膜分離活性污泥（MBR）系統市場：現況分析與預測（2023-2030）

由於水資源短缺和水污染加劇，對創新水處理系統的需求不斷增加，膜分離活性污泥 (MBR) 系統市場預計將以約 8.28% 的複合年增長率強勁增長。 隨著水資源短缺成為一個迫切的問題，MBR發揮重要作用。 MBR高效率的處理流程可實現水的再利用，並減少對淡水資源的壓力。 亞太、南美洲等缺水嚴重的新興國家對MBR的需求正快速增加。 例如，2023年10月，聯合國糧食及農業組織發佈的報告表明，水資源短缺正在以驚人的速度加劇。 此外，該機構估計，到 2030 年，淡水需求將超過可用供應量約 40%。 此外，世界各國政府正在對廢水排放實施更嚴格的法規。 MBR 透過有效去除污染物並確保遵守環境法來滿足這些嚴格的法規。 此外，快速的都市化和工業成長導致廢水產生量增加。 MBR 適用於處理市政、紡織、食品和飲料以及石油和天然氣行業等不同來源的大量廢水。

產品分為中空纖維、平板、多管狀。 中空纖維在市場佔有率和滲透率方面佔據主導地位。 促成這一優勢的關鍵因素是它們能夠有效去除廢水中的懸浮固體、病原體和有機物等污染物顆粒。 如此優質的廢水適合回用和環保排放。 此外，中空纖維MBR將生物處理和固液分離結合在同一裝置內。 這種緊湊的設計比傳統的廢水處理系統需要更少的空間，這在土地空間有限的城市地區尤其有利。 此外，中空纖維MBR可以有效應對進水水質和流量的波動。 這使得它在各種水源上都可靠，並適用於各種應用。 此外，隨著對清潔水的需求和嚴格的環境法規的持續，中空纖維MBR可能會保持其在行業中的主導地位。

依配置，市面上分為水下型和側向型。 潛水式配置佔據了大部分市場佔有率。 這種高需求主要是由於潛水器類別的運作效率。 浸入式 MBR 的工作原理是將膜直接浸入生物反應器槽中。 這種配置確保微生物和膜表面之間的有效接觸，從而有效去除污染物。 此外，與橫向版本相比，設計得到簡化，佔地面積也減少。 此外，潛水式 MBR 通常需要較少的曝氣和攪拌能量。 膜的直接浸沒減少了水力損失並節省了能源。 此外，將為水下MBR的廣泛採用創造環境。 此外，潛水式MBR廣泛應用於都市污水處理設施。 它能夠處理不同的進水水質和流量，使其適合城市地區的多樣化需求。 這些發展最終促使對水下 HBR 的需求預計將激增。

依應用，市場分為城市污水處理和工業污水處理。 城市污水處理佔全球 MBR 市場收入的最大佔有率。 人口成長是需求激增的主要驅動力。 隨著城市人口的增加，廢水的產生量也會增加。 MBR 可有效處理城市廢水並滿足嚴格的環境標準。 此外，快速的都市化也加速了MBR的採用。 城市地區面臨更高的廢水課題。 MBR 提供了適合人口稠密地區的緊湊高效的處理解決方案。 另一方面，遵守嚴格的廢水管理環境法也是市政處理廠採用MBR的主要因素之一。 此外，MBR 確保處理後廢水的可重複利用，使 MRB 與持續的永續發展目標保持一致，並為市政處理廠廣泛採用 MBR 創造有利的環境。

