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排水中の栄養分回収技術におけるイノベーション

Innovations in Wastewater Nutrient Recovery

発行 Frost & Sullivan 商品コード 572938
出版日 ページ情報 英文 59 Pages
納期: 即日から翌営業日
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排水中の栄養分回収技術におけるイノベーション Innovations in Wastewater Nutrient Recovery
出版日: 2017年09月26日 ページ情報: 英文 59 Pages
概要

当レポートでは、排水からの栄養分回収のための各種技術について調査し、技術概要、メリットおよび提供価値、産業成長の推進因子と障壁、リン・窒素など各種栄養分回収技術におけるイノベーションの動向、成長機会の分析、アナリストによる見解、特許データなどをまとめています。

第1章 エグゼクティブサマリー

第2章 排水中の栄養分回収技術部門:概要

  • 訴求力のある栄養分回収の提供価値:持続可能な食品・水品質管理の大きな潜在性
  • 栄養分回収の統合型アプローチ:業務効率改善のため複数の回収ポイントを提供
  • 産業推進因子と障壁:厳しい排水排出限度と肥料としての用途の可能性
  • 産業推進因子と障壁:厳しい排水排出限度が排水中の栄養分回収技術のニーズを推進
  • 肥料・化学品:排水中の栄養分回収技術による主な製品
  • リン・窒素回収:生物化学的酸素要求量・総浮遊物質の削減ニーズ

第3章 排水中の栄養分回収技術におけるイノベーション

  • リン回収の革新的技術
  • リン回収の物理化学的処理の進歩
  • リン回収の生物学的処理の進歩
  • 窒素回収の革新的技術
  • 窒素回収の生物学的処理の進歩
  • 窒素回収の物理化学的処理の進歩

第4章 排水中の栄養分回収技術の分析

  • 主要国の排水排出限度:概要
  • 排水からの栄養分回収に用いられる技術
  • 回収マトリックス・排水排出限度からの主な影響
  • 提言:地域別

第5章 成長機会

  • 栄養分回収:新しい能力
  • 新しい処理法の活用:地域的拡張

第6章 アナリストの見解

第7章 主要特許・契約

目次
Product Code: D7EE

Advancements in wastewater nutrient recovery processes that enable better sludge reclamation and offer sustainable applications to the nutrient recovered

Industrial and Municipal wastewater should be considered as an important source for the recovery of crucial nutrients like nitrogen, phosphorous and also other micro nutrients like potassium. The recovery of nutrients from wastewater will replace the anthropogenic fertilizers used in agriculture which can reduce the soil fertility and can also have serious implications on human health and environment. Recovery of nutrients will eliminate the possibility of eutrophication in water bodies due to the excess discharge of nutrients. Recovery of nutrients will also reduce the operational and maintenance costs as nutrient recovery involves sludge reclamation which will otherwise result in scaling of equipment. The federal regulations of all countries should also consider stringent effluent discharge permissible limits for total phosphorous and total nitrogen in order to reduce the total maximum daily nutrient load in the effluent streams.

Table of Contents

1.0 Executive Summary

  • 1.1 Research Scope
  • 1.2 Research Process and Methodology
  • 1.3 Key Findings in Wastewater Nutrient Recovery

2.0 Overview of Wastewater Nutrient Recovery Sector

  • 2.1 The Attractive Value Proposition of Nutrient Recovery Serves As a Great Potential For Sustainable Food and Water Quality Management
  • 2.2 An Integrated Approach for Nutrient Recovery will Provide Multiple Recovery Points for Increased Operational Efficiencies
  • 2.3 Industry Drivers and Restraints - Stringent Effluent Discharge Limits and Potential to be Used as Fertilizers Will be Key for Wastewater Nutrient Recovery Technologies
  • 2.4 Industry Drivers and Restraints - Stringent Effluent Discharge Limits Have Highlighted the Need for Wastewater Nutrient Recovery Technologies
  • 2.5 Fertilizers and Chemicals Are the Key Products Resulting From Wastewater Nutrient Recovery
  • 2.6 Recovery of Phosphorous and Nitrogen Apart from Reducing Chemical and Biological Oxygen Demand, Total Suspended Solids Should be Complied across the Value Chain

