Ludwig’s Applied Process Design for Chemical and Petrochemical Plants Volume 3. Fourth Edition A. Kayode Coker AMSTERDAM(cid:129)BOSTON(cid:129)HEIDELBERG(cid:129)LONDON(cid:129)NEWYORK(cid:129)OXFORD(cid:129)PARIS SANDIEGO(cid:129)SANFRANCISCO(cid:129)SINGAPORE(cid:129)SYDNEY(cid:129)TOKYO GulfProfessionalPublishingisanimprintofElsevier GulfProfessionalPublishing isanimprint ofElsevier 225WymanStreet,Waltham,MA02451,USA TheBoulevard, LangfordLane,Kidlington,Oxford,OX51GB,UK Copyright ©2015Elsevier Inc.Allrightsreserved. Nopartofthispublication maybereproducedor transmitted inanyformor byanymeans,electronicormechanical, including photocopying,recording,or anyinformationstorage andretrieval system,without permissioninwritingfrom thepublisher. 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Tothefullestextentof thelaw,neither thePublishernor theauthors,contributors, oreditors, assumeanyliabilityforanyinjury and/ordamagetopersons orproperty asamatterof productsliability, negligenceorotherwise, orfromanyuseor operationof anymethods,products,instructions, orideascontained inthematerialherein. ISBN:978-0-7506-8524-5 British LibraryCataloguingin PublicationData Acataloguerecordfor thisbookisavailablefrom theBritishLibrary LibraryofCongress CataloginginPublication Data Acatalogrecordforthisbookisavailablefrom theLibraryofCongress ForinformationonallGulfProfessional publications visit ourwebsiteathttp://store.elsevier.com/ TypesetbyTNQBooksandJournals www.tnq.co.in Printedandboundin UnitedStates ofAmerica Lastdigitisthe printnumber:10 9 8 7 6 5 4 3 2 To honor God in all things and to perform everything solely for the glory of God “In the Light of Truth” by Abd-ru-shin Dedication In memory of Ernest E. Ludwig (A great chemical engineer) and In loving memory of my parents Mr. Gabriel Shodipo Coker and Mrs. Esther Modupe Ajibike Coker To my sons, Akintunde and Ebunoluwa To my wife, Victoria Omolara Coker Love and thanks Crystal images (c) Office Masaru Emoto, LLC Foreword ErnestLudwig’sthree-volume“AppliedProcessDesignfor Industrial College, gives him deep insights into both the Chemical and Petrochemical Plants” is one of the classic fundamentalscienceofprocessdesignandtheneedsofthe texts of chemical engineering. It is known for its blend of students who grapple with its concepts. His industrial practical, scientifically-based design methods and real- experience, including his current role as engineering coor- worlddetailsofequipmentandprocesses,andithasbeena dinatoratSaudiAramcoShellRefineryCompany,together trusted resource for a generation of process engineers. with his consulting work, have given him a broad under- TheworldofplantdesignhasmovedonsinceLudwig’s standingofthereal-worldaspectsofprocessdesignandthe first edition in the 1960s, and he authored two further requirementsofitspractitioners.Thefourtheditionreflects editions to keep the material fresh and current. With his this balanced perspective, and it provides a resource of passing, it has fallen to A. Kayode Coker to handle the great value for readers at every stage of their engineering fourth edition. Dr. Coker brings a great breadth of experi- career. I heartily recommend it to you. encetothisundertaking,bothfromacademiaandindustry, and this uniquely equips him to take on the task. His aca- Alan Rossiter, PhD, PE demic experience, including a period as Chairman of the President, Rossiter & Associates Chemical & Process Engineering Department at Jubail Bellaire, Texas xi Preface to the Fourth Edition This complete revision of Applied Process Design for Chapter16,“ProcessIntegration(PI)”isanewchapter. Chemical and Petrochemical Plants, Volume III, builds The chapter reviews PI in heat exchanger networks, uponthelateErnestE.Ludwig’sclassictexttoenhanceits involving a systematic and oriented approach to heating, use as a chemical engineering design manual of methods cooling and power generation to process design, and opti- and proven fundamentals with supplemental mechanical mization that exploits the interaction between different and related data, nomographs and charts. Significantly units,exchangersandutilitiesinordertoemployresources expanded and thoroughly updated, this fourth edition effectively and minimize costs. The Excel spreadsheet contains new topics that will assist the engineer in exam- program from Ian C. Kemp’s text [21] has been used to ining and analyzing problems and finding design methods determine pinch temperature, cold and hot pinch temper- and mechanical specifications to secure the proper atures, hot and cold composite curves, grand composite mechanical hardware to accomplish a process objective. curve, hot and