Water Infrastructure Development Market - Global Industry Size, Share, Trends, Opportunity, and Forecast, Segmented By Infrastructure Type (Water Supply Infrastructure, Wastewater Infrastructure, Stormwater Management Infrastructure), By End-User (Residential, Commercial, Industrial, Municipal), By Project Type (New Construction, Rehabilitation & Upgrades, Operations & Maintenance), By Region & Competition, 2020-2030F

Market Overview

The Global Water Infrastructure Development Market was valued at USD 25.84 Billion in 2024 and is expected to reach USD 46.44 Billion by 2030 with a CAGR of 10.10% during the forecast period.

The global Water Infrastructure Development Market is experiencing significant growth, driven by increasing demand for clean and reliable water supply, growing concerns over water scarcity, rapid urbanization, and the urgent need for modernization of aging infrastructure. With global water consumption rising due to population growth, industrialization, and agricultural expansion, governments and private sector players are investing heavily in water infrastructure projects to ensure long-term sustainability and resource efficiency. This includes the construction and rehabilitation of water treatment plants, distribution pipelines, wastewater treatment facilities, stormwater drainage systems, and smart water management systems. Climate change has further amplified the urgency for resilient and adaptive water infrastructure capable of withstanding extreme weather events, floods, and droughts.

Developed economies such as the United States, Canada, Germany, and Japan are focusing on upgrading outdated water networks and incorporating digital technologies such as IoT, SCADA, and AI-based monitoring systems to reduce leakage, improve efficiency, and ensure compliance with stringent environmental regulations. In contrast, developing nations across Asia-Pacific, Latin America, the Middle East, and Africa are channeling investments into greenfield infrastructure to expand access to clean water and sanitation services for underserved populations. The Asia-Pacific region, in particular, is emerging as the fastest-growing market, fueled by massive infrastructure spending in countries like China, India, and Southeast Asian nations, along with strong government-backed initiatives for urban water supply and sewage treatment.

Private-public partnerships (PPPs), international funding from organizations such as the World Bank and the Asian Development Bank, and government policy support are playing a crucial role in enabling large-scale water projects globally. Additionally, the growing emphasis on circular water economy principles—such as water reuse, desalination, and rainwater harvesting—is influencing infrastructure planning and technology deployment. The market is also witnessing increased participation from global EPC firms, equipment manufacturers, and technology providers, who are competing to deliver efficient, integrated water solutions.

Despite the promising outlook, the market faces challenges such as high capital costs, long project cycles, regulatory complexities, and issues related to water rights and inter-agency coordination. However, the strategic importance of water security and sustainability continues to position water infrastructure development as a critical investment area for both governments and businesses. With continued innovation, financing, and policy alignment, the global Water Infrastructure Development Market is poised to witness robust growth over the coming years.

Key Market Drivers

Increasing Water Scarcity and Demand

Rising global water demand and diminishing freshwater availability are significantly driving investments in water infrastructure. Nearly 4 billion people experience water scarcity at least one month per year. Global water consumption has increased by around 600% over the last century and continues to rise by approximately 1% annually. Projections suggest water demand will surge by 55% by 2050, particularly driven by agriculture, which already accounts for about 70% of freshwater withdrawals. Around 25 countries currently experience extremely high baseline water stress, withdrawing over 80% of their available renewable water supply. Urban water losses due to leakage amount to approximately 32 billion cubic meters annually—equal to financial losses of over $9 billion globally.

This widespread water stress is accelerating efforts to expand and modernize water infrastructure. New reservoirs, expanded pipeline networks, and smart water management systems are being prioritized to meet increasing domestic, industrial, and agricultural demands. Additionally, the growing gap between supply and demand in water-scarce regions is fostering the development of desalination and water reuse systems. Governments and utilities are compelled to act, making infrastructure upgrades a strategic necessity to ensure water security.

Non-Revenue Water (NRW) and System Inefficiencies

Water utilities worldwide are facing major challenges due to high levels of Non-Revenue Water (NRW), which includes physical losses from leaks and administrative losses due to inaccurate metering or theft. On average, utilities lose 25–30% of their treated water through NRW each year. In monetary terms, these losses cost global utilities approximately USD39 billion annually. In some cities, NRW levels exceed 50%, significantly impacting operating margins. Smart meters and pressure management systems have shown to reduce NRW by as much as 30% within a few years. In major urban centers, addressing NRW can yield a return on investment within 3 to 5 years.

