轉輪輔助空氣冷卻取水技術 涂壤 劉蘭斌著 9787502497385 【台灣高等教育出版社】
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物品所在地:中國大陸
原出版社:冶金工業
物品所在地:中國大陸
原出版社:冶金工業
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| *完成訂單後正常情形下約兩周可抵台。 *本賣場提供之資訊僅供參考,以到貨標的為正確資訊。 印行年月:202403*若逾兩年請先於私訊洽詢存貨情況,謝謝。 台灣(台北市)在地出版社,每筆交易均開具統一發票,祝您中獎最高1000萬元。 書名:轉輪輔助空氣冷卻取水技術 ISBN:9787502497385 出版社:冶金工業 著編譯者:涂壤 劉蘭斌著 頁數:242 所在地:中國大陸 *此為代購商品 書號:1647563 可大量預訂,請先連絡。 內容簡介 本書從針對空氣冷卻取水,研究轉輪輔助的高效空氣取水流程及主動式和被動式冷熱源的高效利用方式,對系統的在多工況下的取水能效、優化運行參數及經濟性進行全面分析。本書主要包括以下內容:空氣冷卻取水類型及特點;固體吸附轉輪熱濕傳遞機理及數值模型;固體轉輪用於空氣加濕和空氣除濕的對比;空氣取水熱力循環構建及性能優化分析;採用主動式冷熱源的轉輪輔助加濕空氣取水系統性能分析;採用被動式冷熱源的轉輪輔助加濕空氣取水系統性能分析等。作者簡介 塗壤,北京科技大學教授、碩士生導師,2014年畢業於清華大學,獲博士學位。主要研究方向為新型空氣處理裝置研發以及面向民用建築和數據中心的高效暖通空調系統設計及機電系統智慧能源管控。負責並參与多項國家級和省部級項目,以第一作者或通訊作者身份在國內外著名學術期刊上發表論文40餘篇,授權國家發明或實用新型專利10餘項。人選「2022-2024」年度北京製冷學會「青年人才托舉」工程,獲評2022年北京科技大學「北科青年學者」。目錄 Chapter 1 Reviews of Atmospheric Water Harvesting Technologies1 1 Atmospheric water harvesting using conventional technologies 1 1 1 Atmospheric water harvesting using condensation technologies 1 1 2 Atmospheric water harvesting using sorption technologies 1 2 Atmospheric water harvesting using other technologies 1 2 1 Innovative technologies for atmospheric water harvesting 1 2 2 Desiccant wheel or membrane assisted technologies for atmospheric water harvesting 1 3 Performance limiting factors and solutions of atmospheric waterharvesting technologies 1 3 1 Performance limiting factors of atmospheric water harvesting technologies 1 3 2 Solutions 1 4 Conclusions References Chapter 2 Working Principles of Desiccant Wheels used to Dehumidify or Humidify Air 2 1 Heat and moisture transfer mechanism in desiccant wheel 2 2 Numerical models of the desiccant wheel 2 2 1 Working principles of desiccant wheels 2 2 2 Two-dimensional-double-diffusion model 2 2 3 One-dimensional-double-diffusion model 2 2 4 One-dimensional-non-diffusion model 2 3 Validations of the mathematic models 2 3 1 Test bench 2 3 2 Validations 2 4 Conclusions References Chapter 3 Performance Analysis of Air Humidification ProcessUsing Desiccant Wheels 3 1 Differences between humidification and dehumidification usingdesiccant wheels 3 2 Air handling process and configurations of the humidifier usingdesiccant wheels 3 2 1 Working principles of air humidification process using desiccant wheels 3 2 2 Parametric studies of the proposed air humidification systems 3 2 3 Operating strategies under partial working conditions 3 3 Energy utilization forms of air humidification process using desiccant wheels 3 3 1 Working principles of the proposed air humidifier using multi-stagedesiccant wheels 3 3 2 Heating systems and system efficiency 3 3 3 Step utilization of heat and heat recovery from low-grade heat sources 3 4 Conclusions References Chapter 4 Performance Analyses and Optimizations of Desiccant Wheels-Assisted Atmospheric Water Harvesting System Based on Ideal Thermodynamic Cycles 4 1 Theoretical analysis of the direct cooling water harvesting method 4 2 Performance analysis of humidification processes based on ideal desiccant wheels 4 2 1 Construction of ideal desiccant wheels 4 2 2 Humidification processes based on ideal desiccant wheels 4 2 3 Ideal performances of the three humidification systems 4 3 Water harvesting performances using actual desiccant wheels 4 3 1 Parametric study of humidification performances of MS-Ⅱ 4 3 2 Optimization studies of water harvesting performances 4 4 Performance comparisons with the DCWH system 4 4 1 Actual cooling and heating systems driven by Vcc 4 4 2 Discussions 4 5 Conclusions References Chapter 5 Performance Analyses of A New System for Water Harvesting from Moist Air that Combines Multi-Stage Desiccant Wheels and Vapor Compression Cycles 5 1 Introduction and analysis of the system's humidifying module 5 1 1 Introduction of the actual desiccant wheel's humidification process 5 1 2 Performance indexes and influencing factors of the humidification process 5 2 System energy consumption analysis 5 2 1 Effects of Ar on WHR 5 2 2 Effects of LDW on WHR 5 2 3 Effects of N on WHR 5 3 Performance analysis with different heat pump systems 5 3 1 Design of highly efficient systems 5 3 2 Effect of tc and wreg, out on WHE 5 4 Optimal system configurations 5 5 Conclusions References Chapter 6 Performance Analysis of Desiccant Wheels-Assisted Atmospheric Water Harvesting System with Passive Heating and Cooling Sources 6 1 Introduction of atmospheric water harvesting system with passive heating and cooling sources 6 2 Performance |
