表紙
市場調查報告書
商品編碼
820551

各種過濾用技術布料的市場機會

Technical Fabrics in Filtration- Opportunity Assessment

出版日期: | 出版商: Frost & Sullivan | 英文 62 Pages | 商品交期: 最快1-2個工作天內

價格
  • 全貌
  • 簡介
  • 目錄
簡介

本報告調查各種過濾用技術布料的市場,並統整了過濾程序概要、各種用途的好處、各種過濾程序的技術布料重要性、各種用途的必須條件、過濾技術區分別的產品開發動態等。

第1章 執行摘要

第2章 關於過濾程序

  • 法規遵守、減少環境風險:使用過濾程序的重要因素
  • 吸附、吸收、膜過濾:主要過濾技術類型
  • 吸附:可以用最大面積去除微量汙染物質
  • 吸收:目標是從全體量吸收汙染
  • 以膜為底的過濾技術:不需要添加用於去除污染的化學物質

第3章 過濾用技術布料:概要

  • 技術布料:低成本、從提升膜的性能到採用膜過濾
  • 因耐用性、低吸濕性、厚度調整等特徵,增加使用技術布料
  • 不織布:用於過濾程序中最重要的技術布料
  • 玻璃纖維合成不織布:尤其常被用在過濾粒子
  • 技術布料的R&D:焦點是附加價值
  • 創新:焦點在技術布料的潛在用途擴大
  • 用於滿足產業條件的技術布料開發的各種材料、程序

第4章 精密過濾用技術布料

  • 棉&聚酯等技術布料:大多用在精密過濾用途
  • 低操作壓力、性價比:技術布料用在精密過濾的優點
  • 提升濾層效率、抗藥性的精密過濾用布料開發
  • 減低運用成本,實現節能的精密過濾用布料成為焦點

第5章 用在超濾膜的技術布料

  • 各種纖維被用在超濾膜流程
  • 低操作壓力、節能:在超濾膜使用技術布料的優點
  • 有效分離蛋白質,可在低壓操作的超濾膜布料正在開發中
  • 使高品質滲透成為可能,有效除去微生物的超濾膜布料也受到矚目

第6章 用在奈米過濾的技術布料

  • 奈米過濾:在醫藥品、食品&飲料產業受矚目
  • 抗藥性、成本效率:技術布料用在奈米過濾的優點
  • 實現選擇性分離的奈米過濾布料正在開發中
  • 在超高溫下維持性能的過濾用布料正在開發中

第7章 用在逆滲透的技術布料

  • 逆滲透:主要用在水、廢水處理
  • 流程效率、抗藥性:主要優點
  • 正在開發可以在海水淡水處理中去除不必要高鹽分的過濾用布料
  • 對於減少鹽水的產生與能源消費量的布料關心升高

第8章 用在正滲透的技術布料

  • 正滲透的使用環境:跟逆滲透相似
  • 抗汙特性、低壓適用性:優點
  • 正在開發具備抗汙特性的過濾用布料
  • 也正在開發有更高去除率的布料

第9章 用在過濾粒子的技術布料

  • 主要用在HVAC用途
  • 粉塵去除率、高滲透性:主要優點
  • 正在開發抗腐蝕的布料
  • 促進汽車產業分離油汙物質的布料也是焦點

第10章 分析師展望

第11章 連絡資訊

目錄
Product Code: D8AC

Technical Fabrics Increase Efficiency, Promote Durability and Facilitate Energy Savings of Filtration Processes

Filtration is of utmost importance due to its ability to reduce contaminants in the effluent stream, air or water. Filtration technologies are primarily classified based on adsorption, absorption and membrane filtration. Technical fabrics are usually filter- and screen-based fabrics made using varied materials, which include natural fibers like cotton and wool, synthetic fibers like polyester, polyamide, polypropylene, glass and ceramic fibers. The use of technical fabric is gaining relevance in filtration processes across industrial, transportation and residential applications. They are predominantly incorporated into membrane filtration processes with non-woven fabrics widely adopted to increase the efficiency of the filtration processes. Membranes incorporated with the fabrics are more effective due to its complex 3D structure. While a wide range of materials/fibers are used for developing the fabrics, synthetic polymer-based fibers made using materials like polyethylene, polyamide, polypropylene are dominant.

This research service titled “Technical Fabrics in Filtration- Opportunity Assessment“ discusses the recent developments in technical fabrics focused on filtration technologies. It also assess the role of technical fabrics in each filtration technology and the emerging opportunities for the same in filtration industry. The research also provides a deep dive analysis of potential use of technical fabrics in key filtration technologies.

