Modified exergy and exergoeconomic analyses of a biomass post fired hydrogen production combined cycle

Accepted Manuscript Modified exergy and exergoeconomic analyses of a biomass post fired hydrogen production combined cycle

Saeed Soltani PII:

S0960-1481(18)31144-3

DOI:

10.1016/j.renene.2018.09.074

Reference:

RENE 10614

To appear in:

Renewable Energy

Received Date:

25 October 2017

Accepted Date:

20 September 2018

Please cite this article as: Saeed Soltani, Modified exergy and exergoeconomic analyses of a biomass post fired hydrogen production combined cycle, Renewable Energy (2018), doi: 10.1016/j. renene.2018.09.074

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ACCEPTED MANUSCRIPT

1

Modified exergy and exergoeconomic analyses of a biomass post fired

2

hydrogen production combined cycle

3

Saeed Soltani

4

Faculty of Mechanical Engineering, University of Tabriz, 16471 Tabriz, Iran

5

[email protected]; [email protected]

6

Tel: +98 914 406 7078

7

Abstract

8

Biomass post fired hydrogen production combined cycle (BPFHPCC) is proposed and analyzed

9

via common exergy and exergoeconomic analyses. In order to have an objective insight and

10

especially realistic approach to the cycle’s thermodynamic and exergoeconomic performance,

11

modified approach is applied. Within common exergy analysis, the components with high exergy

12

destruction are respectively, the combustion chamber, heat recovery steam generator and gasifier

13

while with modified exergy analysis they are the gas turbine, steam turbine and post combustion

14

chamber. As far as components exergy destruction cost rate are concerned, with common

15

analysis the highest exergy destruction cost rates are for the combustion chamber, heat recovery

16

steam generator and steam turbine while with modified analysis they are the combustion

17

chamber, gas turbine, and steam turbine. In this system hydrogen is used for other units.

18

However, if we want to use it within the system, the case in which hydrogen is injected into the

19

combustion chamber is extended. The effects on the thermodynamic efficiency and system

20

product cost were negative while it decreased the system CO2 emissions, exergy destruction and

21

loss rates as well as the exergy destruction and loss cost rates.

1

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Keyword: Modified exergy; Modified exergoeconomic; Hydrogen; Post firing; Biomass

23

gasification

24

1. Introduction

25

Recently, biomass has become a significant source of energy in many countries. It can be an

26

advantageous substitute for non-renewable energy sources such as fossil fuels. Rising the energy

27

consumption, greenhouse gas emissions [1], acid precipitation and ozone depletion have fostered

28

much research on alternatives to non-renewable energy. One disadvantage for renewable energy

29

is that its availability is intermittent, varying throughout the day and year. One means of

30

addressing this problem is to use two or more sources of renewable energies with fossil fuels.

31

Using renewable energy also can help mitigate the harmful environmental effects of fossil fuels.

32

Biomass is a renewable energy form which can be used directly or indirectly after conversion

33

into a biofuel. Various approaches have been demonstrated for utilizing biomass energy, a

34

common one being gasification [2]. Biomass can also be used as a fuel in an externally fired gas

35

turbine [3]. Gnanapragasam et al. [4] have examined the most appropriate conditions in which

36

natural gas is used in a combined cycle power plant as a primary fuel and biomass as a secondary

37

fuel. Gholami et al. [5] compared two types of biomass, and showed that wood has 1 point

38

percent higher energy efficiency and higher CO2 emissions than paper in a cogeneration system.

39

Ahmadi et al. [6] optimized a multi-generation energy system which has a gas turbine to generate

40

multiple products such as the electricity, heating, cooling and domestic hot water. The authors

41

assessed many design parameters to determine the most important to consider for enhancing the

42

exergy efficiency and the total cost of the system. Ghenai and Hachicha [7] examined a 10 MW

43

biomass-fired steam power plant, considering various biomass fuels blended with sub-

44

bituminous coal and fractions varying from 0 to 100%. It was shown that, by increasing the 2

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biomass fraction from 6 to 100%, the annual energy production increases while CO2 emissions

46

decrease. Moharamian et al. [8] investigated various biomass cycles based on organic Rankine

47

cycles and evaluated several working fluids for the system. R141b was identified as the most

48

effective for that system.

49

Hydrogen may become an important energy carrier in the near future because it is a clean fuel,

50

and it can be utilized in chemical and petrochemical processing [9]. The production of hydrogen

51

from renewable energies is described in [10, 11, 12]. As an energy carrier, hydrogen can

52

facilitate the use of renewable energies. For instance, Iribarren et al. [13] examined a hydrogen

53

production system based on biomass gasification. One method of hydrogen production uses

54

electrolysis. Bhandari et al [14] showed that in many studies electrolysis technology was utilized,

55

and global warming potential considered for assessing the environmental impacts. In a water

56

electrolyzer, electric energy is employed to separate water into hydrogen and oxygen. There are

57

several types of electrolysis, including alkaline, solid oxide and proton exchange membrane

58

(PEM) [15]. For increasing the lifetime of an electrolyzer, a solid electrolyte is utilized in the

59

PEM electrolyzer. The PEM electrolyzer has advantages over an alkaline electrolyzer, such as

60

higher hydrogen quality and lower energy waste. Corradetti and Desideri [16] techno-

61

economically compared biomass utilization in two applications: electric power generation and

62

hydrogen production. The authors showed that hydrogen can be generated from wood with an

63

energy efficiency of 66%, and the efficiency of a biomass integrated gasification combined cycle

64

was about 44%. As a result, it was suggested that biomass can be beneficially utilized both for

65

producing the electric power and hydrogen. Parametric analyses have been performed to

66

investigate the effect of important design and operating parameters on the plant energy

67

conversion efficiency by Ni et al [17]. This study has quantified how much the energy efficiency 3

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can decreases by increasing the operating temperature, lowering the current density, reducing the

69

electrolyte thickness, and increasing the electrode catalytic activity. In addition, for high

70

hydrogen production levels, a PEM electrolyzer has some drawbacks, such as high temperature

71

operating conditions and scale up demands while an alkaline electrolyzer can be a suitable choice

72

since it has a higher efficiency than a PEM electrolyzer [18, 19].