With water loss becoming a measurable economic and environmental liability, utilities are actively investing in infrastructure that minimizes wastage. This includes the deployment of smart sensors, pipeline rehabilitation, and advanced metering systems. Municipalities are also tightening regulations, setting specific NRW reduction targets, and linking funding approvals to system performance improvements. Reducing NRW is not only essential to safeguard water resources but also crucial for maintaining public trust and financial sustainability of water services.

Digitalization and Smart Water Technologies

Digital transformation is reshaping how water infrastructure is planned, operated, and maintained. Over 80% of water utilities have either implemented or are developing digital strategies. More than 65% of urban water systems now incorporate smart metering technologies. Approximately 43% of utilities globally are integrating IoT-enabled sensors across their networks. AI-powered platforms are being used by over 60% of utilities for predictive maintenance and real-time analytics. Leak detection using digital tools has reduced water losses by up to 25% in many cities.

Digital systems allow utilities to monitor consumption, detect leaks, manage pressure, and optimize water distribution in real time. As water infrastructure becomes more complex, utilities are shifting to integrated platforms that unify physical and digital assets. In addition, cloud-based SCADA systems and digital twins are enabling utilities to simulate water flows and predict future infrastructure needs. As a result, decision-making is more data-driven, allowing proactive rather than reactive maintenance. Digitalization not only improves operational efficiency but also enhances transparency and customer engagement, making it an essential driver in modern water infrastructure development.

Aging Infrastructure and Urban Expansion

Many regions face a growing crisis due to aging water infrastructure. In the United States alone, an estimated 2.1 trillion gallons of treated water are lost annually due to old and leaking pipes. More than 30% of global water pipes are over 40 years old, and many have exceeded their expected service life. In Europe, over 40% of water infrastructure requires replacement or significant refurbishment within the next decade. Around 20% of global urban areas report frequent service disruptions due to failing infrastructure. Repairing and replacing outdated systems can reduce system losses by up to 50% in some municipalities.

As urban populations expand, the pressure on water systems increases, requiring not just maintenance but complete overhauls. Old cast iron and asbestos cement pipelines are being replaced with ductile iron and HDPE. Urban areas are also expanding their networks to accommodate new residential, commercial, and industrial developments. This necessitates investment in pipelines, booster stations, and high-capacity treatment facilities. Governments are prioritizing infrastructure upgrades to ensure water safety, reduce losses, and improve resilience against climate change. Infrastructure renewal is no longer optional—it is critical to sustaining reliable water service delivery.

Government Policies, Funding, and Regulation

Government policies and regulatory frameworks are playing a crucial role in driving water infrastructure development worldwide. Over USD55 billion has been allocated by the U.S. government under recent legislation specifically for water system modernization. India has committed nearly USD50 billion to rural water projects under national programs. The European Union mandates a 25% reduction in water leakage by 2025 in drought-prone regions. More than 60 countries now require digital water metering in new developments. Globally, public-private partnerships (PPPs) in water infrastructure projects have increased by over 40% in the last five years.

These initiatives are backed by international financial institutions offering grants, subsidies, and low-interest loans to support long-term infrastructure upgrades. Regulatory compliance around water quality, effluent discharge, and leakage prevention is also becoming more stringent, pushing utilities to invest in new technologies and resilient infrastructure. Many governments have also introduced performance-based funding, linking financial support to outcomes such as service coverage, efficiency, and environmental impact. With policy momentum and capital support aligned, the role of regulation and funding is pivotal in accelerating global water infrastructure modernization.

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Key Market Challenges

High Capital Costs and Long Payback Periods

One of the primary challenges in the water infrastructure development market is the high capital investment required for project planning, execution, and maintenance. Large-scale infrastructure such as water treatment plants, desalination facilities, pipelines, and distribution networks often demand hundreds of millions of dollars. Additionally, the financial return on these projects tends to be long-term, with a payback period ranging from 10 to 25 years.

Developing nations, where infrastructure needs are most acute, often struggle to mobilize adequate funding due to budget constraints, low credit ratings, and limited access to international financing. Private investors, meanwhile, are deterred by the sector’s low profit margins and high regulatory involvement. Even when funding is available, bureaucratic hurdles, land acquisition issues, and lengthy environmental approvals delay disbursement and execution. Cost overruns are also common due to fluctuating material and labor costs, outdated planning tools, and unforeseen geological or climatic conditions.

