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E-raamat: Dew Water

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The world’s ever-increasing need for fresh water has led to the use of non-conventional sources such as rain and fog water collection. Although rain water collection is relatively simple, the supply is often erratic. Passive fog water collection has been used in several parts of the world but is only relevant to certain geographical locations. Dew occurrence, however, is far more widespread, can form in most climates and geographic settings, show high frequency and prevalence throughout the year. During the past 20 years, dew collection has therefore been investigated as a serious supplemental source of fresh water. Dew Water offers a thorough review of dew, its formation characteristics and potential for dew collection, for audiences that include policy-makers, non-governmental organizations involved in development aid and sustainable development, engineers, urban planners, researchers and students.

After providing a background on atmospheric water, humid air, and sky and materials emissivity, the book deals with dew formation and its estimation with a focus on the use of meteorological data. Dew measurement techniques are reviewed and discussed as well as dew collection by passive means. Computational fluid dynamics technique is described for better design of dew collectors. Dew quality (chemistry, biology) is assessed in view of potable water quality. Costs and economic aspects are also considered.

Topics include: dew, dew water, sky emissivity, materials emissivity, passive cooling, dew formation, dew collection, computational fluid dynamics, dew chemistry, dew biology, and dew economics.
Forewords xi
Preface xv
Participants of the Reviewing Process xxi
Glossary xxiii
List of Figures xli
List of Tables lix
List of Abbreviations lxiii
1 History 1(4)
2 Water on Earth 5(8)
2.1 Water Cycle
5(2)
2.2 Water Repartition
7(1)
2.3 Atmospheric Water
8(1)
2.3.1 Atmosphere Composition
8(1)
2.3.2 Water Repartition
8(1)
2.4 Contribution and Role of Dew
9(4)
2.4.1 General
9(1)
2.4.2 Dew and Plants
9(2)
2.4.3 Dew Water for Humans
11(2)
3 Atmosphere and Materials Radiative Properties 13(22)
3.1 Radiative Properties of Materials
13(5)
3.1.1 Definitions
13(1)
3.1.2 Planck's Law and Black Body
14(1)
3.1.3 Stefan-Boltzmann Law
15(1)
3.1.4 Kirchhoff's Law of Thermal Radiation
15(1)
3.1.5 Gray Body
16(1)
3.1.6 Atmospheric Radiation
17(1)
3.2 Long Wave Radiative Transfer in Atmosphere
18(17)
3.2.1 Clear Sky Emissivity: Radiation Deficit
22(5)
3.2.2 Clear Sky Emissivity: Angular Dependence
27(3)
3.2.3 Cloudy Sky Emissivity
30(3)
3.2.4 Dry and Wet Substrate Emissivities
33(2)
4 Humid Air 35(20)
4.1 Humid Air Characteristics
35(6)
4.1.1 Dalton's Law
36(1)
4.1.2 Humid Air Equation of State
36(1)
4.1.3 Humid Air Density
37(1)
4.1.4 Saturated Vapor Pressure
37(4)
4.2 Specific Quantities
41(14)
4.2.1 Moisture Content, Humidity Ratio, Mass Mixing Ratio, Absolute and Specific Humidity
41(1)
4.2.2 Relative Humidity
42(1)
4.2.3 Dew Point Temperature and Relative Humidity
42(1)
4.2.4 Dew-point Depression Temperature and Relative Humidity
42(2)
4.2.5 Degree of Saturation
44(1)
4.2.6 Specific Volume
44(1)
4.2.7 Specific Enthalpy
45(2)
4.2.8 Wet-Bulb Temperature: Psychrometric Constant
47(3)
4.2.9 Mollier Diagram. Psychometric Chart
50(1)
4.2.10 Moisture Harvesting Index
50(3)
4.2.11 The Vapor Concentration-Vapor Pressure Relation
53(2)
5 Dew Nucleation and Growth 55(50)
5.1 Nucleation
55(5)
5.1.1 Homogeneous Nucleation
55(3)
5.1.2 Heterogeneous Nucleation
58(2)
5.2 Boundary Layer
60(3)
5.3 Growth Regimes
63(18)
5.3.1 Basic Equations
65(2)
5.3.2 Single Droplet Growth Law
67(1)
5.3.3 Individual Drop Growth in a Pattern
68(2)
5.3.4 Drop Pattern Evolution with Coalescence
70(2)
5.3.5 Effect of Edges and Borders
72(5)
5.3.6 Contact Angle Hysteresis and Surface Coverage
77(2)
5.3.7 New Drop Generation
79(2)
5.3.8 Effects of Gravity
81(1)
5.4 Spatio-temporal Fluctuations
81(1)
5.5 Condensation on Micro-patterned Substrates
82(7)
5.5.1 Micro-pillars
83(2)
5.5.2 Grooves and Stripes