73

Many scientists indicate that, apart from a comprehensive thermodynamic analysis based on

74

exergy, exergy costing is also a significant principle for providing an exergoeconomic

75

perspective. Such a perspective can be utilized to compare the input fuel costs and capital

76

expenditures for determining the product unit costs, which plays an important role in

77

performance optimizing [20]. Taheri et al. [21] have examined a novel integrated biomass

78

multigeneration system. They found that fuel mass flow rate is the most important operating

79

parameter affecting the energy efficiency and the total cost rate. By increasing the fuel mass rate

80

from 4 kg/s to 10 kg/s, energy efficiency decreased by 8% and total cost rate increased by

81

122.8%.

82

Tsatsaronis and Park [22] proposed the avoidable and unavoidable exergy destruction and

83

investment costs in thermal systems with the name of modified exergy and modified

84

exergoeconomic analyses. They concluded in order to evaluate the thermodynamic performance

85

and cost effectiveness of thermal systems and to estimate the potential for improvements, it is

86

useful to know the avoidable part of both exergy destruction and component’s investment costs.

87

They applied this approach on a cogeneration system and concluded that modified

88

exergoeconomic analysis considers the air compressor, gas turbine, and heat recovery steam

89

generator (HRSG) for investment cost reduction. Finally, they showed modified exergy and

90

exergoeconomic analyses are more realistic than normal exergy and exergoeconomic analyses. 4

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In this study, a biomass post fired hydrogen production combined cycle (BPFHPCC) is proposed

92

and evaluated with thermodynamic, exergoeconomic, modified exergy and modified

93

exergoeconomic analyses. Modified exergy and exergoeoconomic analyses are applied to obtain

94

the realistic potentials for system performance improvement. Hydrogen is produced by the PEM

95

electrolyzer and steam turbine output power is the running power for the hydrogen production.

96

The prominent aspects of this system are co-combustion of natural gas and biomass as a

97

renewable energy which makes this system technically flexible for various amount of power

98

production with lesser environmental impacts. Meanwhile, recovery of gas turbine’s heat energy

99

discharge paves the way for existence of the hydrogen production unit by which makes the

100

system to be linked to industrial, commercial or residential areas. For example, product hydrogen

101

can be sold to the mentioned places. As another alternative, when there is no use in

102

aforementioned units, hydrogen is injected into the combustion chamber for ascertaining the

103

results, especially for the environmental impacts.

104

2. System description

105

The BPFHPCC is shown in Fig. 1. The cycle includes: gas turbine (GT), compressor (Comp),

106

post combustion chamber (PCC), combustion chamber (CC), pump, HRSG, condenser (Cond),

107

steam turbine (ST), biomass gasification unit (Ga), heat exchanger (HE), oxygen separator, and

108

PEM electrolyzer. Air enters to the compressor and is compressed until a desired compressor

109

pressure ratio (rp) and then combusts with the natural gas and oxygen in the air until a desired gas

110

turbine inlet temperature (TIT). The combusted gas enters the gas turbine and expands. The

111

expanded gas enters the post combustion chamber and again burns by gasified biomass and after

112

heating the water in the HRSG extracts to the atmosphere. The heated water enters the steam

113

turbine at point 3. The electrical power of the steam turbine in the combined cycle is used in the 5

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electrolyzer section, which is investigated here for the first time. The hot water which is needed

115

in the PEM electrolyzer is supplied by a heat exchanger. Hydrogen is produced at the cathode of

116

the electrolyzer, and oxygen at the anode is separated in the (water/oxygen) mixer, where the

117

hydrogen and oxygen are both cooled to the environment temperature. For later hydrogen

118

production, the remaining hot water is returned to the PEM inlet.

119 19

26

1 2

Pump

20

Cond 4

HRSG

18

Water O2 Separator

29 14

17 ST

HE

28

21

13

27

O2

25 PEM

Gen

H2

15

3 Fuel 24

Tank CC

6

7

22

Comp

GT

23

Gen

5

Air

8 12 PCC

Biofuel 11

Ga

Air 10

120 121 122

9 Biomass

Fig. 1 Biomass post fired hydrogen production combined cycle (BPFHPCC) 3. System analysis

123 6

16

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3.1.

Thermodynamic analysis

125

A thermodynamic analysis framework is represented for the combined system, which has three

126

main parts: steam and gas turbine, PEM electrolyzer and biomass gasifier. The combined cycle

127

operation is steady-state and the net electric power output is 10,000 kW.

128

The following assumptions are brought in Table 1:

129

Table 1

130

Assumptions and data for the components of the BPFHPCC Component or condition

Ambient parameters

Compressor, turbines, pump [23]

Assumptions and data   

    

P=1.01 bar T=298 K The air composition by volume is 79% nitrogen and 21% oxygen η is,Comp=0.87 η is,GT=0.89 η is,ST=0.9 η is,Pump= 0.8 TIT is 1500 K

 The dry biomass (wood) has a gravimetric composition of C: 50%, H: 6% and O: 44%, and a calorific value (on a dry Gasifier [24]

basis) of 449,568 kJ/kmol 

The biomass moisture content is 20% on a mass basis



The equivalence ratio for gasification is 0.4188

7

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HRSG

Combustion and postcombustion chamber [23]

 

The maximum pressure of the steam cycle is 8000 kPa The pinch point temperature difference in the boiler is 10°C



Complete combustion occurs in the combustion

chambers 

The combustion chambers are adiabatic and have a

pressure drop of 1% PEM electrolyzer [17]



TPEM = 353 K



J aref =1.7×105 A/m2



J cref =4.6×103 A/m2



D = 50 μm



F = 96486



λ a =14



λ c =10



E act,a = 76 kJ/mol



E act,c = 10 kJ/mol

131 132

For all components of the system, mass and energy balances can be written respectively as

133

follows [25]:

134

∑ṁin=∑ṁout

(1)

135

E + ∑ṁinhin= Ẇ +∑ṁouthout

(2)

136 137

For the system, the energy efficiency is written based on the net output power of cycle and the

138

amount of hydrogen which is available is accounted for the energy efficiency. In the 8

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139

denominator since we have input energy at point 26 it also should be accounted for the energy

140

efficiency of cycle.