In brief, the research study captures the following:

  • Overview of various filtration technologies and the role of technical fabrics in the same.
  • Assessment of key innovations, research focus areas and technology developments.
  • Key factors that influence the adoption of technical fabrics in filtration technologies.
  • Noteworthy developments related to technical fabrics for various filtration technologies.
  • Mapping of use of technical fabrics to filtration to end-use industries.
  • Emerging opportunities for technology developers of technical fabrics in filtration

Table of Contents

1.0 EXECUTIVE SUMMARY

  • 1.1. Research Scope
  • 1.2. Research Methodology
  • 1.3. Key Findings
  • 1.3. Key Findings (continued)
  • 1.4. Some of the Major Challenges Faced by Membrane Filtration Addressed by Technical Fabrics

2.0 INTRODUCTION TO FILTRATION PROCESSES

  • 2.1. Adherence to Regulations and Reduction of Environmental Hazards are Key Factors That Govern the Use of Filtration Processes
  • 2.2. Adsorption, Absorption and Membrane Filtration are Key Types Of Filtration Technologies
  • 2.3. Adsorption Provides Larger Surface Area for Removal of Micro Pollutants
  • 2.4. Absorption Aims to Capture Pollutants in its Entire Volume
  • 2.5. Membrane-based Filtration Technologies Works Without the Use Of Additional Chemicals to Eliminate Contaminants

3.0 OVERVIEW OF TECHNICAL FABRICS IN FILTRATION

  • 3.1. Technical Fabrics are Being Adopted in Membrane Filtration as They are Cost Effective and Increase the Performance of Membranes
  • 3.2. Characteristics Such as Durability, Low Moisture Absorption And Thickness Control Increases the Use of Technical Fabrics
  • 3.3. Non-wovens are Foremost Amongst Technical Fabrics Used For Filtration Processes
  • 3.4. Non-woven Synthetic Fabrics are Preferred Across Applications With Glass Fibers Gaining Prominence esp. in Particle Filtration
  • 3.5. Technical Fabrics Based R&D Efforts Focused on Providing Value Added Benefits
  • 3.6. Innovations Focused on Increasing Application Potential of Technical Fabrics
  • 3.7. Varied Materials and Processes Used to Develop Technical Fabrics that Meet Industry Requirements

4.0 TECHNICAL FABRICS IN MICROFILTRATION

  • 4.1. Technical Fabrics Such as Cotton and Polyester are Used to Make Technical Fabrics for Microfiltration Applications
  • 4.2. Low Operational Pressure and Cost Efficiency are Key Benefits for Using Technical Fabrics In Microfiltration
  • 4.3. Microfiltration Filter Fabrics With Improved Filter Efficiency and Chemical Resistance Being Developed
  • 4.4. Microfiltration Filter Fabrics, Which Lowers Operating Costs and Impart Energy Savings are Also of Focus

5.0 TECHNICAL FABRICS IN ULTRAFILTRATION

  • 5.1. Wide Range of Fibers are Used for Ultrafiltration Processes for Varied Applications
  • 5.2. Low Operational Pressure and Low Energy Consumption are Key Benefits for Using Technical Fabrics in Ultrafiltration
  • 5.3. Ultrafiltration Filter Fabrics to Efficiently Separate Proteins and Operate at Low Pressures Being Developed
  • 5.4. Ultrafiltration Filter Fabrics That Enable High Quality Permeation and Efficiently Removes Microbes are Also of Focus

6.0 TECHNICAL FABRICS IN NANOFILTRATION

  • 6.1. Nanofiltration is Gaining Prominence in Pharma and Food & Beverage Industries
  • 6.2. Chemical Resistance and Cost Efficiency are Key Benefits of Technical Fabrics in Nanofiltration
  • 6.3. Nanofiltration Filter Fabrics Enable Selective Separation of Organics From Influent Stream are Being Developed
  • 6.4. Filter Fabrics Which Enable Performance at Very High Temperatures are Being Developed

7.0 TECHNICAL FABRICS IN REVERSE OSMOSIS

  • 7.1. Reverse Osmosis is Predominantly Used in Water and Wastewater Treatment
  • 7.2. Process Efficiency and Chemical Resistance are the Key Benefits Offered by Technical Fabrics in Reverse Osmosis
  • 7.3. Filter Fabrics Which Enable Have High Rejection Capability of Unnecessary Salts for Desalination Are Being Developed
  • 7.4. Fabrics That Reduces the Generation of Brine and Also Reduces the Average Energy Consumption are Also of Interest

8.0 TECHNICAL FABRICS IN FORWARD OSMOSIS

  • 8.1. Application Landscape of Forward Osmosis Process is Similar to That of Reverse Osmosis
  • 8.2. Anti-Fouling Properties and Low Pressure Applicability are the Main Benefits Offered by Technical Fabrics in Forward Osmosis
  • 8.3. Filter Fabrics Enabling Anti-fouling Properties are Being Developed
  • 8.4. Fabrics With Higher Rejection Rate are Also Part of Developmental Efforts

9.0 TECHNICAL FABRICS IN PARTICLE FILTRATION

  • 9.1. Particle Filtration Predominantly Used in HVAC Applications
  • 9.2. Dust Removal Efficiency and High Permeability are Key Advantages That Technical Fabrics Offer in Particle Filtration
  • 9.3. Fabrics With High Corrosion Resistance are Being Developed
  • 9.4. Fabrics Facilitating Separation Of Oil Contaminants in Automotive Industry is Also of Focus

10. ANALYST'S PERSPECTIVES

  • 10.1. Filtration Companies are Key Influencers in the Industry Value Chain
  • 10.2. Forward Integration into Filtration Module Development by Fabric Developers is Gaining Traction
  • 10.3. Use of Technical Fabrics for Various Applications Poised to Increase Efficiency of Filtration Processes

11.0 KEY CONTACTS

  • 11.1. Select List of Industry Contacts
  • Legal Disclaimer