為了更瞭解MBR系統的市場實施情況，市場有北美（美國、加拿大等北美地區）、歐洲（德國、英國、法國、西班牙、義大利等歐洲地區）、以及亞太地區（中國、日本、印度、亞太地區其他地區）和世界其他地區。 由於對先進廢水處理解決方案的需求不斷增長，膜分離活性污泥（MBR）系統市場在全球範圍內正在經歷顯著增長。 在主要地區中，北美地區脫穎而出，佔據市場收入的最大佔有率。 北美擁有完善的工業和市政基礎設施。 眾多化學、製藥、食品和飲料以及汽車製造工廠的存在增加了對水處理服務的需求。 例如，2021 年 8 月，久保田膜美國公司向喬治亞州富爾頓縣的 Big Creek 水回收設施交付了每天 3,200 萬加侖 (MGD) 的 MBR 系統，使其成為北美最大的設施之一。 此外，北美國家對廢水排放有嚴格的規定。 MBR 通過去除污染物並確保符合環境規範，有效滿足這些標準。 同時，北美水資源短缺問題日益嚴重。 MBR 可實現高效的水再利用，並減少對淡水資源的壓力。 此外，北美的 MBR 系統技術不斷進步。 公司正在投資研發以增強膜材料和設計。 儘管 2023 年將面臨課題，但北美經濟預計將復甦，經濟穩定支持對水處理基礎設施的投資。

參與市場的主要公司包括Veolia、Xylem、United Utilities Group PLC、SUEZ、KUBOTA Corporation、Evoqua Water Technologies LLC、Mitsubishi Chemical Group Corporation、TORAY INTERNATIONAL, INC.、CITIC Envirotech Ltd.、Kovalus Separation Solutions 等。

目錄

第一章市場介紹

• 市場定義
• 主要目標
• 利害關係人
• 限制

第二章研究方法或前提

• 調查過程
• 調查方法
• 受訪者簡介

第三章市場總結

第 4 章執行摘要

第五章COVID-19對膜分離活性污泥（MBR）系統市場的影響

第六章膜分離活性污泥（MBR）系統市場收入，2020-2030

第七章產品市場分析

• 中空纖維
• 平板
• 多管狀

第 8 章市場構成分析

• 水下類型
• 橫向型

第 9 章依應用程式進行市場分析

• 城市污水處理
• 工業廢水處理

第10章區域市場分析

• 北美
  • 美國
  • 加拿大
  • 其他北美地區
• 歐洲
  • 德國
  • 英國
  • 法國
  • 義大利
  • 其他歐洲地區
• 亞太地區
  • 中國
  • 印度
  • 日本
  • 韓國
  • 其他亞太地區
• 世界其他地區

第十一章膜分離活性污泥（MBR）系統市場動態

• 市場驅動因素
• 市場課題
• 影響分析

第十二章膜分離活性污泥（MBR）系統市場機會

第十三章膜分離活性污泥（MBR）系統市場趨勢

第十四章需求與供給分析

• 需求方分析
• 供給面分析

第15章價值鏈分析

第16章比賽場景

• 競爭狀況
  • 波特五力分析

第十七章公司簡介

• Veolia
• Xylem
• United Utilities Group PLC
• SUEZ
• KUBOTA Corporation.
• Evoqua Water Technologies LLC
• Mitsubishi Chemical Group Corporation.
• TORAY INTERNATIONAL, INC.
• CITIC Envirotech Ltd
• Kovalus Separation Solutions

第十八章免責聲明

A Membrane Bioreactor (MBR) is a cutting-edge wastewater treatment technology that marries two essential components: biological treatment and membrane filtration. In the MBR system, microorganisms (such as bacteria) play a crucial role. They break down organic matter present in the wastewater. This biological degradation process occurs in a specialized chamber. After the biological treatment, the treated water undergoes an additional step. It passes through a membrane filter. This membrane acts as a selective barrier, allowing only clean water molecules to pass through while retaining any remaining suspended solids and microorganisms.

The Membrane Bioreactor (MBR) System Market is expected to grow at a strong CAGR of around 8.28% owing to the increasing demand for innovative water treatment systems with the rising water scarcity and water pollution. As water scarcity is becoming a pressing concern, MBRs play a crucial role. Their efficient treatment process allows for water reuse reducing the strain on freshwater resources. In emerging countries like Asia Pacific and South America, where water scarcity is acute, the demand for MBRs has surged. For instance, in October 2023, the Food and Agricultural Organization published a report suggesting that water scarcity is rising at an unnerving rate. Furthermore, the organization has estimated that, by 2030, the need for freshwater will surpass approximately 40% of the available supply. Furthermore, governments worldwide are imposing stricter regulations regarding wastewater discharge. MBRs meet these stringent regulations by effectively removing pollutants and ensuring compliance with environmental laws. Moreover, rapid urbanization and industrial growth lead to increased wastewater generation. MBRs are well suited for handling large volumes of wastewater from diverse sources, including municipal, textile, food and beverages, and oil & gas industries.

