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Thermodynamic performance assessment of solar based Sulfur-Iodine thermochemical cycle for hydrogen generation
Accepted Manuscript Thermodynamic Performance Assessment of Solar Based Sulfur-Iodine Thermochemical Cycle for Hydrogen Generation
Fatih Yilmaz, Reşat Selbaş PII:
S0360-5442(17)31496-2
DOI:
10.1016/j.energy.2017.08.121
Reference:
EGY 11490
To appear in:
Energy
Received Date:
06 March 2017
Revised Date:
10 July 2017
Accepted Date:
31 August 2017
Please cite this article as: Fatih Yilmaz, Reşat Selbaş, Thermodynamic Performance Assessment of Solar Based Sulfur-Iodine Thermochemical Cycle for Hydrogen Generation, Energy (2017), doi: 10.1016/j.energy.2017.08.121
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ACCEPTED MANUSCRIPT A new solar based S-I thermochemical cycle for hydrogen generation is developed Energy and exergy analyses of each step of S-I cycle are performed A clean hydrogen generation method is proposed The overall energy and exergy efficiency of system are calculated as 32.76% and 34.56%, respectively
ACCEPTED MANUSCRIPT
THERMODYNAMIC PERFORMANCE ASSESSMENT OF SOLAR BASED
1 2 3
SULFUR-IODINE THERMOCHEMICAL CYCLE FOR HYDROGEN GENERATION Fatih YILMAZ a,, Reşat SELBAŞ b
4 5 6 7 8 9 10 11
Department of Electrical and Energy, Vocational School of Technical Science, Aksaray University, 68100, Aksaray/Turkey b Department of Energy Systems, Engineering Faculty of Technology, Suleyman Demirel University, 68100, Isparta/Turkey
a
ABSTRACT
12 13
Recent studies show that thermochemical cycles has a great potential for green hydrogen
14
generation. In this study, the thermodynamic performance assessment of a solar based Sulfur-
15
Iodine (S-I) thermochemical cycle for hydrogen generation is performed focusing on the energy
16
and exergy methods. Moreover, we investigated that various reference environment and reaction
17
temperatures effects on energy and exergy efficiencies of S-I cycle steps. The results of
18
thermodynamic analyses indicated that energy and exergy efficiency of S-I cycle are found to be
19
43.85% and 62.39%, respectively. In addition, the overall energy and exergy efficiencies of
20
cycle are computed as, 32.76% and 34.56%, respectively. It was concluded that the S-I
21
thermochemical cycle offers a feasible and a diverse option for hydrogen generation and seems to
22
be a promising cycle.
23 24 25 26 27
Keywords: Energy, Exergy, Hydrogen generation, Thermochemical cycle, Sulfur-Iodine,
28 29 30
Corresponding author. Tel: +90-382-288-2504 E-mail address:[email protected](F. Yılmaz)
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31 32
1. Introduction
33 34
Nowadays, energy and energy conversion play an important role in our lives and have an impact
35
on every sector of the economy. The energy consumption of the world is increasing day by day
36
due to population growth and industrialization. Thus, the energy consumption is climbing rapidly.
37
The rise in energy consumption is primarily due to increase in fossil fuel usage. The non-
38
renewable energy sources are diminishing and worries about greenhouse gas emissions have
39
increased. Therefore, green and renewable energy resources have gained the importance [1].
40 41
Hydrogen is considered as one of the most promising energy carriers, with high energy content,
42
which can easily be used in fuel cells without any greenhouses gas emissions (GHGE) [3].
43
Hydrogen generation and its usage have come out as one of the paramount solutions to solve the
44
present-day environment problems such as acid rain, global warming and ozone layer depletion.
45
In this regard, the implementation of the hydrogen has numerous advantages to solve the above
46
mentioned problems. Nevertheless, at present, hydrogen is mostly generated from fossil fuels
47
such as steam reforming of natural gas. Therefore, carbon dioxide emissions are still rising
48
around the globe [2]. Subsequently, hydrogen generation is very important because of it does not
49
naturally exist by itself in environment and must be generated from compounds that contain it.
50 51
In the literature, there are several hydrogen generation methods such as steam methane reforming
52
(SMR), thermochemical cycles, and electrolysis. Among these methods, SMR and electrolysis
53
are widely used methods. However, these hydrogen generation methods are not sustainable and
54
environmental benign. Thus, many researchers and industrialists are trying to find new ways to
55
generate hydrogen energy from renewable and sustainable energy resources such as
56
environmentally friendly renewable energy based thermochemical cycles and water electrolysis.
57
Water dissociation through thermochemical cycles offer a significant potential for hydrogen
58
generation process. These cycles consist of a series of chemical reactions which either use water
59
and heat or heat and electricity. The water is decomposed into from oxygen and hydrogen at the
60
end of this process. The sustainable and environmental benign hydrogen generation requires
61
usage of renewable energy sources. So, the required heat for the cycle can be easily obtained
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62
from solar energy, which is a renewable energy source. In this regard, hydrogen generation
63
assisted with solar energy is becoming more attractive day by day for environmental friendly
64
technologies.
65 66
In the recent years, a number of studies has been conducted on different thermochemical cycle
67
for hydrogen generation [4-7]. Balta et al. [8] have been analyzed the geothermal based hydrogen
68
generation using four steps Cu-Cl thermochemical cycle. They have also calculated the energy
69
and exergy efficiencies of the considered thermochemical cycle as 21.67% and 19.35%,
70
respectively. Furthermore, several studies have been analyzed and reviewed on solar based
71
thermochemical hydrogen generation [9-11].
72 73
Balta et al. [12], have studied the thermodynamic analyses of Mg-Cl cycle, driven by solar
74
energy, for hydrogen generation. The energy and exergy efficiencies of the whole system was
75
found as 18.18% and 9.15%, respectively.
76 77
The hydrogen generation from nuclear reactor using sulfur iodine thermochemical cycle was
78
studied by Giraldi et al. [13]. They also investigated the GHGE from this process and compared
79
the obtained results from other hydrogen generation studies in the perspective of life cycle
80
analysis.
81 82
Lattin and Utgikar [14] evaluated the S-I thermochemical cycle and analyzed the variation level
83
of GHGE at different external power loads. The flowsheet study of the thermochemical S-I cycle
84
for hydrogen generation was conducted by Kasahara et al. [15]. In this study, research and
85
development program on the thermochemical S-I for hydrogen generation was performed and
86
reported in Japan Atomic Energy Agency. The energy efficiency of the HI process was estimated
87
as 57%.
88 89
Leybros et al. [16], performed the plant sizing as well as the cost analysis for hydrogen
90
generation using nuclear heat source and found that the hydrogen generation cost is
91
approximately 12 €/kg.
92
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93
Mawdsley et al. [17] investigated that sulfur trioxide (SO3) decomposition step in S-I
94
thermochemical and hybrid cycle which occur at low temperatures. The results of their study
95
showed that the conversion of SO3 can be obtained at 590 oC, as long as the oxygen is removed,
96
during the SO3 decomposition stage.
97 98
The hydrogen generation step in S-I thermochemical cycle was experimentally conducted by
99
Caple et al. [18]. They found that by increasing the initial concentration of water, the rate of
100
reaction substantially increases. They also suggested that the experimental study and modeling
101
of the S-I thermochemical water decomposition cycle can be further developed.
102 103
The S-I thermochemical cycle is a decomposition of water into hydrogen and oxygen, through
104
chemical reactions, using nuclear heat at high temperature. These studies have been proposed S-I
105
thermochemical cycle for hydrogen generation, which is a very promising solution in terms of
106
productivity and cost [19-21].
107 108
Thermodynamic performance and cost assessment of a new design S-I thermochemical for
109
hydrogen generation was conducted by Öztürk et al. [22]. In this study, they found the energy
110
and exergy efficiencies as 76.0% and 75.6%, respectively. The cost rate of SO2 was obtained as
111
2.2 $ per kmol.