141

      W net,cycle =WGT -WComp +WST -WPump -WPEM

142

η=

143

When hydrogen is not available as the final product the energy efficiency becomes:

144

η=

145

Thermomechanical and chemical exergy are considered in the analysis. The specific

146

thermomechanical flow exergy at a state i is [25]:

147

ex i  h i  h 0  T0 s i  s 0 

148

where 0 is the restricted dead state condition.

149

Chemical exergy is calculated respect to the unrestricted dead state, which relates to the chemical

150

composition of the reference environment in addition to the reference pressure and temperature

151

[26]. The chemical exergy of an ideal gas mixture at the restricted dead state is based on the

152

partial pressures of the mixture components and the partial pressures of the same components in

153

the reference environment, but the chemical exergy in a combustion process is used to obtain the

154

potential useful work [26]. Also, the specific chemical exergy of a mixture of ideal gases follows

155

[26]:

156

ch ex ch mixture   u i ex 0,i  RT0  u i lnu i

(3a)

  W net,cycle +m15 LHVH2  fuel LHVfuel +E 26 m

(3b)

 W net,cycle

(3c)

 fuel LHVfuel +E 26 m

(4a)

(4b)

i

9

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157

Here, ui and ex ch 0,i denote the mole fraction and standard chemical exergy, respectively, of a

158

mixture component.

159

The exergy balance of the flows can be expressed as follows:

160

Ėxin+∑iṁiexi=∑eṁeexe+W+ĖxD

161

Conventional exergy analysis has been applied based on approach “exergy of product/exergy of

162

fuel”. Note that an efficiency based on “exergy of product/exergy of fuel” is often but not

163

always similar to an efficiency based on “product outlet streams/inlet streams” or “outlet

164

streams/inlet streams” [27].

165

Exergy of fuels and products for components are listed in Table 2.

(4c)

166

Table 2

167

Exergy of the fuels and products Component Comp GT CC PCC Ga HRSG HE ST Cond Pump PEM electrolyzer

Ė-fuel Ėx22 Ėx7-Ėx8 Ėx24 Ėx11 Ėx10+Ėx9 Ėx12-Ėx13 Ėx26 Ėx3-Ėx4 Ėx4-Ėx1 Ėx19 Ėx17

168 169

The exergy efficiency for the cycle with available hydrogen is:

10

Ė-product Ėx6-Ėx5 Ėx22+Ėx23 Ėx7-Ėx6 Ėx12-Ėx8 Ėx11 Ėx3-Ėx2 Ėx28-Ėx27 Ėx18 Ėx21-Ėx20 Ėx2-Ėx1  +Ex  -Ex  Ex 15

25

14

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170

ε=

  W net,cycle +Ex15  +Ex  +Ex  Ex 10

24

(5a) 26

171

The exergy efficiency for the cycle with unavailable hydrogen is:

172

ε=

173

 W net,cycle Ex +Ex  +Ex  10 24 26

3.2.

(5b)

Biomass combustion

174

A downdraft type gasifier is considered and the equilibrium model presumes that all of the

175

gasifier reactions are in the thermodynamic equilibrium. The reactions in the gasification process

176

are as follows [23, 28]:

177

C+CO2  2CO

(6)

178

C+H2O  CO+H2

(7)

179

C+2H2  CH4

(8)

180

The shift reaction with combination of equations 6 and 7 is:

181

CO + H2O  CO2+H2

182

The overall gasification reaction can be written as:

183

CHxOyNz + μ H2O + λ (O2+3.76N2) →aCO + bN2 + cH2 + dCO2 + eCH4 + fH2O

184

Equilibrium constants, respectively, are:

185

K1 =

e c2

186

K 2=

cd af

187

By MC = (mass of water/mass of wet biomass)

188

Kilomole number of moisture content can be calculated as follows:

(9)

(10)

(11)

(12)

11

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m biomass MC 18 1-MC 

189

μ=

190

where mbiomass is the mass of biomass. Applying mass and energy balances to overall reaction

191

(Eq. 10) and considering the equilibrium constants, values of “a to f” and the gasification

192

temperature T (if m is known) or m (if T is known) are obtained. [23, 28].

193

The equilibrium constants are related to the change in the Gibbs functions, as:

194

-

195

ΔG= h -Tg  s

196

Assuming no heat loss from the gasifier, an energy balance for the reaction in Eq. 10 can be

197

written. The enthalpy of formation of biomass is derived from its heating value [28].

198

The gasification product constituents in the present study are compared with the results of other

199

studies in Table 3 which indicates good agreement. The comparison considers biomass having a

200

20 % moisture content, based on experimental [29] and Zainal equilibrium model [28] results at

201

800 ℃.

(13)

ΔG =lnK RT



(14)



(15)

Table 3 Comparison of mole fractions of gasification constituents Constituent Present model Experiment [29]

Zainal equilibrium model [28]

H2

18.01

15.23

21.06

CO

18.77

23.04

19.61

CH4

0.68

1.58

0.64

CO2

13.84

16.42

12.01

N2

48.7

42.31

46.68

O2

0.00

1.42

0.00

202 12

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203

The heating value of wood represents the amount of heat released by a specific quantity (at 25 ℃

204

). The detailed calculations are mentioned in [30, 31] or as a given value for wood in [28]:

205

The exergy of biomass can be defined as the maximum amount of work that can be extracted in a

206

process in which the biomass is converted to the environment conditions, i.e., to the dead state.

207

Also, exwood can be expressed as follows [32]:

208

exwood=β LHVwood M

209

(16) M

H C

M

β=

C

M

H C

(17)

O

1 ‒ 0.4124 M

210

O

1.044 + 0.016 M ‒ 0.34493 M (1 + 0.0531 M )

C

Mi is the mass fraction of the elements (hydrogen, oxygen and carbon) in the biomass. 3.3.