3.0 Innovations in Wastewater Nutrient Recovery

  • 3.1 Innovative Technologies for Phosphorous Recovery
    • 3.1.1 Phosphorous Recovery From Wastewater Reduces the stress on Natural Phosphorous Cycle in the Ecosystem
  • 3.2 Advancements in Physico-chemical Processes for Phosphorous Recovery
    • 3.2.1 Forward Osmosis Offering Better Selectivity of Nutrients Effectively Recovers Nutrients
    • 3.2.2 Membrane Distillation and Membrane Separation Processes Completely Recovers Nutrients Without Any Fouling Problems
  • 3.3 Advancements in Biological Processes for Phosphorous Recovery
    • 3.3.1 Enhanced Biological Phosphorous Removal for the Recovery of Phosphorous from Wastewater
    • 3.3.2 Natural Constructed Wetlands for the Cost Effective Removal of Nutrients from Wastewaters
    • 3.3.3 Future Prospects Will Aim at the Recovery of Phosphorous in the Form of Brushite or Struvite Crystals
    • 3.3.4 Regulatory Guidelines in Australia Should be a Benchmark for the Other Countries to Follow in Terms of Recovering Nutrients
    • 3.3.5 USA Leads in the Number of Patents Filed and Canadian Government is Providing Funding for the Installation of Wastewater Nutrient Recovery Systems in Canada
    • 3.3.6 Patented Phosphorous Recovery Systems will Aid in the High Quality Production of Fertilizers for Agriculture.
    • 3.3.7 Proprietary Processes from Independent Stakeholders Come With Increased Recovery of Nutrients
    • 3.3.8 Micro Nutrients and Heavy Metals Will also be Recovered from Nutrient Recovery Processes
  • 3.4 Innovative Technologies For Nitrogen Recovery
    • 3.4.1 Efficient Methods for Nitrogen Recovery from WW is Vital to Mitigate the Threat on Food Security and Environment
  • 3.5 Advancements in Biological Processes for Nitrogen Recovery
    • 3.5.1 Adopting Partial Nitritation/Anammox (PN/A) Process for Nitrogen Recovery Reduces the Overall Energy Demand
    • 3.5.2 Utilizing Attached Growth Systems Results in Footprint Reduction of WW Treatment Plant
  • 3.6 Advancements in Physicochemical Processes for Nitrogen Recovery
    • 3.6.1 Adsorbents and Fuel Cells Play a Vital Role in Improving the Performance of Bioelectrochemical Systems for Ammonia Recovery
    • 3.6.2 Electrochemical Stripping is Ideal for Ammonia Recovery from Concentrated Wastewater With Irregular Flow Conditions
    • 3.6.3 Innovations Aiming to Reduce Cost of Physicochemical Treatment and Retention Time For Biological Processes Are Vital For Nutrient Recovery
    • 3.6.4 Stricter Nitrogen Discharge Limits Specifying the Exact Type of Nitrogen Are Required For Improved Adoption of Nutrient Recovery Facilities
    • 3.6.5 NA Leads and EU Shows Promising Growth in the Number of Patents Filed With Funding From Government-led Organizations
    • 3.6.6 Stakeholders in Nitrogen Recovery Through Biological Processes are High in Number Globally Comparatively
    • 3.6.7 Partnering with Regulatory Bodies for Nutrient Recovery will Aid Stakeholders to Design Systems meet the Strict Discharge Limits

4.0 Analysis of Wastewater Nutrient Recovery

  • 4.1 Wastewater Effluent Discharge Limits in Various Countries - Snapshot
  • 4.2 Technologies Utilized for Recovery of Nutrients from Wastewater
  • 4.3 Key Inferences from the Recovery Matrix and Wastewater Effluent Discharge Limits
  • 4.4 Region Wise Recommendations Based on the Current Innovations Projected for the Future

5.0 Growth Opportunities for Wastewater Nutrient Recovery

  • 5.1 Growth Opportunity 1- Recovery of Nutrients-New Capabilities
  • 5.2 Growth Opportunity 2- Recovery of Nutrients-New Capabilities
  • 5.3 Growth Opportunity 3- Utilization of New Processes-Geographical Expansion

6.0 Analyst Insights on Wastewater Nutrient Recovery

  • 6.1 Regulatory and Technological Advancements are the Essential Tools for Enhancing the Economics of WWNR

7.0 Key Patents and Contacts

  • 7.1 Key Patents Covering Wastewater Nutrient Recovery
  • 7.1 Key Patents Covering Wastewater Nutrient Recovery (continued)
  • 7.2 Key Contacts
  • Legal Disclaimer
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