Moreover, operational and maintenance costs are often underestimated, particularly in remote or rural areas. Lack of cost recovery mechanisms, such as metered tariffs or reliable billing systems, makes long-term financial sustainability a concern. Governments and utilities are often forced to subsidize services, which places additional strain on public finances.

These financial challenges hinder timely project execution and expansion, particularly in low- and middle-income countries. To address this, governments need to explore innovative funding mechanisms like blended finance, outcome-based investments, and stronger public-private partnerships. Without sustainable financial models, the pace of water infrastructure development may remain insufficient to meet global water security goals.

Regulatory Complexity and Institutional Fragmentation

The water sector is governed by a complex web of regulations, guidelines, and institutional responsibilities, often overlapping across local, regional, and national levels. In many countries, water supply, wastewater treatment, irrigation, and flood control fall under the jurisdiction of different ministries or agencies, leading to fragmented governance. This lack of coordination results in delayed decision-making, duplicated efforts, and inefficient resource allocation.

For example, a water treatment plant might require permits from environmental authorities, approvals from health departments, land use permissions from urban planning bodies, and compliance with utility standards—all managed by different institutions. The permitting process can take 2–4 years in many regions, delaying project implementation. Inconsistent or outdated regulatory frameworks, particularly in developing countries, further complicate compliance.

Moreover, water pricing policies are often politically sensitive and rarely reflect the true cost of service delivery. This leads to underinvestment in system upgrades and distorts market signals. In some regions, utilities are barred from raising tariffs, even when operational expenses rise significantly. In others, private sector participation is restricted or subject to unclear concession terms, discouraging investment.

Lack of standardized performance benchmarks across utilities makes it difficult to compare or incentivize efficiency. Disputes between municipalities and federal governments over service responsibility also lead to service gaps and infrastructure neglect.

To overcome these challenges, countries must work toward integrated water resource management (IWRM), clearer institutional mandates, and harmonized regulations. Capacity building, policy reforms, and enhanced transparency can help create a more enabling environment for investment and coordinated infrastructure development.

Aging Infrastructure and Legacy System Failures

Aging water infrastructure is a growing challenge, particularly in developed countries where much of the water supply and sewer systems were built over 50 to 100 years ago. These systems are increasingly prone to leakage, bursts, and contamination. For instance, in the U.S., an estimated 2.1 trillion gallons of treated water is lost each year due to leaking pipes. Similarly, many European cities report leakage rates of 20–30%.

Old infrastructure materials such as cast iron, asbestos cement, or clay often corrode, crack, or collapse under pressure. These systems were not designed to accommodate today’s higher demand, variable climate patterns, or advanced technologies. Retrofitting or replacing them is both technically complex and extremely costly, often requiring road excavation and service disruptions.

Another key issue is the lack of accurate documentation and mapping of legacy systems, which complicates planning and integration with new technologies like IoT sensors or digital twins. In many cases, critical infrastructure is buried without records, posing significant risks during maintenance or expansion.

Moreover, asset management is often reactive rather than preventive, resulting in deferred maintenance and increased vulnerability. Utilities often lack the data and tools to conduct condition assessments or prioritize repairs based on lifecycle cost analysis. In addition, older systems are more energy-intensive, less efficient, and harder to monitor remotely.

Upgrading legacy infrastructure requires not just capital, but also skilled workforce, regulatory coordination, and public buy-in. Without urgent and sustained investment, aging infrastructure will continue to pose reliability, safety, and environmental risks, undermining broader water security and service quality goals.

Climate Change and Environmental Vulnerability

Climate change is significantly impacting water infrastructure planning and sustainability. Rising global temperatures, altered precipitation patterns, sea-level rise, and more frequent extreme weather events—such as floods, droughts, and cyclones—are placing water systems under increased stress.

Urban flooding is becoming a regular occurrence in many parts of Asia, Africa, and Latin America. Many existing drainage systems are unable to handle storm events that now occur 20–30% more frequently than just two decades ago. Similarly, prolonged droughts in water-scarce regions are reducing the availability of surface water and groundwater, straining water treatment and distribution networks.

Sea-level rise, projected to exceed 1 meter by 2100, threatens coastal infrastructure, including desalination plants and intake structures. Saline intrusion into freshwater aquifers is also becoming a concern, especially in deltaic and island regions. Meanwhile, higher water temperatures and reduced flows impact the efficiency of biological wastewater treatment processes and increase the risk of pathogen growth.