112 113
Most of thermochemical cycles are required high heat temperature such as 800-900 oC. This
114
temperature can be obtain from nuclear and solar energy sources. The hydrogen generation from
115
water is a promising technology to achieve a carbonless energy system. S-I thermochemical cycle
116
is one of the best hydrogen generation cycles such as Cu-Cl and Mg-Cl [23].
117 118
As mentioned above, there are insufficient studies on the assessment of energy and exergy
119
efficiencies S-I thermochemical cycle assisted with solar energy. The main objective of this study
120
is devoted to examine the thermodynamic performance assessment of solar based S-I
121
thermochemical cycle for hydrogen generation. In order to evaluate the proposed cycle
122
performance, energy and exergy methods of the all steps are performed. A parametric study is
123
conducted for several parameters to evaluate the cycle such as operation conditions, state
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124
properties, and reference environment conditions. The effect of various parameters on the energy,
125
exergy efficiencies and exergy destructions of the cycle are also assessed and demonstrated. The
126
overall energy and exergy efficiencies of solar based S-I cycle are evaluated.
127 128 129 130 131
2. System description
132
generation is given in Fig.1. This cycle uses both heat and electricity for hydrogen generation
133
from water, at maximum step temperature of 850 oC. The S-I thermochemical cycle is composed
134
of two thermochemical reactions and one electrochemical reaction. The chemical reactions and
135
steps of the S-I cycle are given below;
The schematic flow diagram of the S-I thermochemical cycle with solar energy for hydrogen
136 137
(I) H2SO4 (g) →H2O (g) +SO2 (g) + ½ O2 (g)
(850 oC)
138
(II) I2 (l) +SO2 (g) +2H2O (l) →2HI (l) +H2SO4 (aq)
(120 oC)
139
(III) 2HI (l) → I2 (l) + H2 (g)
(450 oC)
140 141
It is possible to divide the cycle into three steps [22, 24]
142 143
I O2 production step at 850 oC
144 145
II HI production step
146 147
III H2 production step
148 149
In step I, which is the first step of S-I cycle, endothermic chemical reaction occurs at the highest
150
temperature of 850 oC. Furthermore, H2SO4 decomposition and O2 generation also take place.
151
The step I consists of two sections; firstly gaseous H2SO4 decomposition into H2O and SO3, at
152
400-500 oC. Secondly, SO3 decomposition into SO2 and O2 at 850 oC with solid catalyst. These
153
reactions take place at same time. H2SO4 enters step I and converts to gaseous O2, SO2, and H2O.
154
The step II, which can be called as Bunsen reaction. In this step, exothermic chemical reaction
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155
occurs at 120 oC, and I2 and H2O in liquid phases enter and react with SO2 gaseous and convert
156
into hydronic acid (HI) and H2SO4. In third (hydrogen production) step, the electrochemical
157
process takes place and then HI decomposition at 450 oC in liquid phase. The hydrogen
158
generation occurs in this step. The general schematic concept of S-I thermochemical cycle for
159
hydrogen generation is shown in Fig.2.
160 161
In short, in S-I hybrid thermochemical cycle, for hydrogen generation, H2O decomposes with
162
input heat and electricity and converts into H2 and O2 as shown below;
163 164 165 166 167 168 169
H2O (v) +Heat and Electricity → H2 (g) + ½ O2 (g)
170
the increasing energy demands [25]. In this regard, the thermodynamic performance analysis of
171
any energy consumption system plays a vital role. In this study, the energy and exergy analyses
172
of each step of S-I cycle for hydrogen generation are performed. For this study, calculations for
173
all the reactions of S-I thermochemical cycle are done according to 1 mole hydrogen generation.
3. Performance analyses The efficient utilization of energy sources is very important for any sustainable plan to confront
174 175
The thermodynamic performance analysis of the solar based S-I thermochemical cycle based on
176
mass, energy and exergy equations for control volume. During the analysis, we assumed that the
177
solar based S-I cycle runs at steady state flow conditions, the reference pressure and environment
178
temperature are taken as 100 kPa and 25 oC, respectively. The kinetic and potential energies are
179
assumed as zero.
180 181
The mass, energy and exergy balance equations, are to calculated work input, energy and exergy
182
efficiencies and exergy destruction rates.
183 184 185 186
For the steady-state mass rate balance as given below;
∑𝐦 = ∑𝐦 𝐢𝐧
𝐨𝐮𝐭
or
∑𝐦 = ∑𝐦 𝐑
𝐏
(1)
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187 188 189 190
Energy balance formulation can be written as; (2)
𝐄𝐢𝐧 ‒ 𝐄𝐨𝐮𝐭 = ∆𝐄𝐬 which becomes [26];
191 192
Q‒W=
∑m
outhout ‒
∑m
(3)
inhin
193 194
where Q and W denote heat and work, respectively. The general energy balance in a chemical
195
processes can be expressed as;
196
Q‒W=
197
where h°f and h° stands for specific enthalpy of formation and enthalpy at reference state,
198
respectively. h is specific enthalpy and its unit is kJ/mole. n, subscripts R and P stands for
199
number of moles, reactants and products, respectively.
200
The exergy balance for a S-I thermochemical cycle can be written as
201
∆Exsys =
202
where Exin, Exout and Exdest are the rate of net exergy transferred and exergy destruction,
203
respectively. ∆Exsys, is zero when the system is in a steady-state condition, so Eq. (5) becomes;
204
ExQ ‒ ExW + Exmass,in ‒ Exmass,out = Exdest
∑ n (h + h ‒ h ) ‒ ∑ n (h + h ‒ h ) P
° f
∑Ex ‒ ∑Ex in
°
P
R
° f
°
(4)
R
(5)
out ‒ Exdest
(6)
205 206
The exergy balance is related to physical and chemical processes, hence it can be written as:
207
ex = exph + exch
208
Finally, if kinetic and potential exergy is ignored, specific exergy formulation can be expressed
209
as:
210
ex = (h ‒ h0) ‒ T0(s ‒ s0) + exch
(7)
(8)
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211
where h is enthalpy, s is entropy, and the subscript zero indicates properties at the reference
212
(dead) state of P0 and T0.
213 214
The last step of S-I cycle, which is hydrogen production step and electrolysis, the electricity
215
demand is calculated by [27].
216 217 218 219
∆G =‒ nFE
(9)
where F is stands for Faraday’s constant and it is 96,485 C/mole, E is the cell potential and n is
220
the number of moles. Electrical energy input of the step III is defined as follows;
221 222
𝑊𝑒𝑙 =‒ ∆G
223 224
The S-I thermochemical cycle of standard chemical exergy values for compounds and elements
225
are taken from the literature [28] and given in the Table 1.
226 227
Shomate equations used to calculated enthalpy and entropy of the each step elements and
228
compounds in S-I thermochemical cycles [29].
229 230 231 232
T2 T3 T4 1 h ‒ h0 = AT + B + C + D ‒ E + F ‒ H 2 3 4 T T2 T3 1 s = Aln(T) + BT + C + D ‒ E 2 + G 2 3 2T
(10)
(11)
(12)
233 234
where T is reaction temperature (K) which is normalized to 1/1000 and constants (A - H) in the
235
formulation are given in Table 2 [29].
236 237
The exergy efficiency for the all steps can be written as follows;
238
Exout
(13)
239
ψstep =
240 241
where Exin the specific exergy is input of step, and Exout is the specific exergy output from step.
242
Exin
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243
The rate of heat received by heliostat can be described as [30];
244
Qs = IsA
245
where Is and A are solar radiation and heliostat field area, respectively. The exergy rate on the
246
heliostat can be expressed as;
(14)
247 248
Exs = Qs (1 ‒
T0 Tsun
)
(15)
249 250
where T0 and Tsun stands for ambient temperature and apparent sun temperature, respectively.
