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市场调查报告书
商品编码
1643881

全球工业水回用与回收市场 - 2025-2032

Global Industrial Water Reuse and Recycling Market - 2025-2032
出版日期: | 出版商: DataM Intelligence | 英文 201 Pages | 商品交期: 最快1-2个工作天内

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简介目录

2024年,全球工业水再利用和循环利用市场规模达到174.7亿美元,预计2032年将达到371.9亿美元,2025-2032年预测期间复合年增长率为9.9%。

在水资源日益短缺和对永续水管理实践的需求的推动下,全球工业用水再利用和循环利用市场正在经历显着增长。严格的环境法规和工业应用中对处理水的需求不断增长推动了这种扩张。各行业越来越多地采用先进的水处理技术,例如薄膜过滤和高级氧化工艺,以提高水回收和再利用系统的效率。

这些创新不仅可以改善水质,还可以降低营运成本,使其成为对各行业有吸引力的解决方案。各国政府和产业正拥抱循环水经济,推动零液体排放(ZLD)和水循环利用作为永续发展目标。世界永续发展工商理事会(WBCSD)强调,到2030年,经济发展将使全球对水的需求增加50%,并支持全球推动永续发展。

在快速工业化、城市化和水资源短缺的推动下,亚太地区是工业用水再利用和循环利用成长最快的市场。中国和印度等国家正在实施严格的法规,以遏制淡水开采并促进废水再利用。例如,与西班牙等一些国家相比,中国在废水回用方面处于领先地位,西班牙每年的再生水量约为368.2 Hm3。

日本先进的废水处理设施和新加坡的新生水计画成为有效工业水管理的基准。对有效处理和回收废水的基础设施的大量投资进一步支持了该地区的成长。

动力学

水资源日益短缺和可持续水资源管理的需求

水资源短缺是一个紧迫的全球问题,联合国报告称,每年约有 40 亿人至少有一个月缺水。到2025年,预计将有18亿人面临严重缺水和绝对缺水。这场不断升级的危机主要是由于人口增长、城市化、工业化和气候变迁等因素造成的,这些因素共同导致了现有淡水资源的紧张。此外,采用水回收实践符合企业永续发展目标并提高品牌声誉。

积极解决水资源短缺问题的公司展现了环境管理能力,从而在市场上获得竞争优势。例如,百事公司宣布目标是到2030年成为「Net Water Positive」。政府政策和法规在推动水再利用和循环利用方面也发挥关键作用。许多国家实施了严格的排放法规,并为节水措施提供奖励措施。

采用不同产业的水再利用与循环利用

工业是用水量最大的产业之一,将水用于冷却、清洁和製造等製程。随着淡水供应量的减少,各行业迫切需要采用可持续的水管理实践,以确保营运连续性和环境合规性。实施水再利用和回收系统使各行业能够处理和重新利用废水,从而减少对淡水资源的依赖并减轻环境影响。

技术进步显着提高了工业水回用的可行性和效率。薄膜过滤、逆渗透和高级氧化製程等创新技术使废水处理能够满足各种工业应用所需的特定品质标准。根据联合国世界水发展报告,2050年,全球各种用途的水需求将增加20%至30%,达到每年5,500至6,000立方公里,强调迫切需要高效率的再利用系统。

初始投资和营运成本高

工业水回用和循环系统的采用往往因建立高级处理设施所需的高额初始资本投资而受到阻碍。逆渗透、高级氧化製程和零液体排放系统等技术涉及大量采购、安装和整合到现有基础设施中的成本。

据国际海水淡化协会 (IDA) 称,每个设施实施工业规模逆渗透系统的成本从 50 万美元到超过 100 万美元不等,具体取决于规模和复杂性。营运成本仍然是另一个关键挑战。

先进的水处理系统通常需要持续的能量输入和化学品的使用,以保持效率并满足监管标准。美国能源部的报告强调,光是能源费用就占水处理设施营运成本的 30-40%,使其成为能源最密集的工业流程之一。

目录

第 1 章:方法与范围

第 2 章:定义与概述

第 3 章:执行摘要

第 4 章:动力学

  • 影响因素
    • 司机
      • 采用不同产业的水再利用与循环利用
      • 水资源日益短缺和可持续水资源管理的需求
    • 限制
      • 初始投资和营运成本高
    • 机会
    • 影响分析