211

PEM electrolyzer

212

The entire energy required for the PEM can be expressed as:

213

∆H=∆G+T∆S

214

Here, ∆G is the Gibbs free energy (for electricity demand), T is the electrolyzer temperature and

215

T∆S represents the thermal demand. The molar flow rate of the hydrogen product can be

216

expressed as:

217

nH

218

Here, J and F respectively denote current density and Faraday constant. The PEM electrolyzer

219

voltage can be expressed as [33, 34, 35]:

220

V=V0 + Vact,c +Vact,a + Vohm

(20)

221

V0 =1.229-8.5  10-4 (TPEM – 298)

(21)

(18)

J

= = ,out 2F nH

2

(19)

2O,reacted

13

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222

where Vact,a, Vact,c and Vohm are the anode, cathode and Ohmic activation overpotentials,

223

respectively. The resistance of the membrane, through which hydrogen ions pass, creates the

224

Ohmic overpotential. The local ionic conductivity σPEM of the electrolyzer and the water quantity

225

at location x can be expressed as follows [36]:

226

  1 1  σ PEM  λ  x   =  0.5139λ  x  -326  ×exp 1268  -   303 T   

227

λ(x)=

228

Here, x represents the distance into the membrane which is evaluated from the cathode

229

membrane interface, D is the membrane thickness, λa is the water quantity at the anode

230

membrane, and λc is the water quantity at the cathode membrane. The overall ohmic resistance,

231

ohmic overpotential and overall activation based on J0 can be expressed respectively as [36]:

232

D RPEM=∫0 σ

(24)

233

Vohm,PEM =JR PEM

(25)

234

Vact,i= F sinh

235

J0,i=J i exp (- RT )

236

Fig. 2 compares the J-V characteristics of the PEM for current model and the experimental

237

results by Ioroi et al. [33]. It is seen that there is a good agreement between these two results.

(22)

λa ‒ λc

x+λc

D

(23)

dx PEM[λ(x)]

RT

ref

‒1

J

(2J )

i=a,c

(26)

0,i

Eact,i

i=a,c

(27)

14

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238

239 240

Fig. 2. Comparison of results for J-V characteristics of PEM for current model and experimental

241

work [33]

242

3.4.

Exergoeconomics

243

Exergoeconomics is a significant part of cycle analysis which is utilized to give economic and

244

thermodynamic insights simultaneously by applying the cost concepts to the exergy, which

245

accounts for the quality of energy. In this study, the specific exergy costing method is used in the

246

exergoeconomic analysis. The relevant cost balance equations and required auxiliary equations

247

are described below and are employed for each of the component of the integrated system [23,

248

37]. The exergy costing principles lead to the cost rate balance, as follows:

249

 +Z=c   c F Ex F P Ex P

(28)

15

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250

C=cEx

(29)

251

Here c is the cost per unit exergy of each stream. Equation (28) indicates that the sum of cost

252

rates associated with all exergy streams entering a component and the cost rates associated with

253

CI OM the capital investment as well as operation and maintenance ( Z  Z  Z ) is equal to the sum

254

of cost rates associated with the exiting exergy streams. The cost data for each component of the

255

system (Zk) is taken from appropriate references [23, 38] and brought in Table 5. The cost data

256

provided in the literature are for different years and in the present work they are brought to the

257

reference year, 2017, using the Marshall and Swift equipment cost index through the following

258

relation [39]:

259

Reference year cost =

260

Table 5

261

Components’ cost equations [23, 38]:

(Original cost) (Reference cost index) Original year cost index

Components Comp

CC and PCC

Cost equations  c m  P  ZComp =  11 air   out  c -η   12 is,Comp   Pin c11 =75$/(kg/s),c12 =0.9

  Pout   ln     Pin 

 air(gas) . 1+exp(c 22 Tout -c 23 )  . ZCC&PCC =c 21.m

1 0.995-

c 21 =48.64$/(kg/s),c 22 =0.018K -1 ,c 23 =26.4

GT

  c m  P  ZGT =  31 gas   out  1+exp(c33Tin -c34 )   c -η   32 is,GT   Pin  c31 =1536$/(kg/s),c32 =0.92, c33 =0.036K -1 16

Pout Pin

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 dry-biomass  kg/h  )0.67 ZGa =1600.(m

Ga ST

  0.05  ZST =c51.W 1+    1-ηis,ST  0.7 ST

  

3

   × 1+5.exp  Tin -866K      10.42K   

c51 =3880.5$.kW -0.7

 Q Cond   CW +70.5.Q +c62 .m Cond × -0.6936.ln  TCW -TWB  +2.1898 2.2.LMTD c61 =280.74$.m -2

Cond



ZCond =c61.

c62 =746$.(kg.s)-1 Pump

   0.71 1+ 0.2  ZPump =c71.W Pump    1-μ is,Pump  c71 =705.48$.(kg.s)-1

HRSG

0.8    Q   i  steam,j +c 43 .m  1.2 ZHRSG =c 41.  f p,i .f T.steam,i .f T.gas,i .   +c 42 . f p,j .m gas  i j  LMTDi    p f p,i =0.0971. i +0.9029 30bar -830K  T f T.steam,i =1+exp  out,steam,i  500K  

-990K  T f T.gas,i =1+exp  out,gas,i  500K   c 41 =4131.8$.(kW.K)0.8 c 42 =13380$.(kg.s)-1 c 43 =1489.7$.(kg.s)-1.2 *PEM

262

 ZPEM=1000 W PEM ($)

electrolyzer * Costs

of the heat exchanger and O2 separator are included

263

The costs of natural gas and biomass respectively are 9.08 $/GJ and 2 $/GJ [23, 40].

264

The annual levelized capital investment for the k th component can be calculated as [23]:

265

 CRF  Z CI k =   Zk  τ 

(30)

17



ACCEPTED MANUSCRIPT

266

where CRF and τ are the capital recovery factor and the annual plant operation hours,

267

respectively. The capital recovery factor is a function of the interest rate, ir, and the number of

268

years of the plant operation, n, as follows:

i r 1+i r 

n

(31)

269

CRF=

270

For the k th component, the annual levelized operation and maintenance cost can be expressed as

271

[23]:

272

1+i r 

n

-1

 ZOM k =γ k Z k +ω k E p,k +R k

(32)

273

Here, γ k and ωk account for the fixed and variable operation and maintenance costs,

274

respectively, associated with the k th component and R k includes all other operation and

275

maintenance costs, which are independent of investment cost and product exergy. The last two

276

terms on the right side of Eq. (32) are neglected in the present work as they are small compared

277

to the first term [23].

