Index
Note: Page numbers followed by “f” refer to figures.
A
Air temperature and velocity,
158
Alkali metal thermal power generation,
5–6
Ambient crosswind, influence of,
163
computational procedure,
175
selection of ambient geometrical dimensions,
175–177
comparison of system output power,
198–200
comparison of system temperature increase, driving force, and updraft velocity,
185–188
comparison of system temperature increase and driving force,
196–197
comparison of temperature contours,
183–185
flow characteristics near the collector inlet,
194–196
influence of crosswind with turbine pressure drop,
188–190
Ambient temperature, influence of,
66–67
Axisymmetric mathematical model,
98–99
B
Betterment model
relative static pressure distribution in,
82f
temperature distribution in,
83f
velocity distribution in,
82f
3-Blade turbine for Spanish prototype,
138–140
5-Blade turbine model,
142
C
Chimney height and diameter, influence of,
63–64
effect on driving force,
86f
effect on efficiency,
90f
effect on power output,
88f,
89
Chimney surface, balance conditions for,
115
China’s energy policy and prospect,
4–5
Coal combustion,
Collector,
12,
13–14,
15,
17f,
23–24,
24,
97,
97–98,
100,
112–113,
127–128,
164,
210
heat balance condition of the glass surface of,
114
Collector diameter, influence of,
64–65
Collector inlet
Crosswind with turbine pressure drop, influence of,
188–190
D
Dish-Stirling solar power plant system,
10–11
effect of chimney height on,
86f
effect of chimney radius on,
86f
effect of collector radius on,
85f
system temperature increase and,
196–197
E
China’s energy policy and prospect,
4–5
energy issue and the status quo,
1–4
solar power generating technologies and the status quo,
5–11
Dish-Stirling solar power plant system,
10–11
parabolic trough solar thermal system,
8–9
solar central power tower system,
6–8
solar photovoltaic power generation system,
11
“Energy—Environment—Ecology” coordinated development model,
224
Energy Information Administration’s (EIA) forecasts for emissions,
Energy storage layer,
55,
97,
148–149,
149,
154,
155–156,
156–157,
157,
158,
158,
158–160,
160,
160
Energy storage of solar chimney,
147
boundary conditions and initial conditions,
152–153
simulation method, reliability of,
153–154
Energy storage with low cost,
13–14
solar chimney power plant (Australia),
32f
Environmental factors
impacts on large-scale SCPPS,
223–224
Experimental investigation,
209
disposal of measurement points,
211–212
temperature distributions of the system,
217–219
variations of air temperature and velocity,
215–217
variations of temperature with time,
212–215
F
Flow characteristics near the collector inlet,
194–196
Fluid flow and heat transfer of solar chimney power plant,
95
computation results and analysis,
116–122
comparison of different helical-wall SC systems,
119–121
comparison of output power for the two type of models,
118–119
comparison on flow and heat transfer characteristics,
116–118
contrast on collector’s initial investment,
121–122
helical heat-collecting solar chimney power plant system,
112
solving determinant condition and solution,
114–115
boundary conditions and solution method,
100–101
Fossil energy, depletion of,
1–2
Fossil fuels, overexploitation of,
1–2
G
Gannon’s Brayton cycle,
27
Generation of turbulence kinetic energy,
98–99
Global change in power generation,
5f
Global CO2 emissions,
H
Heat and mass transfer theory in the system,
28–29
Heat flux, effect of,
213
Heat storage layer, surface condition of,
114–115
Helical heat-collecting SC System
planform of collector configuration of,
113f
Helical-wall SC systems
Helio-aero-gravity (HAG) effect of SC,
27–28,
71
power output and efficiency,
76–77
relative static pressure,
73–75
results and discussions,
77–91
Heliostats, ,
Hexahedral (HEX) meshing method,
174
I
Ideal thermal efficiency,
59
J
Jet Propulsion Laboratory,
10
K
L
Large scale renewable energy collection,
13
external fluid flow and heat transfer in,
