Industrial Boilers and Heat Recovery Steam Generators Design, Applications, and Calculations V. Ganapathy ABCO Industries Abilene, Texas, U.S.A. Marcel Dekker, Inc. New York Basel • TM ISBN:0-8247-0814-8 Thisbookisprintedonacid-freepaper. Headquarters MarcelDekker,Inc. 270MadisonAvenue,NewYork,NY10016 tel:212-696-9000;fax:212-685-4540 EasternHemisphereDistribution MarcelDekker,AG Hutgasse4,Postfach812,CH-4001Basel,Switzerland tel:41-61-260-6300;fax:41-61-260-6333 WorldWideWeb http:==www.dekker.com Thepublisheroffersdiscountsonthisbookwhenorderedinbulkquantities.Formoreinfor- mation,writetoSpecialSales=ProfessionalMarketingattheheadquartersaddressabove. Copyright #2003by Marcel Dekker,Inc.All Rights Reserved. Neither this book nor any part may be reproduced or transmitted in any form or by any means,electronicormechanical,includingphotocopying,microfilming,andrecording,or by any information storage and retrieval system, without permission in writing from the publisher. Current printing(last digit): 10 9 8 7 6 5 4 3 2 1 PRINTED INTHE UNITEDSTATES OFAMERICA To all professionals involved in steam generation and energy conservation. Preface Theroleofboilersandheatrecoverysteamgenerators(HRSGs)intheindustrial economy has been profound. Boilers form the backbone of power plants, cogeneration systems, and combined cycle plants. There are few process plants, refineries, chemical plants, or electric utilities that do not have a steam plant. Steam is the most convenient working fluid for industrial processing, heating, chilling,andpowergenerationapplications.Fossilfuelswillcontinueto be the dominant energy providers for years to come. This book is about steam generators, HRSGs, and related systems. There are several excellent books on steam generation and boilers, and each has been successful in emphasizing certain aspects of boilers and related topics such as mechanical design details, metallurgy, corrosion, constructional aspects, main- tenance, or operational issues. This book is aimed at providing a different perspective on steam generators and is biased toward thermal and process design aspects of package boilers and HRSGs. (The terms ‘‘waste heat boiler’’ and‘‘HRSG’’areusedinthesamecontext.)Myemphasisonthermalengineering aspects of steam generators reinforced by hundreds of worked-out real-life examples pertaining to boilers, HRSGs, and related systems will be of interest toengineersinvolvedinabroadfieldofsteamgenerator–relatedactivitiessuchas consulting, design, performance evaluation, and operation. DuringthelastthreedecadesIhavehadtheopportunitytodesignhundreds ofpackageboilersandseveralhundredwasteheatboilersthatareinoperationin theU.S.andabroad.Basedonmyexperienceinreviewingnumerousspecifica- tionsofboilersandHRSGs,Ifeelthatconsultants,plantengineers,contractors, anddecisionmakersinvolvedinplanninganddevelopingsteamplantsoftendo notappreciatesomeoftheimportantandsubtleaspectsofdesignandperfor- manceofsteamgenerators. (cid:1)Manyengineersstillfeelthatbyraisingtheexitgastemperatureinboilers witheconomizers,onecanavoidaciddewpointconcerns.Itisthefeedwater temperature—notthegastemperature—thatdeterminesthetubewall temperature(andhencethecorrosionpotential). (cid:1)Softenedwaterissometimessuggestedforattemperationforsteamtempera- turecontrol,eventhoughitwilladdsolidstosteamthatcancauseproblems suchasdepositionofsolidsinsuperheatersandsteamturbines. (cid:1)Tooperatesteamplantsmoreefficiently,plantengineersshouldbeableto understandandappreciatethepartloadcharacteristicsofboilersandHRSGs. HoweverwhilespecifyingboilersandHRSGs,oftenonlytheperformanceat 100%loadisstressed. (cid:1)HRSGsteamgenerationandtemperatureprofilescannotbearbitrarilyarrived at,aspinchandapproachpointsdeterminethis.Forexample,Ihaveseen severalspecificationscallfora300 (cid:2)Fexitgastemperaturefromasingle pressureunfiredgasturbineHRSGgeneratingsaturatedsteamat600psig usingfeedwateratabout230 (cid:2)F.Asimpleanalysisrevealsthatonlyabout 340–350(cid:2)Fisthermodynamicallyfeasible. (cid:1)SupplementaryfiringingasturbineHRSGsisanefficientwaytogenerate steamcomparedwithsteamgenerationinapackagedboiler.Thebookexplains whythisisso,withexamplesinChapters1and8.Cogenerationengineerscan make use of this information to minimize fuel costs in their plants. (cid:1) Afewwasteheatboilerspecificationsprovidethefluegasflowinvolumetric units instead of mass units, leading to confusion. Lack of information on molecular weight or gas pressure can lead to incorrect evaluation of density andhencethemassflow.Also,volumeoffluegasisoftengivenincfm(cubic feet per