integration of solid oxide fuel cells and ... - Ea Energianalyse

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C. EES C.3 Results - Optimized parameter configuration ABSO c;i = 36 ABSO c;o = 37 ABSO r ;i = 54 ABSO s;i = 62 ABSO s;o = 55 AddPreHeat$ = ‘On’ Air Fuel Ratio;m = 54,44 [-] Air Fuel Ratio;n = 4,902 [-] Air i = 11 [-] α SPG1 = 0,62 [-] α SPG2 = 0,1412 [-] ASR = 5,54 × 10 −5 [ Ω·m 2] α SPL1 = 0,6199 [-] A cell = 0,0228 [ m 2] BLOW 1 i = 11 BLOW 1 o = 12 Bur n i ;1 = 10 [-] Bur n i ;2 = 16 [-] Bur n i ;3 = 0 Bur n o = 18 [-] COND1 c;i = 35 COND1 c;o = 36 COND1 r ;i = 51 COND1 r ;o = 52 COND2 c;i = 33 COND2 c;o = 34 COND2 r ;i = 71 COND2 r ;o = 72 COP ABS = 1,484 [-] COP ABS;f uel = 0,5872 [-] COP ABS;heat = 1,089 [-] C p M I X L1;o = 2,011 [ k J/kg-K ] C p pump1;i = 2,055 [ k J/kg-K ] C p pump1;o = 2,055 [ k J/kg-K ] C p pump2;i = 2,115 [ k J/kg-K ] C p pump2;o = 2,115 [ k J/kg-K ] C p SHE X 1;hi = 2,011 [ k J/kg-K ] C p SHE X 2;hi = 2,013 [ k J/kg-K ] Ċ SHE X 1;r atio = 0,9005 Ċ SHE X 1;ss = 0,5932 Ċ SHE X 1;ws = 0,6587 Ċ SHE X 2;r atio = 0,8445 Ċ SHE X 2;ss = 0,2176 Ċ SHE X 2;ws = 0,2577 ∆ h;C HK ;min = 8,779 [ k J/kg ] ∆ Ḣ f uel = 100 ∆ Ḣ i = 100 [kW ] ∆ h;M I X L1;chk = 8,779 [ k J/kg ] ∆ h;V B1;chk = 7,608 [ k J/kg ] ∆ h;V B2;chk = 25,83 [ k J/kg ] ∆ p;ABSO;1 = 0 [kPa] ∆ p;ABSO;2 = 0 [kPa] ∆ p;ABSO;c = 0 [kPa] ∆ p;BURN ;i ;1 = −8 [kPa] ∆ p;BURN ;i ;2 = −1 [kPa] ∆ p;COND1;c = 0 [kPa] ∆ p;COND1;r = 0 [kPa] ∆ p;COND2;c = 0 [kPa] ∆ p;COND2;r = 0 [kPa] ∆ p;DES1;h = 0 [kPa] ∆ p;DES1;r = 0 [kPa] ∆ p;DES1;s = 0 [kPa] ∆ p;DES2;h = 2,776 × 10 −17 [kPa] ∆ p;DES2;r = 0 [kPa] ∆ p;DES2;s = 0 [kPa] ∆ p;EV AP;c = 0 [kPa] ∆ p;EV AP;r = 0 [kPa] ∆ p;GGHE X 1;c = −1 [kPa] ∆ p;GGHE X 1;h = −1 [kPa] ∆ p;GGHE X 2;c = −1 [kPa] ∆ p;GGHE X 2;h = −1 [kPa] ∆ p;GGHE X 3;c = −4 [kPa] 250
C.3. Results - Optimized parameter configuration ∆ p;GGHE X 3;h = −4 [kPa] ∆ p;GGHE X 4;c = −2 [kPa] ∆ p;GGHE X 4;h = −2 [kPa] ∆ p;M I XG1;i ;1 = −0,1 [kPa] ∆ p;M I XG1;i ;2 = 9,1 [kPa] ∆ p;M I XG2;i ;1 = −0,1 [kPa] ∆ p;M I XG2;i ;2 = −1,1 [kPa] ∆ p;M I X L1;1 = 0 [kPa] ∆ p;M I X L1;2 = 0 [kPa] ∆ p;M I X R1;1 = 0 [kPa] ∆ p;M I X R1;2 = 0 [kPa] ∆ p;PR = −5 [kPa] ∆ p;PU MP1 = 3,933 [kPa] ∆ p;PU MP2 = 46,69 [kPa] ∆ p;SHE X 1;ss = 0 [kPa] ∆ p;SHE X 1;ws = 0 [kPa] ∆ p;SHE X 2;ss = 0 [kPa] ∆ p;SHE X 2;ws = 0 [kPa] ∆ p;SOFC ;ano = −1 [kPa] ∆ p;SOFC ;cat = −3 [kPa] ∆ p;SPG1;o;1 = −0,1 [kPa] ∆ p;SPG1;o;2 = −0,1 [kPa] ∆ p;SPG2;o;1 = −0,1 [kPa] ∆ p;SPG2;o;2 = −0,1 [kPa] ∆ p;TOW ER1;air = 0,15 [kPa] ∆ p;TOW ER1;air ;dr y = 0,15 [kPa] ∆ p;TOW ER1;air ;wet = 0,15 [kPa] ∆ p;TOW ER1;w = 0 [kPa] ∆ p;W GHE X 1;g = −2 [kPa] ∆ p;W GHE X 1;w = 0 [kPa] ∆ p;W GHE X 2;g = −2 [kPa] ∆ p;W GHE X 2;w = 0 [kPa] ∆ p;W GHE X 3;g = −2 [kPa] ∆ p;W GHE X 3;w = 0 [kPa] ∆ T ;CFG;C HK = 22,97 [C ] ∆ T ;chill;EV AP = 5 [C ] ∆ T ;COND;DES = 43,68 [C ] ∆ T ;c;ABSO = 3,386 [C ] ∆ T ;c;COND1 = 1,509 [C ] ∆ T ;c;COND2 = 5 [C ] ∆ T ;c;TOW ER1 = 5 [C ] ∆ T ;EV AP;ABSO = 20,71 [C ] ∆ T ;h;DES1 = 5 [C ] ∆ T ;h;DES2 = 5 [C ] ∆ T ;min;ABSO;s;o = 1,81 [C ] ∆ T ;min;COND1;mp = 7,012 [C ] ∆ T ;min;COND1;r ;i = 8,491 [C ] ∆ T ;min;COND1;r ;o = 10 [C ] ∆ T ;min;COND1;r ;o;D = 10 [C ] ∆ T ;min;COND1;r ;o;S = 12,5 [C ] ∆ T ;min;COND2;mp = 10,21 [C ] ∆ T ;min;COND2;r ;i = 61 [C ] ∆ T ;min;COND2;r ;o = 15 [C ] ∆ T ;min;DES1;r ;o = 0 [C ] ∆ T ;min;DES2;r ;o = 0 [C ] ∆ T ;min;EV AP;r ;i = 2,69 [C ] ∆ T ;min;EV AP;r ;o = 7,69 [C ] ∆ T ;min;GGHE X 1;c;i = 457,2 [C ] ∆ T ;min;GGHE X 1;c;o = 105,8 [C ] ∆ T ;min;GGHE X 2;c;i = 142,1 [C ] ∆ T ;min;GGHE X 2;c;o = 90 [C ] ∆ T ;min;GGHE X 3;c;i = 334,8 [C ] ∆ T ;min;GGHE X 3;c;o = 271 [C ] ∆ T ;min;GGHE X 4;c;i = 14,54 [C ] ∆ T ;min;GGHE X 4;c;i ; = 14,54 [C ] ∆ T ;min;GGHE X 4;c;o = 10,1 [C ] ∆ T ;min;GGHE X 4;c;o; = 10,1 [C ] ∆ T ;min;SHE X 1;ws;i = 5 [C ] ∆ T ;min;SHE X 1;ws;o = 8,099 [C ] ∆ T ;min;SHE X 2;ws;i = 5 [C ] ∆ T ;min;SHE X 2;ws;o = 15,99 [C ] ∆ T ;min;TOW ER1;a;i ;dr y = 3 [C ] ∆ T ;min;TOW ER1;a;o = 3 [C ] ∆ T ;min;TOW ER1;a;o;dr y = 8 [C ] ∆ T ;min;TOW ER1;a;o;wet = 3 [C ] ∆ T ;min;W GHE X 1;w;i = 15 [C ] ∆ T ;min;W GHE X 1;w;i ; = 15 [C ] ∆ T ;min;W GHE X 1;w;o = 334,7 [C ] ∆ T ;min;W GHE X 1;w;o; = 334,7 [C ] ∆ T ;min;W GHE X 2;w;i = 76 [C ] ∆ T ;min;W GHE X 2;w;i ; = 15 [C ] ∆ T ;min;W GHE X 2;w;o = 76 [C ] 251
Page 1:
INTEGRATION OF SOLID OXIDE FUEL CEL
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Abstract It is investigated whether
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Preface This report is documentatio
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CONTENTS Preface . . . . . . . . .
