Industrial Wastewater Treatment Market

Industrial Wastewater Treatment Market Size, Share, Trends, Growth, and Industry Analysis, By Type (Coagulants, Flocculants, Biocides and Disinfectants, Anti-foaming Agents, pH Adjusters and Stabilizers, Corrosion Inhibitors, Scale Inhibitors, Chelating Agents, and Others), End-Use Industry (Power Generation, Mining, Oil and Gas, Chemical, Food and Beverage, and Others), Regional Analysis and Forecast 2032.

Chemical & Material | May 2024 | Report ID: EMR00883 | Pages: 259

Global Industrial Wastewater Treatment market size was USD 278.83 billion in 2023 and the market is projected to touch USD 498.25 billion by 2032, at a CAGR of 6.66% during the forecast period.


Industrial Wastewater Treatments involves various processes like filtration, chemical treatment, and biological processes to remove harmful contaminants such as chemicals, toxins, and heavy metals from wastewater. Growing environmental concerns and tight rules on wastewater discharge are driving global demand for industrial wastewater treatment technologies. Factors such as increased industrialization, urbanization, and population growth all help to drive the industry forward. Furthermore, technology improvements such as membrane filtration, reverse osmosis, and ultraviolet disinfection improve the efficiency and sustainability of industrial wastewater treatment operations. The industry is also witnessing a shift towards decentralized wastewater treatment systems, creating chances for smaller-scale solutions responding to specific industrial demands.


Global Industrial Wastewater Treatment report scope and segmentation.

Report Attribute


Estimated Market Value (2023)

USD 278.83 billion

Projected Market Value (2032)

USD 498.25 billion

Base Year


Forecast Years

2024 – 2032

Scope of the Report

Historical and Forecast Trends, Industry Drivers and Constraints, Historical and Forecast Market Analysis by Segment- Based on By Type, End-Use, & Region.

Segments Covered

By Type, End-Use, & By Region.

Forecast Units

Value (USD Million or Billion), and Volume (Units)

Quantitative Units

Revenue in USD million/billion and CAGR from 2024 to 2032.

Regions Covered

North America, Europe, Asia Pacific, Latin America, and Middle East & Africa.

Countries Covered

U.S., Canada, Mexico, U.K., Germany, France, Italy, Spain, China, India, Japan, South Korea, Brazil, Argentina, GCC Countries, and South Africa, among others.

Report Coverage

Market growth drivers, restraints, opportunities, Porter’s five forces analysis, PEST analysis, value chain analysis, regulatory landscape, market attractiveness analysis by segments and region, company market share analysis.

Delivery Format

Delivered as an attached PDF and Excel through email, according to the purchase option.


Global Industrial Wastewater Treatment dynamics

One of the primary drivers is the increasing awareness and concern regarding environmental pollution caused by industrial activities. Stringent government regulations and policies aimed at curbing water pollution propel industries to invest in wastewater treatment solutions to ensure compliance and avoid penalties. Furthermore, the growing demand for clean water for industrial processes, combined with dwindling freshwater sources, necessitates the development of effective wastewater treatment technology.

Technological improvements, such as enhanced oxidation processes, membrane bioreactors, and smart water management systems, have also influenced the industry, improving the efficiency and sustainability of wastewater treatment operations. Furthermore, the increased emphasis on corporate social responsibility and sustainable practices motivates firms to implement ecologically friendly wastewater treatment technologies. However, the market confronts constraints such as high initial investment prices, particularly for advanced treatment methods, and the lack of infrastructure in developing economies.


Global Industrial Wastewater Treatment drivers

  • Stringent Regulatory Standards

 Governments worldwide are imposing increasingly stringent regulations and standards to control water pollution, particularly from industrial sources. Compliance with these regulations requires industries to invest in effective wastewater treatment solutions to ensure that their effluents meet environmental discharge standards. As these regulations continue to evolve and become more stringent, the demand for industrial wastewater treatment technologies is expected to rise significantly.

  • Technological Advancements

The constant research and development of improved wastewater treatment technologies are driving the industrial wastewater treatment market forward. Membrane bioreactors, electrocoagulation, and sophisticated oxidation technologies have considerably increased the efficiency and effectiveness of industrial wastewater treatment. Compared to traditional treatment methods, these technologies provide higher contaminant removal rates, lower operational costs, and a smaller environmental effect. Furthermore, the integration of digitization and automation technology allows for real-time monitoring and optimization of wastewater treatment operations, increasing efficiency and lowering operating hazards.



