Outlook of the Global Industrial Wastewater Treatment Market to 2028

DUBLIN, July 30, 2021 / PRNewswire / – The report, “Industrial Wastewater Treatment Market by Treatment Technology and Application – Global Forecast to 2028” has been added to the offering from ResearchAndMarkets.com.

This report provides an in-depth analysis of the Industrial Wastewater Treatment market across five main regions, emphasizing the current market trends, size, market shares, recent developments, and forecast to 2028. The Industrial Wastewater Treatment market is expected. to achieve $ 78.0 billion by 2028 with a CAGR of 6.8% in the forecast period 2021-2028.

The growth of this market is mainly attributed to increasing industrialization and urbanization, declining freshwater resources, increasing global energy needs, increasing focus on water quality and public health, and increasing prevalence of water-borne diseases. Rising industrial demand and stringent government regulations on wastewater treatment are also some of the key factors driving the growth of the industrial wastewater treatment market.

The study provides a comprehensive analysis of the Industrial Wastewater Treatment market related to technologies, applications, and geography. The industrial wastewater treatment market is mainly divided into treatment technologies (membrane separation {reverse osmosis [RO] Membranes, ultrafiltration [UF] Membranes, microfiltration [MF] Membrane, nanofiltration [NF] Membrane and other membrane separation technologies}, activated sludge, clarification, sludge thickening and dewatering, wastewater pretreatment, chlorination, industrial demineralization, sludge drying, membrane bioreactor [MBR], Sludge digestion, sludge incineration, ozonation, activated carbon, electrochemical water treatment, electrochemical sewage treatment plant and other treatment technologies), application (food and beverage, pharmaceutical and chemical, energy, energy, pulp and paper, mining, petrochemical, semiconductor) and other industrial applications) and geography . The study also evaluates the industry’s competitors and analyzes the market at the country level.

In terms of technology, the membrane separation segment is expected to make up the largest share of the industrial wastewater treatment market in 2021. The large share of this segment is mainly due to the increasing demand for energy-saving water treatment processes, with the focus on reducing the use of chemicals in water treatment as well as effective cleaning and reduced operating costs through membrane filtration technology. However, significant growth is expected for the membrane bioreactor (MBR) segment in the forecast period.

Based on the application, the food and beverage segment is expected to have the largest share of the industrial wastewater treatment market in 2021. However, the energy segment is expected to grow with the highest CAGR during the forecast period. The rapid growth of this segment is mainly due to the increasing demand for clean water and energy.

Geographically, the market is divided into five main regions: North America, Europe, Asia Pacific, Latin America, and the middle East & Africa. Asia Pacific The region is expected to have the largest share of the industrial wastewater treatment market in 2021. The large portion of this region is mainly due to the growing population, the growing manufacturing industry, the pulp and paper industry and the power generation industry, the decreasing availability of clean water, increasing research and development expenditures and increasing environmental regulations regarding industrial wastewater in the region, especially in developing countries like China and India.

The main players in the industrial wastewater treatment market are Suez Environnement SA (France), Xylem, Inc. (USA), DuPont de Nemours, Inc. (USA), Evoqua Water Technologies Corporation (USA), 3M Company, Inc. (USA), Pentair plc (UK), United Utilities Group PLC (UK), Kingspan Water & Energy (UK), The Dow Chemical Company (USA), Kemira Oyj (Finland), BASF SE (Germany), Calgon Carbon Corporation (USA), Kurita Water Industries Ltd. (Japan), Bio-Microbics, Inc. (USA), Trojan Technologies Inc. (Canada), Aquatech International Corporation (USA), ASIO, spol. sro (Czech Republic), Orenco Systems, Inc. (USA), Scinor Water America, LLC (USA), Elgressy Engineering Services Ltd. (Israel), Outotec Oyj (Finland), Blue Eden CleanTech Solutions Inc. (Canada), Solenis (USA), Aries Chemical, Inc. (USA), Thermax Limited (India) and Lenntech BV (Netherlands).

Key questions answered in the report

  • What are the high-growth market segments in terms of technology, applications and geography?
  • – What is the historic market size for the Industrial Wastewater Treatment Market?
  • What are the market forecasts and estimates for the period 2021-2028?
  • What are the key drivers, restraints, opportunities, and challenges in the Industrial Wastewater Treatment market?
  • Who are the main players in the market and what market share do they hold?
  • Who are the main players in different countries and what is their market share?
  • What is the competitive landscape for the Industrial Wastewater Treatment market?
  • What are the recent developments in the industrial wastewater treatment market?
  • What are the different strategies of the main players in the market?
  • What are the main geographic trends and which countries are the fastest growing?
  • Who are the local emerging players in the Industrial Wastewater Treatment market, and how are they competing with the other players?