cold utility requirements. The program fur- This latest edition includes improved techniques and ther produces graphical outputs of pinch temperatures, hot fundamentaldesignmethodologiestoguidetheengineerin and cold utility requirements at varying DT . min designingprocessequipment,suchasheatexchangertypes, Chapter 17, “Refrigeration Systems,” has been compressors, and applying chemical processes to the improvedwithadditionaldataandnewsystemsdesignsfor properly detailed hardware. Like its predecessor, this edi- light hydrocarbon refrigeration. The chapter introduces the tioncontinuestopresentupdatedinformationforachieving Carnot refrigeration cycle and its performance, mechanical optimum operational and process conditions and to avoid refrigeration, types ofrefrigeration systems and a glossary. problemscausedbyinadequatesizingandlackofinternally Chapter 18, “Compression Equipment,” has been gen- detailed hardware. The various derived and proven equa- erally updated with equations for the design of com- tionshavebeenemployedinactualplantequipmentdesign, pressors, and it introduces other compressor types, such as processcontrolandoperator’strainingandtheyaresomeof the oil flooded screw compressor and integrally geared themostindispensableavailabletobothinexperiencedand compressors. The chapter reviews compressor trouble- experienced engineers alike. shooting and applies Hysys simulation software on a case This book further provides both fundamental theories study. whereapplicableanddirectsapplicationofthesetheoriesto Chapter 19, “Reciprocating Compression Surge applied equations essential in the design effort. This Drums,” presents several new techniques, as well as addi- approach in presenting design information serves well for tional detailed examples. The chapter provides preliminary troubleshooting heat exchangers, compressors equipment, designmethodsandprovidesthereaderwithreferencesfor and in executing system performance analysis. the most effective design approach. Further, the chapter Chapter 15, “Heat Transfer”, has been thoroughly reviews evaluation of the surge capacity and pulsation revised and updated, and now includes several important frequenciesofthesystem,compressor,anddischargesurge designtechniquesfordifficultcondensingsituationsandfor drums and discharge header in order to comprehend the the application of thermosiphon reboilers, designs of air- performance of the compressor. coolers,plateheatexchangers,doublepipeheatexchanger, Chapter20,“MechanicalDrivers,”hasbeenupdatedto heat tracer requirements for pipelines and heat loss from include the latest code and standards of the National insulated pipelines, batch heating and cooling of fluids, Electrical Manufacturer’s Association and information on troubleshootingofheatexchangersandcasestudiesofheat new energy-efficient motors. The chapter describes the exchangersfailures.Thechapterprovidesadetailedreview commonly used, general-purpose, alternating current offoulinginheatexchangersandsolutionsinreducingthis motors and mechanical drive turbines that are used in the phenomenon.Computerprogramshavebeendevelopedfor chemical and petrochemical industries. The chapter pro- the design/rating of these exchanger types and Microsoft vides National Fire Codes for hazardous locations, and Excelspreadsheetshavebeendevelopedtodealwithbatch articles that recognize certain subjects that are pertinent to heating and cooling of fluids. the process engineer. xiii xiv Preface to the Fourth Edition Chapter 21, “Industrial and Laboratory Reactors e available. All the above can be accessed from the Chemical Reaction Hazard and Process Integration of Elsevier companion website: http://booksite.elsevier.com/ Reactors,” is a new chapter that reviews various reactor 9780750685245 types and their advantages and disadvantages with respect Iassumethatthereaderisanundergraduateorgraduate to their individual applications and control. The chapter student in chemical or process engineering, or a chemical/ considers the design of a packed bed reactor by applying process, or other related engineer, having a sound knowl- POLYMATH software in its design. Reviews of agitator edge of the fundamentals of the profession. With this types pertinent to various reaction systems are considered, assumption, I illustrate the techniques of design and asarecatalystsandcatalyticprocesses.Detailedanalysisof mechanical details necessary for the construction of pro- chemical reaction hazards, hazard and operability (Hazop) cesses. The aim of the process engineer is to ensure that studies of a batch process, hazard analysis (Hazan) and results of his or her process calculations for