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Characteristics of fly ash under oxy-fuel circulating fluidized bed combustion Wei Li, Dianbin Liu, and Shiyuan Li Energy Fuels, Just Accepted Manuscript • DOI: 10.1021/acs.energyfuels.8b00934 • Publication Date (Web): 07 Aug 2018 Downloaded from http://pubs.acs.org on August 8, 2018
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Energy & Fuels
1
Characteristics of fly ash under oxy-fuel circulating fluidized
2
bed combustion
3
Wei Li1, Dianbin Liu1,2, Shiyuan Li1,2,*
4 5
1
Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing 100190, China 2
6 7
University of Chinese Academy of Sciences, Beijing, China
Abstract
8
The objective of the present paper is to study the physiochemical properties of fly ash under
9
oxy-fuel circulating fluidized bed (CFB) combustion mode. Tests were conducted in a 50 kW
10
oxy-fuel CFB combustor under both air and oxy-fuel combustion. The analyses of the collected
11
fly ash samples included particle size analysis, N2 adsorption analysis, char carbon, Inductively
12
Coupled Plasma Optical Emission Spectrometer (ICP-OES) and X-ray diffraction (XRD). It was
13
found that the d10, d50 and d90 of fly ash under oxy-fuel combustion mode were larger than that
14
under air combustion mode and increased with the rise of the inlet oxygen concentration. The
15
Brunauer-Emmett-Teller (BET) surface area, pore volume and pore size of fly ash under air
16
combustion are almost the same with that at inlet oxygen concentration of 30%. The element mass
17
concentrations were obviously different between the two combustion modes, but the main mineral
18
phase was insignificantly different. Moreover, the inlet oxygen concentration has no significant
19
effect on the element mass distribution in the fly ash, except for the alkaline earth metal under
20
oxy-fuel combustion.
21
Keywords: Circulating fluidized bed, Oxy-fuel, Fly ash, Physical properties, Chemical
22
composition.
23
*Corresponding Author. Telephone: +86-10-82543055. Fax: +86-10-82543119.
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24
25
E-mail address:
[email protected] 1. Introduction
26
The CO2 capture utilization and storage (CCUS) technology can achieve nearly zero CO2
27
emission, which is of great significance to realizing reduction target of CO2 emission and
28
developing low carbon economy. Oxy-fuel combustion is considered as the most promising CCUS
29
technology [1-3]. It has the advantages of low cost, can be scaled easily and applied to
30
the existed combustion equipment.
31
Compared with conventional air combustion mode, biggish chemical and physical change of
32
the combustion environment might alter the combustion process under oxy-fuel combustion mode.
33
Oxy-fuel combustion related issues including combustion, heat transfer and pollutant formation
34
have been studied in the past decades [2-6]. However, among these researches, there is less
35
research about the characteristics of ashes, including the bottom ash and fly ash, under the
36
oxy-fuel combustion condition. Most literatures regarding oxy-fuel combustion ashes focused on
37
pulverized coal (PC) combustor. Since combustion of low-grade coals can generate abundant fly
38
ash in circulating fluidized bed (CFB) boilers, thus the pollution of fly ash is a more potential
39
problem than in PC boilers [7-9].
40
The effects of oxy-fuel combustion on ash formation mechanisms, chemical composition and
41
particle size distributions (PSD) have been studied in lab-scale and pilot-scale facility. Sheng et al.
42
[10-12] found that O2/CO2 combustion has no significant influence on formation mechanisms of
43
the submicron particles and the fine fragmentation particles using drop tube furnace (DTF).
44
However, there is visible difference of the mass and composition distributions. Suriyawong et al.
45
[13] also found the same conclusions. Yu et al. [14] studied the ash formation in a 100 kW
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pilot-scale facility under oxy-fuel combustion. The results showed that oxy-fuel atmosphere has
47
no significant impact on the ash PSDs and chemical composition, with the exception of sulfur
48
contents. The ashes under the oxy-fuel combustion has higher sulfur contents comparing air
49
combustion. Li et al. [15] observed that PSDs under two combustion modes are almost the same in
50
a 25 kW quasi one-dimensional down-fired PC combustor. The only difference is the peak of PSD
51
curve moved from 50 µm to 40 µm under oxy-fuel combustion. Zhan et al. [16] also investigated
52
the ash formation under oxy-fuel combustion in a 100 kW down-fired combustor. They concluded
53
that the ash portioning, fouling and slagging under the oxy-fuel combustion have no invisible
54
difference comparing with air combustion. However, the fine particle chemical compositions
55
would be changed.