  • High Initial Costs

High Initial Investment Costs: One of the primary restraints hindering the growth of the industrial wastewater treatment market is the high initial investment required for implementing advanced treatment technologies. These technologies often involve significant capital expenditures for equipment, infrastructure, and skilled labor. The high upfront costs can pose a barrier to adoption, particularly for small and medium-sized enterprises (SMEs) and industries operating in developing countries with limited financial resources.

  • Lack of Infrastructure in Emerging Economies

The lack of adequate infrastructure for wastewater treatment in emerging economies presents a significant challenge for market growth. Many developing countries struggle with insufficient wastewater treatment facilities and outdated infrastructure, leading to untreated or poorly treated industrial effluents being discharged into water bodies. Addressing this infrastructure gap requires substantial investments in building new treatment plants, upgrading existing facilities, and implementing efficient wastewater management systems, which may pose logistical and financial challenges for governments and industries in these regions.



  • Rising Adoption of Decentralized Treatment Systems

The growing trend toward decentralized wastewater treatment systems creates chances for market expansion. Decentralized systems provide advantages over centralized treatment plants, including scalability, flexibility, and lower capital costs. These solutions are especially appropriate for industries located in remote or underdeveloped locations where centralized infrastructure is neither viable nor cost-effective. Furthermore, decentralized solutions enable enterprises to treat wastewater on-site, decreasing the need for costly conveyance lines and the environmental footprint associated with transferring wastewater to centralized facilities.


Segment Overview

  • By Type

The industrial wastewater treatment market encompasses various treatment chemicals and additives to effectively remove contaminants from wastewater. Coagulants are chemicals used to destabilize suspended particles, facilitating their removal through precipitation or filtration. Flocculants aid in the aggregation of fine particles into larger clumps, simplifying their separation from water. Biocides and disinfectants are employed to control microbial growth and pathogens in wastewater treatment processes.

Anti-foaming agents help mitigate foam formation during treatment, improving process efficiency. pH adjusters and stabilizers regulate the acidity or alkalinity of wastewater to optimize treatment performance. Corrosion inhibitors protect infrastructure from corrosion caused by harsh chemicals present in wastewater. Scale inhibitors prevent the formation of scale deposits on equipment surfaces, ensuring smooth operation.

Chelating agents bind with heavy metals and other pollutants, facilitating their removal from wastewater. Other treatment chemicals may include oxidizing agents, reducing agents, and specialty polymers tailored for specific treatment needs.

  • By End-Use

The industrial wastewater treatment market serves a wide range of end-use industries, each with its own set of wastewater characteristics and treatment requirements. Power plants create wastewater from cooling water systems, boiler blowdown, and flue gas desulfurization, which requires specific treatment to remove contaminants such as heavy metals and dissolved particles. Mining activities generate wastewater contaminated with heavy metals, suspended particles, and hazardous compounds, necessitating effective treatment techniques to meet discharge criteria.

Oil and gas refineries produce wastewater comprising hydrocarbons, hazardous compounds, and dissolved salts that must be thoroughly treated to avoid environmental damage. Chemical production operations produce wastewater including a variety of organic and inorganic contaminants, necessitating specific treatment techniques for effective removal.

Food and beverage processing facilities produce wastewater with organic matter, nutrients, and microbial contaminants, requiring biological treatment for safe discharge or reuse. Other industries such as pharmaceuticals, pulp and paper, and textiles also contribute to the industrial wastewater treatment market, each with specific treatment challenges and solutions.


Global Industrial Wastewater Treatment Overview by Region

In North America, stringent environmental regulations, technological advancements, and a strong focus on sustainability drive market growth. The presence of a mature industrial sector, particularly in the United States, contributes to the demand for advanced wastewater treatment solutions. Europe also has strict regulations and an increasing emphasis on circular economy concepts, which encourages the use of novel treatment methods.

Furthermore, government measures promoting water conservation and reuse drive market growth. The Asia-Pacific area is emerging as a profitable market potential as a result of fast industrialization, urbanization, and rising environmental awareness. Countries such as China and India are making large investments in wastewater infrastructure to address water pollution issues and comply with strict rules.

Furthermore, increasing expenditures in industries such as manufacturing, mining, and energy production fuel the demand for wastewater treatment solutions in the region. In Latin America and the Middle East & Africa, industrial growth and urbanization fuel the need for wastewater treatment infrastructure. However, challenges such as limited access to financing, inadequate regulatory enforcement, and political instability hinder market development in these regions.