278

With the Fuel and Product theory [37], which are commonly used for analyzing exergy, the cost

279

rate related to the costs of fuel and product, and exergy destruction rate (i.e., CFuel,k, CP,k, CD,k),

280

we can write:

281

ĊP,k=cP,kĖxP,k

(33)

282

ĊFuel,k=cFuel,kĖxFuel,k

(34)

283

ĊD,k=cD,kĖxD,k

(35)

284

The total unit product cost (TUPC) can be expressed as follows: 18

ACCEPTED MANUSCRIPT

285

TUPC=

∑nk Ż + ∑nfuelc k Fuel ĖFuel i=1

i=1

i

i

(36)

n

∑ p Ė i=1 P

i

286

The exergoeconomic factor indicates the contribution of the component’s capital investment cost

287

to the total cost in terms of costs related to the exergy destruction plus capital investment cost of

288

the component. The exergoeconomic factor can be expressed as

289

f=

290

Table 6 shows the primary equations for exergoeconomic analysis of the NFBPC-HI.

 Z k  Z +C k D,k

(37)

Table 6 Exergy cost rate balances and auxiliary equations of the BPFHPCC Components Auxiliary equation

Cost balance

Comp

-

Ċ6 = Ċ5+ ŻComp+ Ċ22

CC

-

Ċ6+Ċ24+ŻCC = Ċ7

GT

c22 = c23

PCC

-

Ċ8+ ŻPCC + Ċ11 = Ċ12

Ga

-

Ċ9+ ŻGa + Ċ10 = Ċ11

HE

-

Ċ26+Ċ27+ ŻHE = Ċ28

ST

c18 = c19

Ċ3+ ŻST = Ċ4+ Ċ18

Cond

c1 = c4

Pump

-

HRSG

c12 = c13

Ċ2+ ŻHRSG+Ċ12 = Ċ3+ Ċ13

PEM electrolyzer

c14 = c 25

Ċ14+ ŻPEM+Ċ17 = Ċ15+ Ċ25

Ċ7+ ŻGT = Ċ8+ Ċ23 + Ċ22

Ċ4 + Ċ20+ Ż Cond = Ċ1+ Ċ21 Ċ1+ŻPump+Ċ19 = Ċ2

291 292

3.5 Modified exergy analysis

293

Technological and economic design limitations determine a minimum value of the exergy

294

destruction. The part of the exergy destruction that cannot be avoided with technologically

19

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295

feasible design modifications is the unavoidable exergy destruction [22]. The unavoidable exergy

296

destruction is calculated by considering each component in isolation, separated from the system,

297

assuming the most favorable operating conditions. These conditions refer to minimum exergy

298

destruction and are associated with very low temperature differences and thermal/pressure losses

299

within the components. The assumptions for simulating unavoidable conditions depend on the

300

decision maker and are arbitrary to some extent. In this paper these assumptions have been

301

selected based on the authors’ knowledge and experience on plant operation and by considering

302

the maximum improvement potential that could be achieved for each plant component in the

303

foreseeable future. Table 7 lists the assumptions which are used.

304

The modified exergy efficiency of the system is defined based on the realistic definition for

305

exergy efficiency, since unavoidable exergy destruction should not be accounted in the exergy

306

efficiency:

307

ε* =

 Ex P,k Ex -Ex  UN F,k

(38)

D,k

308

Table 7

309

Assumptions for the unavoidable exergy destruction of the components of the BPFHPCC Component Comp GT

CC, PCC

Unavoidable conditions ηis,Comp = 0.98 ηis,GT = 0.99

Δp = 0 Qloss = 0 λ=1

Ga ST Pump HRSG

ER = 0.3632 ηis,ST = 0.97 ηis,Pump = 0.95

Tpp = 7 K 20

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TPEM = 150 oC

PEM 310

3.6 Modified exergoeconomic analysis

311

In modified exergoeconomic analysis, Z UN =Z -Z AV is the unavoidable capital investment, where

312

Z UN is related to the case in which the cost of the component is low [22]. Therefore, poor

313

characteristics are considered for components. In this paper the values are based on Table 8.

314

Note that, as for the unavoidable exergy destruction rate, the assumptions for simulating the

315

unavoidable conditions depend on the decision maker and are arbitrary to some extent.

316

Meanwhile, the cost rates related to the unavoidable exergy destruction rate can be expressed as [22]:

317

UN  UN C D,k,A =cf,k Ex D,k,A

318

Avoidable exergy destruction costs are calculated by [17]

319

  UN C AV D,k,A =C D,k,A -C D,k,A

320

Finally the modified exergoeconomic factor based on the avoidable cost rates is [22]:

321

f k* =

(39)

(40)

Z AV k  AV Z AV +C k

(41)

D,k

322

Table 8

323

Assumptions for the unavoidable capital investment cost rate of the components of the BPFHPCC Component Comp GT CC

Unavoidable conditions ηis,Comp = 0.7 ηis,GT = 0.76

TCC = 1273K

PCC

TPCC = 1062 K

Ga ST Pump

ER = 0.3632 ηis,ST = 0.7 ηis,pump = 0.7 21

ACCEPTED MANUSCRIPT

324

HRSG PEM 4. Results and discussion

Tpp = 20 K

325

Parametric analyses are applied to show the effects of the various design and operating

326

conditions on the performances of the cycle considered in this study. The analyses focus on the

327

effects of varying the gas turbine inlet temperature and pressure ratio since these are the key

328

inputs in power plants. Meanwhile, the hydrogen injection flow rate into the combustion

329

chamber when there is hydrogen injection is an input parameter. The output parameters

330

considered include hydrogen production rate, energy and exergy efficiencies, exergy destruction

331

and loss rates, CO2 emissions rate, exergy destruction and loss cost rates, total unit product cost

332

and exergoeconomic factor.

333

Table 9 lists the thermodynamic values for flows of the BPFHPCC, when the net power output is

334

10,000 kW, the gas turbine inlet temperature is 1500 K, and the heat recovery steam generator

335

(HRSG) inlet temperature is 1050 K.