These challenges necessitate a paradigm shift in design—from static to adaptive and resilient infrastructure. This includes the use of elevated structures, corrosion-resistant materials, flexible storage systems, and nature-based solutions like wetlands or permeable pavements. However, integrating climate resilience adds 20–40% to upfront capital costs, which not all municipalities can afford.

Long-term planning under uncertain climatic scenarios also requires robust modeling and real-time data, which are often lacking in developing countries. Failure to adapt infrastructure to climate realities not only threatens service reliability but also poses safety and environmental risks. Addressing climate vulnerability must therefore be central to all future water infrastructure strategies.

Skilled Workforce Shortage and Knowledge Gaps

A critical yet often overlooked challenge in water infrastructure development is the shortage of skilled personnel across planning, engineering, construction, and operations. The sector relies heavily on civil, mechanical, and environmental engineers, water treatment specialists, SCADA technicians, and asset managers—all of whom are in short supply, especially in developing economies.

In many countries, the average age of water utility workers exceeds 50 years, indicating an imminent wave of retirements. Simultaneously, fewer young professionals are entering the sector, perceiving it as less innovative or rewarding compared to fields like IT or finance. Technical trades like pipefitting, welding, and pump maintenance are also experiencing a 20–40% decline in new entrants in recent years.

Digital transformation compounds the challenge. The deployment of smart meters, GIS mapping, digital twins, and IoT-enabled systems requires new skill sets in data analytics, cybersecurity, and software integration. However, many utilities still rely on legacy training models that don’t address these evolving needs. Staff retraining takes 6–12 months and often requires external partnerships or costly certifications.

Limited training budgets, high turnover, and poor knowledge management practices further exacerbate the situation. In smaller utilities, the departure of a few experienced staff can significantly impact institutional capacity and continuity.

To build a resilient and future-ready workforce, the sector must invest in capacity building, vocational training, and public-private collaboration in education. Upskilling programs, mentorship pipelines, and cross-sector mobility can also help bridge the talent gap. Without adequate human resources, even the best-funded infrastructure projects may underperform or fail to deliver sustainable outcomes.

Key Market Trends

Rise of Decentralized Water Treatment Solutions

Traditionally, water treatment systems have been centralized, with large plants servicing entire cities. However, a growing trend toward decentralized systems is reshaping the market, especially in rural, peri-urban, and rapidly urbanizing areas. These smaller, modular systems are closer to the point of use, offering advantages such as reduced transmission losses, faster deployment, and lower upfront investment.

Decentralized solutions include compact wastewater treatment units, containerized drinking water systems, and on-site greywater recycling technologies. They are particularly effective in addressing the needs of communities with limited access to municipal infrastructure, disaster-prone regions, and off-grid industries. Their scalability allows for phased investments that align with local population growth or industrial demand.

In addition to addressing coverage gaps, decentralized systems also support circular water use by promoting reuse and reducing dependency on fresh sources. Regulatory bodies in many countries are beginning to support this shift by introducing policies and standards that promote decentralized wastewater reuse and treatment. As demand for flexible, sustainable, and community-specific solutions increases, decentralized infrastructure is expected to play a more prominent role in the market’s evolution.

Increasing Focus on Water Reuse and Recycling

With freshwater resources under pressure, water reuse and recycling are gaining traction globally as sustainable alternatives to meet industrial, agricultural, and even potable needs. Municipalities and industries are increasingly adopting wastewater recycling systems that treat and repurpose greywater and effluent for irrigation, cooling, and toilet flushing. Advanced treatment technologies—such as membrane bioreactors (MBR), UV disinfection, and reverse osmosis—have made treated wastewater safe and economically viable for reuse.

Governments are implementing mandates and incentive schemes to promote water reuse. For example, in water-stressed regions, building codes now require dual plumbing systems for recycled water use. Industrial zones are also being developed with centralized recycling facilities, while residential projects include rooftop rainwater harvesting and reuse of domestic greywater.

This trend is being driven not only by water scarcity but also by the need to reduce environmental discharge and pollution. Companies seeking ESG compliance are integrating zero-liquid-discharge systems into their operations. As sustainability becomes a top priority in urban planning and industrial development, water reuse will continue to rise as a cornerstone of future infrastructure design.