Global Industrial Wastewater Treatment market competitive landscape

Major companies such as Suez SA, Veolia Environnement S.A., and Ecolab Inc. dominate the market with their extensive portfolios of treatment technologies and services. These companies leverage their strong R&D capabilities, strategic partnerships, and global presence to cater to a wide range of industries and geographic regions. Additionally, mergers and acquisitions play a significant role in shaping the competitive landscape, allowing companies to expand their market share, enhance product offerings, and strengthen their competitive position.

Along with established companies, rising start-ups and technological innovators are challenging the industry with novel solutions that prioritize sustainability, cost-effectiveness, and efficiency. These newcomers frequently specialize on specialized markets or provide disruptive technologies like improved membrane filtration, electrochemical treatment, and AI-powered optimization platforms. Furthermore, rivalry heats up as corporations compete for contracts and projects in critical areas including power generation, mining, oil and gas, and chemical production. Market participants distinguish themselves by characteristics such as technological innovation, product dependability, customer service, and pricing competitiveness.

Key Players:

  • Ecolab
  • SUEZ
  • Kemira
  • SNF
  • Evoqua Water Technologies LLC
  • Veolia
  • Solenis
  • Feralco AB
  • IXOM
  • Hydrite Chemical
  • Kurita Water Industries Ltd.
  • Dow
  • Cortec Corporation
  • Grupo BAUMINAS
  • Buckman
  • Akzo Nobel N.V.
  • Solvay
  • The Water Treatment Products Ltd
  • Geo Specialty Chemicals, Inc.
  • Thermax Limited
  • Lenntech B.V.
  • Aries Chemical, Inc.


Global Industrial Wastewater Treatment Recent Developments

  • March 2024, Indaver, a waste management company, is acquiring InOpSys, a scale-up based in Mechelen. InOpSys, with its R&D lab located at the Antwerp incubator BlueChem, specializes in developing advanced methods for treating challenging and hazardous wastewaters produced in pharmaceutical and chemical manufacturing. This acquisition aligns with Indaver's commitment to advancing the circular economy and consolidating its position as a leader in sustainable waste management. Additionally, Indaver is excited to integrate the expertise of InOpSys' 24-member team, enhancing its ability to offer a broader range of services.
  • April 2022, SUEZ, in partnership with a local joint venture*, has secured a 30-year contract to construct and manage an industrial wastewater treatment facility in Changshu. This agreement further strengthens the extensive strategic collaboration between SUEZ and the City of Changshu, encompassing various water, wastewater, and waste management initiatives. The project aims to bolster Changshu's economy through the promotion of high-quality, environmentally sustainable development.


Scope of global Industrial Wastewater Treatment report

Global Industrial Wastewater Treatment report segmentation



By Type

  • Coagulants
  • Flocculants
  • Biocides and Disinfectants
  • Anti-foaming Agents
  • pH Adjusters and Stabilizers
  • Corrosion Inhibitors
  • Scale Inhibitors
  • Chelating Agents
  • Others

By End-Use

  • Power Generation
  • Mining
  • Oil and Gas
  • Chemical
  • Food and Beverage
  • Others

By Geography

  • North America (USA, and Canada)
  • Europe (UK, Germany, France, Italy, Spain, Russia and Rest of Europe)
  • Asia Pacific (Japan, China, India, Australia, Southeast Asia and Rest of Asia Pacific)
  • Latin America (Brazil, Mexico, and Rest of Latin America)
  • Middle East & Africa (South Africa, GCC, and Rest of Middle East & Africa)

Customization Scope

  • Available upon request


  • Available upon request


Objectives of the Study

The objectives of the study are summarized in 5 stages. They are as mentioned below:

  • Global Industrial Wastewater Treatment size and forecast: To identify and estimate the market size for global Industrial Wastewater Treatment market segmented By Type, End-Use, and by region. Also, to understand the consumption/ demand created by consumers between 2024 and 2032.
  • Market Landscape and Trends: To identify and infer the drivers, restraints, opportunities, and challenges for global Industrial Wastewater Treatment
  • Market Influencing Factors: To find out the factors which are affecting the market of global Industrial Wastewater Treatment among consumers.
  • Company Profiling:  To provide a detailed insight into the major companies operating in the market. The profiling will include the financial health of the company's past 2-3 years with segmental and regional revenue breakup, product offering, recent developments, SWOT analysis, and key strategies.

Research Methodology

Our research methodology has always been the key differentiating reason which sets us apart in comparison from the competing organizations in the industry. Our organization believes in consistency along with quality and establishing a new level with every new report we generate; our methods are acclaimed and the data/information inside the report is coveted. Our research methodology involves a combination of primary and secondary research methods. Data procurement is one of the most extensive stages in our research process. Our organization helps in assisting the clients to find the opportunities by examining the market across the globe coupled with providing economic statistics for each and every region.  The reports generated and published are based on primary & secondary research. In secondary research, we gather data for global Market through white papers, case studies, blogs, reference customers, news, articles, press releases, white papers, and research studies. We also have our paid data applications which includes hoovers, Bloomberg business week, Avention, and others.