第 5 章:产业分析

  • 波特五力分析
  • 供应链分析
  • 定价分析
  • 监管分析
  • 永续分析
  • DMI 意见

第 6 章:按设备

    • 物理过滤
    • 薄膜过滤
    • 活性碳过滤
  • 机械
    • 泵浦
    • 马达
    • 蒸发器
    • 其他的
  • 坦克
    • 储槽
    • 沉淀池
    • 工艺罐
    • 其他的
  • 其他的
    • 配件及固定装置
    • 电线

第 7 章:按容量

  • 小于25,000L
  • 25,001 至 50,000 公升
  • 50,001 升至 100,000 公升
  • 超过 100,001 公升

第 8 章:按技术

  • 薄膜过滤技术
  • 化学处理
  • 生物治疗
  • 零液体排放 (ZLD) 系统
  • 其他的

第 9 章:最终用户

  • 住宅
  • 商业的
  • 工业的
    • 发电
    • 石油和天然气
    • 食品和饮料
    • 纺织品
    • 药品
    • 其他的

第 10 章:可持续性分析

  • 环境分析
  • 经济分析
  • 治理分析

第 11 章:按地区

  • 北美洲
    • 我们
    • 加拿大
    • 墨西哥
  • 欧洲
    • 德国
    • 英国
    • 法国
    • 义大利
    • 西班牙
    • 欧洲其他地区
  • 南美洲
    • 巴西
    • 阿根廷
    • 南美洲其他地区
  • 亚太
    • 中国
    • 印度
    • 日本
    • 澳洲
    • 亚太其他地区
  • 中东和非洲

第 12 章:竞争格局

  • 竞争场景
  • 市场定位/份额分析
  • 併购分析

第 13 章:公司简介

  • Alfa Laval
    • 公司概况
    • 产品组合和描述
    • 财务概览
    • 主要进展
  • Dow Chemical Company
  • Evoqua Water Technologies
  • Fluence Corporation Limited
  • Hitachi Ltd.
  • Kubota Corporation
  • Melbourne Water
  • Siemens
  • SUEZ Water Technologies & Solutions
  • Veolia Water Technologies.

第 14 章:附录

简介目录
Product Code: EP9075

Global Industrial Water Reuse and Recycling Market reached US$ 17.47 billion in 2024 and is expected to reach US$ 37.19 billion by 2032, growing with a CAGR of 9.9% during the forecast period 2025-2032.

The global industrial water reuse and recycling market is experiencing significant growth, driven by increasing water scarcity and the need for sustainable water management practices. This expansion is fueled by stringent environmental regulations and the rising demand for treated water in industrial applications. Industries are increasingly adopting advanced water treatment technologies, such as membrane filtration and advanced oxidation processes, to enhance the efficiency of water recycling and reuse systems.

The innovations not only improve water quality but also reduce operational costs, making them attractive solutions for various sectors. Governments and industries are embracing the circular water economy, promoting zero-liquid discharge (ZLD) and water recycling as sustainability goals. The World Business Council for Sustainable Development (WBCSD) highlights that economic development will increase global demand for water by 50% by 2030, supporting the global push for sustainable development.

Asia-Pacific is the fastest-growing market for industrial water reuse and recycling, driven by rapid industrialization, urbanization and water scarcity. Countries like China and India are implementing strict regulations to curb freshwater extraction and promote wastewater reuse. For instance, China is advanced in terms of wastewater reuse compared with some countries, such as Spain, where the volume of reclaimed water is about 368.2 Hm3 per year.

Japan's advanced wastewater treatment facilities and Singapore's NEWater initiative serve as benchmarks for effective industrial water management. The region's growth is further supported by significant investments in infrastructure to treat and recycle wastewater efficiently.

Dynamics

Increasing Water Scarcity and Need for Sustainable Water Management

Water scarcity is a pressing global issue, with the United Nations reporting that approximately 4 billion people experience water shortages for at least one month each year. By 2025, an estimated 1.8 billion people will face severe water shortages and absolute water scarcity. This escalating crisis is primarily due to factors such as population growth, urbanization, industrialization and climate change, which collectively strain existing freshwater resources. Moreover, the adoption of water recycling practices aligns with corporate sustainability goals and enhances brand reputation.

Companies that proactively address water scarcity issues demonstrate environmental stewardship, which lead to competitive advantages in the market. For instance, PepsiCo announced that it aims to become "Net Water Positive" by 2030. This means that PepsiCo will replenish more water than it uses, aiming to replenish more water than it consumes. Government policies and regulations also play a pivotal role in driving the adoption of water reuse and recycling. Many countries have implemented stringent discharge regulations and offer incentives for water conservation initiatives.

