ebook img

Waste to Renewable Biohydrogen, Volume 2: Numerical Modelling and Sustainability Assessment PDF

272 Pages·2022·5.724 MB·English
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview Waste to Renewable Biohydrogen, Volume 2: Numerical Modelling and Sustainability Assessment

Waste to Renewable Biohydrogen Numerical Modelling and Sustainability Assessment This page intentionally left blank Waste to Renewable Biohydrogen Numerical Modelling and Sustainability Assessment Volume 2 Edited by Quanguo Zhang Director of the Key Laboratory of New Materials and Facilities for Rural Renewable Energy of Ministry of Agriculture and Rural Affairs of China, Henan Agricultural University, PR China; Dean of the Institute of AgriculturalEngineering,HUANGHEScienceandTechnologyUniversity, PR China Chao He Associate Professor and Director of the Department of Energy and Environmental Engineering, College of Mechanical and Electrical Engineering, Henan Agricultural University, China Jingzheng Ren Associate Professor, Department of Industrial and Systems Engineering, The Hong Kong Polytechnic University, Hong Kong SAR, China Michael Evan Goodsite Director, Institute for Sustainability, Energy and Resources, Division of Research and Innovation, The University of Adelaide AcademicPressisanimprintofElsevier 125LondonWall,LondonEC2Y5AS,UnitedKingdom 525BStreet,Suite1650,SanDiego,CA92101,UnitedStates 50HampshireStreet,5thFloor,Cambridge,MA02139,UnitedStates TheBoulevard,LangfordLane,Kidlington,OxfordOX51GB,UnitedKingdom Copyright(cid:1)2023ElsevierInc.Allrightsreserved. Nopartofthispublicationmaybereproducedortransmittedinanyformorbyanymeans, electronicormechanical,includingphotocopying,recording,oranyinformationstorage andretrievalsystem,withoutpermissioninwritingfromthepublisher.Detailsonhowto seekpermission,furtherinformationaboutthePublisher’spermissionspoliciesandour arrangementswithorganizationssuchastheCopyrightClearanceCenterandtheCopyright LicensingAgency,canbefoundatourwebsite:www.elsevier.com/permissions. Thisbookandtheindividualcontributionscontainedinitareprotectedundercopyrightby thePublisher(otherthanasmaybenotedherein). Notices Knowledgeandbestpracticeinthisfieldareconstantlychanging.Asnewresearchand experiencebroadenourunderstanding,changesinresearchmethods,professionalprac- tices,ormedicaltreatmentmaybecomenecessary. Practitionersandresearchersmustalwaysrelyontheirownexperienceandknowledgein evaluatingandusinganyinformation,methods,compounds,orexperimentsdescribed herein.Inusingsuchinformationormethodstheyshouldbemindfuloftheirownsafety andthesafetyofothers,includingpartiesforwhomtheyhaveaprofessionalresponsibility. Tothefullestextentofthelaw,neitherthePublishernortheauthors,contributors,or editors,assumeanyliabilityforanyinjuryand/ordamagetopersonsorpropertyasamatter ofproductsliability,negligenceorotherwise,orfromanyuseoroperationofanymethods, products,instructions,orideascontainedinthematerialherein. ISBN:978-0-12-821675-0 ForinformationonallAcademicPresspublicationsvisitourwebsiteat https://www.elsevier.com/books-and-journals Publisher:CharlotteCockle AcquisitionsEditor:PeterAdamson EditorialProjectManager:RupinderHeron ProductionProjectManager:PaulPrasadChandramohan CoverDesigner:MatthewLimbert TypesetbyTNQTechnologies Contents Contributors xi 1. Modeling of biohydrogen production by dark fermentation WeiWang,ShengyongLiuandYamengLi 1.1. Introduction 1 1.2. Mathematicalmodelingofbiohydrogenproductionbydark