251
Additionally, Tsun is taken as 4500 K. The field efficiency of the heliostat can be taken as 75%
252
[30].
253 254
The absorbed heat rate of the receiver Qrec is expressed as,
255 256
Qrec = mms (Tout,rec ‒ Tin,rec)
(16)
257 258
Where mms is molten salt, Tout,rec is outlet temperature of receiver and Tin,rec inlet temperature
259
of receiver. The exergy rate on the receiver can be expressed as;
260 261
Exrec = Qrec (1 ‒
T0
) Tms
(17)
262 263
The S-I thermochemical and overall system energy efficiency can be written as;
264 265 266
ηS ‒ I =
LHVH2
∑Q + W
el
(18)
267 268
ηsystem =
LHVH2 Qs
(19)
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269 270
where Q is heat flow into cycle, the hydrogen lower heating value is taken as 240 kJ/mole Wel is
271
the electricity requirement of the last step.
272 273
The S-I thermochemical and overall system exergy efficiency can be formulated as
∑Ex
274
ψ𝑆 ‒ 𝐼 =
275
ψ𝑠𝑦𝑠𝑡𝑒𝑚 =
H2
(20)
Exin + Wel LHVH2
(21)
Exs
276 277 278 279 280 281 282
where Exin is energy input to the S-I cycle and ExH total exergy content of hydrogen generation. 2
4. Results and discussion The solar heliostat system was designed according to the heat demand of heat exchangers and
283
reactors of the S-I hybrid cycle. For hydrogen generation rate of 1 mole/s, the solar heliostat area
284
was calculated as 140 m2 with a solar radiation intensity of 800 W/m2. The properties of the solar
285
heliostat subsystem are listed in Table 3.
286 287
The exergy efficiencies of the subsystems, which consists of heliostats, receiver system, SGSS
288
and S-I cycle are calculated as 75%, 40.89%, 23.19% and 62.39% respectively, at a constant
289
ambient temperature of 25 oC. Total heat loss to the environment from the system is accepted as
290
20%. The total exergy destruction rate of the system is computed as 630.70 kJ/mole.
291 292
The heat requirement of step 1 at 850 oC is 170.4 kJ/mol H2. The correlation between exergy
293
destruction, reaction temperatures and environment reference temperatures for Step I, is
294
graphically illustrated in Fig.3. In this figure, the exergy destruction of the step I decreases with
295
increase in reaction temperature from 750 oC to 850 oC. Fig.3 also shows that with increase in
296
reference environment temperature the exergy destruction rate of the step I decreases. The
297
variation in the inlet and outlet exergy rates for step I for various ambient temperatures is shown
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298
in Fig.4. It can also be seen from Fig.4 that the inlet and outlet exergies of step I decrease by
299
increasing reference environment temperature, from 0 oC to 50 oC, at a reaction temperature 850
300
oC.
301
The change in exergy destruction rates for step II, with reaction and reference environment
302
temperatures are given in Fig.5. The exergy destruction rate increases with increase in reaction
303
temperature, from 80 oC to 120 oC. The inlet and outlet exergies, with different reference
304
temperatures, are illustrated in Fig.6. If the reference environment temperature increases, the inlet
305
and outlet exergies decreases, at a reaction temperature of 120 oC.
306 307
In the last step of S-I cycle, namely hydrogen generation step, an endothermic reaction was
308
occurred. The heat requirement of step III at 450 oC is 91.52 kJ/mol H2. The variation in exergy
309
destruction rate with different reaction and environment reference temperatures is shown in Fig.7.
310
It can be seen from Fig.7 that when the reaction temperature increases, the exergy destruction of
311
this step also increases. Fig.8 illustrates the relation between reference environment temperature
312
and the inlet and outlet exergies of step III, at a reaction temperature of 450 oC. The Fig.8 also
313
shows that by increasing the reference environment temperature the outlet exergy increases,
314
whereas the inlet exergy decreases.
315 316
The relationship with reference environment-temperature and energy and exergy efficiency of the
317
step I is illustrated in Fig.9. The figure shows that while increasing the reference environment
318
temperature from 0 oC to 50 oC, the energy efficiency does not change, but the exergy efficiency
319
increases. Fig.10, demonstrates the effects of the reference temperature on the energy and exergy
320
efficiency for step II. The exergy efficiency of step II increases nearly 9% with increase in
321
reference environment temperature, at 120 oC reaction temperature. The effect of reference
322
environment temperature on energy and exergy efficiency for step III is shown in the Fig.11. As
323
it can be seen from Fig.11, the energy efficiency is constant at 0.3317, while the exergy
324
efficiency increases, at standard step temperature of 450 oC.
325 326
Fig.12, shows that the exergy efficiency of S-I cycle increases by increasing the reference
327
environment temperature. The exergy efficiency of this cycle increases nearly 5%, when
328
reference environment temperature increases from 0 oC to 50 oC. Fig.13, illustrates the energy
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329
and exergy efficiencies of S-I cycle and the overall system. The energy and exergy efficiency of
330
the whole system are calculated as 32.76% and 34.56%, respectively. According to this results, it
331
can be said that the solar based S-I cycle is better than solar based Mg-Cl cycle.
332 333 334 335 336 337
5. Conclusion
338
thermochemical cycle for hydrogen generation. In addition, we presented the energy and exergy
339
efficiencies, inlet and outlet exergy rates as well as the exergy destruction for each step of a solar
340
based S-I thermochemical cycle. S-I thermochemical cycle energy and exergy efficiencies are
341
computed as 43.85% and 62.39, respectively. The energy and exergy efficiency of the whole
342
system are computed as 32.76% and 34.56%, respectively. The highest exergy destruction is
343
observed in the central receiver system. The total heat demand required for S-I cycle is calculated
344
as 456.1 kJ/mole. The total heat demand of heat exchangers calculated as 90.03 kJ/mole while the
345
total heat released from heat exchanger calculated as -65.04 kJ/mole. The electricity demand
346
required for hydrogen generation step is calculated as 104.203 kJ (e)/mole H2.
347
As a result, the S-I thermochemical cycle for hydrogen generation become prominent cycle in
348
terms of the energy and exergy efficiency and environmentally friendly hydrogen generation
349
ways. Additionally, the proposed study showed that S-I thermochemical cycle has reasonable
350
results at least as good as Mg-Cl and Cu-Cl cycles. In the near future, the use of thermochemical
351
cycles for hydrogen generation is expected to increase. It is envisaged that the offered cycle can
352
be used for hydrogen generation as a more environmentally and more feasible option.