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CONTENTS 4.2.3 SOFC stack . . . . .
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CONTENTS A.4 DG appendix . . . . .
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LIST OF FIGURES 4.3 Diagram of sing
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NOMENCLATURE Acronyms Acronym ABS A
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Greek (and other) Symbols Greek (an
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Subscripts Subscripts Subscript 2P
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1. INTRODUCTION Chapter 4, System d
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1. INTRODUCTION the electricity and
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1. INTRODUCTION 1.4 SOFC The fuel c
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1. INTRODUCTION 1.5 Heat driven coo
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1. INTRODUCTION Cycle description.
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1. INTRODUCTION Ammonia-water The C
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1. INTRODUCTION 1.5.3 Platen Munter
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1. INTRODUCTION Open loop In an ope
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1. INTRODUCTION 1.7 Problem stateme
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2. MARKET INVESTIGATION appendix A.
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2. MARKET INVESTIGATION 2.2.2 Ship
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2. MARKET INVESTIGATION Pay Back Ti
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2. MARKET INVESTIGATION 2.3.2 Micro
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2. MARKET INVESTIGATION Sensitivity
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2. MARKET INVESTIGATION • ECH pri
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2. MARKET INVESTIGATION 2.4.3 Resul
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2. MARKET INVESTIGATION 16000 14000
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2. MARKET INVESTIGATION Annuity pri
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2. MARKET INVESTIGATION 2.4.4 Concl
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C H A P T E R 3 COMPONENT DESCRIPTI
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3.1. Introduction The seven stream
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3.2. Absorber - ABSO 3.2 Absorber -
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3.2. Absorber - ABSO implicitly thr
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3.4. Burner - BURN 3.4 Burner - BUR
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3.5. Condenser - COND T [° C ] ΔT
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3.6. Desorber - DES 3.6 Desorber -
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3.7. Evaporator - EVAP 3.7 Evaporat
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3.8. Heat Exchanger - HEX 3.8 Heat
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3.8. Heat Exchanger - HEX The press
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3.10. Pre Reformer - PR 3.10 Pre Re
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3.11. Pump - PUMP 3.11 Pump - PUMP
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3.12. Solid Oxide Fuel Cell - SOFC
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3.14 Cooling Tower - TOWER 3.14. Co
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3.14. Cooling Tower - TOWER tower d
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3.14. Cooling Tower - TOWER The air
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3.15. Expansion valve - VA/VB possi
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4. SYSTEM DESCRIPTION 8 SPG 10 20 1
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4. SYSTEM DESCRIPTION Pre reformer
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4. SYSTEM DESCRIPTION which increas
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4. SYSTEM DESCRIPTION 4.3 Absorptio
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4. SYSTEM DESCRIPTION 4.3.3 Pumping
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4. SYSTEM DESCRIPTION The temperatu
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4. SYSTEM DESCRIPTION 4.5 Absorptio
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4. SYSTEM DESCRIPTION 4.6 Cooling T
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4. SYSTEM DESCRIPTION (below 100
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4. SYSTEM DESCRIPTION as: Ẇ AC =
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4. SYSTEM DESCRIPTION 4.8 Verificat
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4. SYSTEM DESCRIPTION SOFC net effi
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C H A P T E R 5 SIMULATION AND RESU
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5.1. Basic absorption cooling Figur
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5.1. Basic absorption cooling geous
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5.1.3 Changing evaporator temperatu
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5.1. Basic absorption cooling as de
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5.2. System configurations Red repr
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5.2. System configurations Dual Hea
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5.2. System configurations in a hot
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5.3. Partial optimization of standa
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Anode recycling (α SPG1 ) 5.3. Par
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5.4. Sensitivity Analysis ηsys,el,
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5.4. Sensitivity Analysis the press
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5.4. Sensitivity Analysis 1. The x-
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5.5 Total optimization of system 5.
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5.5. Total optimization of system i
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5.5. Total optimization of system e
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C H A P T E R 6 CASES AND ECONOMICS
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6.2. High humidity climate BBC Home
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6.2. High humidity climate Figure 6
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6.3. Low humidity climate Figure 6.