56
Oxy-fuel CFB combustion outperforms PC combustion owing to several advantages and thus
57
is considered as a more suitable technology for oxy-fuel combustion. In the late years, researcher
58
has done lots of work about oxy-fuel CFB combustion [17-24]. However, literatures about ash
59
issues are rare under oxy-fuel CFB combustion. Wu et al. [25] studied the physiochemical
60
properties of fly ash and bed ash in a 100kW mini-CFB under oxy-fuel combustion, but did not
61
compare air and oxy-fuel combustion modes using the same facility. Furthermore, the influence of
62
the inlet O2 concentration on the physiochemical properties of fly ash was not reported under
63
oxy-fuel combustion. These all are necessary to better understand the characteristic of the oxy-fuel
64
CFB combustion fly ash.
65
The objective of present paper is to investigate the physical and chemical properties of
66
oxy-fuel CFB combustion fly ash and to identify the difference of fly ash under between oxy-fuel
67
and air combustion mode. The influence of inlet O2 concentration was also taken into
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consideration. All the tests were done in a 50 kW CFB combustor under O2/CO2 and air
69
combustion mode. And, the collected fly ash samples were analyzed through various methods,
70
including particle size distribution analysis, N2 adsorption analysis, char carbon, Inductively
71
Coupled Plasma Optical Emission Spectrometer (ICP-OES) and X-ray diffraction (XRD).
72
2. Experimental
73
2.1 A 50 kW CFB facility
74
The schematic diagram of the installation is shown in the Figure 2. The inside diameter of
75
furnace is 100 mm. And the height is 3250 mm. Three electrical heaters and a return leg cooler
76
were arranged on the facility. These all help to control of the combustion temperature during the
77
different combustion atmosphere. So, the O2 concentration of inlet gas can be ranged from 21% to
78
50%. More detailed description of the installation has been given elsewhere [24].
79 Figure 1 Schematic diagram of the experimental apparatus
80
81
2.2 Materials
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Energy & Fuels
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The fuel using in the tests is Datong (DT) coal. The fuel and ash analysis were presented in
83
Tables 1 and Table 2, respectively. The DT coal contained 26.05% ash, which was mainly
84
composed of SiO2 and Al2O3, followed by CaO and Fe2O3. The diameter of the experimental coal
85
is 0.1-1 mm. The diameter of the bed material (silicon sand) is ranged from 0.25 mm to 0.355 mm,
86
with a weight of 2.5 kg. Table 1 Fuel analysis of DT coal
87 LHV (MJ·kg−1)
Proximate analysis (wt%)
Qnet,ar
FCar
Mar
Aar
Var
Car
Har
Oar
Sar
Nar
22.61
44.38
2.2
26.05
27.37
58.08
3.73
8.58
0.32
1.04
Table 2 Ash Composition of DT coal
88
89
Ultimate analysis (wt%)
Component
SiO2
Al2O3
Fe2O3
CaO
MgO
TiO2
SO3
P2O5
K2O
Na2O
Content (wt%)
45.23
37.83
4.02
5.42
0.66
1.62
2.50
0.18
0.32
0.14
2.3 Experimental conditions and analysis methods
90
Experiments were conducted under O2/CO2 and air combustion modes. The O2 concentration
91
in the inlet gas ranged from 30% to 50% under oxy-fuel combustion. Table 3 showed the
92
important operation parameters and the emission dates under the both two combustion mode. All
93
the testes condition were operated at the steady-state for at least 1 h. The temperature profiles of
94
the furnace under both two combustion conditions were showed in Figure 2. The concentrations of
95
gas emissions, such as NO, N2O, SO2, CO and CO2, were monitored via a FTIR gas analyzer
96
(GASMET DX4000, Finland) continuously. All the unit of the emissions were transfer to
97
mass/unit energy input.