equipment are others such as Process Hazard Analysis (PHA), Failure specified in terms of something that can be economically Mode Effect Analysis (FMEA) and Fault Tree Analysis constructed or selected from special designs or manu- (FTA) are reviewed. A case study of a runaway reaction facturers. This edition follows the format of previous edi- incident at T2 Laboratories, Jacksonville, Florida, USA is tions, and the concept is stressed to a reasonable degree in presented.ReactionSystemScreeningToolsforclassifying the various chapters. runaway chemical reactions, hazards of pyrophoric reac- Thetechniquesofappliedchemicalplantprocessdesign tions and heat integration of reactors are described. continuetoimproveasthescienceofchemicalengineering Chapter22,“MetallurgyeCorrosion,”isanewchapter developsnewandbetterinterpretationsofthefundamentals that describes factors affecting the selection of materials, of chemistry, physics, metallurgy, mechanical engineering and reviews Stress Corrosion Cracking (SCC),providing a and polymer/plastics science. Accordingly, this fourth case study of a pressure vessel failure at NDK manu- edition presents additional reliable design methods based facturingcompanyinBelvidere,Illinois,USA.Thechapter on sound experimental data, proven techniques developed describes corrosion types with illustrations, factors affect- by companies and individuals and groups considered ing the rate of corrosion and control. Finally, corrosion competent in their subjects and which are supported by monitoring and common mistakes in chemical processing pertinent data. In many chemical and petrochemical pro- plants are considered. cesses,thedesignerwillfinddesigntechniquesadaptableto 75to80%ofhis/herrequirements.Thus,anefforthasbeen made to place this book in a position of utilization some- Software/Programs/Excel Spreadsheets/ where between a handbook and an applied teaching text. Charts The present work is considered suitable to provide a ExcelTM spreadsheet programs as worked examples, and practical guide to chemical process design for under- developedcomputerprograms(AbsoftFortranTM)thatuse graduate and graduate students in chemical engineering, the Microsoft Runtime Windows Environment (MRWE) practicing process engineers and chemical or process are new additions to the fourth edition in various sections engineers working in process development. The text can of the chapters. These programs are provided in execut- readily be used, if a general course in plant design is able format, and Appendix I provides an illustration of available to fill in the broader factors associated with their use. overall plant layout and planning. Incorporated is Hysys simulation design software to Toaccesstheadditionalmaterialaccompanyingthisbook, performcasestudiesandsomeworkedexamplesinthetext. pleasevisit:http://booksite.elsevier.com/9780750685245 A program on Conversion Tables developed by Onthiscompanion website thereare manyusefulExcel Mr. Ahmed Mutuwa, formerly from SASREF Co., is spreadsheets,appendices,examplesandsoftware. Biography A. Kayode Coker, Ph.D., is an engineering coordinator at Engineering, all from Aston University, Birmingham, UK Saudi Aramco Shell Refinery Company in Jubail, Saudi andaTeachers’CertificateinEducationattheUniversityof Arabia, and was Chairman of Chemical & Process Engi- London, UK. He has directed and conducted short courses neering Department at Jubail Industrial College, and is a in both the UK and for SABIC industries in Saudi Arabia. consultant for AKC Technology in England. He has been His articles have been published in several international bothacharteredscientistandacharteredchemicalengineer journals, he is an author of four books in chemical engi- formorethan 30years. HeisaFellow oftheInstitution of neering and a contributor to the encyclopedia of Chemical Chemical Engineers, UK, (C.Eng., CSci, FIChemE). He is Processing and Design, vol. 61. He was named as one of alsoaseniormemberoftheAmericanInstituteofChemical the International Biographical Centre (Headquarters in Engineers (MAIChE). He holds a B.Sc. honors degree in Cambridge, UK) as LEADING ENGINEERS of the World Chemical Engineering, a Master of Science degree in 2008.Also,heisamemberofInternationalWho’sWhoof ProcessAnalysisandDevelopment,andPh.D.inChemical ProfessionalsTM and Madison’s Who’s Who in the US. xv Acknowledgments This final project of Ludwig’s three-volume texts is a cul B. Cutlip for granting permission to use the POLYMATH mination of four years of research, collating relevant and software. recent materials from organizations, institutions, companies Many organizations, institutions and companies