| Preface |
|
xi | |
|
INTEGRATED SUSTAINABLE URBAN WATER, ENERGY, AND SOLIDS MANAGEMENT |
|
|
1 | (356) |
|
1 Sustain Ability Goals For Urban Water And Solid Waste Systems |
|
|
3 | (28) |
|
1.1 Introduction to Urban Sustainability |
|
|
3 | (5) |
|
1.2 Historic and Current Urban Paradigms |
|
|
8 | (6) |
|
Paradigms of Urbanization |
|
|
9 | (5) |
|
1.3 Global Climate Changes |
|
|
14 | (2) |
|
1.4 Need for a Paradigm Shift to Sustainability |
|
|
16 | (3) |
|
1.5 Population Increase, Urbanization, and the Rise of Megalopolises |
|
|
19 | (5) |
|
|
|
23 | (1) |
|
Brief Outlook Toward the Future |
|
|
23 | (1) |
|
1.6 What Is a Sustainable Ecocity? |
|
|
24 | (7) |
|
Impact of Global Warming and Continuing Overuse of Resources |
|
|
28 | (1) |
|
The UN 2015 Resolution of Sustainability |
|
|
28 | (3) |
|
2 The New Paradigm Of Urban Water, Energy, And Resources Management |
|
|
31 | (20) |
|
2.1 The Search for a New Paradigm |
|
|
31 | (2) |
|
2.2 From Linear to Hybrid Urban Metabolism |
|
|
33 | (7) |
|
|
|
37 | (3) |
|
2.3 Urban Resilience and Adaptation to Climate Change |
|
|
40 | (11) |
|
Engineering and Infrastructure Hazards and Disaster Resilience |
|
|
42 | (6) |
|
Socioecological or Governance Resilience |
|
|
48 | (3) |
|
3 Goals And Criteria Of Urban Sustainability |
|
|
51 | (22) |
|
3.1 Review of Existing Sustainability Criteria |
|
|
51 | (10) |
|
LEED Criteria for Buildings and Subdivisions |
|
|
53 | (1) |
|
Triple Net-Zero (TNZ) Goals |
|
|
54 | (2) |
|
|
|
56 | (2) |
|
GHG (Carbon Dioxide) Net-Zero Footprint Goal |
|
|
58 | (2) |
|
|
|
60 | (1) |
|
|
|
60 | (1) |
|
3.2 Zero Solid Waste to Landfill Goal and Footprint |
|
|
61 | (8) |
|
|
|
64 | (4) |
|
|
|
68 | (1) |
|
Swedish Recycling Revolution |
|
|
68 | (1) |
|
3.3 Importance of Recycling versus Combusting or Landfilling |
|
|
69 | (4) |
|
4 Origin Of Hydrogen Energy, Ghg Emissions, And Climatic Changes |
|
|
73 | (44) |
|
4.1 Introduction to Energy |
|
|
73 | (6) |
|
Energy Definitions and Units |
|
|
73 | (3) |
|
|
|
76 | (3) |
|
|
|
79 | (12) |
|
Blue and Green Sources of Hydrogen on Earth |
|
|
79 | (5) |
|
Hydrogen as a Source of Energy |
|
|
84 | (5) |
|
Vision of Hydrogen Role in the (Near) Future |
|
|
89 | (2) |
|
4.3 Carbon Dioxide Sequestering and Reuse |
|
|
91 | (7) |
|
Stopping the Atmospheric CO2 Increase and Reversing the Trend |
|
|
91 | (2) |
|
|
|
93 | (3) |
|
Non-CCUS Reuse of Carbon Dioxide |
|
|
96 | (1) |
|
|
|
97 | (1) |
|
4.4 Solar and Wind Blue Power |
|
|
98 | (10) |
|
|
|
98 | (5) |
|
|
|
103 | (3) |
|
Green and Blue Energy Storage |
|
|
106 | (2) |
|
4.5 Food/Water/Energy/Climate Nexus |
|
|
108 | (2) |
|
4.6 World and US Energy Outlook |
|
|
110 | (7) |
|
5 Decentralized Hierarchical Urban Water, Used Water, Solids, And Energy Management Systems |
|
|
117 | (24) |
|
5.1 Economy of Scale Dogma Forced Centralized Management 45 Years Ago |
