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市場調查報告書
商品編碼
961331

太陽熱海水淡化技術的進步

Technological Advances in Solar Thermal Desalination

出版日期: | 出版商: Frost & Sullivan | 英文 51 Pages | 商品交期: 最快1-2個工作天內

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  • 全貌
  • 簡介
  • 目錄
簡介

超過70%的地球表面被水覆蓋。但是,缺水或缺乏清潔水的情況很普遍,而且還在繼續增加。在增長和發達經濟體中都可以看到這種情況。在全球水資源減少和水需求增加的推動下,自來水公司開始尋求淡化海水。

本報告調查並分析了太陽熱造成的海水淡化,並提供了有關新興創新,最新發展,技術準備水平,主要現有技術,增長機會等的系統信息。

目錄

第1章戰略要點

第2章通過太陽能(STD)進行海水淡化:生長環境概述

  • 技術定義和顯示
  • 擴大供需差距促進採用海水淡化技術
  • 可靠性,成本和地理依賴性是採用STD的主要挑戰。
  • 研發活動實現了STD技術的採用

第3章太陽熱海水淡化(STD)技術的進展

  • 太陽熱海水淡化(STD)技術的進展
  • 其他顯著的技術進步

第4章技術和IP:情況

  • 中國領導著太陽能誘導海水淡化(STD)技術的研發活動

第5章增長機會和考慮

  • 納米光子學
  • 能源存儲/熱交換器等技術的整合
  • 自來水公司,技術提供商和研究機構的合作

第6章主要聯繫信息

  • 主要聯繫人
  • 免責聲明
目錄
Product Code: D99F

R&D activities in solar thermal desalination technology driven by rising water scarcity, widening water demand-supply gap, and emission reduction policy level initiatives.

Even though more than 70% of our planet's surface is covered with water, water scarcity, i.e., lack of access to clean drinking water, is widespread and remains on the rise: it is found in both growing and developed economies. Further, driven by declining freshwater resources and increasing water demand around the world, water utilities have begun looking towards desalinated seawater as an ideal candidate to narrow the water supply-demand gap. As of now, most of the desalinated water comes by using reverse osmosis (RO) based water desalination technology, which has challenges of its own such as environmental issues due to brine water disposal, high energy requirement, and high capital cost involved.

Policy-level initiatives for emission reduction have also resulted in driving technological advancements towards sustainable practices, such as solar thermal desalination. These technologies have a far lower carbon footprint, are potentially more cost-effective, and can be scaled relatively more effectively. Most of the technological advancements in the field of Solar Thermal Desalination focuses on optimizing the following aspects: economics of the process, operational reliability, and dependence of the process on the operational area's climate conditions and elevations. Researchers are actively exploring technological solutions such as nanoparticles, nanophotonics, plasmonics, and specially fabricated photothermal membranes for enhanced conversion of solar irradiation to heat energy, for generating water vapors.

This research, 'Technological Advances in Solar Thermal Desalination' focuses on the emerging innovations and the latest developments in the Solar Thermal Desalination technologies and the respective technology readiness levels. In addition to the above, major and existing desalination technologies along with growth opportunities for industry participants is provided.

The study deeply illustrates the following:

  • Overview of the Solar Thermal Desalination Technologies
  • Key stakeholders involved in Solar Thermal Desalination
  • IP Analysis
  • Growth opportunities

Table of Contents

1.0 Strategic Imperatives

  • 1.1 Why Is It Increasingly Difficult to Grow?
  • 1.2 The Strategic Imperative 8™
  • 1.3 The Impact of the Top Two Strategic Imperatives on the Solar Thermal Desalination Industry
  • 1.4 Growth Opportunities Fuel the Growth Pipeline Engine™
  • 1.5 Research Process & Methodology
  • 1.5 Research Process and Methodology (continued)
  • 1.6 Research Scope - Foreseeing Challenges and Solutions

2.0 Solar Thermal Desalination - Growth Environment Overview

  • 2.1 Technology Definition and Indications
  • 2.2 Widening Water Demand Supply Gap Driving Desalination Technology Adoption
  • 2.3 Reliability, Cost, and Geographical Dependence Identified as Key Challenges Associated with STD Adoption
  • 2.4 R&D Activities Enabling Adoption of STD Technology

3.0 Advances in Solar Thermal Desalination Technology

  • 3.1 Technological Advancements in Solar Thermal Desalination3.1.1 Light To Heat Energy Conversion
    • 3.1.1.1 Nanophotonics-enabled Solar Membrane Distillation (NESMD)
    • 3.1.1.1 Nanophotonics-enabled Solar Membrane Distillation (NESMD)
    • 3.1.1.2 Carbon Nanoparticles Infused on a Graphite Foam Enabling Efficient Solar Thermal Desalination
    • 3.1.1.2 Carbon Nanoparticles Infused on a Graphite Foam Enabling Efficient Solar Thermal Desalination
    • 3.1.1.3 Solar Thermal Desalination Via Plasmonics
    • 3.1.1.3 Solar Thermal Desalination Via Plasmonics
    • 3.1.1.4 Solar Thermal Desalination Via Steam Storage Integrated CSP
    • 3.1.1.4 Solar Thermal Desalination Via Steam Storage Integrated CSP
    • 3.1.1.5 Photothermal Membrane Assisted Solar Thermal Desalination
    • 3.1.1.5 Photothermal Membrane Assisted Solar Thermal Desalination
    • 3.1.2 Thermal Vapor Generation & Vapor Condensation
    • 3.1.2.1 Vacuum Driven Condensing Engine for Solar Thermal Desalination
    • 3.1.2.1 Vacuum Driven Condensing Engine for Solar Thermal Desalination
    • 3.1.2.2 Low-temperature Solar Thermal Desalination
    • 3.1.2.2 Low-temperature Solar Thermal Desalination
    • 3.1.2.3 Desalination via a Multi-layer Solar Still
    • 3.1.2.3 Desalination via a Multi-layer Solar Still
  • 3.2 Other Prominent Technological Advances in Solar Thermal Desalination
    • 3.2.1 Large Scale Solar Thermal Desalination Via Solar Dome Technology
    • 3.2.1 Large Scale Solar Thermal Desalination Via Solar Dome Technology
    • 3.2.2 Desalination Utilizing Residual Heat from Solar Panels
    • 3.2.2 Desalination Utilizing Residual Heat from Solar Panels

4.0 Technology and IP - Landscape

  • 4.1 China Leads R&D Activity in Solar Thermal Desalination Technologies

5.0 Growth Opportunities and Insights

  • 5.1 Nanophotonics Exhibits Great Potential for Future Solar Thermal Desalination Plants
  • 5.2 Integration of Technologies Such as Energy Storage or Heat Exchangers Drives Innovations in Solar Thermal Desalination
  • 5.3 Collaborations Among Water Utilities, Technology Providers, and Research Institutes to Drive Technological Advancements

6.0 Key Contacts

  • 6.1 Key Contacts
  • 6.1 Key Contacts
  • Legal Disclaimer