such as and publishers. The three-volume texts took twelve years to Gas Processors Supplier Associations (GPSA), USA, complete, and soliciting for proofreaders has also been an American Institute of Chemical Engineers (AIChE), The important step in the editorial process. Emulating the Institution of Chemical Engineers (IChemE), Absoft incredible work of the late Ernest E. Ludwig is a formidable Corporation© USA, Chemical Engineering magazine by task, and without the help of various experts in their field of Access Intelligence, USA , Hydrocarbon Processing, specializations and organizations, this project would have Chemical Safety & Hazard Investigation Board (CSB), been impossible to achieve. have readily given permission for the use of materials, and My mentor, the late Dr. Clive Mumford, had provided their release for publication. I greatly acknowledge and constructive criticisms and inspiration in earlier works of express my deepest gratitude to these organizations. the three-volume text for which I am deeply grateful. His I have been privileged to meet with wonderful indi views on various aspects in the earlier volumes and his viduals such as Tim Calk and Phil Carmical, former editors attention to intricate details are greatly appreciated. of Gulf Publishing Company and Elsevier respectively. Phil Sincere appreciation and thanks to Mr. Dale Gulley and first suggested Ludwig’s classic work over twelve years Mr. Manish Shah for their critical reviews and providing ago and defended my proposals in the presence of invaluable comments and suggestion for the various aspects Elsevier’s management to revise the three volumes of of Chapter 15. In particular, Mr. Shah also gave permission Ludwig. It has been an eventful and formidable task and I to include his article “Good Practice for Heat Exchanger thank you for your trust and encouragement. To Tim, I am Selection and Design” in Appendix M of the text. Many grateful for your friendship and help since my first book thanks to Professors John R. Thome for providing figures some nineteen years ago. relating to boiling and evaporation in Chapter 15, Gratitude to the students of Chemical Engineering Mahmoud El-Halwagi, Robin Smith and Daniel R. Lewin Technology major during my tenure as an instructor and as for granting permission to incorporate exercises and departmental chairman at Jubail Industrial College, Saudi examples from their texts in Chapter 16 and Professor Arabia. It has indeed been a privilege to have enriched the Toyin Ashiru for providing figures for Chapter 22. lives of these individuals in chemical engineering and to Chapter 16, a new chapter on process integration, have learned from them also. involved the participation of many experts, namely: I also wish to express my sincere thanks to the Elsevier Drs. Gavin Towler, Alan Rossiter and Uday V. Shenoy. I team: Jonathan Simpson, Naomi Robertson, Pauline would like to record my appreciation and gratitude to these Wilkinson, Fiona Geraghty, and Cari Owen, and the pro renowned people for their expert knowledge and help in duction staff for their patience and professionalism in the providing suggestions and comments in the text. This production of this final volume. chapter is greatly enhanced by comments and suggestions Finally, provided by these individuals and the review of case studies Bow down in humility before the Greatness of God, carried out by Dr. Alan Rossiter. whose Love is never ending, and who sends us his help at Dr. James P. Burelbach has provided an invaluable help all times. He alone is Life and the Power and the Glory in reviewing aspects of Chapter 21 relating to two-phase forever and ever. flow in reactors, incorporating the new methodology and sizing equations, for which I am deeply grateful. Also, A. Kayode Coker I would like to express my gratitude to Professor Micheal xvii Chapter 15 Heat Transfer Theescalatingcostofenergyinrecentyearshasresultedin introduced through the shell-side, and viscous liquids, for increased attention being given to conservation and effi- whichthepressuredropforflowthroughthetubesishigh, cient energy management. Other types of technology, for are introduced on the shell-side. example, pinch technology (Chapter 16) have been Generally, shell and tube exchanger types are non- employedintheenergyintegrationofprocessplantsandof compact exchangers, and the heat-transfer area per unit heat exchangers, in particular. This has resulted in volume ranges from 15 to 30ft2/ft3 (50e100m2/m3). improved plant performance and reduced operation costs. Therefore, they require a considerable amount of space, Heat transfer is perhaps the most important, as