|
|
117 | (2) |
|
5.2 Distributed Building and Cluster Level Designs and Management |
|
|
119 | (7) |
|
Cluster or Neighborhood Level Water and Energy Recovery |
|
|
121 | (5) |
|
5.3 Flow Separation: Gray Water Reclamation and Reuse |
|
|
126 | (15) |
|
Tap a Sewer, Keep the Liquid, and Sell the Solids |
|
|
132 | (4) |
|
Integrated District Water and Energy Providing Loop |
|
|
136 | (1) |
|
Energy Savings and GHG Reduction by Gray Water Reuse in Clusters |
|
|
137 | (4) |
|
6 Biophilic Sustainable Landscape And Low Impact Development |
|
|
141 | (34) |
|
6.1 Urban Nature and Biophilic Designs |
|
|
141 | (3) |
|
|
|
142 | (2) |
|
6.2 Low-Impact Development |
|
|
144 | (21) |
|
Classification of LID (SUDS) Practices |
|
|
149 | (16) |
|
6.3 Restoring, Daylighting, and Creating Urban Water Bodies |
|
|
165 | (6) |
|
|
|
165 | (4) |
|
|
|
169 | (1) |
|
Vertical Forests and Systems |
|
|
170 | (1) |
|
6.4 Biophilic Urban Biomass Management and Carbon Sequestering |
|
|
171 | (4) |
|
Lawns and Grass Clippings |
|
|
172 | (1) |
|
|
|
172 | (3) |
|
7 Building Blocks Of The Regional Integrated Resources Recovery Facility (Irrf) |
|
|
175 | (36) |
|
7.1 Traditional Aerobic Treatment |
|
|
175 | (4) |
|
GHG Emissions from Traditional Regional Water/Resources Recovery Facilities |
|
|
178 | (1) |
|
7.2 Energy-Producing Treatment |
|
|
179 | (10) |
|
Anaerobic Digestion and Decomposition |
|
|
179 | (3) |
|
Comparison of Aerobic and Anaerobic Treatment and Energy Recovery (Use) Processes |
|
|
182 | (2) |
|
Acid Fermentation and Its Hydrogen Production |
|
|
184 | (4) |
|
|
|
188 | (1) |
|
7.3 Triple Net-Zero: COF Future Direction and Integrated Resource Recovery Facilities |
|
|
189 | (14) |
|
Goals of the Future IRRFs and Enabling Technologies |
|
|
190 | (2) |
|
Energy Recovery in a Centralized Concept with Anaerobic Treatment and Digestion as the Core Technology |
|
|
192 | (2) |
|
Anaerobic Energy Production and Recovery Units and Processes |
|
|
194 | (1) |
|
High Rate Anaerobic Treatment Systems |
|
|
195 | (8) |
|
7.4 Co-Digestion of Sludge with Other Organic Matter |
|
|
203 | (4) |
|
7.5 Conversion of Chemical and Sensible Energy in Used Water into Electricity and Heat |
|
|
207 | (4) |
|
8 Integrating Gasification And Developing An Integrated "Waste To Energy" Power Plant |
|
|
211 | (54) |
|
8.1 Traditional Waste-to-Energy Systems |
|
|
211 | (5) |
|
|
|
212 | (3) |
|
Heat Energy to Dry the Solids |
|
|
215 | (1) |
|
8.2 Pyrolysis and Gasification |
|
|
216 | (16) |
|
Gasification of Digested Residual Used Water Solids with MSW |
|
|
218 | (3) |
|
Gasification of Municipal Solid Wastes (MSW) |
|
|
221 | (11) |
|
8.3 Converting Biogas to Electricity |
|
|
232 | (3) |
|
Steam Methane Reforming (SMR) to Syngas and Then to Hydrogen |
|
|
234 | (1) |
|
8.4 Microbial Fuel Cells (MFCs) and Microbial Electrolysis Cells (MECs) |
