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Experimental investigation of solar chimney with phase change material (PCM)
Accepted Manuscript Experimental Investigation of Solar Chimney with Phase Change Material (PCM)
Niloufar Fadaei, Alibakhsh Kasaeian, Aliakbar Akbarzadeh, Seyed Hassan Hashemabadi PII:
S0960-1481(18)30132-0
DOI:
10.1016/j.renene.2018.01.122
Reference:
RENE 9727
To appear in:
Renewable Energy
Received Date:
04 June 2017
Revised Date:
09 January 2018
Accepted Date:
31 January 2018
Please cite this article as: Niloufar Fadaei, Alibakhsh Kasaeian, Aliakbar Akbarzadeh, Seyed Hassan Hashemabadi, Experimental Investigation of Solar Chimney with Phase Change Material (PCM), Renewable Energy (2018), doi: 10.1016/j.renene.2018.01.122
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Experimental Investigation of Solar Chimney with Phase Change Material (PCM)
3 4 5
Niloufar Fadaei1, Alibakhsh Kasaeian1*, Aliakbar Akbarzadeh2, Seyed Hassan
6
Hashemabadi3
7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37
1Department
of Renewable Energies, Faculty of New Science and Technologies, University of Tehran, Tehran, Iran. 2Department of Mechanical and Manufacturing Engineering, School of Aerospace, RMIT University, Melbourne, Australia. 3Faculty
of Chemical Engineering, Iran University of Science and Technology, Tehran, Iran. Corresponding author: [email protected], Tel: +98 9121947510, Fax: +98 21 88617087
Abstract The effect of latent heat storage (LHS) on a solar chimney pilot was studied experimentally. Two kinds of experiments including with and without phase change material (PCM) were carried out, and the parameters including temperature and velocity were measured to investigate the solar chimney (SC) performance. Paraffin wax was used as a PCM in the constructed SC with 3 m chimney height and 3 m collector diameter in the campus of University of Tehran. The results show that the maximum absorber surface temperature for the SC with PCM and the conventional solar chimney (CSC) are 72°C and 69°C, respectively. Also, the maximum air velocity for the CSC is 1.9 m/s, while it is 2 m/s for the system equipped with PCM thermal storage. So, the LHS system causes increasing the average mass flow rate of the pilot around 8.33%. As a result, using LHS system in SC leads to improve the solar chimney performance.
Keywords: Solar chimney; latent heat storage; phase change material; paraffin wax; Solar energy; Renewable energy.
1
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1. Introduction
39
The solar chimney power plant (SCPP) technology has been developed during these years. A solar
40
chimney consists of three main sectors: collector, chimney, and turbine. According to the
41
definition, at first, solar radiation is transferred to the absorber, and then the radiation heats the
42
fluid due to the greenhouse effect. After that, the heat raises the temperature of the fluid and
43
converts it to kinetic energy; then the fluid flows inside the chimney. This flow is used to move
44
the turbine to produce electricity in a generator. An overview of solar chimney power plant can be
45
seen in Fig. 1.
46 47
Fig. 1. A schematic of the SCPP performance.
48 49
In 1931, Hanns Gunther [1] expressed the concept of solar chimney system to generate electricity
50
for the first time. Followed by this expression, in 1980, the first solar chimney power plant was
51
built in Manzanares, Spain. So far, the results of this chimney have been the base of many
52
researchers’ works. Haaf et al. [2,3] studied the performance of SCPP for the first time and
53
compared the results with the Manzanares pilot’s results. With the development of this technology,
54
Koonsrisuk and Chitsomboon [4] investigated several parameters of the system by using
55
dimensionless variables in a small scale solar chimney. Zhou et al. [5] examined the temperature
56
distribution on a constructed SC. They found that air temperature inversion appeared on the top of
57
the chimney after sunrise; because the absorber was not heated enough to make airflow through 2
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the chimney. Generally speaking, the numerical methods for modeling the solar chimney systems
59
is a good idea to evaluate the performance of SCPP and design its optimum conditions, technically
60
and economically. In 2009, Petela [6] presented a thermodynamic model of SCPP that was based
61
on the energy and exergy analysis.
62
Koonsrisuk and Chitsomboon [7] studied the effect of the SCPP geometry. Also, they investigated
63
the solar radiation impact on the SCPP performance. In another work, they examined the flow
64
properties changes using the computational fluid dynamics (CFD) [8]. Zou and He [9] presented a
65
solar chimney combined with natural draft dry cooling tower. The system not only generated
66
electricity but also dissipated the waste heat. The results showed that the obtained power output
67
was several times greater than the power output of the traditional solar chimney with the same
68
dimensions. In 2016, Ming et al. [10] proposed a new structure of solar chimney power plant,
69
which consisted of black tubes instead of a collector. The black tubes were used as the solar
70
collector. The system not only was able to produce power but also extracted freshwater from the
71
air.
72
Bernardes and Zhou [11] used water bags for analyzing the sensible heat storage effects on a solar
73
chimney. Also, Bernardes [12] investigated the thermal diffusivity and effusivity for different soil
74
materials as the ground for the solar updraft tower. Akbarzadeh et al. [13] examined a desalination
75
process, using solar chimney system, by combining a solar pond with SCPP to produce power.
76
Khanel and Lei [14] studied on an inclined passive wall solar chimney, experimentally. The results
77
showed that the inclination angle had a considerable impact on the air flow velocity inside the air
78
gap width.