222–223
impacts of environmental factors on,
223–224
turbine running theory for,
223
LUZ Solar Thermal Electricity Generation International Co., Ltd.,
M
in collector and chimney regions,
131–132
Maximum efficiency of the system,
77
Mean velocity, law-of-the-wall for,
134
Mechanical exergy (ezergy) of air,
48,
50f
Multiple reference frame (MRF) model,
132–133,
136
N
New-type large-scale SCPPS,
224
boundary conditions and initial conditions,
152–153
O
Oil and natural gas reserves,
P
Parabolic trough solar thermal system (TSTEGS),
8–9
Photovoltaic power generation system,
11
Power conversion units (PCU),
12
Q
R
effect of chimney height on,
85f
effect of collector radius on,
84f
economic and ecological theory and feasibility studies,
30–31
experiments and prototypes,
15–25
potential application of SCPPS,
31–33
HAG effect of the system,
27–28
heat and mass transfer theory in the system,
28–29
operation principle of the turbine and the design,
29–30
thermodynamic theory for the circulation system,
25–27
external fluid flow and heat transfer in large-scale channels,
222–223
impacts of environmental factors on large-scale SCPPS,
223–224
new-type large-scale SCPPS,
224
thermodynamic theory for large-scale SCPP,
221–222
turbine running theory for large-scale SCPPS,
223
S
SC turbines, design and simulation method for,
127
in collector and chimney regions,
131–132
near-wall treatments for turbulent flows,
134–135
numerical simulation method,
135–136
characteristic of 3-blade turbine for Spanish prototype,
138–140
results for MW-graced solar chimney,
140–142
validity of the method for Spanish prototype,
136–137
Simulation method
competitive investment and operation costs,
14–15
energy storage with low cost,
13–14
environmental remediation,
14
large scale renewable energy collection,
13
technical feasibility,
14
cycle efficiencies of MW-graded,
60f
Solar power generating technologies and the status quo,
5–11
Dish-Stirling solar power plant system,
10–11
parabolic trough solar thermal system,
8–9
solar central power tower system,
6–8
solar photovoltaic power generation system,
11
Solar radiation, influence of,
65–66
evaluation of performance of,
165–166
factors that influence the characteristics of,
192
Solar updraft tower (SUT),
12
Spanish prototype
characteristic of 3-blade turbine for,
138–140
relative static pressure distribution in,
79f
velocity distribution in,
79f
SSUPP prototype in Damascus University, Syria,
24f
Static pressure inside and outside the chimney,
73f
Structural integrity of solar chimneys,
166–167
SUPPS Manzanares prototype,
191–192
System output power, comparison of,
198–200
System temperature increase, driving force, and updraft velocity, comparison of,
185–188
System temperature increase and driving force, comparison of,
196–197
T
Temperature contours, comparison of,
183–185
Temperature variations with time,
212–215
boundary conditions and solution method,
100–101
Thermal conductivity,
158,
158
Thermal equilibrium, 1-dimensional,
97,
97
Thermal power generation technologies,
5–6
Thermionic power generation,
5–6
Thermodynamic fundamentals,
47
effect of various parameters,
60–67
influence of ambient temperature,
66–67
influence of chimney height and diameter,
63–64
influence of collector diameter,
64–65
influence of solar radiation,
65–66
influence of turbine efficiency,
62–63
results and analysis,
54–60
computation results for commercial SCPPSS,
59–60
computation results for the Spanish prototype,
56–59
thermal efficiency,
53–54
thermodynamic cycle,
51–53
Thermodynamic theory
for circulation system,
25–27
Thermoelectric power generation,
5–6
Total energy consumption for China,
pressure drop across,
111
Turbine efficiency, influence of,
62–63
Turbine pressure drop,
190
Turbine running theory for large-scale SCPPS,
223
Turbulent flows, near-wall treatments for,
134–135
W
Wei’s solar heated wind updraft tower power,
25f
Wuhai Inner Mongolia SUPPS,
167