This study investigated the detailed thermodynamic performance assessment of a solar based S-I
353 354 355 356 357
NOMENCLATURE A
area m2
358
𝐸
energy, kW
359
𝐸𝑥
exergy, kW
360
𝑒𝑥
specific exergy, kJ/kg
ACCEPTED MANUSCRIPT
361
exph
specific physical exergy, kJ/kg
362
exch
specific chemical exergy, kJ/kg
363
G
Gibbs function, kJ
364
G
gravity, m/s2
365
h
enthalpy, kJ/kg
366
h
enthalpy, kJ/mole
367
h0
specific enthalpy at reference point, kJ/mole
368
h0
formation enthalpy, kJ/mole
369
m
mass flow rate, kg/s
370
n
moles number, mole
371
s
specific entropy, kJ/kg K
372
T
temperature, K - oC
373
W
work, kW
374
Q
heat, kJ
375
Greek letters
376
𝜼
energy efficiency
377
𝝍
exergy efficiency
378
Subscripts
379
in
inlet
380
P
product
381
R
reactant
382
out
outlet
383
0
dead state point
384 385 386 387 388 389 390 391
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[16] Leybros J, Gilardi T, Saturnin A, Mansilla C, Carles P. Plant sizing and evaluation of hydrogen generation costs from advanced processes coupled to a nuclear heat source. Part I: Sulphur–iodine Cycle, International Journal of Hydrogen Energy 2010;35: 1008–1018. [17] Mawdsley JR, Carter JD, Myers, DJ, Lewis, MA, Krause TR. Sulfur trioxide electrolysis studies: Implications for the Sulfur-Iodine thermochemical cycle for hydrogen generation, International Journal of Hydrogen Energy 2012;34: 11004-11011 [18]
Caple K, Kreider P, AuYeung N, Yokochi A. Experimental modeling of hydrogen producing steps in a novel sulfur-sulfur thermochemical water splitting Cycle, International Journal of Hydrogen Energy 2015;40: 2484-2492
[19] Vitart Xavier, Carles Philippe, Anzieu Pascal. A general survey of the potential and the main issues associated with the sulfur-iodine thermochemical cycle for hydrogen generation using nuclear heat. Prog Nucl Energy 2008;50:402-10. [20] Zhang P, Chen SZ, Wang LJ, Yao TY, Xu JM. Study on a labscale hydrogen generation by closed cycle thermo-chemical iodine sulfur process. International Journal Hydrogen Energy 2010;35:10166-72. [21] Garcia, L., Gonzalez, D., Garcia, C., Garcia L., Brayner, C., Efficiency of the sulfureiodine thermochemical water splitting process for hydrogen production based on ADS (accelerator driven system) Energy 2013;57:469-477 [22] Öztürk I.T., Hammache A, Bilgen E. An improve process for H2SO4 decomposition steep of the sulfure iodine cycle, Energy Convers. Mgmt 1995 ;(36),1, 11-21 [23] Xinxin W. Kaoru O. Thermochemical water splitting for hydrogen generation utilizing nuclear heat from an HTGR, Tsinghua Science and Technology 2005;10: 270–276. [24] Norman J.H., Mysels K.J. Sharp S. Williamson D. Studies of the sulfur–iodine thermochemical water-splitting cycle. International Journal of Hydrogen Energy 1982;7 (7):545–556. [25] Orhan MF. Dincer İ. Rosen MA. Energy and exergy assessments of the hydrogen generation step of a copper–chlorine thermochemical water splitting cycle driven by nuclearbased heat, International Journal of Hydrogen Energy 2008;33: 6456–6466 [26] Cengel, Y.A. and Boles, M.A. Thermodynamics: An Engineering Approach, 6th edition, McGraw-Hill, NY 2008. [27] Barbir F. PEM fuel cells theory and practice. Elsevier; 2005 [28] The Exergoecology Portal, http://www.exergoecology.com/excalc/ (accessed 03.01.2016)
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484 485 486 487 488 489 490 491 492 493 494 495 496 497 498 499
[29]National
Enstitute
of
Standards
and
Technology,
(NIST).
http://webbook.nist.gov/chemistry/form-ser.html (accessed 03.01.2016)
[30] Xu C, Wang Z, Li X, Sun F. Energy and exergy analysis of solar power tower plants. Appl Therm Eng 2011;31:3904-13.
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Fig.1. A schematic flow diagram of solar S-I cycle
Fig.2. A general schematic concept of S-I cycle
ACCEPTED MANUSCRIPT
Fig. 3. Variation of the exergy destruction for the step I with reaction temperature, for several reference-environment temperatures. 168 T 0 = 25 o C T 0 = 15 o C
Exdest (kJ/mol H2 )
T 0= 5 oC
166
164
162 740
760
780
800
820
840
860
o
Treaction ( C)
Fig. 4. Inlet and outlet exergy rates of step I as a variation of reference-environment temperature at a reaction temperature of 850 oC. 320
Exergy Rate (kJ/mol)
300 Exout,SI
280
Exin,SI
260 240 220 200 0
10
20
30 T0 (o C)
40
50
ACCEPTED MANUSCRIPT
Fig. 5. Variation of the exergy destruction for the step II with reaction temperature, for several reference-environment temperatures. 220 T0 = 25 o C
200
T0 = 15 o C T0 = 5 o C
Exdest (kJ/mol H2 )
180 160 140 120 100 70
80
90
100
110
120
130
Treaction (o C)
Fig. 6. Inlet and outlet exergy rates of step II as a variation of reference-environment temperature at a reaction temperature of 120 oC.
575
Exergy Rate (kJ/mol)
570
Exout , SII Exin , SII
565
560
555
550 0
10
20 T0 (o C)
30
40
50
ACCEPTED MANUSCRIPT
Fig. 7. Effects of the reaction temperature on exergy destruction of step III, for several referenceenvironment temperatures 48 47 46
T0 = 25 o C T0 = 15 o C T0 = 5 o C
Exdest (kJ/mol)
45 44 43 42 41 40 39 400
420
440 Treaction
460
480
500
(o C)
Fig. 8. Effects of the reference environment temperature on inlet and outlet exergy rate of step III, for reaction temperature 450 oC 600
Exergy Rate (kJ/mol)
580 Exout, SIII
560
Exin, SIII
540
520
500 0
10
20 T0 (o C)
30
40
50
ACCEPTED MANUSCRIPT
Fig. 9. Effects of the reference environment temperature on energy and exergy efficiency of step I, for reaction temperature 850 oC 1.0
0.714
Treaction = 850 (o C) en,SI ex ,SI
0.712
0.710 0.90 0.708 0.85
Exergy Efficiecny
Energy Efficiecny
0.95
0.706
0.80
0
10
20
30
40
0.704
50
T0 (o C)
Fig. 10. Effects of the reference environment temperature on energy and exergy efficiency of step II, for reaction temperature 120 oC 0.52
0.80 Treaction = 120 (o C) en,SII ex,SII
0.78
0.76 0.48 0.74 0.46 0.72
0.44
0
10
20
T0 (o C)
30
40
50
0.70
Exergy Efficiecny
Energy Efficiecny
0.50
ACCEPTED MANUSCRIPT
Fig. 11. Effects of the reference environment temperature on energy and exergy efficiency of step III, for reaction temperature 450 oC 0.36
0.91 Treaction = 450 (o C) en, SIII ex, SIII
Energy Efficiency
0.90 0.32 0.90 0.30
0.28
Exergy Efficiecny
0.90
0.34
0.89
0
10
20
30
40
50
0.88
T0 (o C)
Fig. 12. Variation of exergy efficiency of S-I cycle with reference environment temperature
0.65
Exergy Efficiecny
0.64 0.63 0.62 0.61 0.6 0
10
20 T0 (o C)
30
40
50
ACCEPTED MANUSCRIPT
Fig. 13. Energy and exergy efficiency of S-I cycle and overall systems
ACCEPTED MANUSCRIPT Table 1. Standard chemical exergy of the compounds (adapted from ref [27]) 𝒆𝒙𝒄𝒉 (kJ/mol) 160.53 106.89 9.34 0.75 126.34 310.41 3.97 191.15 153.8 236.10
Chemical H2SO4 (aq) H2SO4 (g) H2O (g) H2O(l) SO3 SO2 O2 I2 HI H2
Table 1. Enthalpy of formation, reference entropy and Shomate constants for chemical compounds (adapted from ref. [28]) Compoun ds
ℎ0𝑓 (kJ/mol)
𝑠00 (kJ/mol* K)
A
B
C
D
E
F
G
H
H2SO4
-735.13
298.78
47.28924
190.3314
-148.1299
43.86631
-0.740016
-758.9525
301.2961
735.1288
H2O (850 oC)
-241.830
188.840
30.092
6.832514
6.793435
-2.53448
0.082139
-250.881
223.3967
-241.8264
-395.770
256.770
24.02503
119.4607
-94.38686
26.96237
-0.117517
-407.8526
253.5186
-395.7654
-296.84
248.21
21.43049
74.35094
-57.75217
16.35534
0.086731
-305.7688
254.8872
-296.8422
205.15
30.03235 0
8.772972
-0.398813
0.788313
-0.741599
11.32468 0
236.1663 00
0
SO3 SO2 O2
0
I2 (120 oC)
13.52
150.36
80.66919
6.855652 ×10-8
8.724352 ×10-8
3.723132 ×10-8
4.735829 ×10-10
-10.53
247.98
13.523
HI
26.36
206.59
26.0454
4.6897
4.911765
-2.654
0.1214
18.755
237.2
26.359
H2
0
130.68
33.06617 8
-11.36
11.43282
-2.773
-0.159
-9.981
172.71
0
I2 (450 oC)
62.42
260.69
37.798
0.225453
-0.913
1.0349
-0.084
50.869
305.92
62.4211
H2O (120 oC)
-285.83
69.95
203.6060 0
1523.290 00
3196.413 00
2474.455 00
3.85533
256.5478 0
488.7163 0
285.8304 0
ACCEPTED MANUSCRIPT
Table 3. Properties of the base case solar heliostat subsystem Subsystem Heliostat Field
Properties Solar irradiation Aperture area Field efficiency
Values 800 140 75%
Unit W/m2 m2 -
Receiver
Inlet temperature of molten salt Outlet temperature of molten salt Mass flow rate of molten salt Emissivity
565 293 0.1946 0.8
oC
Inlet temperature of water Outlet temperature of water Reference state temperature
230 552 25
oC
SGSS
oC
kg/s -
oC oC
Table 4. The results of exergy analysis of the considered system Subsystem
Inlet (kW)
Outlet (kW)
Heliostat field Central receiver SGSS S-I cycle
526.2 394.7 161.8 378.4
394.7 161.8 37.8 236.1
Exergy destruction rate (kW) 131.5 232.9 124 142.3
Efficiency 75 40.89 23.19 62.39
Fatih Yilmaz, Reşat Selbaş PII:
S0360-5442(17)31496-2
DOI:
10.1016/j.energy.2017.08.121
Reference:
EGY 11490
To appear in:
Energy
Received Date:
06 March 2017
Revised Date:
10 July 2017
Accepted Date:
31 August 2017
Please cite this article as: Fatih Yilmaz, Reşat Selbaş, Thermodynamic Performance Assessment of Solar Based Sulfur-Iodine Thermochemical Cycle for Hydrogen Generation, Energy (2017), doi: 10.1016/j.energy.2017.08.121
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.