79
In 2011, Kasaeian et al. [15] constructed a solar chimney with 12 m chimney height and 10 m
80
collector diameter. The results showed that, by decreasing the entrance size of the collector, the
81
efficiency of the system was improved. In another work, Kasaeian et al. [16] numerically analyzed
82
a solar chimney to conduct a geometric optimization. Then, validated their results with the
83
experimental data from a constructed pilot with 2 m chimney height. They also evaluated the air
84
velocity and temperature distribution of the solar chimney in the campus of the University of
85
Tehran. They found that the air inversion phenomenon depended directly on the geometry of the
86
system [17]. Nasirivatan et al. [18] evaluated the corona wind effect on the thermal performance
87
of solar chimney absorber. The goal of their experimental research was to enhance the solar
88
chimney efficiency. 3
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Energy Storage
90
Energy storage is one of the significant concerns of the current energy technologies, as it can be
91
converted to energy wherever it is needed. The storage of energy not only eliminates the
92
incoordination between the demand and supply but also can improve the application and increase
93
the reliability of the energy systems [19]. Solar energy can be stored in different forms of energy
94
such as kinetic, magnetic, and thermal energies. In order to improve the thermal energy storage
95
capacity, the latent heat storage system has been developed. The system is based on the absorbing
96
and releasing of heat due to the phase change from solid to liquid, liquid to gas, and vice versa
97
[20]. The PCMs, which are used in an LHS system, show an isothermal behavior due to the heat
98
charge and discharge. These materials have a high potential for heat storage with a small change
99
in the temperature so that this little change would lead to improving the operational efficiency
100
significantly. During nights or cloudy days, when the temperature decreases, the phase change
101
process starts and the latent heat of the PCM is released. This thermal energy causes warming the
102
fluid in the absence of solar radiation [21]. There are various types of PCMs which can be utilized
103
in the thermal storage applications. The classification of the PCMs is presented in Fig. 2 [22].
104
In 2008, Chen et al. [23] carried out a numerical work, using MATLAB, to investigate the energy-
105
storing wallboards with a new type of PCM. Benli and Durmus [24] analyzed the thermal
106
performance of CaCl2.H2O as a PCM to design a solar collector in greenhouse heating. The study
107
was based on the experimental results to investigate the thermal behavior of the storage unit due
108
to the phase change process. Avci and Yazici [25] studied the usage of PCM for energy storage in
109
a horizontal shell-and-tube heat exchanger, experimentally. They considered the melting or
110
charging process in their setup. Also, they investigated the solidification and discharging
111
operations. To prepare a better indoor air temperature fluctuation, Meng et al. [26] used a new kind
112
of PCM in the room conditions. The research was carried out experimentally and numerically for
113
two cases as "with PCM" and "without PCM."
114 115 116 117 118 119 4
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Paraffin Compounds Organic
122
Non-Paraffin Compounds
123
Metallic
124 125
Phase Change Material
Inorganic
Salt
126
Salt Hydrate
127 128
Organic-Organic
129 130
Inorganic-Inorganic
Eutectic
131
Inorganic-Organic
132 133
Fig. 2. Category of PCMs.
134 135
Baby and Balaji [27] used two types of PCMs consisting paraffin wax and n-eicosane in a heat
136
sink, including pin fin. They investigated the thermal performance of the heat sink with PCM and
137
without any fin. Also, they studied the impact of the PCM volume fraction on the heat transfer
138
performance of the system. To achieve an ultra-high temperature energy storage, Datas et al. [28]
139
used silicon as a PCM in thermophotovoltaic (TPV) cells. Cheng et al. [29] carried out a study to
140
investigate the feasibility of storage for the solar cooling application; for achieving that goal, the
141
C-L/O composite PCM was used. Finally, they validated the mathematical model by comparing
142
the experimental data with the numerical results. Rezaei et al. [30] investigated the effect of the
143
melting point of different PCMs on the energy and exergy efficiencies. They considered the price
144
of energy and exergy for the PCMs in their research. Panayiotou et al. evaluated a conventional
5
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dwelling using PCM for the climate of Cyprus. They used the TRNSYS software to simulate the
146
process [31].
147
There are several methods to study the solar chimney performance and improve the SC efficiency.
148
The latent heat storage route, which has a significant thermal energy storage capacity, has rarely
149
been considered. In this study, the LHS thermal energy storage in a solar chimney is studied
150
experimentally. For evaluating the effects of PCM on the SC performance, the experimental data
151
are extracted and analyzed for two cases including with and without paraffin wax in the collector
152
of a solar chimney. The most notable benefits of this method and the reason for choosing paraffin
153
wax as a PCM are their low price and availability.
154 155
2. Experimental setup
156
2.1. Solar chimney
157
A solar chimney with 3 m height and 3 m collector diameter was constructed. The chimney was
158
built of polycarbonate pipe with 20 cm in diameter and 4 mm in thickness. The reasons for this
159
choice were factors such as proper thermal resistance and fairly UV resistance of polycarbonate
160
sheets. The collector roof was made of iron-free glass, 3 mm thickness, to provide suitable
161
greenhouse effect. Steel profiles were welded for maintaining the collector structure. A proper gap
162
was considered between the collector edge and the ground to prepare the possibility of air intake
163
through the collector. Also, a combination of steel sheet and chipboard wood pieces constituted
164
the absorber part [32]. Black matt paint was applied for painting the absorber to maximize the
165
emittance, for achieving the highest possible temperature below the collector. The main
166
geometrical parameters of the setup are shown in Table 1.
167 168
Table 1. Geometrical parameters of the SC. Parameter
Size (m)
Collector height
0.06
Collector radius
1.50
Chimney height
3.00
Chimney radius
0.10
169 170 6
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2.2. LHS system
172
In this research, to optimize the thermal performance of the solar chimney and increase the thermal
173
efficiency, an LHS system was applied inside the collector. To prepare the PCM pack, paraffin
174
wax (C20) with “Merck code 107150” was provided. The shape of the paraffin wax and its thermo-
175
physical properties are shown in Fig. 3 and Table 2, respectively. This paraffin wax is a subset of
176
the organic phase change materials, which is solid at the room temperature and begins to melt
177
approximately at 45°C.