well as the supportstructure,capitalandinstallationcosts.Asaresult, most applied, process inrefining, gas processing, chemical they are often replaced with compact heat exchangers andpetrochemicalplants.Theeconomicsofplantoperation (e.g.plateexchangers,spiralplateheatexchangers)inthose are controlled by the effectiveness of the use and recovery applications where the operating conditions permit it. For of heat or cold (refrigeration). The service functions of the equivalent cost of the shell and tube exchangers, steam,power,refrigeration supplyandthelikearedictated compact heat exchangers provide high effectiveness and by how these services or utilities are used within the pro- are more efficient in heat (energy) transfer. cess to produce an efficient conversion and recovery of Although many excellent references [5,22,36,40,61,70, heat. 74,82,286,287,288and289]areavailable,andthetechnical Shell and tube heat exchanger types are widely literature contains important details of good heat transfer employed,andgenerally,theyarecustomdesignedforany designprinciplesandgoodapproachestoequipmentdesign, capacity and operating conditions, including from high anunknownfactorstillentersintoeverydesign.Thisfactor vacuum to ultra-high pressures of over 15,000psig isthescaleorfoulingfromthefluidsbeingprocessedandis (100MPa),fromcryogenicconditionstohightemperatures wholly dependent on the fluids, their temperature and ve- of w2000(cid:1)F (1100(cid:1)C), and any temperature and pressure locity,andtoacertainextent,thenatureoftheheat-transfer differencesbetweenthefluids,limitedonlybythematerials tube surface and its chemical composition. Due to the un- ofconstruction.Theycanbedesignedforspecialoperating known nature of the assumptions, these fouling factors can conditions: heavy fouling, highly viscous fluids, erosion, markedly affect the design of heat transfer equipment. We corrosion, toxicity, multicomponent mixtures, vibration, shallreviewthisaspect,andotherssuchasthepressuredrop, etc.Theyarethemostversatileexchangertypesmadefrom laterinthechapterasthesecouldhavedeleteriouseffectson a variety of metals (e.g. Admiralty, copper, alloys, monel, the performance of heat exchangers resulting in high oper- nickel, aluminum, carbon/stainless steel, etc.) and non- ating costs of millions of US dollars per annum. Conven- metal materials (e.g. graphite, glass and Teflon) and in tional practiceispresented here; however,Kernand Seaton various sizes from 1ft2 (0.1m2) to 106ft2 (105m2). They [71] have proposed thermal concepts that may offer new are extensively employed as process heat exchangers in approaches. petroleumrefining,petrochemicalsandchemicalindustries; Themostpopularandreliablesoftwarepackagesforthe as boiler feed water heaters, phase change heatexchangers design or rating of shell and tube heat exchangers are: (e.g. reboilers and condensers), evaporators, steam gener- l BJAC: USA based company ators and oil coolers in power plants, in some air condi- l HEI: Heat Exchange Institute, USA tioning and refrigeration applications; in waste heat l HTRI: Heat Transfer Research Institute (www.HTRI. recovery applications with heat recovery from liquids and net), USA condensing fluids and in environmental control. The tube- l HFTS: Heat Transfer Fluid Flow Services (HTFS pro- side is for corrosive, heavy fouling, scaling, hazardous, gramsarepartofAspenTechnology’sAspenEngineer- high temperature and pressure, and more expensive fluids, ing Suite and Honeywell’s UniSim Design Suite) whiletheshell-sideisforcleaner,moreviscous,lowerflow rate, evaporating and condensing fluids. When a gas or Generally, the design methods and equations used by vapor is used as an exchanger fluid, it is typically these companies and institutes are proprietary and Ludwig’sAppliedProcessDesignforChemicalandPetrochemicalPlants.http://dx.doi.org/10.1016/B978-0-7506-8524-5.00015-X 1 Copyright©2015ElsevierInc.Allrightsreserved. 2 Ludwig’sAppliedProcessDesignforChemicalandPetrochemicalPlants therefore, are not provided in the open literature. Tinker [290,291] published the first detailed stream analysis streams. The shell type has a significant effect on the flow configuration and thermal performance of the heat ex- method for predicting shell and tube heat transfer co- efficientsandpressuredrop,andhismodelhasbeenusedas changers. Shell and tube heat exchangers use baffles to transport heat to or from tube-side process fluids by the basis for the proprietary computer methods developed by these institutes and companies. Tinker’s method is directing the shell-side fluid flow. The increased structural difficult and tedious to apply in manual