Adoption of the Water Reuse and Recycle from Diverse Industries

Industries are among the largest consumers of water, utilizing it for processes like cooling, cleaning and manufacturing. As freshwater availability diminishes, there is a critical need for industries to adopt sustainable water management practices to ensure operational continuity and environmental compliance. Implementing water reuse and recycling systems allows industries to treat and repurpose wastewater, thereby reducing dependence on freshwater sources and mitigating environmental impacts.

Technological advancements have significantly enhanced the feasibility and efficiency of industrial water reuse. Innovations such as membrane filtration, reverse osmosis and advanced oxidation processes enable the treatment of wastewater to meet specific quality standards required for various industrial applications. According to the United Nations World Water Development Report, Global water demand for all uses will increase by 20% to 30% by 2050, up to 5,500 to 6,000 km3 per year, emphasizing the urgent need for efficient reuse systems.

High Initial Investment and Operational Costs

The adoption of industrial water reuse and recycling systems is often hindered by the high initial capital investment required for setting up advanced treatment facilities. Technologies such as reverse osmosis, advanced oxidation processes and zero liquid discharge systems involve substantial costs for procurement, installation and integration into existing infrastructure.

According to the International Desalination Association (IDA), the cost of implementing industrial-scale reverse osmosis systems can range from US$ 500,000 to over US$ 1 million per facility, depending on the scale and complexity. Operational costs remain another critical challenge.

Advanced water treatment systems often demand continuous energy input and chemical usage to maintain efficiency and meet regulatory standards. A report by the U.S. Department of Energy highlights that energy expenses alone account for 30-40% of the operational costs in water treatment facilities, making it one of the most energy-intensive industrial processes.

Segment Analysis

The global industrial water reuse and recycling market is segmented based on equipment, capacity, technology, end-user and region.

Biological Treatments Meet the Demand for Sustainable Solutions

Biological treatment processes are critical for managing and recycling industrial wastewater, particularly in sectors like food processing, pharmaceuticals and textiles, where high levels of organic contaminants are present. Techniques such as activated sludge processes, moving bed biofilm reactors (MBBRs) and sequencing batch reactors (SBRs) are widely used due to their efficiency in degrading organic matter.

Processes like coagulation, flocculation and chlorination are extensively used in industries such as petrochemicals, pulp and paper and mining, where wastewater often contains heavy metals and hazardous chemicals. Around 52% of industrial wastewater is treated in wastewater treatment plants, underscoring the demand for these technologies.

Industries are increasingly adopting advanced biological systems that integrate real-time monitoring and process optimization to comply with environmental standards, ensuring efficient and cost-effective operations. The United Nations Industrial Development Organization (UNIDO) reports that demand for biological treatment systems is growing at a robust rate, driven by stricter discharge norms and water quality standards.

Geographical Penetration

Rising Demand for Industrial Water Reuse in North America

North America dominates the industrial water reuse market due to advanced infrastructure, technological adoption and supportive policies. U.S. Environmental Protection Agency (EPA) and Canadian Water Act promote sustainable water management, driving the adoption of water recycling technologies. U.S. Department of Energy highlights that power plants recycle up to 80% of their cooling water, reducing freshwater withdrawals by millions of gallons annually.

Chevron's oil refineries in California utilize membrane systems for water recycling, achieving over-significant reuse. Similarly, PepsiCo's "Positive Water Impact" initiative in North America underscores the role of water recycling in reducing consumption across manufacturing plants. The region is expected to witness sustained growth due to increased investments in infrastructure and technological advancements. According to the Water Environment Federation, the North American industrial water reuse market is projected to grow at a CAGR of 8% through 2030, reinforcing its leadership in the sector.

Competitive Landscape

The major global players in the market include Alfa Laval, Dow Chemical Company, Evoqua Water Technologies, Fluence Corporation Limited, Hitachi Ltd., Kubota Corporation, Melbourne Water, Siemens, SUEZ Water Technologies & Solutions and Veolia Water Technologies.

Sustainable Analysis

The shift toward sustainable water practices aligns with global goals such as the United Nations Sustainable Development Goal 6 (Clean Water and Sanitation), which emphasizes efficient water use and the reduction of water pollution. Industrial water reuse minimizes the need for freshwater extraction, alleviating pressure on natural water bodies and supporting ecosystem health.

Energy efficiency and carbon reduction are also integral to sustainability in the industrial water reuse market. For example, according to the U.S. Department of Energy, using energy-efficient reverse osmosis systems lower energy costs by compared to conventional methods. Additionally, the adoption of zero-liquid discharge (ZLD) systems and advanced wastewater treatment technologies significantly reduces the release of contaminants into the environment, promoting cleaner industrial operations.