178
179
Fig. 3. The prepared sample of paraffin wax as a PCM.
180 181 182 183
Table 2. Thermo-physical properties of paraffin wax (C20).
184 Melting
Heat of Fusion
Thermal
Oil
Specific Heat
Mass of
Point
[ΔHm ,
Conductivity
Content
at 100 °C
Paraffin
[Tm , °C]
(KJ/Kg)]
(Solid Phase)
[%]
[CP,
[m, kg]
[k , (W.m-1.K-1)]
44-46
189
0.21
(KJ/KgK)]
0.25
185 186
7
2.1
40
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In order to make a container for placing the PCM, aluminum foils were used. The sealed PCM
188
pack with the thickness of 1 cm was installed inside the collector of the solar chimney. The PCM
189
container was placed on the absorber, as shown in Fig. 4. Since the collector slope was zero, there
190
was no accumulation in the tank. As a result, there was the same pressure in all directions. In other
191
words, the same thickness was created through the PCM pack during the melting process. It is
192
worth noting that during the preparation of the PCM pack and installing on the absorber, entering
193
the air into the container must be prevented. The reason is that the air inside the container acts as
194
an insulator, and reduces the heat transfer from the PCM pack to the ambient.
195
196 197 198
Fig. 4. A view of the PCM container after installation on the absorber.
199
For measuring the temperature distribution in the SC, 16 sensors of type SMT-160 were used. The
200
data were recorded on a micro-SD card by a data-logger. The sensors configuration in a specific
201
part of the collector is shown in Fig. 5. Two sensors were placed inside the chimney to measure
202
air temperature. Seven sensors were embedded on the collector for the fluid, and six sensors were
203
utilized for the absorber and PCM surface. Also, for measuring the ambient temperature, a thermal
204
sensor was located in the shadow, 1 m over the ground. A pyranometer was applied to measure
205
the vertical solar radiation on the collector, and a hot wire anemometer was placed at the chimney
206
entrance, for measuring the air velocity. Also, an infrared camera was used to verify the 8
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experimental thermal data. The model of the mentioned devices is listed in Table 3, and a photo
208
of the solar chimney is shown in Fig. 6.
209
210 211
Fig. 5. Schematic layout of the thermal sensors.
212 213 214 215
Table 3. Models of the measurement devices. Device
Model
Infrared Camera
ITI P-240
Hotwire Anemometer
Lutron, YK-2004AH
Pyranometer
Hukseflux,CM11
9
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Fig. 6. Photo of the solar chimney applied to the research.
217 218 219
2.3. Uncertainty analysis
220
By using GUM (Guide to the expression of Uncertainty in Measurement) method, the uncertainty
221
of the air velocity and temperature are calculated as following [33].
222
𝑢 =
∑𝑛
(𝑋𝑖 ‒ 𝑋)
2
𝑖=1
(1)
𝑛(𝑛 ‒ 1)
223
Where u, X and 𝑋 are the standard uncertainty, measured parameters (velocity or temperature) and
224
their average values, respectively. Also, n is sample count in this research. The standard
225
uncertainty are 0.74% for the air velocity and 0.81% for the temperature.
226 227
4. Results and discussion
228
In this paper, the solar chimney performance is evaluated by using the phase change material. For
229
this purpose, two kinds of experiments are designed and carried out. Firstly, the performance of
230
the constructed solar chimney without PCM is investigated. Secondly, to study the effects of the
10
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PCM on the SC, paraffin wax is used as a PCM in the collector of the set-up. Finally, the obtained
232
results from the experiments are compared with each other.
233 234 235
4.1. Hourly radiation The experimental data were recorded under the sunny weather conditions with 306 K average
236
ambient temperature. The hourly radiation was an average of the radiation data, which were
237
measured by pyranometer (Fig. 7).
238 1200
(W/m2) Radiation
1000 800 600 400 200 0 0
239 240
2
4
6
8 10 (hr) time
12
14
16
18
20
Fig. 7. Hourly solar radiation on 28th July 2016.
241 242
4.2. PCM temperature during the discharge period
243
According to Fig. 8, after 90 min from the beginning, the PCM temperature reduced with a sharp
244
slope, because the energy was released by the PCM as sensible heat. When the temperature of
245
paraffin reaches approximately at the initial solidification temperature of 45°C, the paraffin begins
246
to be frozen. This condition continues until the whole paraffin inside the container is completely
247
frozen. Actually, after sunset, the temperature of the PCM drops sharply down to the solidification
248
point. After that, the temperature decreases slowly. The solidification duration, containing the
249
discharging process, takes about 12 hrs.
250
11
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Temperature (ºC)
67
62
Temperature
57
52
47
42 12:57
13:26
13:55
14:24
14:52
15:21
15:50
16:19
16:47
17:16
Time (hr) 251 252
Fig. 8. The temperature of the PCM surface within solidification period.
253 254
4.3. Absorber surface temperature
255
For the experiments, to satisfy the certainty requirement, the tests and measurements were
256
conducted for two times. At the first step, the system was considered as a conventional solar
257
chimney without PCM container. The temperature of the absorber surface was logged using the
258
data-logger. After that, the solid paraffin wax container was added into the collector. Fig. 9
259
illustrates the absorber surface temperature distribution during the operation. A specified point of
260
the absorber, where is located at 0.5 m radial distance of the collector, was considered as the
261
temperature report reference. As it is shown in Fig. 9, at the beginning of the set-up without LHS
262
system, the absorber surface temperature is nearly constant. After about 4:00 a.m., the temperature
263
increases quickly. This trend continues until noon when the maximum absorber surface
264
temperature is obtained. For another curve (without PCM), a similar pattern is formed from the
265
starting at 7:30 a.m., but with higher temperature level. At this time, when the temperature reaches
266
to about 46°C, the temperature profile is kept almost constant; because the charging period of the
267
paraffin starts. This process lasts for about 2 hours; then the temperature drops rapidly. At 3:00
268
p.m., the temperature of the LHS system is constant because the discharge period starts around
269
45°C. The discharge process lasts about 12 hrs. For the CSC, the temperature curve has a smooth
270
descending trend after 4:00 p.m., while the temperature level is located at a higher place for the 12
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PCM case. The reason is that, after this time, heat is released from the PCM material due to the
272
phase change.