Emergence of Nature-Based and Green Infrastructure Solutions

As urban centers face more frequent flooding and ecosystem degradation, nature-based solutions (NBS) and green infrastructure are emerging as viable complements to traditional grey infrastructure. These include constructed wetlands, rain gardens, bioswales, permeable pavements, and green roofs. Such systems manage stormwater naturally by enhancing infiltration, filtration, and storage.

Green infrastructure helps mitigate urban flooding, reduce runoff pollution, and recharge aquifers—all while offering aesthetic and ecological benefits. For example, bioswales along urban roads not only control stormwater but also improve biodiversity and air quality. Cities around the world are embedding such designs into their urban plans to enhance climate resilience and comply with environmental regulations.

Public-private partnerships are also forming to fund these sustainable interventions. Nature-based infrastructure often involves lower capital and operational costs over the long term compared to conventional systems. It also aligns with carbon neutrality and climate action goals, making it attractive to donors, urban planners, and investors alike. As awareness of climate resilience grows, the integration of green infrastructure in water planning will become more widespread.

Adoption of Resilient Infrastructure for Climate Adaptation

Climate change has become a major design consideration in water infrastructure planning. Rising sea levels, prolonged droughts, and increasingly intense storms are putting traditional systems under strain. As a result, water utilities and governments are increasingly adopting resilient design principles that anticipate and adapt to climate risks.

Key practices include elevating critical facilities above flood zones, using corrosion-resistant and temperature-tolerant materials, and designing flexible storage and distribution networks that can handle extreme variability. Desalination plants are being designed with backup power and brine management systems, while stormwater infrastructure is being upsized to handle 100-year floods occurring more frequently.

Moreover, infrastructure is being co-designed with hydrologists and climate scientists using simulation models that account for future climate scenarios. These systems aim not only to survive climate shocks but to continue functioning during and after them. Resilience planning is also being incentivized by international lenders and insurance firms, which link project financing to climate risk assessments.

As the frequency and intensity of climate-related events grow, the demand for climate-resilient water infrastructure is expected to become a defining trend in the global market over the next decade.

Segmental Insights

Infrastructure Type Insights

Water Supply Infrastructure segment dominated in the Global Water Infrastructure Development market in 2024 due to a combination of rising demand, aging infrastructure, rapid urbanization, and increasing government investments. This segment includes essential components such as water treatment plants, transmission pipelines, distribution networks, pumping stations, and storage reservoirs that ensure the delivery of potable water to urban and rural populations.

A primary driver is the surging global demand for clean and safe drinking water. As of 2024, over 2 billion people still lack access to safely managed drinking water services. Rapid population growth, especially in developing regions across Asia and Africa, is placing immense pressure on existing supply systems, pushing governments to expand and upgrade infrastructure. Additionally, urbanization is accelerating, with an estimated 55% of the global population now living in cities—a figure projected to reach 68% by 2050—increasing the need for robust municipal water supply systems.

Another major factor is the deteriorating state of existing water supply networks in developed nations. In countries like the U.S., many water mains are over 60 years old, leading to frequent pipe bursts, leakages, and contamination. The need to replace or rehabilitate these aging systems is driving large-scale investments.

Furthermore, climate change has intensified water supply challenges. Extended droughts and water stress in regions such as California, the Middle East, and Australia are prompting investments in resilient infrastructure, including inter-basin transfer systems and desalination-integrated supply networks. In response, global and regional authorities are allocating substantial budgets. For instance, several national infrastructure plans in 2024 include multi-billion-dollar allocations specifically for water supply enhancement.

Technological advancements such as smart meters and SCADA systems are also being incorporated into supply infrastructure to improve efficiency and monitoring. Together, these factors make the Water Supply Infrastructure segment the cornerstone of the global water infrastructure development market in 2024.

End-User Insights

Residential segment dominated the Global Water Infrastructure Development market in 2024 due to rapid urban population growth, increased housing construction, and rising demand for reliable and safe household water access. Over 55% of the global population now lives in urban areas, leading to significant pressure on municipal water networks. Governments are prioritizing water infrastructure in residential zones to address shortages, reduce leakage, and improve sanitation. Additionally, smart water metering, rainwater harvesting systems, and decentralized treatment solutions are increasingly adopted in housing projects, reinforcing the residential sector’s dominance in water infrastructure investments and development initiatives globally.

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Regional Insights

Largest Region

North America dominated the Global Water Infrastructure Development market in 2024 due to a combination of aging infrastructure replacement, substantial federal funding, advanced technology adoption, and strong regulatory frameworks. The region’s water systems, particularly in the United States and Canada, are among the oldest globally, with many pipelines and treatment facilities exceeding 50–100 years in age. This has resulted in increased system failures, leaks, and contamination risks, prompting urgent modernization efforts.

