling Water Filtration market in the coming period due to its strong commitment to sustainability, circular economy policies, and EU-wide water reuse regulations. Countries like Spain, Germany, and the Netherlands are leading initiatives in wastewater recycling for agricultural, industrial, and urban applications. The EU’s Water Reuse Regulation (2020/741), effective from 2023, mandates safe and efficient reuse practices, driving demand for advanced filtration technologies. Additionally, increasing climate-related water stress and public funding for green infrastructure are accelerating market growth. Innovation in membrane filtration and decentralized treatment systems also supports Europe’s expanding role in this market.

Recent Developments

• In May 2025, SUEZ, in partnership with CTCI Group and Hung Hua, commenced construction of Taiwan’s first large-scale municipal reverse osmosis desalination facility in Hsinchu. The groundbreaking event, attended by over 200 dignitaries including the Prime Minister and Economic Affairs Minister, highlights a major advancement in securing long-term water resilience for residents and local industries. This initiative underscores SUEZ’s commitment to addressing water scarcity challenges in fast-growing regions through advanced desalination infrastructure.
• In October 2024, during the French President’s state visit to Morocco, Veolia and the Kingdom of Morocco signed a Memorandum of Agreement for a strategic desalination project near Rabat. Structured as a 35-year public-private partnership, the facility will produce 822,000 m³/day—Africa’s largest and the world’s second-largest plant—delivering potable water to 9.3 million residents in drought-affected regions. This agreement reinforces Veolia’s leadership in sustainable water infrastructure across emerging markets.
• In March 2025, Larsen & Toubro (L&T), in joint venture with Spain’s Lantania, signed a contract with ACWA Power to construct a large-scale SWRO desalination plant in Saudi Arabia. Executed under L&T’s Water & Effluent Treatment division, the project will serve the Makkah and Al-Baha regions, providing drinking water for nearly one million people. This strategic agreement enhances L&T’s footprint in the Middle East’s critical infrastructure development sector.
• In April 2025, SUEZ, in collaboration with JEMCO and Metro Pacific Water (MPW), began construction of the Philippines’ largest SWRO desalination facility in Metro Iloilo. Scheduled for completion in 24 months, the project will significantly improve water availability for local communities facing acute shortages. This venture strengthens SUEZ’s presence in Southeast Asia’s water sector and aligns with MPW’s strategy to expand access to sustainable water infrastructure across the Philippines.

Key Market Players

• Veolia 
• Toray Industries, Inc.
• Xylem Inc.
• DuPont
• KUBOTA Corporation
• NEWater
• Hongtek Filtration Co. Ltd.
• Swati Water Purification
• REE & Company Engineering Works
• Pure Aqua, Inc. 

Report Scope:

In this report, the Global Recycling Water Filtration Market has been segmented into the following categories, in addition to the industry trends which have also been detailed below:

•  Recycling Water Filtration Market, By Technology:

o   Membrane Filtration

o   Biological Filtration

o   Chemical Filtration

o   Mechanical Filtration

• Recycling Water Filtration Market, By Application:

o   Municipal

o   Industrial

o   Commercial

o   Agriculture

• Recycling Water Filtration Market, By Component:

o   Filtration Units

o   Pumps

o   Valves

o   Tanks

o   Others

• Recycling Water Filtration Market, By Region:

o   North America

§  United States

§  Canada

§  Mexico

o   Europe

§  Germany

§  France

§  United Kingdom

§  Italy

§  Spain

o   South America

§  Brazil

§  Argentina

§  Colombia

o   Asia-Pacific

§  China

§  India

§  Japan

§  South Korea

§  Australia

o   Middle East & Africa

§  Saudi Arabia

§  UAE

§  South Africa

Competitive Landscape

Company Profiles: Detailed analysis of the major companies present in the Global Recycling Water Filtration Market.

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