ηis,ST = 0.7

336 337

Table 9

338

Thermodynamic values for flows of the BPFHPCC State

ṁ (kg/s)

P (bar)

T (K)

h (kJ/kmol)

1 2 3 4 5 6

3.61 3.61 3.61 3.61 14 14

0.08 80 80 0.08 1.01 9.09

314.7 315.4 850 314.7 298 589.9

3132 3314 64600 41742 -4.366 8673

10.67 10.79 125.3 133.4 198.6 200.6

6.461 35.96 5489 417 0 3990

7

14.33

8.99

1500

5340

234.8

15158

8

14.33

1.02

964.3

-13789

237.3

5101

22

s (kJ/(kmol K))

Ėx (kW)

ACCEPTED MANUSCRIPT

11

0.4228

1.02

1073

-67564

227.5

1648

12 13 14 15 20 21 24 25

14.75 14.75 0.6925 0.0390 185.22 185.22 0.323 0.6541

1.01 1.01 1.01 1.01 1.01 1.01 9.09 1.01

1050 322.7 353.2 353.2 308.1 318.15 298.15 353.2

-15411 -38982 6035 1596 1889 2642 -74595 -4563

240.6 203 19.37 135.5 6.61 9.069 168 85.97

6399 15.19 378.6 4557 0 131 16901 190.6

339 340

Fig. 3 shows the variations of the hydrogen production rate in the BPFHPCC with rp and TIT.

341

Increasing rp leads to a minimum hydrogen rate at rp=12 and increasing TIT decreases the

342

hydrogen production rate. These variations are affected by the variation of the steam turbine

343

power output with either rp or TIT, since the hydrogen is produced using the steam turbine output

344

power. For example, increasing TIT increases the gas turbine output power and for the constant

345

 =10000 kW ), steam turbine power decreases. Therefore, by TIT total output power ( W net

346

increase, hydrogen production decreases.

23

ACCEPTED MANUSCRIPT

347 348

Fig. 3 Variations of hydrogen production rate with rp and TIT

349

Variations for the energy and exergy efficiencies of the BPFHPCC plant with rp and TIT are

350

shown in Fig.4. Increasing rp leads to an optimum point for energy efficiency, at a value of

351

around rp=11, while exergy efficiency decreases. Raising TIT increases the energy and exergy

352

efficiencies.

24

ACCEPTED MANUSCRIPT

353

354 355 356

Fig. 4 Variations for the BPFHPCC of the energy and exergy efficiencies with rp and TIT

357

Fig. 5 shows the variations with TIT and rp for the BPFHPCC plant of the exergy destruction and

358

loss rates. Increasing rp raises the exergy destruction rate. While increasing TIT decreases the

359

exergy destruction rate. Increasing TIT reduces the exergy loss rate while increasing rp at TIT=

360

1500 K leads to an optimum point for the exergy loss rate, approximately at a compressor

361

pressure ratio of 12.

25

ACCEPTED MANUSCRIPT

362

363 364

Fig. 5 Variations for the BPFHPCC plant of exergy destruction and loss rates with rp and TIT

365

Fig. 6 presents the variations of the exergy destruction and loss cost rates with rp and TIT for the

366

BPFHPCC plant. Increasing rp decreases the exergy destruction cost rate. Meanwhile, increasing

367

rp reduces the exergy loss cost rate. Increasing TIT decreases the exergy destruction cost rate in

368

the BPFHPCC plant. Furthermore, increasing TIT raises the exergy loss cost rate, which is

369

opposite to the variation of exergy loss rate with TIT. The reason is the natural gas flow rate

370

increases with TIT, so the high cost of natural gas is the determining factor.

26

ACCEPTED MANUSCRIPT

371

372 373 374

Fig. 6 Variations for the BPFHPCC plant of the exergy destruction and loss cost rates with rp and

375

TIT

376 377

Fig. 7 displays the variations for the BPFHPCC plant of the total unit product cost and

378

exergoeconomic factor with rp and TIT. Increasing rp reduces the total unit product cost.

379

However, the total unit product cost increases with TIT. For the BPFHPCC plant, a higher TIT is

380

advantageous only thermodynamically. Furthermore, increasing rp raises the exergoeconomic

381

factor, showing that component purchase and maintenance costs increase more with rp than does

382

the exergy destruction cost. Note also that, at all values of rp, the component purchase and

27

ACCEPTED MANUSCRIPT

383

maintenance costs are higher than the exergy destruction cost. As TIT rises, the component

384

purchase and maintenance costs are optimized, with the optimal rp value of 14 (TIT= 1500 K).

385

386 387 388

Fig. 7 Variations for the BPFHPCC plant of the total unit product cost and exergoeconomic

389

factor with rp and TIT

390

Until now, the analysis was based on the hydrogen production for other units. However, suppose

391

we want to exploit hydrogen in the BPFHPCC. In the following figures these effects on the

392

energy efficiency, CO2 emissions rate, exergy destruction and loss rates, exergy destruction and

393

loss cost rates, total unit product cost and exergoeoconomic factor, will be shown.

28

ACCEPTED MANUSCRIPT

394

Variations for the BPFHPCC plant of the energy efficiency and CO2 emissions rate with

395

hydrogen injection rate into the combustion chamber are shown in the Fig. 8. Energy efficiency

396

decreases by hydrogen injection around 0.15 points. Increasing the hydrogen injection decreases

397

the natural gas flow rate in the combustion chamber with the expense of lower available

398

hydrogen, the latter effect leads to lower energy efficiency. An appealing result is shown for the

399

CO2 emissions rate in which the emissions decrease by hydrogen injection.

400 401 402

Fig. 8 Variations for the BPFHPCC plant of the energy efficiency and CO2 emissions rate with hydrogen injection rate into the combustion chamber

29

ACCEPTED MANUSCRIPT

403

Fig. 9 shows the variations for the BPFHPCC plant of the exergy destruction and exergy loss

404

rates with hydrogen injection rate into the combustion chamber. Exergy destruction rate

405

decreases in the plant. The reason is by hydrogen injection the combustion chamber exergy

406

destruction decreases and overall exergy destruction of system decreases. The effect of hydrogen

407

injection on the exergy loss of the system is negligible.