The measures reduce industrial wastewater discharge magnificently, contributing to global water sustainability targets. Furthermore, recycling and reusing industrial wastewater decreases the reliance on energy-intensive freshwater extraction and transportation systems, reducing the overall carbon footprint of industrial operations.

Integration of Renewable Energy & Decarbonization in Industrial Water Reuse and Recycling

The integration of renewable energy into industrial water reuse systems is transforming the market by enhancing sustainability and reducing operational costs. Solar-powered water treatment facilities and wind-powered desalination plants are emerging as viable solutions to energy-intensive processes. According to the U.S. Environmental Protection Agency, by incorporating energy efficiency practices into their water and wastewater plants, municipalities and utilities can save 15 to 30 percent.

Decarbonization is increasingly prioritized in industrial water management as industries aim to reduce their carbon footprints while optimizing water use. The United Nations Industrial Development Organization (UNIDO) emphasizes that carbon-neutral water treatment systems, supported by innovations like biogas recovery and energy-efficient technologies, are essential to achieving sustainability.

Recent Developments

  • In April 2023, the World Bank approved a US$ 500 million loan to support water reuse and recycling projects in India. This investment is targeted at alleviating water stress in urban and industrial regions by funding the construction of advanced wastewater treatment plants and promoting technologies like zero-liquid discharge (ZLD) systems.
  • In April 2023, Hydraloop introduced water recycling systems designed for residential applications, marking a notable advancement in the accessibility of water reuse technologies. The systems recycle water from baths, showers and laundry activities, enabling its reuse for non-potable purposes such as flushing toilets and irrigating gardens and landscapes.
  • In February 2023, the European Union launched a groundbreaking initiative to increase the share of reused water in member states by 20% by 2030. This initiative underscores the EU's commitment to sustainable water management and aligns with its broader environmental goals.

Why Purchase the Report?

  • To visualize the global industrial water reuse and recycling market segmentation based on equipment, capacity, technology, end-user and region.
  • Identify commercial opportunities by analyzing trends and co-development.
  • Excel data sheet with numerous data points at the industrial water reuse and recycling market level for all segments.
  • PDF report consists of a comprehensive analysis after exhaustive qualitative interviews and an in-depth study.
  • Product mapping available as excel consisting of key products of all the major players.

The global industrial water reuse and recycling market report would provide approximately 70 tables, 67 figures and 201 pages.

Target Audience 2024

  • Manufacturers/ Buyers
  • Industry Investors/Investment Bankers
  • Research Professionals
  • Emerging Companies

Table of Contents

1. Methodology and Scope

  • 1.1. Research Methodology
  • 1.2. Research Objective and Scope of the Report

2. Definition and Overview

3. Executive Summary

  • 3.1. Snippet by Equipment
  • 3.2. Snippet by Capacity
  • 3.3. Snippet by Technology
  • 3.4. Snippet by End-User
  • 3.5. Snippet by Region

4. Dynamics

  • 4.1. Impacting Factors
    • 4.1.1. Drivers
      • 4.1.1.1. Adoption of the Water Reuse and Recycle from Diverse Industries
      • 4.1.1.2. Increasing Water Scarcity and Need for Sustainable Water Management
    • 4.1.2. Restraints
      • 4.1.2.1. High Initial Investment and Operational Costs
    • 4.1.3. Opportunity
    • 4.1.4. Impact Analysis

5. Industry Analysis

  • 5.1. Porter's Five Force Analysis
  • 5.2. Supply Chain Analysis
  • 5.3. Pricing Analysis
  • 5.4. Regulatory Analysis
  • 5.5. Sustainable Analysis
  • 5.6. DMI Opinion

6. By Equipment

  • 6.1. Introduction
    • 6.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Equipment
    • 6.1.2. Market Attractiveness Index, By Equipment
  • 6.2. Filtration*
    • 6.2.1. Introduction
    • 6.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
    • 6.2.3. Physical Filtration
    • 6.2.4. Membrane Filtration
    • 6.2.5. Activated Carbon Filtration
  • 6.3. Machinery
    • 6.3.1. Pumps
    • 6.3.2. Motors
    • 6.3.3. Evaporators
    • 6.3.4. Others
  • 6.4. Tanks
    • 6.4.1. Storage Tanks
    • 6.4.2. Settling Tanks
    • 6.4.3. Process Tanks
    • 6.4.4. Others
  • 6.5. Others
    • 6.5.1. Fittings & Fixtures
    • 6.5.2. Wires