273
80 with PCM
T (°C)
70
without PCM
60 50 40 30 20 10 0 0
2
4
6
8
10
12 14 TIME (H)
16
18
20
22
24
26
274
Fig. 9. Absorber surface temperature, with and without PCM
275 276 277
4.4. Air flow velocity
278
The velocity of the fluid was measured using the hot wire anemometer which was placed at the
279
chimney entrance. Figs. 10-12 illustrate the air velocity for two cases: with and without PCM.
280
According to Figs. 10-12, before noon and before reaching the maximum radiation, both curves
281
have good agreement with each other. But after about 2:30 p.m., when the solar radiation is
282
decreasing, the air velocity level for the curve with PCM starts stands higher than the other one,
283
and the graphs are slowly taken apart. This trend lasts until the phase change of paraffin would
284
start. The reason is that the latent heat of the PCM is released, so this phenomenon creates a heat
285
flux through the collector, which causes warming of the air. One can observe from Figs. 10 to 12
286
that the maximum velocities for the two states as “with” and “without” PCM, are 2 m/s and 1.9
287
m/s, respectively.
288
By assuming steady and one-dimensional flow, the mass flow rate is obtained as below:
289
𝑚 = 𝜌𝐴𝑉𝑖𝑛
(2)
13
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290
where 𝜌, A and 𝑉𝑖𝑛are density, area and air flow velocity, respectively. For calculating the air flow
291
rate for the states, it is assumed that A= 0.0314 m2 and 𝜌 = 1.225 kg/m3. The air velocity in fully
292
developed region of chimney is shown in Fig. 13.
293 2.5 With PCM
Velocity (m/s)
2 Without PCM 1.5
1
0.5
0 0:00
2:24
4:48
7:12
9:36
12:00
14:24
16:47
19:12
21:35
0:00
Time
294
Fig. 10. The velocity of fluid, with and without PCM on August 22nd.
295 296 297
2.5 Without PCM
Velocity (m/s)
2
With PCM 1.5 1 0.5 0 0:00
2:24
4:48
7:12
9:36 Time
12:00
14:24
16:47
19:12
21:35
0:00
298 299
Fig. 11. The velocity of fluid, with and without PCM on August 23rd. 14
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300
Velocity (m/s)
2.5 2
Without PCM With PCM
1.5 1 0.5 0 0:00
2:24
4:48
7:12 9:36 Time
12:00 14:24 16:47 19:12 21:35
0:00
301 302
Fig. 12. The velocity of fluid, with and without PCM on August 24th.
303 304
The difference between the diagrams is not considerable, but generally, the PCM causes 8.33 %
305
increase in the average mass flow rate compared with the case without PCM. Thus, the usage of
306
PCM in the set-up has a significant effect on the SC efficiency.
307
Velocity (m/s)
2.5 With PCM
2
Without PCM
1.5 1 0.5 0 0
5
10
15
20
25
Distance from chimney wall (cm)
308 309
Fig. 13. The air velocity in the fully developed region of the chimney.
310 311 15
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312 313
4.5. Verification of the experimental data using infrared camera
314
For verifying the accuracy of the sensors, the infrared camera was used. An infrared picture of the
315
solar chimney is shown in Fig. 14. Also, the temperature distribution of the thermal sensor of
316
absorber surface (T5) and the infrared camera results are shown in Fig. 15. In this image, as it is
317
observed, the temperature changes have good agreement with the temperature difference which
318
has been obtained by the sensors.
319
320
Fig. 14. An Infrared image of the solar chimney.
321 322 80
Temperature (ºC)
70 60 50 40 30 20 10 0 0:00:00
12:00:00
0:00:00
12:00:00
Time
323 324
Fig. 15. Comparison between thermal sensor data and the Infrared results.
325 16
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326
5. Conclusion
327
In this study, the effect of latent heat storage was investigated experimentally for a solar chimney
328
set-up. The thermal performance of the SC with and without PCM was assessed under similar
329
conditions. Paraffin wax was used as the phase change material in the set-up with 3 m chimney
330
height and 1.5 m collector radius. According to the obtained results, the findings are expressed as
331
below:
332
thermal efficiency of the SC.
333 334
In the absence of sunlight, due to the phase change of liquid paraffin to the solid phase, the latent heat is released.
335 336
The paraffin wax, used in the collector of the pilot as an LHS system, improved the
The maximum absorber surface temperature is obtained at 1:00 p.m. when the solar
337
radiation is in the maximum value. This temperature for the cases of with PCM and
338
without PCM is 72°C and 69°C, respectively.
339
The maximum air velocity through the pilot is 2 m/s for the SC with LHS system and
340
1.9 m/s for the conventional SC. It means that, by using the LHS, the average mass
341
flow rate is increased about 8.33 %; consequently, the SC efficiency is improved.
342
Finally, the sensors` function and accuracy were verified, using an infrared camera.
343
The comparison of the experimental data with numerical results shows a good
344
agreement.
345 346 347
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Highlights:
The effect of LHS system in a solar chimney is studied experimentally. Performance investigation is carried out for two cases with and without PCM. The maximum absorber temperature, with and without PCM, are 72°C and 69°C. The maximum air velocity, with and without the LHS system, are 2 m/s and 1.9 m/s. PCM causes increasing the SC mass flow rate around the 52.63%.