ACCEPTED MANUSCRIPT A new solar based S-I thermochemical cycle for hydrogen generation is developed Energy and exergy analyses of each step of S-I cycle are performed A clean hydrogen generation method is proposed The overall energy and exergy efficiency of system are calculated as 32.76% and 34.56%, respectively
ACCEPTED MANUSCRIPT
THERMODYNAMIC PERFORMANCE ASSESSMENT OF SOLAR BASED
1 2 3
SULFUR-IODINE THERMOCHEMICAL CYCLE FOR HYDROGEN GENERATION Fatih YILMAZ a,, Reşat SELBAŞ b
4 5 6 7 8 9 10 11
Department of Electrical and Energy, Vocational School of Technical Science, Aksaray University, 68100, Aksaray/Turkey b Department of Energy Systems, Engineering Faculty of Technology, Suleyman Demirel University, 68100, Isparta/Turkey
a
ABSTRACT
12 13
Recent studies show that thermochemical cycles has a great potential for green hydrogen
14
generation. In this study, the thermodynamic performance assessment of a solar based Sulfur-
15
Iodine (S-I) thermochemical cycle for hydrogen generation is performed focusing on the energy
16
and exergy methods. Moreover, we investigated that various reference environment and reaction
17
temperatures effects on energy and exergy efficiencies of S-I cycle steps. The results of
18
thermodynamic analyses indicated that energy and exergy efficiency of S-I cycle are found to be
19
43.85% and 62.39%, respectively. In addition, the overall energy and exergy efficiencies of
20
cycle are computed as, 32.76% and 34.56%, respectively. It was concluded that the S-I
21
thermochemical cycle offers a feasible and a diverse option for hydrogen generation and seems to
22
be a promising cycle.
23 24 25 26 27
Keywords: Energy, Exergy, Hydrogen generation, Thermochemical cycle, Sulfur-Iodine,
28 29 30
Corresponding author. Tel: +90-382-288-2504 E-mail address:[email protected](F. Yılmaz)
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31 32
1. Introduction
33 34
Nowadays, energy and energy conversion play an important role in our lives and have an impact
35
on every sector of the economy. The energy consumption of the world is increasing day by day
36
due to population growth and industrialization. Thus, the energy consumption is climbing rapidly.
37
The rise in energy consumption is primarily due to increase in fossil fuel usage. The non-
38
renewable energy sources are diminishing and worries about greenhouse gas emissions have
39
increased. Therefore, green and renewable energy resources have gained the importance [1].
40 41
Hydrogen is considered as one of the most promising energy carriers, with high energy content,
42
which can easily be used in fuel cells without any greenhouses gas emissions (GHGE) [3].
43
Hydrogen generation and its usage have come out as one of the paramount solutions to solve the
44
present-day environment problems such as acid rain, global warming and ozone layer depletion.
45
In this regard, the implementation of the hydrogen has numerous advantages to solve the above
46
mentioned problems. Nevertheless, at present, hydrogen is mostly generated from fossil fuels
47
such as steam reforming of natural gas. Therefore, carbon dioxide emissions are still rising
48
around the globe [2]. Subsequently, hydrogen generation is very important because of it does not
49
naturally exist by itself in environment and must be generated from compounds that contain it.
50 51
In the literature, there are several hydrogen generation methods such as steam methane reforming
52
(SMR), thermochemical cycles, and electrolysis. Among these methods, SMR and electrolysis
53
are widely used methods. However, these hydrogen generation methods are not sustainable and
54
environmental benign. Thus, many researchers and industrialists are trying to find new ways to
55
generate hydrogen energy from renewable and sustainable energy resources such as
56
environmentally friendly renewable energy based thermochemical cycles and water electrolysis.
57
Water dissociation through thermochemical cycles offer a significant potential for hydrogen
58
generation process. These cycles consist of a series of chemical reactions which either use water
59
and heat or heat and electricity. The water is decomposed into from oxygen and hydrogen at the
60
end of this process. The sustainable and environmental benign hydrogen generation requires
61
usage of renewable energy sources. So, the required heat for the cycle can be easily obtained
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62
from solar energy, which is a renewable energy source. In this regard, hydrogen generation
63
assisted with solar energy is becoming more attractive day by day for environmental friendly
64
technologies.
65 66
In the recent years, a number of studies has been conducted on different thermochemical cycle
67
for hydrogen generation [4-7]. Balta et al. [8] have been analyzed the geothermal based hydrogen
68
generation using four steps Cu-Cl thermochemical cycle. They have also calculated the energy
69
and exergy efficiencies of the considered thermochemical cycle as 21.67% and 19.35%,
70
respectively. Furthermore, several studies have been analyzed and reviewed on solar based
71
thermochemical hydrogen generation [9-11].
72 73
Balta et al. [12], have studied the thermodynamic analyses of Mg-Cl cycle, driven by solar
74
energy, for hydrogen generation. The energy and exergy efficiencies of the whole system was
75
found as 18.18% and 9.15%, respectively.
76 77
The hydrogen generation from nuclear reactor using sulfur iodine thermochemical cycle was
78
studied by Giraldi et al. [13]. They also investigated the GHGE from this process and compared
79
the obtained results from other hydrogen generation studies in the perspective of life cycle
80
analysis.
81 82
Lattin and Utgikar [14] evaluated the S-I thermochemical cycle and analyzed the variation level
83
of GHGE at different external power loads. The flowsheet study of the thermochemical S-I cycle
84
for hydrogen generation was conducted by Kasahara et al. [15]. In this study, research and
85
development program on the thermochemical S-I for hydrogen generation was performed and
86
reported in Japan Atomic Energy Agency. The energy efficiency of the HI process was estimated
87
as 57%.