7. By Capacity

  • 7.1. Introduction
    • 7.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Capacity
    • 7.1.2. Market Attractiveness Index, By Capacity
  • 7.2. Less than 25,000L*
    • 7.2.1. Introduction
    • 7.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
  • 7.3. 25,001 TO 50,000 L
  • 7.4. 50,001 L TO 100,000 L
  • 7.5. More than 100,001 L

8. By Technology

  • 8.1. Introduction
    • 8.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 8.1.2. Market Attractiveness Index, By Technology
  • 8.2. Membrane Filtration Technologies*
    • 8.2.1. Introduction
    • 8.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
  • 8.3. Chemical Treatments
  • 8.4. Biological Treatments
  • 8.5. Zero Liquid Discharge (ZLD) Systems
  • 8.6. Others

9. By End-User

  • 9.1. Introduction
    • 9.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 9.1.2. Market Attractiveness Index, By End-User
  • 9.2. Residential*
    • 9.2.1. Introduction
    • 9.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
  • 9.3. Commercial
  • 9.4. Industrial
    • 9.4.1. Power Generation
    • 9.4.2. Oil and Gas
    • 9.4.3. Food and Beverage
    • 9.4.4. Textiles
    • 9.4.5. Pharmaceuticals
    • 9.4.6. Others

10. Sustainability Analysis

  • 10.1. Environmental Analysis
  • 10.2. Economic Analysis
  • 10.3. Governance Analysis

11. By Region

  • 11.1. Introduction
    • 11.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Region
    • 11.1.2. Market Attractiveness Index, By Region
  • 11.2. North America
    • 11.2.1. Introduction
    • 11.2.2. Key Region-Specific Dynamics
    • 11.2.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Equipment
    • 11.2.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Capacity
    • 11.2.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 11.2.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 11.2.7. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 11.2.7.1. US
      • 11.2.7.2. Canada
      • 11.2.7.3. Mexico
  • 11.3. Europe
    • 11.3.1. Introduction
    • 11.3.2. Key Region-Specific Dynamics
    • 11.3.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Equipment
    • 11.3.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Capacity
    • 11.3.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 11.3.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 11.3.7. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 11.3.7.1. Germany
      • 11.3.7.2. UK
      • 11.3.7.3. France
      • 11.3.7.4. Italy
      • 11.3.7.5. Spain
      • 11.3.7.6. Rest of Europe
  • 11.4. South America
    • 11.4.1. Introduction
    • 11.4.2. Key Region-Specific Dynamics
    • 11.4.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Equipment
    • 11.4.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Capacity
    • 11.4.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 11.4.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 11.4.7. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 11.4.7.1. Brazil
      • 11.4.7.2. Argentina
      • 11.4.7.3. Rest of South America
  • 11.5. Asia-Pacific
    • 11.5.1. Introduction
    • 11.5.2. Key Region-Specific Dynamics
    • 11.5.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Equipment
    • 11.5.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Capacity
    • 11.5.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 11.5.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 11.5.7. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 11.5.7.1. China
      • 11.5.7.2. India
      • 11.5.7.3. Japan
      • 11.5.7.4. Australia
      • 11.5.7.5. Rest of Asia-Pacific
  • 11.6. Middle East and Africa
    • 11.6.1. Introduction
    • 11.6.2. Key Region-Specific Dynamics
    • 11.6.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Equipment
    • 11.6.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Capacity
    • 11.6.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 11.6.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User

12. Competitive Landscape

  • 12.1. Competitive Scenario
  • 12.2. Market Positioning/Share Analysis
  • 12.3. Mergers and Acquisitions Analysis

13. Company Profiles

  • 13.1. Alfa Laval*
    • 13.1.1. Company Overview
    • 13.1.2. Product Portfolio and Description
    • 13.1.3. Financial Overview
    • 13.1.4. Key Developments
  • 13.2. Dow Chemical Company
  • 13.3. Evoqua Water Technologies
  • 13.4. Fluence Corporation Limited
  • 13.5. Hitachi Ltd.
  • 13.6. Kubota Corporation
  • 13.7. Melbourne Water
  • 13.8. Siemens
  • 13.9. SUEZ Water Technologies & Solutions
  • 13.10. Veolia Water Technologies.

LIST NOT EXHAUSTIVE

14. Appendix

  • 14.1. About Us and Services
  • 14.2. Contact Us