|
|
235 | (7) |
|
Increasing Hydrogen Energy Production |
|
|
236 | (1) |
|
Microbial Fuel Cells (MFCs) |
|
|
236 | (2) |
|
Modifications of MFCs to MECs for Hydrogen Production |
|
|
238 | (3) |
|
Hybrid Fermentation and the MEC System |
|
|
241 | (1) |
|
8.5 Hydrogen Yield Potential by Indirect Gasification |
|
|
242 | (7) |
|
Sources of Energy Hydrogen |
|
|
244 | (7) |
|
Maximizing Hydrogen Energy Yield by Selecting the Proper Technologies |
|
|
251 | (1) |
|
|
|
250 | (1) |
|
Molten Carbonate Fuel Cells (MCFCs) |
|
|
250 | (3) |
|
Solid Oxide Fuel Cells (SOFCs) |
|
|
253 | (1) |
|
Producing Hydrogen and Oxygen by Electrolysis |
|
|
254 | (2) |
|
|
|
256 | (1) |
|
|
|
257 | (8) |
|
|
|
260 | (2) |
|
Carbon Dioxide Sequestering in an IRRF |
|
|
262 | (2) |
|
Carbon Dioxide Capture and Concentration by the Molten Carbonate Fuel Cell |
|
|
264 | (1) |
|
|
|
265 | (26) |
|
9.1 The Need to Recover, Not Just Remove Nutrients |
|
|
265 | (2) |
|
9.2 Biological Nutrient Removal and Recovery |
|
|
267 | (6) |
|
Traditional Nutrient Removal Processes |
|
|
267 | (1) |
|
|
|
268 | (2) |
|
Phosphorus Biological Removal and Limited Recovery |
|
|
270 | (2) |
|
|
|
272 | (1) |
|
9.3 Unit Processes Recovering Nutrients |
|
|
273 | (18) |
|
|
|
273 | (1) |
|
|
|
274 | (1) |
|
Phytoseparation of Nutrients |
|
|
275 | (8) |
|
Chemical Removal and Recovery of Nutrients |
|
|
283 | (2) |
|
Phosphorus Flow in the Distributed Urban System |
|
|
285 | (1) |
|
Nutrients in Gasifier Ash |
|
|
286 | (5) |
|
10 Building The Sustainable Integrated System |
|
|
291 | (46) |
|
10.1 Assembling the System |
|
|
291 | (4) |
|
Concepts, Building Blocks, and Inputs |
|
|
291 | (4) |
|
10.2 Upgrading Traditional Systems to Cities of the Future |
|
|
295 | (9) |
|
Milwaukee (Wisconsin) Plan |
|
|
295 | (1) |
|
Danish Billund BioRefinery |
|
|
296 | (3) |
|
|
|
299 | (5) |
|
10.3 Visionary Mid-Twenty-First Century Regional Resource Recovery Alternative |
|
|
304 | (7) |
|
|
|
309 | (2) |
|
10.4 Water-Energy Nexus and Resource Recovery of Three Alternative Designs |
|
|
311 | (26) |
|
|
|
311 | (4) |
|
|
|
315 | (4) |
|
CO2/Kw-h Ratio for the Alternatives |
|
|
319 | (2) |
|
|
|
321 | (16) |
|
11 Closing The Quest Toward Triple Net-Zero Urban Systems |
|
|
337 | (20) |
|
11.1 Community Self-Reliance on TMZ System for Power and Recovering Resources |
|
|
337 | (4) |
|
11.2 Economic Benefits and Approximate Costs of the 2040+ Integrated Water/Energy/MSW Management |
|
|
341 | (8) |
|
Cost of Green and Blue Energies Is Decreasing |
|
|
342 | (7) |
|
11.3 Can It Be Done in Time to Save the Earth from Irreversible Damage? |
|
|
349 | (8) |
|
Political-Economical Tools |
|
|
349 | (2) |
|
The Process to Achieve the Goals |
|
|
351 | (6) |
| References |
|
357 | (28) |
| Index |
|
385 | |
Daugiau apie elektronines knygas