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200 1 $a*Solid-Phase Synthesis of Nitrogenous Heterocycles$fViktor Krch?ák
205   $aCham : Springer, 2017
210   $aIX$d170 p.$cill. ; 24 cm
215   $aPubblicazione in formato elettronico
410  1$1001SUN0123329$12001 $a*Topics in Heterocyclic Chemistry$v52$1210  $aCham$cSpringer.
620   $aCH$dCham$3SUNL001889
676   $a660$cIngegneria chimica e tecnologie connesse$v22
676   $a540$cChimica generale$v22
676   $a547$cChimica organica$v22
676   $a546$cChimica inorganica$v22
700  1$aKrch?ák$b, Viktor$3SUNV095153$0767221
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856 4 $uhttps://link.springer.com/book/10.1007%2F978-3-319-58616-8#toc
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950   $aUFFICIO DI BIBLIOTECA DEL DIPARTIMENTO DI SCIENZE E TECNOLOGIE AMBIENTALI BIOLOGICHE E FARMACEUTICHE$d17CONS      e-book                  2111        $e17BIB2111      173     20190927            
996   $aSolid-Phase Synthesis of Nitrogenous Heterocycles$91561819
997   $aUNICAMPANIA

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200 10$aTroubleshooting vacuum systems$b[electronic resource] $esteam turbine surface condensers and refinery vacuum towers /$fauthored by Norman P. Lieberman
210   $aSalem, Mass. $cScrivener Pub. ;$aHoboken, N.J. $cWiley$dc2012
215   $a1 online resource (282 p.)
300   $aIncludes index.
311   $a1-118-29034-8 
327   $aCover; Title Page; Copyright Page; Dedication; Contents; Preface; Introduction; Definition of Terms; Other Books by Author; 1 How Jets Work; 1.1 The Converging-Diverging Ejector; 1.2 Interaction of Steam Nozzle with Converging-Diverging Diffuser; 1.3 Compression Ratio; 1.4 Converging-Diverging Ejector; 1.5 Velocity Boost; 1.6 Surging; 1.7 Critical Discharge Pressure; 1.8 Observing the Conversion of Heat to Velocity; 1.9 Jet Discharge Pressure; 1.10 Reducing Primary-Jet Discharge Pressure; 1.11 Bypassing First Stage Ejectors; 2 Making Field Measurements; 2.1 Getting Started
327   $a2.2 How to Unscrew Steel Plugs2.3 Effect of Barometric Pressure on Indicated Vacuum; 2.4 Use of Piccolo; 2.5 Measuring Deep Vacuums using an Hg Manometer; 2.6 Measurement of a Deep Vacuum without Mercury; 2.7 Measuring Condensibles in Feed to First Stage Ejector; 2.8 Identifying Loss of Sonic Boost by Sound; 2.9 Identifying Air Leaks; 2.10 Air Leaks in Flanges; 2.11 Vacuum Measurement Units; 3 Tabulation of Vacuum System Malfunctions; 3.1 Tidal Flop in Delaware; 3.2 Critical Discharge Pressure; 3.3 Fouling in Final Condenser; 3.4 Reduction in Back Pressure; 3.5 Loss of LVGO Pan Level
327   $a3.6 Variations in Cooling Water Temperature3.7 Multi-Component Malfunctions; 3.8 Partial Tabulation of Vacuum System Malfunctions; 4 Effect of Water Partial Pressure on Jet Efficiency; 4.1 Vapor Pressure of Water Limits Vacuum; 4.2 Reminder about Water Partial Pressure; 4.3 Air Leaks in Steam Turbine Surface Condensers; 4.4 Variable Cooling Water Temperature; 4.5 Loss of Sonic Boost; 4.6 Relative Jet Efficiency; 4.7 Definition of ""Vacuum Breaking""; 4.8 Critical Discharge Pressure Exceeded; 5 Air Leaks; 5.1 Upper Explosive Limits; 5.2 How to Find Air Leaks; 5.3 Diffuser Air Leaks