Based on the product, the market is categorized into hollow fiber, flat sheet, and multi-tubular. The hollow fiber stands out as a dominant player in terms of market share and widespread adoption. The primary factor driving this dominance includes its capability to efficiently remove contaminant particles such as suspended solids, pathogens, and organic matter from wastewater. This high-quality effluent output makes these discharges suitable for reuse or environmentally friendly discharge. Furthermore, Hollow fiber MBRs combine biological treatment and solid-liquid separation within the same unit. This compact design requires less space compared to conventional wastewater treatment systems, particularly advantageous for urban areas with limited land space. Additionally, Hollow fiber MBRs can handle variations in influent quality and flow rates effectively. Thus making them reliable across various water sources, and making them adaptable to diverse applications. Moreover, as the demand for clean water and stringent environmental regulations persist, hollow fiber MBRs will likely maintain their dominance in the industry.

Based on the configuration, the market is bifurcated into submerged and side streams. The submerged configuration holds the major portion of the market in terms of market share. This high demand is primarily due to the efficiency with which the submerged category operates. Submerged MBRs operate with membranes immersed directly in the bioreactor tank. This configuration ensures efficient contact between microorganisms and the membrane surface, leading to effective contaminant removal. Furthermore, it simplifies the design and reduces the footprint compared to side-stream systems. Moreover, submerged MBRs typically require less energy for aeration and mixing. The direct immersion of membranes reduces hydraulic losses, resulting in energy savings. Further creating a conducive environment for the widespread adoption of submerged MBRs. Additionally, Submerged MBRs are widely used in municipal wastewater treatment plants. Their ability to handle variable influent quality and flow rates suits the diverse needs of urban areas. These developments are culminating in a scenario, where a surge in demand for submerged HBRs is being anticipated.

Based on application, the market is categorized into municipal and industrial wastewater treatment. Municipal wastewater treatment accounts for the largest share of MBR market revenue globally. Population growth is the primary factor leading to this surge in demand. As urban populations grow, so does the volume of sewage generated. MBRs efficiently treat municipal wastewater, meeting stringent environmental standards. Furthermore, rapid urbanization is also accelerating the adoption of MBRs. Urban areas face higher wastewater challenges. MBRs offer compact, efficient treatment solutions suitable for densely populated regions. Meanwhile, compliance with strict environmental laws, regarding wastewater management is also one of the major factors driving the adoption of MBRs in municipal treatment plants. Additionally, as MBRs ensure reusability of the treated discharge, align MRBs with the ongoing sustainability goals, creating a favorable environment for the widespread adoption of MBRs in municipal treatment plants.

For a better understanding of the market adoption of the MBR system, the market is analyzed based on its worldwide presence in countries such as North America (The U.S., Canada, and the Rest of North America), Europe (Germany, The U.K., France, Spain, Italy, Rest of Europe), Asia-Pacific (China, Japan, India, Rest of Asia-Pacific), Rest of World. The Membrane Bioreactor (MBR) system market has witnessed significant growth globally, driven by the increasing demand for advanced wastewater treatment solutions. Among the major regions, North America stands out as the leader, accounting for the largest share of market revenue. North America boasts a well-established industrial and municipal infrastructure. The presence of numerous chemical, pharmaceutical, food & beverage, and automotive manufacturing facilities drives the demand for water treatment services. For instance, in August 2021, KUBOTA Membrane USA Corporation provided a 32 million gallon per day (MGD) MBR system to Fulton County's Big Creek Water Reclamation Facility in Georgia, making it one of the largest facilities in North America. Furthermore, North American countries have stringent regulations regarding wastewater discharge. MBRs effectively meet these standards by removing pollutants and ensuring compliance with environmental norms. Meanwhile, Water scarcity is a growing concern in North America. MBRs allow for efficient water reuse, reducing strain on freshwater resources. Additionally, North America is witnessing continuous technological advancements in MBR systems. Companies invest in research and development, enhancing membrane materials and designs. Despite challenges in 2023, North America's economy is projected to rebound, and economic stability supports investments in water treatment infrastructure.