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Energy & Fuels
3500
Air O2:CO2 30%
m m
2500
O2:CO2 40%
e c a n r u f f o t h g i e H
2000
)
3000
O2:CO2 50%
(
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1500 1000 500 0 800
820
840
860
880
900
o
Temperature ( C)
98 99
Figure 2 The temperature profiles of the furnace under both two combustion mode Table 3 Operation parameters and the emission dates
100 Conditions
1
2
3
4
Atmosphere
Air
O2/CO2
O2/CO2
O2/CO2
Inlet oxygen concentration, %
21
30
40
50
Gas velocity, m/s
2.5±0.1
2.5±0.2
2.5±0.1
2.5±0.1
Average riser temperature, oC
849±5
846±10
848±7
852±5
Fuel feeding rate, kg/h
2.3±0.5
3.7±0.8
5.1±0.3
6.3±0.5
O2 in flue gas, % d.b
6.0±0.8
5.5±1.1
5.8±0.6
5.6±0.7
CO2 in the flue gas, %
13.5±2.3
91.3±2.5
90.6±1.8
90.9±1.6
CO in the flue gas, mg/MJ
616.8±45.2
502.1±52.3
384.8±46.3
289.9±32.7
SO2 in the flue gas, mg/MJ
279.2±25.5
99.9±12.3
82.3±13.1
72.1±8.5
NO in the flue gas, mg/MJ
67.6±12.6
37.3±6.2
28.0±5.8
18.9±4.8
N2O in the flue gas, mg/MJ
73.6±8.7
64.1±6.3
82.0±5.8
87.7±7.8
101
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All the fly ash samples were obtained from the ash-collecting unit, which is arranged on the
103
bottom of the flue gas cooler, after each test. Physicochemical properties of the collected samples
104
under the both two CFB combustion conditions were investigated in terms of PSD, N2 adsorption,
105
char carbon, ICP-OES and XRD.
106
3. Results and discussion
107
3.1 Physical properties
108
3.1.1 Particle size distribution (PSD)
109
Figure 3 showed the PSDs under different combustion conditions. PSDs of fly ashes were not
110
considerably different compared the two combustion modes. The PSDs of curve all samples were
111
showed as S-shaped. However, the center position of the PSD curve moved leftward obviously
112
under the oxy-fuel combustion mode. And as rise of the O2 concentration in the inlet gas, the
113
center position of the particle size distribution curve moved rightward gradually. 100
5
Air O2:CO2 30%
4
80
O2:CO2 40% O2:CO2 50%
3
Volume (%)
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Energy & Fuels
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2 40 1 20 0 0 0.1
1
10
100
1000
Particle Size (µm) 114 115
Figure 3 The particle size distribution under different combustion mode
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116
There are four formation mechanisms of the fly ash particles, including char fragmentation,
117
mineral coalescence, vaporization and subsequent condensation of inorganic matter and excluded
118
mineral char fragmentation [26]. In addition, the collection efficiency of cyclones affects the PSD
119
of fly ash in CFB boilers [27]. The d10, d50 and d90 of different conditions were showed in Table 4.
120
The d10, d50 and d90 are corresponding the particle size with cumulative volume of 10%, 50% and
121
90%, respectively. Table 4 The d10、d50 and d90 under different conditions
122 Condition
d10/µm
d50 /µm
d90 /µm
Air
5.03±1.08
37.17±6.07
166.05±12.87
O2/CO2:30%
2.89±0.32
22.35±5.36
81.09±6.85
O2/CO2:40%
3.56±0.68
26.91±3.25
128.39±25.85
O2/CO2:50%
4.46±0.53
34.80±3.58
162.53±19.53
123 124
The d10, d50 and d90 of oxy-fuel combustion fly ashes all are smaller than those of air
125
combustion fly ash. Zhang et al. found the same results using a DTF. They observed noticeable
126
mineral fragmentation under oxy-fuel combustion [28].
127 128 129
Expect char fragmentation, the char abrasion also considerably affected the PSD of fly ash during the CFB combustion. The rate of char abrasion ܴ can be calculated as follows [29]:
ܴ = −
ௗ ௗఛ
=݇
൫௨బ ି௨ ൯ௐ തതതത ௗ
(1)
130
where ݇ is the constant of Ra; ݑ is the fluidized gas velocity and ݑ is its minimum value,
131
m/s; ܹ is the mass of the char in the furnace, kg; തതത ݀ is the average diameter of char, mm.