minute) and one is not sure whether it is acfm (actual cubic feet per minute)orscfm(standardcubicfeetperminute).Thedifferenceinmassflow can be significant depending on the basis. (cid:1) Althoughfluegasanalysisaffectsgasspecificheat,heattransfer,boilerduty, and temperature profiles, these data are often not given in specifications for waste heat boilers. Forexample,theratioofspecificheats offluegases from combustion of natural gas and fuel oil is about 3.5%, which is not insignif- icant.Thisisduetothe18%volumeofwatervaporinnaturalgasproductsof combustion versus 12% in fuel oil combustion products. (cid:1)AfewconsultantsselectboilersandHRSGsbasedonsurfacearea,although itcanvarysignificantlybasedontubegeometryorfinconfiguration.With finnedtubes,ascanbeseenfromseveralexamplesinthisbook,thevariation insurfaceareascouldbeintherangeof200–300%forthesameduty. (cid:1)Operatingcostduetofuelconsumptionorgaspressuredropacrossheating surfacesisoftenignoredbymanyconsultantsintheirevaluationandonly initialcostsarecomparedwhilepurchasingsteamgeneratorsorHRSGs, resultinginapoorselectionfortheenduser.Afewplantsarenowrealizing thattheitemsofsteamplantequipmenttheypurchasedyearsagobasedonlow initialcostsaredrainingtheircashreservesthroughcostlyfuelandelectricity billsandhencearescramblingtoimprovetheirdesignandperformance. (cid:1)Manyengineersarenotawareofrecentdevelopmentsinoil-andgas-fired packagedboilersandarestillspecifyingboilersusingrefractorylinedfurnace wallsandfloors! (cid:1)Plantengineersoftenassumethataboilerdesignedfor600psig,forexample, canbeoperatedat200psigandatthesamecapacity.Thepotentialproblems associatedwithsignificantchangesinsteampressureandspecificvolumein boileroperationarediscussedinChapters1and3. (cid:1) Condensing exchangersarebeing considered in boilers andHRSGsnotonly forimprovementinefficiencybutalsotorecoverandrecyclethewaterinthe flue gases, which is a precious commodity in some places. (cid:1) Emission control methods such as flue gas recirculation increase the mass flowof flue gases through the boiler; yet standard boilers are being selected thatcanbeexpensivetooperateintermsoffanpowerconsumption.Manyare not aware of the advantages of custom-designed boilers, which can cost less to own and operate. (cid:1) Afewsteamplantprofessionalsdonotappreciatetherelationbetweenboiler efficienciesandhigherandlowerheatingvalues,andthusspecifyvaluesthat are either impossible to accomplish or too inefficient. As a result of this ‘‘knowledge=information gap’’ in process engineering aspects of boilers or HRSG, the end user may need to settle for a product with substandardperformanceandhighcosts.Thisbookelaboratesonvariousdesign and performance aspects of steam generators and heat recovery boilers so that anyone involved with them will become more informed and ask the right questions during the early stages of development of any steam plant project. This will give the best chance of selecting the steam generator with the right design and parameters. Even a tiny improvement in design, efficiency, operating costs, or performance goes a long way in easing the ‘‘energy crunch.’’ The first four chapters describe some of the recent trends in power generation systems, a few aspects of steam generator and HRSG design and performance, and the impact of emissions on boilers in general. The remaining chaptersdealwithcalculationsthatshouldbeofinteresttosteamplantengineers. IauthoredtheSteamPlantCalculationsManual(MarcelDekker,Inc.)several yearsagoandhadbeenthinkingofaddingmoreexamplestothisworkforquite sometime.Thisbookbuildsonthatfoundation. Chapter1isanintroductorydiscussionofpowerplantsanddescribessome oftherecentdevelopmentsinpowersystemssuchasthesupercriticalRankine cycle,theKalinacycle,theChengcycle,andtheintegratedcoalgasificationand combinedcycle(IGCC)plantthatisfastbecomingareality. Thesecondchapterdescribesheatrecoverysystemsinvariousindustries. TheroleoftheHRSGinsulfurrecoveryplants,sulfuricacidplants,gasturbine plants,hydrogenplants,andincinerationsystemsiselaborated. Chapter3,onsteamgenerators,describesthelatesttrendsincustom- designedpackageboilersandthelimitationsofstandardboilersdeveloped decadesago.Emissionregulationshaveresultedinchangesinboileroperating parameterssuchashigherexcessairandFGRratesthatimpactboilerperfor- mancesignificantly.Itshouldbenotedthattherecanbeseveraldesignsfora boilersimplybecausetheemissionlevelsaredifferent,althoughthesteam parametersmaybeidentical.IfanSCRsystemisrequired,itnecessitatesthe additionofagasbypasssystem,addingtothecostandcomplexityofboiler