A key driver is the massive public investment in infrastructure. In the U.S., the Bipartisan Infrastructure Law allocated USD55 billion specifically for water system upgrades, including lead pipe replacement, new treatment facilities, and improved drinking water access in underserved communities. Similarly, Canada has committed billions to water and wastewater projects under its “Investing in Canada Infrastructure Program,” focusing on improving rural and Indigenous community services.

Technological advancement is another major factor behind North America’s lead. Utilities across the region are increasingly deploying smart water technologies, including IoT sensors, AI-powered leak detection, SCADA systems, and digital twins, which improve efficiency and reduce operational costs. In fact, more than 70% of utilities in the U.S. have integrated smart metering or are in the process of deployment.

Moreover, North America has robust environmental and water quality regulations enforced by agencies like the U.S. Environmental Protection Agency (EPA) and Health Canada, which mandate compliance with stringent drinking water and effluent discharge standards. These regulations compel municipalities and utilities to continually invest in infrastructure upgrades to avoid penalties and ensure public health.

Climate resilience also plays a critical role, as the region faces increasing threats from droughts, floods, and extreme weather. As a result, infrastructure is being designed with greater resilience and adaptability. Combined, these factors position North America as the leading region in the global Water Infrastructure Development market in 2024.

Emerging Region

Europe was the emerging region in the Global Water Infrastructure Development market in the coming period due to aging infrastructure, increasing water stress, and stringent environmental regulations. Many EU countries face leakage rates exceeding 25%, prompting urgent modernization of pipelines and treatment systems. The European Union has set ambitious goals, including a 25% reduction in water loss by 2025 and expanded wastewater reuse targets. Climate change impacts, such as severe droughts and floods, are accelerating investments in resilient and green water infrastructure. Additionally, significant EU funding and public-private partnerships are supporting large-scale projects, driving market growth across the continent.

Recent Developments

• In March 2025, VA Tech WABAG signed a non-binding term sheet to establish a dedicated investment platform targeting municipal water infrastructure. The platform is expected to commit up to USD100 million in equity investments over the next three to five years. This strategic initiative aligns with WABAG’s long-term vision to expand its footprint in sustainable urban water solutions and attract institutional capital into critical infrastructure development across emerging markets.
• In September 2024, At the 6th EU-India Water Forum during the 8th India Water Week in New Delhi, India and the EU agreed to strengthen collaboration on sustainable water management. Key focus areas include river basin governance, innovation, and sustainable investment. Both sides also explored trilateral partnerships with East Africa to address shared challenges in regional water bodies. The initiative builds on the India-EU Water Partnership (IEWP), now in Phase III, which aims to foster technology transfer and resilient water infrastructure solutions.
• In June 2025, Amazon launched a 400-million-litre annual water replenishment initiative in Delhi’s Yamuna River basin. The project marks Amazon’s first groundwater recharge effort in the National Capital Region and supports its goal to return more water to communities than it consumes by 2027. This initiative will restore and construct water-saving systems, targeting high-stress areas. The project is being implemented in collaboration with Hasten Regeneration, Arpan Seva Sansthan, and Bangalore-based consultancy Clear Water Dynamics.

Key Market Players

• Veolia Water Technologies  
• Xylem Inc.
• AQUAFINE Corporation
• Trojan Technologies
• Kurita Water Industries Ltd.
• Calgon Carbon Corporation
• Advanced Oxidation Technologies
• Pall Corporation
• Lenntech B.V.
• Aquatech International     

Report Scope:

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

•  Water Infrastructure Development Market, By Infrastructure Type:

o   Water Supply Infrastructure

o   Wastewater Infrastructure

o   Stormwater Management Infrastructure

• Water Infrastructure Development Market, By End-User:

o   Residential

o   Commercial

o   Industrial

o   Municipal

• Water Infrastructure Development Market, By Project Type:

o   New Construction

o   Rehabilitation & Upgrades

o   Operations & Maintenance

• Water Infrastructure Development 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 Water Infrastructure Development Market.

Available Customizations:

Global Water Infrastructure Development Market report with the given market data, TechSci Research offers customizations according to a company's specific needs. The following customization options are available for the report:

Company Information

• Detailed analysis and profiling of additional market players (up to five).

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