Key topics covered:

1 Introduction

2. Research methodology

3. Summary

4. Pollutant analysis
4.1. Key pollutant
4.1.1. introduction
4.2. Regulatory evaluation
4.2.1. introduction
4.2.2. Types of pollutants
4.2.3. Existing regulations

5. Market insights
5.1. introduction
5.2. driver
5.2.1. Increasing industrialization and urbanization
5.2.2. Depletion of freshwater resources
5.2.3. Increasing energy demand worldwide
5.2.4. Increasing focus on water quality and public health
5.2.5. Rising prevalence of water-borne diseases
5.3. Restrictions
5.3.1. High installation, maintenance and operating costs
5.3.2. Rise of alternative wastewater treatment technologies
5.4. opportunities
5.4.1. Growing focus on industrial wastewater treatment in countries like the USA, China, and India
5.5. challenges
5.5.1. High energy consumption and increasing expenses due to excessive sludge production
5.6. Effects of COVID-19 on the Industrial Wastewater Treatment Market

6. Global Industrial Wastewater Treatment Market By Technology
6.1. introduction
6.2. Membrane separation technology
6.2.1. Reverse Osmosis (RO) membrane technology
6.2.2. Ultrafiltration (UF) membrane technology
6.2.3. Microfiltration (MF) membrane technology
6.2.4. Nanofiltration (NF) membrane technology
6.2.5. Other membrane separation technologies
6.3. Activated sludge technology
6.4. Sewage technology
6.5. Sludge thickening and dewatering technology
6.6. Wastewater pre-treatment technology
6.7. Chlorination technology
6.8. Industrial demineralization technology
6.9. Sludge drying technology
6.10. Membrane bioreactor (MBR) technology
6.11. Sludge digestion technology
6.12. Sludge incineration technology
6.13. Ozonization technology
6.14. Activated carbon technology
6.15. Electrochemical water treatment (electrocoagulation and electrooxidation – EEC / EEO)
6.16. Electrochemical Scale Treatment (EST)
6.17. Other technologies for industrial wastewater treatment

7. Global Industrial Wastewater Treatment Market By Application
7.1. introduction
7.2. food and drinks
7.3. Pharmaceuticals and chemicals
7.4. perfomance
7.5. energy
7.6. Pulp & paper
7.7. Mining
7.8. Petrochemicals
7.9. semiconductor
7.10. Other industrial applications

8. Industrial Wastewater Treatment Market by Geography
8.1. introduction
8.2. Asia Pacific
8.2.1. China
8.2.2. Japan
8.2.3. India
8.2.4. Indonesia
8.2.5. Australia
8.2.6. South Korea
8.2.7. Malaysia
8.2.8. Thailand
8.2.9. Vietnam
8.2.10. Philippines
8.2.11. Singapore
8.2.12. Taiwan
8.2.13. New Zealand
8.2.14. the rest of Asia Pacific (RoAPAC)
8.3. North America
8.3.1. US
8.3.2. Canada
8.3.3. Mexico
8.4. Europe
8.4.1. France
8.4.2. Germany
8.4.3. United Kingdom
8.4.4. Italy
8.4.5. Spain
8.4.6. Poland
8.4.7. Belgium
8.4.8. Switzerland
8.4.9. Denmark
8.4.10. Sweden
8.4.11. the rest of Europe (Roe)
8.5. Latin America
8.5.1. Brazil
8.5.2. Chile
8.5.3. Argentina
8.5.4. the rest of Latin America (RoLATAM)
8.6. middle East & Africa
8.6.1. Saudi Arabia
8.6.2. United Arab Emirates (UAE)
8.6.3. Kuwait
8.6.4. Iran
8.6.5. South Africa
8.6.6. The rest of middle East & Africa (RoMEA)

9. Competitive landscape
9.1. introduction
9.2. Important growth strategies
9.3. Competitive comparison

10. Company profiles
10.1. Suez Environment SA
10.2. Veolia Environment SA
10.3. Xylem, Inc.
10.4. DuPont de Nemours, Inc.
10.5. Evoqua Water Technologies Corporation
10.6. 3M Company, Inc.
10.7. Pentair plc
10.8. United Utilities Group PLC
10.9. Kingspan Water & Energy (subsidiary of Kingspan Group plc)
10.10. Calgon Carbon Corporation (part of Kuraray Co., Ltd.)
11/10 Kurita Water Industries, Ltd.
10.12. Bio-Microbes, Inc.
10.13. ASIO, spol. s ro
10.14. Trojan Technologies Inc. (subsidiary of Danaher Corporation)
10.15. Aquatech International Corporation
10.16. Orenco Systems, Inc.
10.17. Scinor Water America, LLC
10.18. Elgressy Engineering Services Ltd.
10.19. Outotec Oyja
10.20. Blue Eden CleanTech Solutions, Inc.
10.21. Membracon Ltd.
10.22. Lamor Corporation Ab
10.23. Ozone Tech Systems (part of Melllifiq Ab)
10.24. Solenis LLC
10.25. Widder Chemical, Inc.
10.26. Thermax Limited
10.27. Lenntech BV

11. Appendix

Please visit https://www.researchandmarkets.com/r/4a074j for more information on this report

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