fermentation 2 1.2.1 Gompertzmodel 3 1.2.2 LuedekingePiretmodel 4 1.2.3 Monodmodel 4 1.2.4 HanandLevenspielmodel 5 1.2.5 Anaerobicdigestionmodeln.1 5 1.3. Conclusion 10 References 11 2. Numerical simulation and application of photofermentative bio-hydrogen production system YiWangandChunyaoQing 2.1. Introduction 15 2.2. NumericalsimulationofbiomassPBHPS flowfield 17 2.2.1 Photofermentativepolyphasicflowhydrogen productionsystem 17 2.2.2 Controlequation 19 2.2.3 Boundaryandinitialconditions 21 2.2.4 Meshingandsolutionmethod 22 2.2.5 Calculationconditionsandrelatedassumptions 23 2.2.6 Numericalsimulationresultsandanalysisofflowfield 24 2.2.7 Conclusion 36 2.3. Numericalsimulationoftemperaturefield ofPBHPS 37 2.3.1 Temperaturefieldanalysismethodofphotosynthetic biologicalhydrogenproductionsystem 38 2.3.2 Analysisbasisfortemperature fieldofbiomass multiphaseflowphotosynthetichydrogen productionSystem 40 2.3.3 Temperaturefieldnumericalsimulationofthebiomass multiphaseflowPBHPSbyFluent 43 v vi Contents 2.3.4 Regulationoftemperaturefielddistributionby parameteradjustment 54 2.3.5 Conclusion 61 References 61 3. CFD simulation, design, and optimization for biohydrogen systems SenYaoandJia-TaoDang 3.1. Introduction 65 3.2. Existingresearchandprospects 66 3.2.1 Biologicalhydrogenproductiontechnology 67 3.2.2 Advancesinflowfieldsimulationofbiohydrogen reactor 69 3.3. CFDsimulationmethod 71 3.3.1 Physical model 71 3.3.2 Mathematicalmodels 72 3.3.3 Solvingmethod 78 3.3.4 Summaryandintroductionofcommoncommercial software 80 3.4. Biologicalhydrogenproductionforreactoroptimization 81 3.4.1 Optimizationofbiophotolysiswatertohydrogen reactor 82 3.4.2 Optimizationofdarkfermentationhydrogen productionreactor 82 3.4.3 Optimizationofphotofermentationhydrogen productionreactor 85 3.4.4 Optimizationofadarkelightcofermentationhydrogen productionreactor 86 3.5. Summaryofthischapter 88 References 88 4. Artificial neural networks for modeling of biohydrogen production systems LiangLiu,YapingZheng andXinxinLiu 4.1. Introduction 93 4.2. Thebasicprinciplesofartificialneuralnetworks 94 4.3. Applicationofartificialneuralnetworks onmodeling of biohydrogenproduction 97 4.4. Conclusion 102 References 103 Contents vii 5. The biomass-based hydrogen production yield prediction model based on PSO-BPNN YiMan,YushaHu,JingzhengRenandChaoHe 5.1. Introduction 107 5.2. Research dataandmethods 110 5.2.1 Methodologicaloverviewofbiomasshydrogen productionprocesses 110 5.2.2 Constructionofahydrogenyieldpredictionmodel 111 5.2.3 Datacollection 112 5.2.4 Particleswarmoptimizationebackpropagationneural network algorithm 112 5.3. Resultsanddiscussion 117 5.3.1 Predictionresultsandanalysisofhydrogen productionyieldsfromasinglebiomasssubstrate 117 5.3.2 Predictionresultsandanalysisofhydrogen productionyieldsfromvariousbiomasssubstrates 118 5.4. Conclusion 120 References 120 6. Costebenefit analysis of waste-to-biohydrogen systems XiaoranMaandHonggeTao 6.1. Introduction 123 6.1.1 Hydrogenfrombiomass 123 6.1.2 Hydrogenfromwaste 124 6.2. Themethodsforproducing biohydrogenfromwaste 126 6.2.1 Darkfermentation 127 6.2.2 Photofermentation 128 6.2.3 Dark-photocofermentationwithbiologicalhydrogen production 129 6.3. Cost analysisofdifferentbiohydrogenproduction methods 129 6.3.1 Rawmaterialcost 130 6.3.2 Equipmentoperationcost 130 6.3.3 Casestudy 131 6.4. Environmentalbenefit analysisofwastebiomasshydrogen 132 6.4.1 Incomecausedby wastegas emissionreduction 133 