design.Theseareexplainedthroughquantitativeandpracticalexamples. Chapter4,onemissions,describesthevariousmethodsusedinboilersand HRSGstolimitNOxandCOandhowtheirdesignsareimpacted.Forexample, theHRSGevaporatormayhavetobesplituptoaccommodatetheselective catalyticreduction(SCR)system;gasbypassdampersmayhavetobeusedin packagedsteamgeneratorstoachievetheoptimalgastemperatureatthecatalyst forNOxconversionatvariousloads.Fluegasrecirculation(FGR)addstothefan powerconsumptionifthestandardboilerisnotredesigned.Itmayalsoaffectthe boilerefficiencythroughhigherexitgastemperatureduetothelargermassflow offluegases.Othermethodsforemissioncontrol,suchassteaminjectionand burnermodifications,arealsoaddressed. Chapters4–8,whichpresentcalculationspertainingtovariousaspectsof boilersandHRSGsandtheirauxiliaries,elaborateonthesecondeditionofthe SteamPlantCalculationsbook.Severalexampleshavealsobeenadded.Chapter 5dealswithcalculationssuchasconversionofmasstovolumetricflowrates, energyutilizationfromboilerblowdown,generalASMEcodecalculations,and lifecyclecostingmethods.(ASMEhasbeenupdatingtheallowablestressvalues forseveralboilermaterialsandoneshouldusethelatestdata.)Alsoprovidedare ABMAandASMEguidelinesonboilerwater,forevaluatingtheblowdownor estimatingthesteamfordeaeration.Lifecyclecostingisexplainedthroughafew examples. Chapter6dealswithcombustioncalculations,boilerefficiency,and emission conversion calculations. Simplified combustion calculation procedures suchastheMMBtumethodareexplained.Oftenboilerefficiencyiscitedona HigherHeatingValuebasis,whileafewengineersusetheLowerHeatingValue basis.Therelationbetweenthetwoisillustrated.TheASMEPTC4.1methodof calculatingheatlossesforestimatingboilerefficiencyiselaborated,andsimpli- fiedequationsforboilerefficiencyarepresented.Examplesillustratetherelation betweenoxygeninturbineexhaustgasesandfuelinput.Correlationsfordew pointofvariousacidvaporsaregivenwithexamples. Chapter7explainsboilercirculationcalculationsinbothfiretubeandwater tubeboilers.Fluidflowinblowoffandblowdownlines,whichinvolvetwo-phase flowcalculations,canbeestimatedbyusingtheproceduresshown.Theproblem offlowinstabilityinboilingcircuitsisexplained,alongwithmeasuresto minimizethisconcern,suchasuseoforificesattheinlettothetubes. Calculationsinvolvingorificesandsafetyvalvesshouldalsobeofinterestto plantengineers. Chapter8onheattransferhasover65examplesofsizing,off-design performance calculations pertaining to boilers, superheaters, economizers, HRSGs, and air heaters. Tube wall temperature calculations and calculations with finned tubes for insulation performance will help engineers understand the design concepts better and even question the boiler supplier. HRSG temperature profiles are also explained, with methods described for evaluating off-design HRSG performance. The last chapter deals with pumps, fans, and turbines and examples show the effect of a few important variables on their performance. The impact of air density on boiler fan operation is illustrated, and the effect of elevation and temperature on flow and head are explained. With flue gas recirculation being used in almost all boilers, the effect of density on the volume is important to understand.Theeffectof inletairtemperatureonBraytoncycleefficiencyisalso explained and plant engineers will appreciate the need for inlet air-cooling in summer months in large gas turbine plants. The efficiency of cogeneration is explained, as are also power output calculations using steam turbines. Asimplequizisgivenattheendofthebook.Itspurposeistorecapitulate important aspects of boiler and HRSG performance discussed in the book. In sum, the book will be a valuable addition to anyone involved in steam plants,cogenerationsystems,orcombinedcycleplants.Manyexamplesarebased on my personal experience and hence, the conclusions drawn do not reflect the viewsofanyorganization.Itispossible,duetolackof informationonmypartor totherapiddevelopmentsinsteamplantengineeringandtechnology,thatIhave expressedsomeviewsthatmaynotbecurrentormaybeagainstthegrain;ifso,I expressmyregrets.Iwouldappreciatereadersbringingthesetomyattention.The calculations have been checked to the best of my ability; however if there are errors,Iapologizeandwouldappreciateyourfeedback.Itismyferventhopethat this book will be the constant companion of professionals involved in the steam generation industry. I would like to thank ABCO Industries for allowing me to reproduce severalofthedrawingsandphotographsofboilersandHRSGs.Ialsothankother sources that have provided me with information on recent developments on various technologies. V. Ganapathy