408 409

Fig. 9 Variations for the BPFHPCC plant of the exergy destruction and exergy loss rates with

410

hydrogen injection rate into the combustion chamber

411

Fig. 10 shows the variations for the BPFHPCC plant of the exergy destruction and exergy loss

412

cost rates with hydrogen injection rate into the combustion chamber. The effects are similar with

413

the exergy destruction and loss rates.

30

ACCEPTED MANUSCRIPT

414 415

Fig. 10 Variations for the BPFHPCC plant of the exergy destruction and exergy loss cost rates

416

with hydrogen injection rate into the combustion chamber

417

Fig. 11 shows the variations for the BPFHPCC plant of the total unit product cost and

418

exergoeconomic factor with hydrogen injection rate into the combustion chamber. Both the total

419

unit product cost and exergoeconomic factor increases by the hydrogen injection.

420

31

ACCEPTED MANUSCRIPT

421 422

Fig. 11 Variations for the BPFHPCC plant of the total unit product cost and exergoeconomic factor with

423

hydrogen injection rate into the combustion chamber

424 425

Table 10 shows the results for modified exergy analysis of the BPFHPCC plant. Modified exergy

426

efficiency ( ε* ) has an advantage over common exergy efficiency ( ε ) since it accounts the

427

avoidable exergy destruction and unavoidable part due to non-realistic definition is discarded.

428

The highest exergy efficiencies, in the rank order, are: the PEM, GT, Comp, ST, HRSG, Pump,

429

PCC, Ga and CC. However, from the modified perspective, they are: the HRSG, PEM, GT,

430

Comp, ST, CC, pump and PCC. This shows how a realistic definition of exergy efficiency

431

changes the interpretation across the components. For example, the gasifier, CC and HRSG with

32

ACCEPTED MANUSCRIPT

432

common exergy analysis have low efficiencies but with modified exergy analysis have high

433

efficiencies.

434

Table 10

435

Results for the modified exergy analysis of the BPFHPCC

Component

 Ex

F

 Ex

P

 Ex D

 UN Ex D

 AV Ex D

 UN Ex P

ε

ε*

(kW)

(%)

(%)

(kW)

(kW)

(kW)

(kW)

(kW)

Comp

4213

3927

286

38.24

247.76

4174.76

93.22

94.06

GT

10057

9674

383

32.21

350.79

10024.79 96.19

96.50

CC

16901

11168

5733

4076

1657

12825

66.08

87.08

PCC

1648

1298

350

11.89

338.11

1636.11

78.79

79.33

HRSG

6384

5437

947

917

30

5467

85.16

99.45

Pump

36.33

29.41

6.92

1.49

5.43

34.84

80.96

84.41

ST

5057

4575

482

139.5

342.5

4917.5

90.48

93.03

PEM

4919

4755

164

69.55

94.45

4849.45

96.66

98.05

Ga

2296

1648

648

593

55

1703

71.79

96.77

436 437

Table 11 shows the results of the modified exergoeconomic analysis for the BPFHPCC. The

438

exergoeconomic factor ( f k ) indicates the contribution of component capital investment cost to

439

the total costs related to that component. A comparison of the exergoeconomic factor with the

440

modified exergoeconomic factor ( f *k ), which is the contribution of component avoidable capital

441

investment cost on the total avoidable costs of that component, gives interesting results. Based

442

on the conventional exergoeconomic factor, the components that should be considered for

443

reduction of capital investment cost are: the PEM, ST, GT, Pump, and Comp, while from the

444

modified perspective they are replaced by the HRSG, GT, PEM, ST, and Comp. Like modified

445

exergy analysis, modified exergoeconomic analysis is a better and realistic benchmark for

33

ACCEPTED MANUSCRIPT

446

engineers and in this plant the modified exergoeconomic analysis and conventional

447

exergoeconomic analysis give completely different recommendations for the pump. This is

448

because, within the modified analysis, the PCC, and the pump should be considered for quality

449

betterment. But conventional analysis gives apposite results. Also with conventional analysis, the

450

HRSG should be considered for the quality improvement but modified analysis gives apposite

451

result.

452

Table 11

453

Results for the modified exergoeconomic analysis of the BPFHPCC

 AV Z K

C D,k

C D,k UN

C D,k AV f k (%)

($/h)

($/h)

($/h)

($/h)

3.75

18.55

15.66

2.04

13.62

58.75

57.66

86.71

19.26

67.45

20.2

1.70

18.50

81.10

78.47

9.33

12.38

5.29

7.09

192.6

136.90

55.70

6.15

11.29

PCC

2.78

4.49

4.43

0.06

3.50

0.12

3.38

56.17

1.74

HRSG

12.38

38.06

29.76

8.30

42.22

40.87

1.35

46.29

86.01

Pump

16.1

0.75

0.69

0.06

0.40

0.09

0.31

65.37

16.22

ST

14.57

138.5

111.8

26.70

25.25

7.32

17.93

84.58

59.82

PEM

16.1

137.6

118.9

18.70

9.55

4.03

5.52

93.51

77.21

Ga

2

3.014

2.98

0.034

4.66

4.27

0.39

39.25

8.02

c F,k

 Z k

($/GJ)

($/h)

Comp

15.22

22.3

GT

14.64

CC

Component

 UN Z k ($/h)

f *k (%)

454 455 456

5. Conclusions

457

The BPFHPCC is analyzed with two set of approaches namely conventional energy, exergy and

458

exergoeconomic analyses as well as the modified exergy and modified exergoeconomic analyses.

459

The latter focusses on the real and practical potentials for system performance improvement via

460

the avoidable and unavoidable exergy destruction and cost rates. That is to say, it discards the

34

ACCEPTED MANUSCRIPT

461

margins for improvement which is not aligned with the engineering applications since there are

462

technology limitations for absolute elimination of inefficiencies. The results for both approaches

463

are brought below:

464

Increasing the rp leads to a minimum point for hydrogen production (rp=12), an optimum point

465

for the energy efficiency and the exergy loss rate (rp=12), decreases the exergy efficiency, the

466

exergy destruction and loss cost rates, the product cost and increases the exergy destruction, and

467

the exergoeconomic factor. Furthermore, increasing the TIT leads to the decrease in the

468

hydrogen production cost, the exergy destruction and loss rates, the exergy destruction and loss

469

cost rates and increase in the energy and exergy efficiencies, the product cost, and an optimum

470

point for the exergoeconomic factor (rp=14). Overall, rp has some contradictory effects while

471

TIT increase is almost always favorable for thermodynamic performance except for the

472

exergoeconomic and the hydrogen production. In case hydrogen is injected to the CC the

473

benefits are: lower CO2 emissions, lower exergy destruction and loss rates and their

474

corresponding cost rates and the other results are not favorable. Finally, modified exergy and

475

modified exergoeconomic analyses give almost opposite results compared with conventional

476

analyses in which with the modified exergy analysis highest and lowest exergy efficiencies of the

477

components are the HRSG and the PCC, respectively, while with conventional analysis they are

478

the PEM electrolyzer and the CC. Moreover, with modified exergoeconomic analysis, the

479

highest and lowest exergoeconomic factor are, respectively, the HRSG and the PCC while with

480

conventional analysis they are the PEM and the CC.