88 89
Leybros et al. [16], performed the plant sizing as well as the cost analysis for hydrogen
90
generation using nuclear heat source and found that the hydrogen generation cost is
91
approximately 12 €/kg.
92
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93
Mawdsley et al. [17] investigated that sulfur trioxide (SO3) decomposition step in S-I
94
thermochemical and hybrid cycle which occur at low temperatures. The results of their study
95
showed that the conversion of SO3 can be obtained at 590 oC, as long as the oxygen is removed,
96
during the SO3 decomposition stage.
97 98
The hydrogen generation step in S-I thermochemical cycle was experimentally conducted by
99
Caple et al. [18]. They found that by increasing the initial concentration of water, the rate of
100
reaction substantially increases. They also suggested that the experimental study and modeling
101
of the S-I thermochemical water decomposition cycle can be further developed.
102 103
The S-I thermochemical cycle is a decomposition of water into hydrogen and oxygen, through
104
chemical reactions, using nuclear heat at high temperature. These studies have been proposed S-I
105
thermochemical cycle for hydrogen generation, which is a very promising solution in terms of
106
productivity and cost [19-21].
107 108
Thermodynamic performance and cost assessment of a new design S-I thermochemical for
109
hydrogen generation was conducted by Öztürk et al. [22]. In this study, they found the energy
110
and exergy efficiencies as 76.0% and 75.6%, respectively. The cost rate of SO2 was obtained as
111
2.2 $ per kmol.
112 113
Most of thermochemical cycles are required high heat temperature such as 800-900 oC. This
114
temperature can be obtain from nuclear and solar energy sources. The hydrogen generation from
115
water is a promising technology to achieve a carbonless energy system. S-I thermochemical cycle
116
is one of the best hydrogen generation cycles such as Cu-Cl and Mg-Cl [23].
117 118
As mentioned above, there are insufficient studies on the assessment of energy and exergy
119
efficiencies S-I thermochemical cycle assisted with solar energy. The main objective of this study
120
is devoted to examine the thermodynamic performance assessment of solar based S-I
121
thermochemical cycle for hydrogen generation. In order to evaluate the proposed cycle
122
performance, energy and exergy methods of the all steps are performed. A parametric study is
123
conducted for several parameters to evaluate the cycle such as operation conditions, state
ACCEPTED MANUSCRIPT
124
properties, and reference environment conditions. The effect of various parameters on the energy,
125
exergy efficiencies and exergy destructions of the cycle are also assessed and demonstrated. The
126
overall energy and exergy efficiencies of solar based S-I cycle are evaluated.
127 128 129 130 131
2. System description
132
generation is given in Fig.1. This cycle uses both heat and electricity for hydrogen generation
133
from water, at maximum step temperature of 850 oC. The S-I thermochemical cycle is composed
134
of two thermochemical reactions and one electrochemical reaction. The chemical reactions and
135
steps of the S-I cycle are given below;
The schematic flow diagram of the S-I thermochemical cycle with solar energy for hydrogen
136 137
(I) H2SO4 (g) →H2O (g) +SO2 (g) + ½ O2 (g)
(850 oC)
138
(II) I2 (l) +SO2 (g) +2H2O (l) →2HI (l) +H2SO4 (aq)
(120 oC)
139
(III) 2HI (l) → I2 (l) + H2 (g)
(450 oC)
140 141
It is possible to divide the cycle into three steps [22, 24]
142 143
I O2 production step at 850 oC
144 145
II HI production step
146 147
III H2 production step
148 149
In step I, which is the first step of S-I cycle, endothermic chemical reaction occurs at the highest
150
temperature of 850 oC. Furthermore, H2SO4 decomposition and O2 generation also take place.
151
The step I consists of two sections; firstly gaseous H2SO4 decomposition into H2O and SO3, at
152
400-500 oC. Secondly, SO3 decomposition into SO2 and O2 at 850 oC with solid catalyst. These
153
reactions take place at same time. H2SO4 enters step I and converts to gaseous O2, SO2, and H2O.
154
The step II, which can be called as Bunsen reaction. In this step, exothermic chemical reaction
ACCEPTED MANUSCRIPT
155
occurs at 120 oC, and I2 and H2O in liquid phases enter and react with SO2 gaseous and convert
156
into hydronic acid (HI) and H2SO4. In third (hydrogen production) step, the electrochemical
157
process takes place and then HI decomposition at 450 oC in liquid phase. The hydrogen
158
generation occurs in this step. The general schematic concept of S-I thermochemical cycle for
159
hydrogen generation is shown in Fig.2.
160 161
In short, in S-I hybrid thermochemical cycle, for hydrogen generation, H2O decomposes with
162
input heat and electricity and converts into H2 and O2 as shown below;
163 164 165 166 167 168 169
H2O (v) +Heat and Electricity → H2 (g) + ½ O2 (g)
170
the increasing energy demands [25]. In this regard, the thermodynamic performance analysis of
171
any energy consumption system plays a vital role. In this study, the energy and exergy analyses
172
of each step of S-I cycle for hydrogen generation are performed. For this study, calculations for
173
all the reactions of S-I thermochemical cycle are done according to 1 mole hydrogen generation.
3. Performance analyses The efficient utilization of energy sources is very important for any sustainable plan to confront
174 175
The thermodynamic performance analysis of the solar based S-I thermochemical cycle based on
176
mass, energy and exergy equations for control volume. During the analysis, we assumed that the
177
solar based S-I cycle runs at steady state flow conditions, the reference pressure and environment
178
temperature are taken as 100 kPa and 25 oC, respectively. The kinetic and potential energies are
179
assumed as zero.
180 181
The mass, energy and exergy balance equations, are to calculated work input, energy and exergy
182
efficiencies and exergy destruction rates.
183 184 185 186
For the steady-state mass rate balance as given below;
∑𝐦 = ∑𝐦 𝐢𝐧
𝐨𝐮𝐭
or
∑𝐦 = ∑𝐦 𝐑
𝐏
(1)
ACCEPTED MANUSCRIPT
187 188 189 190
Energy balance formulation can be written as; (2)
𝐄𝐢𝐧 ‒ 𝐄𝐨𝐮𝐭 = ∆𝐄𝐬 which becomes [26];
191 192
Q‒W=
∑m
outhout ‒
∑m
(3)
inhin
193 194
where Q and W denote heat and work, respectively. The general energy balance in a chemical
195
processes can be expressed as;
196
Q‒W=
197
where h°f and h° stands for specific enthalpy of formation and enthalpy at reference state,
198
respectively. h is specific enthalpy and its unit is kJ/mole. n, subscripts R and P stands for
199
number of moles, reactants and products, respectively.
200
The exergy balance for a S-I thermochemical cycle can be written as
201
∆Exsys =
202
where Exin, Exout and Exdest are the rate of net exergy transferred and exergy destruction,
203
respectively. ∆Exsys, is zero when the system is in a steady-state condition, so Eq. (5) becomes;
204
ExQ ‒ ExW + Exmass,in ‒ Exmass,out = Exdest
∑ n (h + h ‒ h ) ‒ ∑ n (h + h ‒ h ) P
° f
∑Ex ‒ ∑Ex in
°
P
R
° f
°
(4)
R
(5)
out ‒ Exdest
(6)
205 206
The exergy balance is related to physical and chemical processes, hence it can be written as:
207
ex = exph + exch
208
Finally, if kinetic and potential exergy is ignored, specific exergy formulation can be expressed
209
as:
210
ex = (h ‒ h0) ‒ T0(s ‒ s0) + exch
(7)
(8)
ACCEPTED MANUSCRIPT
211
where h is enthalpy, s is entropy, and the subscript zero indicates properties at the reference
212
(dead) state of P0 and T0.
213 214
The last step of S-I cycle, which is hydrogen production step and electrolysis, the electricity
215
demand is calculated by [27].