6.4.2 Contributionrateofwasteemissionreduction 133 6.5. Economicbenefit analysisofwastebiomasshydrogen 136 6.5.1 Totalcostofcapital 137 6.5.2 Annualproductioncost 138 6.5.3 Annualprofitability 138 6.5.4 Sensitivityanalysis 139 References 139 viii Contents 7. Technoeconomic analysis of biohydrogen production from waste JianzhiYueandLiHuang 7.1. Introduction 143 7.2. Literaturereviews 144 7.2.1 Technicalandeconomicevaluationofbiohydrogen productionfromanaerobicfermentation 144 7.3. Methods 149 7.4. Casestudy 150 7.4.1 Solid-statefermentationcombinedwithdark fermentationtoproducehydrogen 150 7.4.2 Two-stepproductionofhydrogenandmethane 152 7.4.3 H productionby darkephotofermentation 153 2 7.4.4 Usingsugarmill wastewatertoproducehydrogen 155 7.4.5 Usingindustrialwastewatertoproducehydrogen 157 7.4.6 Twopromisingbiohydrogenproduction technologiesforlarge-scaleandcommercial production 160 7.4.7 Technicalandeconomicanalysisoftheproduction ofhydrogencombinedwiththermophilic fermentationandphotoheterotrophicfermentation 161 7.4.8 Technicalandeconomicanalysisofsupercritical water-reformingglyceroltoproducehydrogen 163 7.4.9 Theuseofwastewaterandagriculturalwaste to producehydrogen 164 7.4.10. Technicalandeconomicanalysisofhydrogen productioninCaliforniabiomassgasification orbiogasrestructuringtechnology 167 7.4.11. Technicalandeconomicanalysisofthesupplyof hydrogenfromwastewaterandwoodtomunicipal publictransport systems 169 7.5. Conclusionsandrecommendations 173 References 174 8. Lifecycleassessmentofwaste-to-biohydrogensystems XiaohuiPanandGuizhuanXu 8.1. Introductiontothelifecycleassessmentmethod 177 8.1.1 Overviewoflifecycleassessment 177 8.1.2 Lifecycleassessmentframework 178 8.2. Lifecycleassessmentmethods andsoftware 182 8.2.1 Lifecycleassessmentmethods 182 8.2.2 Analysissoftware 183 8.3. Progressofbiohydrogenlifecycleassessment 183 8.3.1 Researchstatus 183 8.3.2 Casestudies 187 Contents ix 8.4. Evaluationofbiohydrogenproductionbylifecycleanalysis 190 8.4.1 Evaluationoftheenergyperspective 190 8.4.2 Ecologicalperspective evaluation 191 8.5. Conclusions 191 References 193 9. Multicriteria sustainability ranking of biohydrogen systems HengWang 9.1. Introduction 195 9.2. Biohydrogenproductiontechnology 196 9.2.1 Thermochemicalhydrogenproductionfrombiomass 196 9.2.2 Hydrogenproductionfrombiomass 200 9.3. Principlesandmethods ofconstructing comprehensive evaluationindex system 201 9.3.1 Principlesofconstructingcomprehensiveevaluation indexsystem 201 9.3.2 Methodsofconstructingcomprehensiveevaluation indexsystem 202 9.4. Comprehensiveimpact analysisofbiomasshydrogen productiontechnology 203 9.4.1 Energyimpactanalysisofbiomasshydrogen productiontechnology 204 9.4.2 Economicimpactanalysisofbiomasshydrogen productiontechnology 205 9.4.3 Environmental impactanalysisofbiomasshydrogen productiontechnology 205 9.5. Multicriteria sustainabilityassessmentofbiohydrogen systems 206 9.6. Conclusion 207 References 207 10. Sustainable supply chain design for waste to biohydrogen ZhenfengWangandZhanwuWang 10.1. Introduction 211 10.2. Supplychain structureofwastetobiohydrogen 212 10.2.1 Structure compositionofsupplychain 212 10.2.2 Supplychainmodelofwastetobiohydrogen 213 10.3. Sustainablesupplychaindesignforhydrogenproduction fromwaste 214 10.3.1 Goalsofsustainablesupplychaindesign 214 10.3.2 Choosing sustainabilityassessmentcriteria 215 10.3.3 Sustainablesupplychaindesign 217

See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.