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6.4. Economics 6.4 Economics When t
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C H A P T E R 7 DISCUSSION In this
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7.1.1 Accuracy and sensitivity 7.1.
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7.2. Economical considerations Furt
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7.2.3 Distributed Generation (DG) D
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7.2. Economical considerations to 6
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7.2. Economical considerations As m
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C H A P T E R 8 CONCLUSION System c
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For the APU segment a SOFC-ABS syst
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C H A P T E R 9 FURTHER WORK Some i
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BIBLIOGRAPHY [1] Acfshop.dk: http:/
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Bibliography [24] Nordea invest: ht
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Appendices 187
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A. MARKET INVESTIGATION A.1 Market
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A. MARKET INVESTIGATION No cost for
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Absorpton unit (free waste heat) Pr
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A. MARKET INVESTIGATION A.3 CHP app
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Absorption Refrigerator RGE 400 fro
Page 226 and 227: Sensitivity analysis The effect on
Page 228 and 229: A. MARKET INVESTIGATION A.4 DG appe
Page 230 and 231: From the "CHP in the Hotel and Casi
Page 232 and 233: Hotel with 230 rooms and 18000 m^2
Page 234 and 235: SOFC + Water Heating (no ABS), Cool
Page 236 and 237: 16000 Pay Back Time: Entire System
Page 238 and 239: SOFC + Water Heating (no ABS), Cool
Page 240 and 241: Hot climate SOFC + ABS + HW vs pure
Page 242 and 243: Assumptions SOFC price = 2650kr/kW
Page 244 and 245: Hot climate Increase (Delta NPV_10)
Page 246 and 247: Prices of absorption cooling units
Page 248 and 249: 1'000'000 900'000 800'000 143'600 7
Page 250 and 251: A. MARKET INVESTIGATION A.6 Gas and
Page 252 and 253: Retail electricity prices Exchange
Page 254 and 255: B. DIAGRAMS AND PLOTS B.1 GAX diagr
Page 256 and 257: B. DIAGRAMS AND PLOTS B.3 Closed ad
Page 258 and 259: B. DIAGRAMS AND PLOTS B.4.2 p-T dia
Page 260 and 261: C. EES Efficiencies SOFC η inver t
Page 262 and 263: C. EES ∆ p;GGHE X 1;c = −1 [kPa
Page 264 and 265: C. EES ˙Q loss;Bur n = 0 [kW ] ˙Q
Page 266 and 267: C. EES SOFC ∆ T ;SOFC ;av = 30 [C
Page 268 and 269: C. EES C.2 Results - Standard param
Page 270 and 271: C. EES 244 DES2 h;o = 42 DES2 i = 7
Page 272 and 273: C. EES SOFC ano;i = 5 SOFC ano;o =
Page 274 and 275: C. EES Point T i p i ṁ i qu i h i
Page 278 and 279: C. EES ∆ T ;min;W GHE X 3;w;i = 1
Page 280 and 281: C. EES ˙Q tr ans;W GHE X 3 = 2,752
Page 282 and 283: C. EES Point T i p i ṁ i qu i h i
Page 284 and 285: C. EES C.4 Results - Uncertainty pr
Page 286 and 287: C. EES ∆T ;min;W GHE X 3;w;i = 15
Page 288 and 289: C. EES ∆p;TOW ER1;air ;dr y = 0,1
Page 290 and 291: C. EES ∆p;GGHE X 1;c = −1 ±
Page 292 and 293: C. EES C.4.4 ∆p for absorption su
Page 294 and 295: C. EES C.4.5 ˙Qloss for absorption
Page 297 and 298: A P P E N D I X D OTHER D.1 Explana
Page 299 and 300: D.3. Water consumption Hence it is
Page 301 and 302: A P P E N D I X E OPTIMIZATION GRAP
Page 303 and 304: E.1. Simulations and Results E.1.2
Page 305 and 306: E.1. Simulations and Results Figure
Page 307 and 308: E.1. Simulations and Results Figure
Page 309: E.2. Cases E.2 Cases E.2.1 Extreme
Page 312 and 313: SEG Scandinavian Energy Group Aps.
Page 320 and 321: 8 SPG 1 10 1-α GGHEX1 9 α 7 GGHEX
Page 322: 1 8 GGHEX1 CH4, in Air, in 21 2 11
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