216 217 218 219
∆G =‒ nFE
(9)
where F is stands for Faraday’s constant and it is 96,485 C/mole, E is the cell potential and n is
220
the number of moles. Electrical energy input of the step III is defined as follows;
221 222
𝑊𝑒𝑙 =‒ ∆G
223 224
The S-I thermochemical cycle of standard chemical exergy values for compounds and elements
225
are taken from the literature [28] and given in the Table 1.
226 227
Shomate equations used to calculated enthalpy and entropy of the each step elements and
228
compounds in S-I thermochemical cycles [29].
229 230 231 232
T2 T3 T4 1 h ‒ h0 = AT + B + C + D ‒ E + F ‒ H 2 3 4 T T2 T3 1 s = Aln(T) + BT + C + D ‒ E 2 + G 2 3 2T
(10)
(11)
(12)
233 234
where T is reaction temperature (K) which is normalized to 1/1000 and constants (A - H) in the
235
formulation are given in Table 2 [29].
236 237
The exergy efficiency for the all steps can be written as follows;
238
Exout
(13)
239
ψstep =
240 241
where Exin the specific exergy is input of step, and Exout is the specific exergy output from step.
242
Exin
ACCEPTED MANUSCRIPT
243
The rate of heat received by heliostat can be described as [30];
244
Qs = IsA
245
where Is and A are solar radiation and heliostat field area, respectively. The exergy rate on the
246
heliostat can be expressed as;
(14)
247 248
Exs = Qs (1 ‒
T0 Tsun
)
(15)
249 250
where T0 and Tsun stands for ambient temperature and apparent sun temperature, respectively.
251
Additionally, Tsun is taken as 4500 K. The field efficiency of the heliostat can be taken as 75%
252
[30].
253 254
The absorbed heat rate of the receiver Qrec is expressed as,
255 256
Qrec = mms (Tout,rec ‒ Tin,rec)
(16)
257 258
Where mms is molten salt, Tout,rec is outlet temperature of receiver and Tin,rec inlet temperature
259
of receiver. The exergy rate on the receiver can be expressed as;
260 261
Exrec = Qrec (1 ‒
T0
) Tms
(17)
262 263
The S-I thermochemical and overall system energy efficiency can be written as;
264 265 266
ηS ‒ I =
LHVH2
∑Q + W
el
(18)
267 268
ηsystem =
LHVH2 Qs
(19)
ACCEPTED MANUSCRIPT
269 270
where Q is heat flow into cycle, the hydrogen lower heating value is taken as 240 kJ/mole Wel is
271
the electricity requirement of the last step.
272 273
The S-I thermochemical and overall system exergy efficiency can be formulated as
∑Ex
274
ψ𝑆 ‒ 𝐼 =
275
ψ𝑠𝑦𝑠𝑡𝑒𝑚 =
H2
(20)
Exin + Wel LHVH2
(21)
Exs
276 277 278 279 280 281 282
where Exin is energy input to the S-I cycle and ExH total exergy content of hydrogen generation. 2
4. Results and discussion The solar heliostat system was designed according to the heat demand of heat exchangers and
283
reactors of the S-I hybrid cycle. For hydrogen generation rate of 1 mole/s, the solar heliostat area
284
was calculated as 140 m2 with a solar radiation intensity of 800 W/m2. The properties of the solar
285
heliostat subsystem are listed in Table 3.
286 287
The exergy efficiencies of the subsystems, which consists of heliostats, receiver system, SGSS
288
and S-I cycle are calculated as 75%, 40.89%, 23.19% and 62.39% respectively, at a constant
289
ambient temperature of 25 oC. Total heat loss to the environment from the system is accepted as
290
20%. The total exergy destruction rate of the system is computed as 630.70 kJ/mole.
291 292
The heat requirement of step 1 at 850 oC is 170.4 kJ/mol H2. The correlation between exergy
293
destruction, reaction temperatures and environment reference temperatures for Step I, is
294
graphically illustrated in Fig.3. In this figure, the exergy destruction of the step I decreases with
295
increase in reaction temperature from 750 oC to 850 oC. Fig.3 also shows that with increase in
296
reference environment temperature the exergy destruction rate of the step I decreases. The
297
variation in the inlet and outlet exergy rates for step I for various ambient temperatures is shown
ACCEPTED MANUSCRIPT
298
in Fig.4. It can also be seen from Fig.4 that the inlet and outlet exergies of step I decrease by
299
increasing reference environment temperature, from 0 oC to 50 oC, at a reaction temperature 850
300
oC.
301
The change in exergy destruction rates for step II, with reaction and reference environment
302
temperatures are given in Fig.5. The exergy destruction rate increases with increase in reaction
303
temperature, from 80 oC to 120 oC. The inlet and outlet exergies, with different reference
304
temperatures, are illustrated in Fig.6. If the reference environment temperature increases, the inlet
305
and outlet exergies decreases, at a reaction temperature of 120 oC.
306 307
In the last step of S-I cycle, namely hydrogen generation step, an endothermic reaction was
308
occurred. The heat requirement of step III at 450 oC is 91.52 kJ/mol H2. The variation in exergy
309
destruction rate with different reaction and environment reference temperatures is shown in Fig.7.
310
It can be seen from Fig.7 that when the reaction temperature increases, the exergy destruction of
311
this step also increases. Fig.8 illustrates the relation between reference environment temperature
312
and the inlet and outlet exergies of step III, at a reaction temperature of 450 oC. The Fig.8 also
313
shows that by increasing the reference environment temperature the outlet exergy increases,
314
whereas the inlet exergy decreases.
315 316
The relationship with reference environment-temperature and energy and exergy efficiency of the
317
step I is illustrated in Fig.9. The figure shows that while increasing the reference environment
318
temperature from 0 oC to 50 oC, the energy efficiency does not change, but the exergy efficiency
319
increases. Fig.10, demonstrates the effects of the reference temperature on the energy and exergy
320
efficiency for step II. The exergy efficiency of step II increases nearly 9% with increase in
321
reference environment temperature, at 120 oC reaction temperature. The effect of reference
322
environment temperature on energy and exergy efficiency for step III is shown in the Fig.11. As
323
it can be seen from Fig.11, the energy efficiency is constant at 0.3317, while the exergy
324
efficiency increases, at standard step temperature of 450 oC.
325 326
Fig.12, shows that the exergy efficiency of S-I cycle increases by increasing the reference
327
environment temperature. The exergy efficiency of this cycle increases nearly 5%, when
328
reference environment temperature increases from 0 oC to 50 oC. Fig.13, illustrates the energy
ACCEPTED MANUSCRIPT
329
and exergy efficiencies of S-I cycle and the overall system. The energy and exergy efficiency of
330
the whole system are calculated as 32.76% and 34.56%, respectively. According to this results, it
331
can be said that the solar based S-I cycle is better than solar based Mg-Cl cycle.
332 333 334 335 336 337
5. Conclusion
338
thermochemical cycle for hydrogen generation. In addition, we presented the energy and exergy
339
efficiencies, inlet and outlet exergy rates as well as the exergy destruction for each step of a solar
340
based S-I thermochemical cycle. S-I thermochemical cycle energy and exergy efficiencies are
341
computed as 43.85% and 62.39, respectively. The energy and exergy efficiency of the whole
342
system are computed as 32.76% and 34.56%, respectively. The highest exergy destruction is
343
observed in the central receiver system. The total heat demand required for S-I cycle is calculated
344
as 456.1 kJ/mole. The total heat demand of heat exchangers calculated as 90.03 kJ/mole while the
345
total heat released from heat exchanger calculated as -65.04 kJ/mole. The electricity demand
346
required for hydrogen generation step is calculated as 104.203 kJ (e)/mole H2.
347
As a result, the S-I thermochemical cycle for hydrogen generation become prominent cycle in
348
terms of the energy and exergy efficiency and environmentally friendly hydrogen generation
349
ways. Additionally, the proposed study showed that S-I thermochemical cycle has reasonable
350
results at least as good as Mg-Cl and Cu-Cl cycles. In the near future, the use of thermochemical
351
cycles for hydrogen generation is expected to increase. It is envisaged that the offered cycle can
352
be used for hydrogen generation as a more environmentally and more feasible option.