132
തതത In our experiments, because the same bed material and coal were used, the ݑ and ݀
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133
were constant. And ݑ in the furnace was also kept the same under different combustion modes.
134
However, the coal feeding increased when the combustion mode switched from air to oxy-fuel
135
combustion mode, because the inlet O2 concentration rose from 21% to above 30%. As can be
136
seen in Figure 4, the average pressure drop of the furnace was higher under oxy-fuel combustion,
137
indicating the larger ܹ and ܴ . This was another reason why the diameter of the oxy-fuel
138
combustion fly ash was smaller.
3.0
Air O2/CO2:30%
2.5
Average pressure drop(kPa)
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Energy & Fuels
O2/CO2:40%
2.0
O2/CO2:50%
1.5
1.0
0.5
0.0 -500
0
500
1000
1500
2000
2500
3000
3500
Height of the furnace (mm)
139 140
Figure 4 The average pressure drop of the furnace
141
It was also indicated oxy-fuel combustion produced finer particles, which may be because the
142
oxygen concentration enhanced the mineral vaporization and nucleation under this mode [15,30].
143
With the increment of the inlet oxygen concentration which would enhance the char
144
fragmentation, the d10, d50 and d90 all increased under oxy-fuel combustion and the char particle
145
temperature noticeably rose. As reported, during single char particle combustion in a fluidized bed,
146
the char particle temperature rose nearly 100 oC as the inlet oxygen concentration increased from
147
21% to 40% under O2/CO2 combustion, although the bed temperature was fixed as 815 oC [31].
148
Thus, the higher temperature promoted the coalescence of minerals, which explained why the fly
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149
ash particles under higher inlet oxygen concentration were bigger-sized.
150
3.1.2 N2 adsorption analysis
151
N2 adsorption analysis of fly ash under different conditions was illustrated in Table 5. The
152
BET surface area, pore volume and pore size at inlet oxygen concentration of 30% were all almost
153
the same between the two combustion modes. The pore structure of the fly ash is highly influences
154
by the char particle temperature. Because of different physiochemical properties between CO2 and
155
N2, inlet oxygen concentration higher than 21% under oxy-fuel combustion mode should be
156
needed to achieve the similar particle temperature as that under air combustion. As reported, the
157
particle temperature of char at inlet oxygen concentration of ~30% under oxy-fuel combustion is
158
almost the same as that under air combustion [31]. However, the particle temperature at higher
159
inlet oxygen concentration under oxy-fuel combustion was higher [31]. The melting of
160
alumino-silicate mineral in char occurs under oxy-fuel condition has been reported [28]. Thus, the
161
BET surface area, pore volume and pore size all decreased with the rise of inlet oxygen
162
concentration (Table 5). Under oxy-fuel combustion, the BET surface area, pore volume and pore
163
size in the fly ash varied within 14.69-23.42 m2/g, 0.024-0.040 cm3/g and 6.36-7.01 nm,
164
respectively. Wu et al. [25] also studied the surface analysis of fly ash in a 100 kWth
165
mini-CFBC facility under oxy-fuel combustion mode using the coal and petroleum coke.
166
They found that the BET surface area, pore volume and pore size in the fly ash are ranged of 5-67
167
m2/g, 0.0083-0.040 cm3/g and 1.20-2.93 nm, respectively. The difference between studies may
168
be caused by the fuel type and operation parameters.
169
Table 5 The N2 adsorption analysis of fly ash under different conditions
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BET Surface Area
Pore Volume
Pore Size
m2/g
cm3/g
nm
Air
23.17±2.18
0.040±0.02
6.72±1.08
O2/CO2:30%
23.42±1.69
0.040±0.03
6.76±0.96
O2/CO2:40%
19.45±1.57
0.034±0.01
7.01±1.35
O2/CO2:50%
14.69±1.52
0.024±0.01
6.36±0.75
Condition
170
3.2 Chemical composition
171
3.2.1 Unburned carbon
172
Figure 5 showed the unburned carbon contents in fly ash under different conditions. The
173
carbon contents ranging from 11.5% to 15.6% were all higher than under the commercial-scale air
174
combustion CFB boiler ranging from 0.5% to 3% [32], but were still within the acceptable range
175
of 5%-20% [27]. The higher unburned carbon content was mainly caused by the relatively short
176
residence time of only ~ 1 sec in such a small-scale CFB combustor as used in the experiments.