85(4)
5.6 Liquid and Liquid-Imbibed Substrate
89(2)
5.7 Melting Substrate
91(2)
5.8 Thermal Aspects
93(12)
5.8.1 Drop Surface
93(1)
5.8.2 Radiative Versus Conductive Cooling: Planar Substrate
94(4)
5.8.3 Radiative Versus Conductive Cooling: Bumpy Substrate
98(3)
5.8.4 Condensation Rates of Bumpy Substrates
101(4)
6 Dew Collection by Gravity 105(28)
6.1 Smooth Substrates
106(8)
6.1.1 Filmwise
106(5)
6.1.2 Dropwise
111(3)
6.2 Edge Effects
114(2)
6.3 Textured Substrates
116(11)
6.3.1 Filmwise
116(6)
6.3.2 Dropwise
122(5)
6.4 Rough and Porous Substrate
127(3)
6.4.1 Enhanced Roughness
127(2)
6.4.2 Porous Substrate (Fibrocement)
129(1)
6.5 Oil-Imbibed Micro-substrate
130(3)
7 Dew Yield Estimation 133(28)
7.1 Artificial Neural Networks
134(6)
7.1.1 Model Inputs and Architecture
135(1)
7.1.2 Model Optimization
136(2)
7.1.3 Results
138(2)
7.2 Energy Balance Models
140(5)
7.2.1 Basic Equations
141(4)
7.2.2 Semi-empirical Models
145(1)
7.3 Analytical Model with Simple Meteorological Data
145(10)
7.3.1 Approximations in the Energy Equation
147(1)
7.3.2 Laboratory Tests
147(1)
7.3.3 Wind Influence
148(1)
7.3.4 Radiation Deficit
149(1)
7.3.5 Dew Yield
150(1)
7.3.6 Comparison with Measured Dew Yields
151(4)
7.4 CFD-based Extrapolation to Non-planar Condensers
155(1)
7.5 Dew Maps
155(6)
8 Computational Fluid Dynamics 161(24)
8.1 Principles of the Simulation
162(2)
8.2 Dew Yield and Cooling Temperature
164(1)
8.3 Radiative Cooling
165(4)
8.3.1 Radiative Modules
166(1)
8.3.2 Mimicking Radiation by Surface-like Heat Flux
167(2)
8.4 Program Setup
169(3)
8.5 Study of Structures
172(13)
8.5.1 Planar Structures
173(4)
8.5.2 Roofs
177(1)
8.5.3 Hollow Ridges
178(1)
8.5.4 Hollow Cones
178(4)
8.5.5 Positive Cones and Pines
182(1)
8.5.6 Calibrations
183(2)
9 Dew Measurement and Collection 185(20)
9.1 Optical Means
185(4)
9.1.1 Observation-based Methods
185(2)
9.1.2 Light Transmission or Reflection
187(1)
9.1.3 Change of Spectral Reflectance
188(1)
9.2 Electrical Means: Leaf-Wetness Sensors
189(1)
9.3 Direct Weighing
190(1)
9.4 Evaluation by Gravity Flow Collection
191(2)
9.4.1 Scraping
191(1)
9.4.2 Boundary Effects
192(1)
9.5 General Effect of Materials and Forms
193(1)
9.6 Enhanced Dew Condensation and Collection
194(3)
9.7 Dew Measurement Standard
197(2)
9.8 Super Absorbing Hydrogels
199(1)
9.9 Massive Dew Condensers
200(3)
9.10 Review of Large Dew Condensers
203(2)
10 Dew Water Quality 205(26)
10.1 Chemical Characteristics
205(22)
10.1.1 Catchment Techniques and Data Analyses
207(2)
10.1.2 Electric Conductivity. Total Dissolved Solids
209(3)
10.1.3 Major and Minor Ions
212(4)
10.1.4 pH
216(1)
10.1.5 Ion Source Characterization (Correlations, Enrichment Factor, Air Mass Trajectory, Isotope Analysis)
217(8)
10.1.6 Urban Environment
225(2)
10.2 Biological Features
227(4)
10.2.1 Dew on Plants
227(1)
10.2.2 Dew on Inert Substrates
228(1)
10.2.3 Sterilization by Dew Condensation
229(2)
11 Economic Aspects 231(6)
11.1 Mirleft (SW Morocco)
232(1)
11.2 Coquimbo Region (S-center Chile)
233(1)
11.3 Kothara (NW India)
234(3)
Appendix A Slab and Hemisphere Emissivities 237(4)
Appendix B The Clausius-Clapeyron Equation 241(2)
Appendix C Relation between Vapor and Heat Transfer Coefficients 243(4)
C.1 Vapor Transfer
243(1)
C.2 Heat Transfer
244(1)
C.3 Ratio of Transfer Coefficients
244(3)
Appendix D Volume of a Spherical Cap 247(2)
Appendix E Wetting and Super Wetting Properties 249(6)
E.1 Ideal Surface
249(1)
E.2 Rough and Micro-patterned Surfaces
250(5)
E.2.1 Rough Substrate
250(1)
E.2.2 Micro-patterned Substrate. Cassie Baxter and Wenzel States
251(4)
Appendix F Sand Blasting Roughness 255(4)
F.1 Roughness Amplitudes
255(2)
F.2 Wenzel Roughness Factor
257(2)
Appendix G Meniscus in a Groove 259(2)
Appendix H The Penman-Monteith Equation 261(4)
H.1 The Penman-Monteith Equation
261(1)
H.2 Aerodynamic Resistance ra
262(1)
H.3 (Bulk) Surface Aerodynamic Resistance rs
262(1)
H.4 Reference Surface
263(2)
Appendix I Relation between Dew Yield and Dry Air Cooling 265(4)
Bibliography 269(28)
Index 297(8)
About the Author 305
Daniel Beysens
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