481

Nomenclature

482

c

Cost per unit exergy, $/GJ

483

CRF

Capital recovery factor 35

ACCEPTED MANUSCRIPT

484

Ċ

Cost rate, $/h

485

D

Membrane thickness, µm

486

ex

Specific exergy, kJ/kg

487

Ė

Energy rate, kW

488

Ėx

Exergy rate, kW

489

Eact,a

Activation energy of anode, kJ/mol

490

Eact,c

Activation energy of cathode, kJ/mol

491

F

Faraday constant, C/mol

492

G

Gibbs free energy, J/mol

493

Ga

Gasifier

494

h

Specific enthalpy, kJ/kg

495

H

Enthalpy, kJ

496

HE

Heat exchanger

497

ir

Interest rate

498

J

Current density, A/m2

499

J0

Exchange current density, A/m2

500

Ja

501

ref

Pre-exponential factor of anode, A/m2

Jc

ref

Pre-exponential factor of cathode, A/m2

502

LHV

Lower heating value, kJ/kg

503

MC

Moisture fraction of wet biomass

504

Mi

Mass fraction

505

ṁ

Mass flow rate, kg/s 36

ACCEPTED MANUSCRIPT

506

Pi

Pressure at state i, bar

507

rp

Compressor pressure ratio

508

RPEM

Proton exchange membrane resistance, Ω

509

Rk

Independent operation and maintenance cost, $

510

s

Specific entropy, kJ/(kg.K)

511

S

Entropy, kJ/K

512

T

Temperature, K

513

Tg

Gasification temperature, K

514

TIT

Gas turbine inlet temperature, K

515

TUPC

Total unit product cost, $/GJ

516

Ẇ

Electrical power, kW

517

 W PEM

Electrical power required to split water in the electrolyzer (kW)

518

V0

Reversible potential, V

519

Vact,a

Anode activation over potential, V

520

Vact,c

Cathode activation overpotential, V

521

VOhm

Ohmic overpotential, V

522

Z

Investment cost of component, $

523

Ż

Investment cost rate of component, $/h

524

Greek letters

525

γ

Fixed operation and maintenance cost

526

η

Energy efficiency

527

ηis,Comp

Isentropic efficiency of compressor

37

ACCEPTED MANUSCRIPT

528

ηis,GT

Isentropic efficiency of gas turbine

529

ηis,ST

Isentropic efficiency of steam turbine

530

ηis,Pump

Isentropic efficiency of pump

531

ε

Exergy efficiency

532

ε*

Modified exergy efficiency

533

f

Exergoeconomic factor

534

f*

Modified exergoeconomic factor

535

σ (x)

Local ionic PEM conductivity, S/m

536

σ PEM

Proton conductivity in PEM, S/m

537

τ

Annual plant operation hours, h

538

λc

Water content at cathode-membrane interface

539

λa

Water content at anode-membrane interface

540

λ (x)

Water content in location x in membrane

541

β

Ratio of the chemical exergy to the LHV of the organic fraction of biomass

542

ω

Variable operation and maintenance cost, $/kW

543

Subscripts

544

a

Anode

545

act

Activation

546

HRSG

Heat recovery steam generator

547

C

Cathode

548

Comp

Compressor

549

CC

Combustion chamber

550

CI

Capital investment 38

ACCEPTED MANUSCRIPT

551

Cond

Condenser

552

CW

Cooling water

553

D

Destruction

554

F

Fuel

555

Ga

Gasifier

556

GT

Gas turbine

557

HE

Heat exchanger

558

i

Index for thermodynamic state point

559

in

Inlet condition

560

is

Isentropic

561

k

Index for component

562

K

Equilibrium constant

563

P

Product

564

PEM

Proton exchange membrane

565

PCC

Post combustion chamber

566

ohm

Ohmic

567

out

Outlet condition

568

ST

Steam turbine

569

WB

Wet bulb

570

0

Reference

571

Superscripts

572

AV

Avoidable

573

CI

Capital investment

574

OM

Operation and maintenance 39

ACCEPTED MANUSCRIPT

575

UN

Unavoidable

576 577

Acronyms and Abbreviations

578 579

BPFHPCC

Biomass post fired hydrogen production combined cycle

580

References

581

[1] Basu P. Combustion and gasification in fluidized beds. CRC Press (2006).

582

[2] Demirbaş A. Biomass resource facilities and biomass conversion processing for fuels and

583

chemicals. Energy Conversion and Management, 42(11), 1357-1378 (2001).

584

[3] Bridgwater AV, Toft AJ, Brammer JGA. Techno-economic comparison of power production

585

by biomass fast pyrolysis with gasification and combustion. Renewable and Sustainable Energy

586

Reviews, 6(3), 181-246 (2002).

587

[4] Gnanapragasam NV, Reddy BV, Rosen MA. Optimum conditions for a natural gas combined

588

cycle power generation system based on available oxygen when using biomass as supplementary

589

fuel. Energy, 34(6), 816-826 (2009).

590

[5] Gholamian E, Mahmoudi, SMS, Zare V. Proposal, exergy analysis and optimization of a

591

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ACCEPTED MANUSCRIPT Highlights

 Biomass post fired hydrogen production cycle is proposed  Modfied exergy and exergoeconomic analyses are applied  Hydrogen is injected into the combustion chamber  Modified exergy and exergoeconomic analyses yield more realistic results