Niloufar Fadaei, Alibakhsh Kasaeian, Aliakbar Akbarzadeh, Seyed Hassan Hashemabadi PII:
S0960-1481(18)30132-0
DOI:
10.1016/j.renene.2018.01.122
Reference:
RENE 9727
To appear in:
Renewable Energy
Received Date:
04 June 2017
Revised Date:
09 January 2018
Accepted Date:
31 January 2018
Please cite this article as: Niloufar Fadaei, Alibakhsh Kasaeian, Aliakbar Akbarzadeh, Seyed Hassan Hashemabadi, Experimental Investigation of Solar Chimney with Phase Change Material (PCM), Renewable Energy (2018), doi: 10.1016/j.renene.2018.01.122
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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1 2
Experimental Investigation of Solar Chimney with Phase Change Material (PCM)
3 4 5
Niloufar Fadaei1, Alibakhsh Kasaeian1*, Aliakbar Akbarzadeh2, Seyed Hassan
6
Hashemabadi3
7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37
1Department
of Renewable Energies, Faculty of New Science and Technologies, University of Tehran, Tehran, Iran. 2Department of Mechanical and Manufacturing Engineering, School of Aerospace, RMIT University, Melbourne, Australia. 3Faculty
of Chemical Engineering, Iran University of Science and Technology, Tehran, Iran. Corresponding author: [email protected], Tel: +98 9121947510, Fax: +98 21 88617087
Abstract The effect of latent heat storage (LHS) on a solar chimney pilot was studied experimentally. Two kinds of experiments including with and without phase change material (PCM) were carried out, and the parameters including temperature and velocity were measured to investigate the solar chimney (SC) performance. Paraffin wax was used as a PCM in the constructed SC with 3 m chimney height and 3 m collector diameter in the campus of University of Tehran. The results show that the maximum absorber surface temperature for the SC with PCM and the conventional solar chimney (CSC) are 72°C and 69°C, respectively. Also, the maximum air velocity for the CSC is 1.9 m/s, while it is 2 m/s for the system equipped with PCM thermal storage. So, the LHS system causes increasing the average mass flow rate of the pilot around 8.33%. As a result, using LHS system in SC leads to improve the solar chimney performance.
Keywords: Solar chimney; latent heat storage; phase change material; paraffin wax; Solar energy; Renewable energy.
1
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1. Introduction
39
The solar chimney power plant (SCPP) technology has been developed during these years. A solar
40
chimney consists of three main sectors: collector, chimney, and turbine. According to the
41
definition, at first, solar radiation is transferred to the absorber, and then the radiation heats the
42
fluid due to the greenhouse effect. After that, the heat raises the temperature of the fluid and
43
converts it to kinetic energy; then the fluid flows inside the chimney. This flow is used to move
44
the turbine to produce electricity in a generator. An overview of solar chimney power plant can be
45
seen in Fig. 1.
46 47
Fig. 1. A schematic of the SCPP performance.
48 49
In 1931, Hanns Gunther [1] expressed the concept of solar chimney system to generate electricity
50
for the first time. Followed by this expression, in 1980, the first solar chimney power plant was
51
built in Manzanares, Spain. So far, the results of this chimney have been the base of many
52
researchers’ works. Haaf et al. [2,3] studied the performance of SCPP for the first time and
53
compared the results with the Manzanares pilot’s results. With the development of this technology,
54
Koonsrisuk and Chitsomboon [4] investigated several parameters of the system by using
55
dimensionless variables in a small scale solar chimney. Zhou et al. [5] examined the temperature
56
distribution on a constructed SC. They found that air temperature inversion appeared on the top of
57
the chimney after sunrise; because the absorber was not heated enough to make airflow through 2
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the chimney. Generally speaking, the numerical methods for modeling the solar chimney systems
59
is a good idea to evaluate the performance of SCPP and design its optimum conditions, technically
60
and economically. In 2009, Petela [6] presented a thermodynamic model of SCPP that was based
61
on the energy and exergy analysis.
62
Koonsrisuk and Chitsomboon [7] studied the effect of the SCPP geometry. Also, they investigated
63
the solar radiation impact on the SCPP performance. In another work, they examined the flow
64
properties changes using the computational fluid dynamics (CFD) [8]. Zou and He [9] presented a
65
solar chimney combined with natural draft dry cooling tower. The system not only generated
66
electricity but also dissipated the waste heat. The results showed that the obtained power output
67
was several times greater than the power output of the traditional solar chimney with the same
68
dimensions. In 2016, Ming et al. [10] proposed a new structure of solar chimney power plant,
69
which consisted of black tubes instead of a collector. The black tubes were used as the solar
70
collector. The system not only was able to produce power but also extracted freshwater from the
71
air.
72
Bernardes and Zhou [11] used water bags for analyzing the sensible heat storage effects on a solar
73
chimney. Also, Bernardes [12] investigated the thermal diffusivity and effusivity for different soil
74
materials as the ground for the solar updraft tower. Akbarzadeh et al. [13] examined a desalination
75
process, using solar chimney system, by combining a solar pond with SCPP to produce power.
76
Khanel and Lei [14] studied on an inclined passive wall solar chimney, experimentally. The results
77
showed that the inclination angle had a considerable impact on the air flow velocity inside the air
78
gap width.
