Water and Energy Engineering for Sustainable Buildings Mihouse Project. Varios autores
Calculation of Ecological Footprint
Making of materials
Figure 1.1. Mihouse urban proposal
Figure 1.3. Main Table and Central Table
Figure 1.4. Mihouse Prototype design
Figure 1.5. Assembly of the modules up to the completed building
Figure 2.1. Sloping Slabs
Figure 2.2. Prototype rainwater tank
Figure 2.3. System components groundwater
Figure 2.4. Technical data of low consumption toilet
Figure 2.5. Greywater storage for apartment blocks (zone 1)
Figure 2.6. Greywater storage for apartment blocks (zone 2)
Figure 2.7. Flowchart for greywater treatment system
Figure 2.8. Prototype greywater storage.
Figure 2.9. Drinking water distribution system
Figure 3.1. The Solar Village location
Figure 3.2. Meteorological span figures from 10th November until 10th of December 2014
Figure 3.3. Solar radiation and temperature in an specific day
Figure 3.4. Components and energy flow on a solar PV grid connected system
Figure 3.5. Rooftop with the solar PV system
Figure 3.6. Solar grid-connected inverter
Figure 3.7. Panel technical information
Figure 3.8. System metrics
Figure 3.9. Monthly Production
Figure 3.10. Sources of loss
Figure 3.13. Wring Zones and field segments
Figure 3.14. System Connection
Figure 3.15. Simulation results, cash flow summary
Figure 3.16. Simulation results, cash flow
Figure 3.17. Monthly Average Electric Production
Figure 3.18. PV Output
Figure 3.19. Primary Load
Figure 3.20. Grid sales
Figure 3.21. PV power
Figure 3.22. Frame for a flat roof
Figure 3.20. Heater components
Figure 3.23. Energy Balance Simulation
Figure 3.24. CO2 Emissions Simulation
Figure 4.1. Lifecycle analysis of materials
Figure 4.2. Lightweight concrete
Figure 4.3. Lightweight concrete production process
Figure 4.4. Energy Efficiency strategies for sustainable social housing in developing countries
Figure 4.5. Efficient selection of photovoltaic equipment
Figure 4.6. Energy rating label
Figure 4.7. Comparative between incandescent and LED lightning
Figure 4.8. Benefits of good lighting in each scene
Figure 5.1. Location of the TSU and waste use areas
Table 2.1. Type A apartment data
Table 2.2. Values of the necessary variables for the calculation of the catchment area, water demand and water supply
Table 2.3. Calculation of maximum flow that transports the gutters in the apartment
Table 2.4. Maximum permissible flows in downspouts
Table 2.5. Number of required drainpipes
Table 2.6. Results of the monthly average precipitation, monthly water demand and water supply, and calculation of the demand and accumulated supply and storage volume
Table 2.7. Greywater consumption
Table 2.8. Devices that generate greywater at home.
Table 2.9. Apartments Distribution by type
Table 2.10. Storage volume for the Drinking water tank
Table 2.11. Drinking Water Pre-dimensioning
Table 2.12. Activities related to the water consumption
Table 2.13. Daily Cycles
Table 2.14. Total generated volume of water
Table 3.1. One-year time series detailed analysis of Mihouse electrical load
Table 3.2. Monthly Averaged Insolation Incident on a Horizontal Surface (kWh/m2/day)
Table 3.3. Top manufacturers
Table 3.4. Available surfaces
Table 3.5. Estimation of area per living unit module
Table 3.6. Energy load requirements per living unit
Table 3.7. Energy consumption during a regular day