calculations. support that baffles provide is essential to the tube’s sta- However,ithasbeensimplifiedbyDevore[292,293],using bility, as they prevent the tube from sagging due to its structuralweightandalsominimizevibrationduetocyclic standard tolerances for commercial exchangers and only a limited number of baffle cuts. Devore has presented no- flowforces.Bafflesimproveheattransferattheexpenseof increased pressure drop. Tubesheets seal the ends of the mographs that facilitate the application of the method in manual calculations. Mueller [294] has further simplified tubes, ensuring separation between the two streams. Devore’smethodandprovidesanillustrativeexample.Bell The process engineer needs to understand the termi- nology of the heat transfer equipment manufacturers in [295,296] has provided a semi-analytical method based on order to properly design, specify, evaluate bids and to researchprogramscarriedoutonshellandtubeexchangers check drawings of this equipment. at the University of Delaware, where his results accounted The shell and tube exchanger consists of four major for the major bypass and leakage streams. parts: This text provides the designer with a basis for manually checking the expected equations, coefficients, l Front header e this is where the fluid enters the tube- etc., enabling him/her to accept or reject the computed side of the exchanger. It is sometimes referred to as results.Thetextprovidesabasisforcompletelydesigning the stationary header. theprocessheattransferequipment(exceptforspecialized l Rear header e this is where the tube-side fluid leaves items such as fired heaters, steam boiler/generators, theexchanger,orwhereitisreturnedtothefrontheader cryogenic equipment and some other process re- in exchangers with multiple tube-side passes. quirements), and sizing (for mechanical dimensions/ l Tubebundleethiscomprisesofthetubes,tubesheets, details, but not for pressure or strength) the mechanical bafflesandtierodsetc.whichholdthebundletogether. hardware thatwill accomplish this function. Additionally, l Shell e this contains the tube bundle. the text presents research studies on fouling in shell and ThestandardsoftheTubularExchangerManufacturers tube heat exchangers, and, in particular, in pre-heat trains in the refining of crude oil. Detailed reviews are supplied Association(TEMA)[107]istheonlyassemblyofunfired mechanical standards, including selected design details with examples, employing developed Microsoft Excel programs for determining heat transfer coefficients in and Recommended Good Practice and it is used by all reputable exchanger manufacturers in the US and many jacketed, agitated vessels and the time required for batch manufacturers in other countries who supply US plant processing involving isothermal and non-isothermal equipment.Thesestandardsaredeveloped,assembledand heating and cooling conditions with coils and external updatedbyatechnicalcommitteeofassociationmembers. heat exchangers, as experienced in various chemical pro- The standards are updated and reissued every tenyears. cess industries. They do not designate or recommend thermal design methods or practices for specific process applications, but TYPES OF HEAT TRANSFER EQUIPMENT they do outline basic heat transfer fundamentals, and list suggested fouling factors for a wide variety of fluid or TERMINOLOGY process services. The chemical process industries (CPIs) require heat ex- ThethreeclassesofmechanicalstandardsinTEMAare changerstotransferheatfromahotstreamtoacoldstream. Classes R, C and B, and they represent varying degrees of This heat transfer equipment must meet various codes/ mechanical details for the designated process plant appli- standardstodealwiththethermal,mechanical,operational, cations’severity.Thescopeofstandards/codedesignations installation and maintenance demands of the process. The [TEMA e 2007, 9th Ed] for mechanical design and optimal heat exchanger design should minimize operating fabrication are: costs and maximize product output. Shell and tube heat RCBeIncludesallclassesofconstruction/designand exchangers(Figures15-1BeD)consistofabundleoftubes areidentical;shelldiameter(inside)notexceeding100in. inside a cylindrical shell. One fluid (the tube-side fluid) (2540mm); product of nominal diameter, in. (mm); and flows inside the tubes while the other fluid (the shell-side design pressure of 100,000psi (17.5 (cid:3) 106kPa); and fluid)flowsthroughtheshellandaroundthetubes.Heatis maximum design pressure of 3,000psi (20684kPa). The transferredacrossthetubewallseparatingthehotandcold intention of these parameters is to limit the maximum
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