79
In 2011, Kasaeian et al. [15] constructed a solar chimney with 12 m chimney height and 10 m
80
collector diameter. The results showed that, by decreasing the entrance size of the collector, the
81
efficiency of the system was improved. In another work, Kasaeian et al. [16] numerically analyzed
82
a solar chimney to conduct a geometric optimization. Then, validated their results with the
83
experimental data from a constructed pilot with 2 m chimney height. They also evaluated the air
84
velocity and temperature distribution of the solar chimney in the campus of the University of
85
Tehran. They found that the air inversion phenomenon depended directly on the geometry of the
86
system [17]. Nasirivatan et al. [18] evaluated the corona wind effect on the thermal performance
87
of solar chimney absorber. The goal of their experimental research was to enhance the solar
88
chimney efficiency. 3
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Energy Storage
90
Energy storage is one of the significant concerns of the current energy technologies, as it can be
91
converted to energy wherever it is needed. The storage of energy not only eliminates the
92
incoordination between the demand and supply but also can improve the application and increase
93
the reliability of the energy systems [19]. Solar energy can be stored in different forms of energy
94
such as kinetic, magnetic, and thermal energies. In order to improve the thermal energy storage
95
capacity, the latent heat storage system has been developed. The system is based on the absorbing
96
and releasing of heat due to the phase change from solid to liquid, liquid to gas, and vice versa
97
[20]. The PCMs, which are used in an LHS system, show an isothermal behavior due to the heat
98
charge and discharge. These materials have a high potential for heat storage with a small change
99
in the temperature so that this little change would lead to improving the operational efficiency
100
significantly. During nights or cloudy days, when the temperature decreases, the phase change
101
process starts and the latent heat of the PCM is released. This thermal energy causes warming the
102
fluid in the absence of solar radiation [21]. There are various types of PCMs which can be utilized
103
in the thermal storage applications. The classification of the PCMs is presented in Fig. 2 [22].
104
In 2008, Chen et al. [23] carried out a numerical work, using MATLAB, to investigate the energy-
105
storing wallboards with a new type of PCM. Benli and Durmus [24] analyzed the thermal
106
performance of CaCl2.H2O as a PCM to design a solar collector in greenhouse heating. The study
107
was based on the experimental results to investigate the thermal behavior of the storage unit due
108
to the phase change process. Avci and Yazici [25] studied the usage of PCM for energy storage in
109
a horizontal shell-and-tube heat exchanger, experimentally. They considered the melting or
110
charging process in their setup. Also, they investigated the solidification and discharging
111
operations. To prepare a better indoor air temperature fluctuation, Meng et al. [26] used a new kind
112
of PCM in the room conditions. The research was carried out experimentally and numerically for
113
two cases as "with PCM" and "without PCM."
114 115 116 117 118 119 4
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120 121
Paraffin Compounds Organic
122
Non-Paraffin Compounds
123
Metallic
124 125
Phase Change Material
Inorganic
Salt
126
Salt Hydrate
127 128
Organic-Organic
129 130
Inorganic-Inorganic
Eutectic
131
Inorganic-Organic
132 133
Fig. 2. Category of PCMs.
134 135
Baby and Balaji [27] used two types of PCMs consisting paraffin wax and n-eicosane in a heat
136
sink, including pin fin. They investigated the thermal performance of the heat sink with PCM and
137
without any fin. Also, they studied the impact of the PCM volume fraction on the heat transfer
138
performance of the system. To achieve an ultra-high temperature energy storage, Datas et al. [28]
139
used silicon as a PCM in thermophotovoltaic (TPV) cells. Cheng et al. [29] carried out a study to
140
investigate the feasibility of storage for the solar cooling application; for achieving that goal, the
141
C-L/O composite PCM was used. Finally, they validated the mathematical model by comparing
142
the experimental data with the numerical results. Rezaei et al. [30] investigated the effect of the
143
melting point of different PCMs on the energy and exergy efficiencies. They considered the price
144
of energy and exergy for the PCMs in their research. Panayiotou et al. evaluated a conventional
5
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dwelling using PCM for the climate of Cyprus. They used the TRNSYS software to simulate the
146
process [31].
147
There are several methods to study the solar chimney performance and improve the SC efficiency.
148
The latent heat storage route, which has a significant thermal energy storage capacity, has rarely
149
been considered. In this study, the LHS thermal energy storage in a solar chimney is studied
150
experimentally. For evaluating the effects of PCM on the SC performance, the experimental data
151
are extracted and analyzed for two cases including with and without paraffin wax in the collector
152
of a solar chimney. The most notable benefits of this method and the reason for choosing paraffin
153
wax as a PCM are their low price and availability.
154 155
2. Experimental setup
156
2.1. Solar chimney
157
A solar chimney with 3 m height and 3 m collector diameter was constructed. The chimney was
158
built of polycarbonate pipe with 20 cm in diameter and 4 mm in thickness. The reasons for this
159
choice were factors such as proper thermal resistance and fairly UV resistance of polycarbonate
160
sheets. The collector roof was made of iron-free glass, 3 mm thickness, to provide suitable
161
greenhouse effect. Steel profiles were welded for maintaining the collector structure. A proper gap
162
was considered between the collector edge and the ground to prepare the possibility of air intake
163
through the collector. Also, a combination of steel sheet and chipboard wood pieces constituted
164
the absorber part [32]. Black matt paint was applied for painting the absorber to maximize the
165
emittance, for achieving the highest possible temperature below the collector. The main
166
geometrical parameters of the setup are shown in Table 1.
167 168
Table 1. Geometrical parameters of the SC. Parameter
Size (m)
Collector height
0.06
Collector radius
1.50
Chimney height
3.00
Chimney radius
0.10
169 170 6
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171
2.2. LHS system
172
In this research, to optimize the thermal performance of the solar chimney and increase the thermal
173
efficiency, an LHS system was applied inside the collector. To prepare the PCM pack, paraffin
174
wax (C20) with “Merck code 107150” was provided. The shape of the paraffin wax and its thermo-
175
physical properties are shown in Fig. 3 and Table 2, respectively. This paraffin wax is a subset of
176
the organic phase change materials, which is solid at the room temperature and begins to melt
177
approximately at 45°C.