Data Collection

Data collection is the process of gathering, measuring, and analyzing accurate and relevant data from a variety of sources to analyze market and forecast trends. Raw market data is obtained on a broad front. Data is continuously extracted and filtered to ensure only validated and authenticated sources are considered. Data is mined from a varied host of sources including secondary and primary sources.

Primary Research

After the secondary research process, we initiate the primary research phase in which we interact with companies operating within the market space. We interact with related industries to understand the factors that can drive or hamper a market. Exhaustive primary interviews are conducted. Various sources from both the supply and demand sides are interviewed to obtain qualitative and quantitative information for a report which includes suppliers, product providers, domain experts, CEOs, vice presidents, marketing & sales directors, Type & innovation directors, and related key executives from various key companies to ensure a holistic and unbiased picture of the market. 

Secondary Research

A secondary research process is conducted to identify and collect information useful for the extensive, technical, market-oriented, and comprehensive study of the market. Secondary sources include published market studies, competitive information, white papers, analyst reports, government agencies, industry and trade associations, media sources, chambers of commerce, newsletters, trade publications, magazines, Bloomberg BusinessWeek, Factiva, D&B, annual reports, company house documents, investor presentations, articles, journals, blogs, and SEC filings of companies, newspapers, and so on. We have assigned weights to these parameters and quantified their market impacts using the weighted average analysis to derive the expected market growth rate.

Top-Down Approach & Bottom-Up Approach

In the top – down approach, the Global Batteries for Solar Energy Storage Market was further divided into various segments on the basis of the percentage share of each segment. This approach helped in arriving at the market size of each segment globally. The segments market size was further broken down in the regional market size of each segment and sub-segments. The sub-segments were further broken down to country level market. The market size arrived using this approach was then crosschecked with the market size arrived by using bottom-up approach.

In the bottom-up approach, we arrived at the country market size by identifying the revenues and market shares of the key market players. The country market sizes then were added up to arrive at regional market size of the decorated apparel, which eventually added up to arrive at global market size.

This is one of the most reliable methods as the information is directly obtained from the key players in the market and is based on the primary interviews from the key opinion leaders associated with the firms considered in the research. Furthermore, the data obtained from the company sources and the primary respondents was validated through secondary sources including government publications and Bloomberg.

Market Analysis & size Estimation

Post the data mining stage, we gather our findings and analyze them, filtering out relevant insights. These are evaluated across research teams and industry experts. All this data is collected and evaluated by our analysts. The key players in the industry or markets are identified through extensive primary and secondary research. All percentage share splits, and breakdowns have been determined using secondary sources and verified through primary sources. The market size, in terms of value and volume, is determined through primary and secondary research processes, and forecasting models including the time series model, econometric model, judgmental forecasting model, the Delphi method, among Flywheel Energy Storage. Gathered information for market analysis, competitive landscape, growth trends, product development, and pricing trends is fed into the model and analyzed simultaneously.

Quality Checking & Final Review

The analysis done by the research team is further reviewed to check for the accuracy of the data provided to ensure the clients’ requirements. This approach provides essential checks and balances which facilitate the production of quality data. This Type of revision was done in two phases for the authenticity of the data and negligible errors in the report. After quality checking, the report is reviewed to look after the presentation, Type and to recheck if all the requirements of the clients were addressed.

Frequently Asked Questions

Global Industrial Wastewater Treatment forecast period is 2024 - 2032.
According to global Industrial Wastewater Treatment research, the market is expected to grow at a CAGR of ~ 6.66% over the next eight years.
The possible segments in global Industrial Wastewater Treatment are based on By Type, End-Use, & by region.
The expected market size for Global Industrial Wastewater Treatment is USD 498.25 billion in 2032.
The major players in the market are Ecolab, SUEZ, Kemira, SNF, Evoqua Water Technologies LLC, Veolia, Solenis, Feralco AB, IXOM, Hydrite Chemical, Kurita Water Industries Ltd., Dow, BWA WATER ADDITIVES UK LIMITED, Cortec Corporation, Grupo BAUMINAS, Buckman, Akzo Nobel N.V., Solvay, The Water Treatment Products Ltd, Geo Specialty Chemicals, Inc., Thermax Limited, Lenntech B.V., HOLLAND COMPANY, and Aries Chemical, Inc.

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