327   $a5.4 Air Leaks on Vacuum Towers5.5 Air Leaks in Heater Transfer Lines; 5.6 Air Leaks - Turbine Mechanical Seal; 6 Sources and Disposal of Hydrocarbon Off-Gas; 6.1 Evolution of Cracked Gas; 6.2 Sources of Cracked Gas; 6.3 Cracked Gas Evolution from Boot; 6.4 Air Equivalent; 6.5 Overloading Vacuum Jets; 6.6 Excess Cracked Gas Flow; 6.7 Field Checking Gas Flow Meter in Vacuum Service; 6.8 Surging 3rd Stage Jet Bogs Down Primary Jet; 6.9 Exchanger Leaks Overloads Jets; 6.10 Poor Vacuum Tower Feed Stripping; 6.11 Level Connection Purges and Pump Mechanical Seal Gas
327   $a6.12 Effect of Heater Outlet Temperature6.13 Extracting H2S from Vacuum Tower Off-Gas Upstream of Ejectors; 6.14 Disposal of Seal Drum Off-Gas; 6.15 Fouling of Waste Gas Burner; 7 Motive Steam Conditions; 7.1 Effect of Wet Steam; 7.2 Water in Motive Steam; 7.3 The Tale of Weak Steam; 7.4 Internal Freezing of Steam Nozzle; 7.5 High Pressure, Superheated Motive Steam; 7.6 Effect of Moisture Content of Saturated Steam on Temperature; 7.7 Steam Pressure Affects Vacuum; 7.8 Effect of Superheated Steam; 8 Mechanical Defects of Ejectors; 8.1 Steam Nozzle Testing; 8.2 Other Mechanical Defects of Jets
327   $a8.3 Fouled Steam Nozzles
330   $a Vacuum systems are in wide spread use in the petrochemical plants, petroleum refineries and power generation plants. The existing texts on this subject are theoretical in nature and only deal with how the equipment functions when in good mechanical conditions, from the viewpoint of the equipment vendor.  In this much-anticipated volume, one of the most well-respected and prolific process engineers in the world takes on troubleshooting vacuum systems, and especially steam ejectors, an extremely complex and difficult subject that greatly effects the profitability of the majority of the world'
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200 10$aAdvanced statistical methods for astrophysical probes of cosmology $edoctoral thesis accepted by the Astrophysics Group of Imperial College London /$fMarisa Cristina March
205   $a1st ed. 2013.
210   $aNew York $cSpringer$d2013
215   $a1 online resource (191 p.)
225 1 $aSpringer theses : recognizing outstanding Ph.D. research,$x2190-5053
300   $aDescription based upon print version of record.
311   $a3-642-44454-7 
311   $a3-642-35059-3 
320   $aIncludes bibliographical references and index.
327   $aIntroduction -- Cosmology background -- Dark energy and apparent late time acceleration -- Supernovae Ia -- Statistical techniques -- Bayesian Doubt: Should we doubt the Cosmological Constant? -- Bayesian parameter inference for SNeIa data -- Robustness to Systematic Error for Future Dark Energy Probes -- Summary and Conclusions -- Index.
330   $aThis thesis explores advanced Bayesian statistical methods for extracting key information for cosmological model selection, parameter inference and forecasting from astrophysical observations. Bayesian model selection provides a measure of how good models in a set are relative to each other - but what if the best model is missing and not included in the set? Bayesian Doubt is an approach which addresses this problem and seeks to deliver an absolute rather than a relative measure of how good a model is.   Supernovae type Ia were the first astrophysical observations to indicate the late time acceleration of the Universe - this work presents a detailed Bayesian Hierarchical Model to infer the cosmological parameters (in particular dark energy) from observations of these supernovae type Ia.
410  0$aSpringer theses.
606   $aAstrophysics
606   $aCosmology
615  0$aAstrophysics.
615  0$aCosmology.
676   $a523.101
700   $aMarch$b Marisa Cristina$0858466
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