178
179
Fig. 3. The prepared sample of paraffin wax as a PCM.
180 181 182 183
Table 2. Thermo-physical properties of paraffin wax (C20).
184 Melting
Heat of Fusion
Thermal
Oil
Specific Heat
Mass of
Point
[ΔHm ,
Conductivity
Content
at 100 °C
Paraffin
[Tm , °C]
(KJ/Kg)]
(Solid Phase)
[%]
[CP,
[m, kg]
[k , (W.m-1.K-1)]
44-46
189
0.21
(KJ/KgK)]
0.25
185 186
7
2.1
40
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187
In order to make a container for placing the PCM, aluminum foils were used. The sealed PCM
188
pack with the thickness of 1 cm was installed inside the collector of the solar chimney. The PCM
189
container was placed on the absorber, as shown in Fig. 4. Since the collector slope was zero, there
190
was no accumulation in the tank. As a result, there was the same pressure in all directions. In other
191
words, the same thickness was created through the PCM pack during the melting process. It is
192
worth noting that during the preparation of the PCM pack and installing on the absorber, entering
193
the air into the container must be prevented. The reason is that the air inside the container acts as
194
an insulator, and reduces the heat transfer from the PCM pack to the ambient.
195
196 197 198
Fig. 4. A view of the PCM container after installation on the absorber.
199
For measuring the temperature distribution in the SC, 16 sensors of type SMT-160 were used. The
200
data were recorded on a micro-SD card by a data-logger. The sensors configuration in a specific
201
part of the collector is shown in Fig. 5. Two sensors were placed inside the chimney to measure
202
air temperature. Seven sensors were embedded on the collector for the fluid, and six sensors were
203
utilized for the absorber and PCM surface. Also, for measuring the ambient temperature, a thermal
204
sensor was located in the shadow, 1 m over the ground. A pyranometer was applied to measure
205
the vertical solar radiation on the collector, and a hot wire anemometer was placed at the chimney
206
entrance, for measuring the air velocity. Also, an infrared camera was used to verify the 8
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experimental thermal data. The model of the mentioned devices is listed in Table 3, and a photo
208
of the solar chimney is shown in Fig. 6.
209
210 211
Fig. 5. Schematic layout of the thermal sensors.
212 213 214 215
Table 3. Models of the measurement devices. Device
Model
Infrared Camera
ITI P-240
Hotwire Anemometer
Lutron, YK-2004AH
Pyranometer
Hukseflux,CM11
9
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216
Fig. 6. Photo of the solar chimney applied to the research.
217 218 219
2.3. Uncertainty analysis
220
By using GUM (Guide to the expression of Uncertainty in Measurement) method, the uncertainty
221
of the air velocity and temperature are calculated as following [33].
222
𝑢 =
∑𝑛
(𝑋𝑖 ‒ 𝑋)
2
𝑖=1
(1)
𝑛(𝑛 ‒ 1)
223
Where u, X and 𝑋 are the standard uncertainty, measured parameters (velocity or temperature) and
224
their average values, respectively. Also, n is sample count in this research. The standard
225
uncertainty are 0.74% for the air velocity and 0.81% for the temperature.
226 227
4. Results and discussion
228
In this paper, the solar chimney performance is evaluated by using the phase change material. For
229
this purpose, two kinds of experiments are designed and carried out. Firstly, the performance of
230
the constructed solar chimney without PCM is investigated. Secondly, to study the effects of the
10
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PCM on the SC, paraffin wax is used as a PCM in the collector of the set-up. Finally, the obtained
232
results from the experiments are compared with each other.
233 234 235
4.1. Hourly radiation The experimental data were recorded under the sunny weather conditions with 306 K average
236
ambient temperature. The hourly radiation was an average of the radiation data, which were
237
measured by pyranometer (Fig. 7).
238 1200
(W/m2) Radiation
1000 800 600 400 200 0 0
239 240
2
4
6
8 10 (hr) time
12
14
16
18
20
Fig. 7. Hourly solar radiation on 28th July 2016.
241 242
4.2. PCM temperature during the discharge period
243
According to Fig. 8, after 90 min from the beginning, the PCM temperature reduced with a sharp
244
slope, because the energy was released by the PCM as sensible heat. When the temperature of
245
paraffin reaches approximately at the initial solidification temperature of 45°C, the paraffin begins
246
to be frozen. This condition continues until the whole paraffin inside the container is completely
247
frozen. Actually, after sunset, the temperature of the PCM drops sharply down to the solidification
248
point. After that, the temperature decreases slowly. The solidification duration, containing the
249
discharging process, takes about 12 hrs.
250
11
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Temperature (ºC)
67
62
Temperature
57
52
47
42 12:57
13:26
13:55
14:24
14:52
15:21
15:50
16:19
16:47
17:16
Time (hr) 251 252
Fig. 8. The temperature of the PCM surface within solidification period.
253 254
4.3. Absorber surface temperature
255
For the experiments, to satisfy the certainty requirement, the tests and measurements were
256
conducted for two times. At the first step, the system was considered as a conventional solar
257
chimney without PCM container. The temperature of the absorber surface was logged using the
258
data-logger. After that, the solid paraffin wax container was added into the collector. Fig. 9
259
illustrates the absorber surface temperature distribution during the operation. A specified point of
260
the absorber, where is located at 0.5 m radial distance of the collector, was considered as the
261
temperature report reference. As it is shown in Fig. 9, at the beginning of the set-up without LHS
262
system, the absorber surface temperature is nearly constant. After about 4:00 a.m., the temperature
263
increases quickly. This trend continues until noon when the maximum absorber surface
264
temperature is obtained. For another curve (without PCM), a similar pattern is formed from the
265
starting at 7:30 a.m., but with higher temperature level. At this time, when the temperature reaches
266
to about 46°C, the temperature profile is kept almost constant; because the charging period of the
267
paraffin starts. This process lasts for about 2 hours; then the temperature drops rapidly. At 3:00
268
p.m., the temperature of the LHS system is constant because the discharge period starts around
269
45°C. The discharge process lasts about 12 hrs. For the CSC, the temperature curve has a smooth
270
descending trend after 4:00 p.m., while the temperature level is located at a higher place for the 12
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PCM case. The reason is that, after this time, heat is released from the PCM material due to the
272
phase change.
