01878oam 2200445M 450 991071573260332120191123063214.6(CKB)5470000002514751(OCoLC)1065845168(OCoLC)995470000002514751(EXLCZ)99547000000251475120070221d1852 ua 0engurcn|||||||||txtrdacontentcrdamediacrrdacarrierClaim against branch Mint -- New Orleans. Letter from the Secretary of the Treasury, transmitting letters in reference to an account against the branch Mint at New Orleans. July 7, 1852. Referred to the Committee of Ways and Means, and ordered to be printed[Washington, D.C.] :[publisher not identified],1852.1 online resource (2 pages)Ex. doc. / 32nd Congress, 1st session. House ;no. 118[United States congressional serial set ] ;[serial no. 648]Batch processed record: Metadata reviewed, not verified. Some fields updated by batch processes.FDLP item number not assigned.ClaimsPavementsRoadsDesign and constructionLegislative materials.lcgftClaims.Pavements.RoadsDesign and construction.United States.Department of the Treasury.WYUWYUOCLCOOCLCQBOOK9910715732603321Claim against branch Mint -- New Orleans. Letter from the Secretary of the Treasury, transmitting letters in reference to an account against the branch Mint at New Orleans. July 7, 1852. Referred to the Committee of Ways and Means, and ordered to be printed3510237UNINA05159nam 2200685 450 991082526550332120200903223051.01-118-98445-51-118-98447-11-118-98446-3(CKB)3710000000187049(EBL)1734308(SSID)ssj0001340227(PQKBManifestationID)11866476(PQKBTitleCode)TC0001340227(PQKBWorkID)11355930(PQKB)10316425(Au-PeEL)EBL1734308(CaPaEBR)ebr10892213(CaONFJC)MIL627086(OCoLC)883892083(MiAaPQ)EBC1734308(EXLCZ)99371000000018704920140719h20142014 uy 0engur|n|---|||||txtccrCO2 biofixation by microalgae modeling, estimation and control /Sihem Tebbani [and four others]London, [England] ;Hoboken, New Jersey :ISTE :Wiley,2014.©20141 online resource (191 p.)Focus : Bioengineering and Health Science Series,2051-249XDescription based upon print version of record.1-84821-598-3 Includes bibliographical references and index.Cover; Title Page; Copyright; Contents ; Introduction; Chapter 1. Microalgae; 1.1. Definition; 1.2. Characteristics; 1.3. Uses of microalgae; 1.3.1. Nutrition; 1.3.2. Pharmaceuticals; 1.3.3. Cosmetics; 1.3.4. Energy; 1.3.5. Environmental field; 1.4. Microalgae cultivation systems; 1.4.1. Open systems; 1.4.2. Closed systems: photobioreactors; 1.5. Factors affecting algae cultivation; 1.5.1. Light; 1.5.2. Temperature; 1.5.3. pH; 1.5.4. Nutrients; 1.5.5. Medium salinity; 1.5.6. Agitation; 1.5.7. Gas-liquid mass transfer; 1.6. Conclusion; Chapter 2. Co2 Biofixation2.1. Selection of microalgae species2.1.1. Photosynthetic activity; 2.1.2. CO2 concentrating mechanism "CCM"; 2.1.3. Choice of the microalgae species; 2.2. Optimization of the photobioreactor design; 2.3. Conclusion; Chapter 3. Bioprocess Modeling; 3.1. Operating modes; 3.1.1. Batch mode; 3.1.2. Fed-batch mode; 3.1.3. Continuous mode; 3.2. Growth rate modeling; 3.2.1. General models; 3.2.2. Droop's model; 3.2.3. Models dealing with light effect; 3.2.4. Model dealing with carbon effect; 3.2.5. Models of the simultaneous influence of several parameters; 3.2.6. Choice of growth rate model3.3. Mass balance models3.4. Model parameter identification; 3.5. Example: Chlorella vulgaris culture; 3.5.1. Experimental set-up; 3.5.2. Modeling; 3.5.3. Parametric identification; 3.6. Conclusion; Chapter 4. Estimation of Biomass Concentration; 4.1. Generalities on estimation; 4.2. State of the art; 4.3. Kalman filter; 4.3.1. Principle; 4.3.2. Discrete Kalman filter; 4.3.3. Discrete extended Kalman filter; 4.3.4. Kalman filter settings; 4.3.5. Example; 4.4. Asymptotic observer; 4.4.1. Principle; 4.4.2. Example; 4.5. Interval observer; 4.5.1. Principle; 4.5.2. Example4.6. Experimental validation on Chlorella vulgaris culture4.7. Conclusion; Chapter 5. Bioprocess Control; 5.1. Determination of optimal operating conditions; 5.1.1. Optimal operating conditions; 5.1.2. Optimal set-point; 5.2. Generalities on control; 5.3. State of the art; 5.4. Generic Model Control; 5.4.1. Principle; 5.4.2. Advantages and disadvantages; 5.4.3. Example; 5.5. Input/output linearizing control; 5.5.1. Principle; 5.5.2. Advantages and disadvantages; 5.5.3. Example; 5.6. Nonlinear model predictive control; 5.6.1. Principle; 5.6.2. Nonlinear Model Predictive Control5.6.3. Advantages and disadvantages5.6.4. Example; 5.7. Application to Chlorella vulgaris cultures; 5.7.1. GMC law performance; 5.7.2. Performance of the predictive control law; 5.8. Conclusion; Conclusion; Bibliography; IndexDue to the consequences of globa l warming and significant greenhouse gas emissions, several ideas have been studied to reduce these emissions or to suggest solut ions for pollutant remov al. The most promising ideas are reduced consumption, waste recovery and waste treatment by biological systems. In this latter category, studies have demonstrated that the use of microalgae is a very promising solution for the biofixation of carbon dioxide. In fact, these micro-organisms are able to offset high levels of CO2 thanks to photosynthesis. Microalgae are also used in various fields (food industrFocus bioengineering and health science series.MicroalgaeBiotechnologyCarbon dioxideMetabolismCarbon sequestrationMicroalgaeBiotechnology.Carbon dioxideMetabolism.Carbon sequestration.579.8Tebbani Sihem1652271Tebbani SihemMiAaPQMiAaPQMiAaPQBOOK9910825265503321CO2 biofixation by microalgae4002819UNINA