Some of the major players operating in the market include Veolia; Xylem; United Utilities Group PLC; SUEZ; KUBOTA Corporation.; Evoqua Water Technologies LLC; Mitsubishi Chemical Group Corporation.; TORAY INTERNATIONAL, INC.; CITIC Envirotech Ltd; and Kovalus Separation Solutions

TABLE OF CONTENTS

1MARKET INTRODUCTION

• 1.1.Market Definitions
• 1.2.Main Objective
• 1.3.Stakeholders
• 1.4.Limitation

2RESEARCH METHODOLOGY OR ASSUMPTION

• 2.1.Research Process of the Membrane Bioreactor (MBR) System Market
• 2.2.Research Methodology of the Membrane Bioreactor (MBR) System Market
• 2.3.Respondent Profile

3MARKET SYNOPSIS

4EXECUTIVE SUMMARY

5IMPACT OF COVID-19 ON THE MEMBRANE BIOREACTOR (MBR) SYSTEM MARKET

6MEMBRANE BIOREACTOR (MBR) SYSTEM MARKET REVENUE (USD BN), 2020-2030F.

7MARKET INSIGHTS BY PRODUCT

• 7.1.Hollow Fiber
• 7.2.Flat Sheet
• 7.3.Multi-Tubular

8MARKET INSIGHTS BY CONFIGURATION

• 8.1.Submerged
• 8.2.Side Stream

9MARKET INSIGHTS BY APPLICATION

• 9.1.Municipal Wastewater Treatment
• 9.2.Industrial Wastewater Treatment

10MARKET INSIGHTS BY REGION

• 10.1.North America
  • 10.1.1.The U.S.
  • 10.1.2.Canada
  • 10.1.3.Rest of North America
• 10.2.Europe
  • 10.2.1.Germany
  • 10.2.2.The U.K.
  • 10.2.3.France
  • 10.2.4.Italy
  • 10.2.5.Rest of Europe
• 10.3.Asia-Pacific
  • 10.3.1.China
  • 10.3.2.India
  • 10.3.3.Japan
  • 10.3.4.South Korea
  • 10.3.5.Rest of Asia-Pacific
• 10.4.Rest of the World

11MEMBRANE BIOREACTOR (MBR) SYSTEM MARKET DYNAMICS

• 11.1.Market Drivers
• 11.2.Market Challenges
• 11.3.Impact Analysis

12MEMBRANE BIOREACTOR (MBR) SYSTEM MARKET OPPORTUNITIES

13MEMBRANE BIOREACTOR (MBR) SYSTEM MARKET TRENDS

14DEMAND AND SUPPLY-SIDE ANALYSIS

• 14.1.Demand Side Analysis
• 14.2.Supply Side Analysis

15VALUE CHAIN ANALYSIS

16COMPETITIVE SCENARIO

• 16.1.Competitive Landscape
  • 16.1.1.Porters Fiver Forces Analysis

17COMPANY PROFILED

• 17.1.Veolia
• 17.2.Xylem
• 17.3.United Utilities Group PLC
• 17.4.SUEZ
• 17.5.KUBOTA Corporation.
• 17.6.Evoqua Water Technologies LLC
• 17.7.Mitsubishi Chemical Group Corporation.
• 17.8.TORAY INTERNATIONAL, INC.
• 17.9.CITIC Envirotech Ltd
• 17.10.Kovalus Separation Solutions

18DISCLAIMER