273
80 with PCM
T (°C)
70
without PCM
60 50 40 30 20 10 0 0
2
4
6
8
10
12 14 TIME (H)
16
18
20
22
24
26
274
Fig. 9. Absorber surface temperature, with and without PCM
275 276 277
4.4. Air flow velocity
278
The velocity of the fluid was measured using the hot wire anemometer which was placed at the
279
chimney entrance. Figs. 10-12 illustrate the air velocity for two cases: with and without PCM.
280
According to Figs. 10-12, before noon and before reaching the maximum radiation, both curves
281
have good agreement with each other. But after about 2:30 p.m., when the solar radiation is
282
decreasing, the air velocity level for the curve with PCM starts stands higher than the other one,
283
and the graphs are slowly taken apart. This trend lasts until the phase change of paraffin would
284
start. The reason is that the latent heat of the PCM is released, so this phenomenon creates a heat
285
flux through the collector, which causes warming of the air. One can observe from Figs. 10 to 12
286
that the maximum velocities for the two states as “with” and “without” PCM, are 2 m/s and 1.9
287
m/s, respectively.
288
By assuming steady and one-dimensional flow, the mass flow rate is obtained as below:
289
𝑚 = 𝜌𝐴𝑉𝑖𝑛
(2)
13
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290
where 𝜌, A and 𝑉𝑖𝑛are density, area and air flow velocity, respectively. For calculating the air flow
291
rate for the states, it is assumed that A= 0.0314 m2 and 𝜌 = 1.225 kg/m3. The air velocity in fully
292
developed region of chimney is shown in Fig. 13.
293 2.5 With PCM
Velocity (m/s)
2 Without PCM 1.5
1
0.5
0 0:00
2:24
4:48
7:12
9:36
12:00
14:24
16:47
19:12
21:35
0:00
Time
294
Fig. 10. The velocity of fluid, with and without PCM on August 22nd.
295 296 297
2.5 Without PCM
Velocity (m/s)
2
With PCM 1.5 1 0.5 0 0:00
2:24
4:48
7:12
9:36 Time
12:00
14:24
16:47
19:12
21:35
0:00
298 299
Fig. 11. The velocity of fluid, with and without PCM on August 23rd. 14
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300
Velocity (m/s)
2.5 2
Without PCM With PCM
1.5 1 0.5 0 0:00
2:24
4:48
7:12 9:36 Time
12:00 14:24 16:47 19:12 21:35
0:00
301 302
Fig. 12. The velocity of fluid, with and without PCM on August 24th.
303 304
The difference between the diagrams is not considerable, but generally, the PCM causes 8.33 %
305
increase in the average mass flow rate compared with the case without PCM. Thus, the usage of
306
PCM in the set-up has a significant effect on the SC efficiency.
307
Velocity (m/s)
2.5 With PCM
2
Without PCM
1.5 1 0.5 0 0
5
10
15
20
25
Distance from chimney wall (cm)
308 309
Fig. 13. The air velocity in the fully developed region of the chimney.
310 311 15
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312 313
4.5. Verification of the experimental data using infrared camera
314
For verifying the accuracy of the sensors, the infrared camera was used. An infrared picture of the
315
solar chimney is shown in Fig. 14. Also, the temperature distribution of the thermal sensor of
316
absorber surface (T5) and the infrared camera results are shown in Fig. 15. In this image, as it is
317
observed, the temperature changes have good agreement with the temperature difference which
318
has been obtained by the sensors.
319
320
Fig. 14. An Infrared image of the solar chimney.
321 322 80
Temperature (ºC)
70 60 50 40 30 20 10 0 0:00:00
12:00:00
0:00:00
12:00:00
Time
323 324
Fig. 15. Comparison between thermal sensor data and the Infrared results.
325 16
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5. Conclusion
327
In this study, the effect of latent heat storage was investigated experimentally for a solar chimney
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set-up. The thermal performance of the SC with and without PCM was assessed under similar
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conditions. Paraffin wax was used as the phase change material in the set-up with 3 m chimney
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height and 1.5 m collector radius. According to the obtained results, the findings are expressed as
331
below:
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thermal efficiency of the SC.
333 334
In the absence of sunlight, due to the phase change of liquid paraffin to the solid phase, the latent heat is released.
335 336
The paraffin wax, used in the collector of the pilot as an LHS system, improved the
The maximum absorber surface temperature is obtained at 1:00 p.m. when the solar
337
radiation is in the maximum value. This temperature for the cases of with PCM and
338
without PCM is 72°C and 69°C, respectively.
339
The maximum air velocity through the pilot is 2 m/s for the SC with LHS system and
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1.9 m/s for the conventional SC. It means that, by using the LHS, the average mass
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flow rate is increased about 8.33 %; consequently, the SC efficiency is improved.
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Finally, the sensors` function and accuracy were verified, using an infrared camera.
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The comparison of the experimental data with numerical results shows a good
344
agreement.
345 346 347
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Highlights:
The effect of LHS system in a solar chimney is studied experimentally. Performance investigation is carried out for two cases with and without PCM. The maximum absorber temperature, with and without PCM, are 72°C and 69°C. The maximum air velocity, with and without the LHS system, are 2 m/s and 1.9 m/s. PCM causes increasing the SC mass flow rate around the 52.63%.