20
15
Carbon content (%)
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Energy & Fuels
10
5
0
Air O2/CO2:30%
O2/CO2:40%
O2/CO2:50%
177 178
Figure 5 The unburn carbon content in fly ash under different conditions
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179
As can be seen in Figure 5, the unburned carbon contents of oxy-fuel combustion fly ash
180
were all lower than those of air combustion fly ash, and decreased as the increase of the O2
181
concentration in the inlet gas, which are consistent with the results in a 1 MW oxy-fuel CFBC [33].
182
It also indicates the higher inlet oxygen concentration is beneficial to improving the coal
183
combustion efficiency.
184
3.2.2 Chemical composition
185
The element mass concentrations in the fly ash under different combustion modes were
186
analyzed by ICP-OES. To eliminate the influence of the unburned carbon, we processed the
187
original ICP-OES data as follows:
188
ா
బ ( = ܧଵି
ೠ )
× 100
(2)
189
where ܧ and ܧare the element mass concentration before and after processing, respectively,
190
wt/%; ܥ௨ is the unburned carbon content, wt/%.
191
Figure 6 showed the processed element mass concentrations in the fly ash under different
192
conditions. The element mass concentrations were obviously different between the two
193
combustion modes. Under oxy-fuel combustion mode, higher mass concentrations of the Ca and
194
Mg, Al and Ti, and lower mass concentrations of alkaline metals (Na and K), Si and S were found.
195
The mass concentrations of Ba and Sr were higher at the inlet oxygen concentration of 30% and
196
40%, but suddenly dropped or were even lower than that under air combustion when the O2
197
concentration in the inlet gas reached 50%. This phenomenon should be reconfirmed and studied
198
in the future. The mass concentrations of Mn, P and Fe were similar between the two modes.
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3.0
25
2.5
20
Air O2/CO2:30%
2.0
O2/CO2:40%
15
O2/CO2:50%
1.5
10 1.0 5
0.5
0.0
Mass concentration(wt%)
Mass concentration(wt%)
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Energy & Fuels
0 Na
K
Ca Mg
S
Ti
Mn
P
Ba
Sr
Si
Al
Fe
199 200
Figure 6 The chemical composition of the fly ash
201
The lower alkaline metal was caused by the higher vaporization degrees under oxy-fuel
202
combustion mode. A fast combustion rate and reduction atmosphere on the surface of char particle
203
may resulted in the higher vaporization degrees under oxy-fuel combustion mode [24, 28]. The
204
vaporization of alkaline metals was harmful for coal combustion, which form the PM2.5 emission
205
and aggravate deposition and slag [34]. In our study, the concentrations of alkaline earth metals in
206
the fly ash were relatively higher. It has been reported that these metals more easily form alkali
207
aluminum silicates under oxy-fuel combustion [35].
208
Compare the air combustion, the S mass concentration in the oxy-fuel combustion fly ash is
209
lower, indicating most of S is released to the flue gas instead of existing in the solid mineral phase
210
under oxy-fuel combustion [35]. Many researches have proved that SO2 emissions under oxy-fuel
211
combustion mode are almost 3-5 times of that under air combustion mode, and the high content of
212
CO2 in the furnace inhibit the self-desulphurization of Ca and Mg [24, 36]. In addition, the SO2 in
213
the furnace would react with vaporized alkaline metals, forming alkali sulfates which deposit on
214
the cool tube surface. Wall et al. [4] and Zeng et al. [29] all found that the higher S content in the
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215
deposition ash under oxy-fuel combustion. Moreover, the intensified carbonation of sulfates in the
216
fly ash under the oxy-fuel combustion due to higher CO2 partial pressure also should be
217
considered [37, 38].