This study investigated the detailed thermodynamic performance assessment of a solar based S-I
353 354 355 356 357
NOMENCLATURE A
area m2
358
𝐸
energy, kW
359
𝐸𝑥
exergy, kW
360
𝑒𝑥
specific exergy, kJ/kg
ACCEPTED MANUSCRIPT
361
exph
specific physical exergy, kJ/kg
362
exch
specific chemical exergy, kJ/kg
363
G
Gibbs function, kJ
364
G
gravity, m/s2
365
h
enthalpy, kJ/kg
366
h
enthalpy, kJ/mole
367
h0
specific enthalpy at reference point, kJ/mole
368
h0
formation enthalpy, kJ/mole
369
m
mass flow rate, kg/s
370
n
moles number, mole
371
s
specific entropy, kJ/kg K
372
T
temperature, K - oC
373
W
work, kW
374
Q
heat, kJ
375
Greek letters
376
𝜼
energy efficiency
377
𝝍
exergy efficiency
378
Subscripts
379
in
inlet
380
P
product
381
R
reactant
382
out
outlet
383
0
dead state point
384 385 386 387 388 389 390 391
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Fig.1. A schematic flow diagram of solar S-I cycle
Fig.2. A general schematic concept of S-I cycle
ACCEPTED MANUSCRIPT
Fig. 3. Variation of the exergy destruction for the step I with reaction temperature, for several reference-environment temperatures. 168 T 0 = 25 o C T 0 = 15 o C
Exdest (kJ/mol H2 )
T 0= 5 oC
166
164
162 740
760
780
800
820
840
860
o
Treaction ( C)
Fig. 4. Inlet and outlet exergy rates of step I as a variation of reference-environment temperature at a reaction temperature of 850 oC. 320
Exergy Rate (kJ/mol)
300 Exout,SI
280
Exin,SI
260 240 220 200 0
10
20
30 T0 (o C)
40
50
ACCEPTED MANUSCRIPT
Fig. 5. Variation of the exergy destruction for the step II with reaction temperature, for several reference-environment temperatures. 220 T0 = 25 o C
200
T0 = 15 o C T0 = 5 o C
Exdest (kJ/mol H2 )
180 160 140 120 100 70
80
90
100
110
120
130
Treaction (o C)
Fig. 6. Inlet and outlet exergy rates of step II as a variation of reference-environment temperature at a reaction temperature of 120 oC.
575
Exergy Rate (kJ/mol)
570
Exout , SII Exin , SII
565
560
555
550 0
10
20 T0 (o C)
30
40
50
ACCEPTED MANUSCRIPT
Fig. 7. Effects of the reaction temperature on exergy destruction of step III, for several referenceenvironment temperatures 48 47 46
T0 = 25 o C T0 = 15 o C T0 = 5 o C
Exdest (kJ/mol)
45 44 43 42 41 40 39 400
420
440 Treaction
460
480
500
(o C)
Fig. 8. Effects of the reference environment temperature on inlet and outlet exergy rate of step III, for reaction temperature 450 oC 600
Exergy Rate (kJ/mol)
580 Exout, SIII
560
Exin, SIII
540
520
500 0
10
20 T0 (o C)
30
40
50
ACCEPTED MANUSCRIPT
Fig. 9. Effects of the reference environment temperature on energy and exergy efficiency of step I, for reaction temperature 850 oC 1.0
0.714
Treaction = 850 (o C) en,SI ex ,SI
0.712
0.710 0.90 0.708 0.85
Exergy Efficiecny
Energy Efficiecny
0.95
0.706
0.80
0
10
20
30
40
0.704
50
T0 (o C)
Fig. 10. Effects of the reference environment temperature on energy and exergy efficiency of step II, for reaction temperature 120 oC 0.52
0.80 Treaction = 120 (o C) en,SII ex,SII
0.78
0.76 0.48 0.74 0.46 0.72
0.44
0
10
20
T0 (o C)
30
40
50
0.70
Exergy Efficiecny
Energy Efficiecny
0.50
ACCEPTED MANUSCRIPT
Fig. 11. Effects of the reference environment temperature on energy and exergy efficiency of step III, for reaction temperature 450 oC 0.36
0.91 Treaction = 450 (o C) en, SIII ex, SIII
Energy Efficiency
0.90 0.32 0.90 0.30
0.28
Exergy Efficiecny
0.90
0.34
0.89
0
10
20
30
40
50
0.88
T0 (o C)
Fig. 12. Variation of exergy efficiency of S-I cycle with reference environment temperature
0.65
Exergy Efficiecny
0.64 0.63 0.62 0.61 0.6 0
10
20 T0 (o C)
30
40
50
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Fig. 13. Energy and exergy efficiency of S-I cycle and overall systems
ACCEPTED MANUSCRIPT Table 1. Standard chemical exergy of the compounds (adapted from ref [27]) 𝒆𝒙𝒄𝒉 (kJ/mol) 160.53 106.89 9.34 0.75 126.34 310.41 3.97 191.15 153.8 236.10
Chemical H2SO4 (aq) H2SO4 (g) H2O (g) H2O(l) SO3 SO2 O2 I2 HI H2
Table 1. Enthalpy of formation, reference entropy and Shomate constants for chemical compounds (adapted from ref. [28]) Compoun ds
ℎ0𝑓 (kJ/mol)
𝑠00 (kJ/mol* K)
A
B
C
D
E
F
G
H
H2SO4
-735.13
298.78
47.28924
190.3314
-148.1299
43.86631
-0.740016
-758.9525
301.2961
735.1288
H2O (850 oC)
-241.830
188.840
30.092
6.832514
6.793435
-2.53448
0.082139
-250.881
223.3967
-241.8264
-395.770
256.770
24.02503
119.4607
-94.38686
26.96237
-0.117517
-407.8526
253.5186
-395.7654
-296.84
248.21
21.43049
74.35094
-57.75217
16.35534
0.086731
-305.7688
254.8872
-296.8422
205.15
30.03235 0
8.772972
-0.398813
0.788313
-0.741599
11.32468 0
236.1663 00
0
SO3 SO2 O2
0
I2 (120 oC)
13.52
150.36
80.66919
6.855652 ×10-8
8.724352 ×10-8
3.723132 ×10-8
4.735829 ×10-10
-10.53
247.98
13.523
HI
26.36
206.59
26.0454
4.6897
4.911765
-2.654
0.1214
18.755
237.2
26.359
H2
0
130.68
33.06617 8
-11.36
11.43282
-2.773
-0.159
-9.981
172.71
0
I2 (450 oC)
62.42
260.69
37.798
0.225453
-0.913
1.0349
-0.084
50.869
305.92
62.4211
H2O (120 oC)
-285.83
69.95
203.6060 0
1523.290 00
3196.413 00
2474.455 00
3.85533
256.5478 0
488.7163 0
285.8304 0
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Table 3. Properties of the base case solar heliostat subsystem Subsystem Heliostat Field
Properties Solar irradiation Aperture area Field efficiency
Values 800 140 75%
Unit W/m2 m2 -
Receiver
Inlet temperature of molten salt Outlet temperature of molten salt Mass flow rate of molten salt Emissivity
565 293 0.1946 0.8
oC
Inlet temperature of water Outlet temperature of water Reference state temperature
230 552 25
oC
SGSS
oC
kg/s -
oC oC
Table 4. The results of exergy analysis of the considered system Subsystem
Inlet (kW)
Outlet (kW)
Heliostat field Central receiver SGSS S-I cycle
526.2 394.7 161.8 378.4
394.7 161.8 37.8 236.1
Exergy destruction rate (kW) 131.5 232.9 124 142.3
Efficiency 75 40.89 23.19 62.39