218
The inlet oxygen concentration seemingly has no significant effect on the element mass
219
concentrations in the fly ash, except for the alkaline earth metals (Figure 4). Li et al. [24]
220
concluded the influence of O2 concentration on alkaline earth metals release was not apparent,
221
probably because of the small amounts of Ca and Mg in the their experimental coal. In this study,
222
there are a large number of Ca and Mg in the ash of DT coal, which cannot be ignored. During the
223
oxy-fuel combustion with higher inlet oxygen concentration, the strong combustion reaction
224
would accelerate the heat release, result in the higher char particles temperature. It would promote
225
the formation of Ca(Mg)-Si-Al compounds and thereby fix more Ca and Mg in the fly ash.
226
3.2.3 XRD
227
XRD results of fly ash under different condition were given in Figure 5. The mineral phase of
228
the fly ash did not vary obviously under different combustion modes. As reported similarly, the
229
main mineral phase was not significantly different between two different combustion modes. And
230
the difference of the relative content of mineral phase was due to the different fuel type and
231
combustion temperature [12, 35]. It is also indicated the mineral phase of the fly ash is mainly
232
determined by the coal type, rather than the combustion mode.
233
Regardless of the combustion mode, SiO2 is the main component, followed by Al2O3, and
234
other minor species are KAlSi3O8, CaO and CaCO3 (Figure 7). Because of the high Ca content in
235
the DT coal, Ca-based compounds were detected in the fly ash. It should be noticed that CaSO4
236
was not observed because of the lower content of S in the fly ash. CaO was found under both two
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combustion modes, but CaCO3 was only seen under the oxy-fuel combustion mode.
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Since the O2 concentration in the inlet gas ranged from 30% to 50% during the experiments,
239
the CO2 concentration varied from 50% to above 90% along the height of furnace. According to
240
the equilibrium CO2 pressure over CaCO3 on temperature, as suggested by Baker et al. (Figure 8)
241
[39], CaCO3 seems would react with SO2 directly at temperature of 850 oC, which happened in our
242
experiments. However, the existence of both CaCO3 and CaO in the fly ash indicated sulfur
243
capture under oxy-fuel combustion took place through both direct and indirect sulfation, which
244
was because the higher particle temperature would promote the calcination of CaCO3 under
245
oxy-fuel combustion. This result implied the indirect sulfation reaction of CaCO3 always
246
occurred under oxy-fuel combustion even at lower combustion temperature, especially at high
247
oxygen concentration.
1
Air 1
2
3
41
1
1
1
1
O2/CO2:30% 1 2 3 5 4
Intensity
1 2 3 4 5 6 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 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
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1 4
1
O2/CO2:40%
3 2 5 4
4
1
O2/CO2:50%
1 2 3
0
248 249
20
5 4
1 4
40
1
60
80
100
2θ Figure 7 XRD charts fort fly ash under different combustion mode.
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1: SiO2, 2: Al2O3, 3: KAlSi3O8, 4: CaO, 5:CaCO3.
250
1.0
Oxy-fuel CFB combustion 0.8
CO2 partial pressure (atm)
1 2 3 4 5 6 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 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
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0.6
0.4
Direct sulfation Indirect sulfation
0.2
0.0 700
750
800
850
900
950
1000
o
Temperature ( C)
251
Figure 8 Equilibrium CO2 partial pressure over limestone
252
253
254 255
4. Conclusions
Tests were conducted in a 50 kW CFB combustor under both air and oxy-fuel combustion modes.
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The d10, d50 and d90 were smaller and increased as the rise of O2 concentration in the inlet gas
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under oxy-fuel combustion. The BET surface area, pore volume and pore size were all the same
258
between the two combustion modes at inlet oxygen concentration of 30%.
259
The element mass concentrations were obviously different between the two combustion
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modes. Compared with air combustion, higher mass concentrations of alkaline earth metals (Ca
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and Mg), Al and Ti, and lower mass concentrations of alkaline metals (Na and K), Si and S were
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found in the oxy-fuel combustion fly ash. However, the main mineral phase was insignificantly
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different between the two combustion modes.
264 265
The O2 concentration in the inlet gas seemingly has no significant effect on the element mass concentrations in the fly ash, except for the alkaline earth metals.
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CaO was found under both combustion modes, but CaCO3 was only found under oxy-fuel
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combustion.
268
Acknowledgments
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This study is supported by the National Natural Science Foundation of China (Grant
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51706227).
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