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Troubleshooting process plant control [[electronic resource] /] / Norman P. Lieberman
| Troubleshooting process plant control [[electronic resource] /] / Norman P. Lieberman |
| Autore | Lieberman Norman P |
| Pubbl/distr/stampa | Hoboken, N.J., : Wiley, c2009 |
| Descrizione fisica | 1 online resource (257 p.) |
| Disciplina | 665.5028/8 |
| Soggetto topico | Petroleum refineries - Maintenance and repair |
| ISBN |
1-118-21114-6
1-282-26781-7 9786612267819 0-470-43225-X 1-61583-659-4 0-470-43224-1 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Troubleshooting Process Plant Control; Contents; PREFACE; INTRODUCTION-A HISTORY OF POSITIVE FEEDBACK LOOPS; Chapter 1 Learning from Experience; Chapter 2 Process Control Parameter Measurement; Chapter 3 Dependent and Independent Variables; Chapter 4 Binary Distillation of Pure Components; Chapter 5 Distillation Tower Pressure Control; Chapter 6 Pressure Control in Multicomponent Systems; Chapter 7 Optimizing Fractionation Efficiency by Temperature Profile; Chapter 8 Analyzer Process Control; Chapter 9 Fired Heater Combustion Air Control; Chapter 10 Sizing Process Control Valves
Chapter 11 Control Valve Position on Instrument Air FailureChapter 12 Override and Split-Range Process Control; Chapter 13 Vacuum System Pressure Control; Chapter 14 Reciprocating Compressors; Chapter 15 Centrifugal Compressor Surge vs. Motor Over-Amping; Chapter 16 Controlling Centrifugal Pumps; Chapter 17 Steam Turbine Control; Chapter 18 Steam and Condensate Control; Chapter 19 Function of the Process Control Engineer; Chapter 20 Steam Quality and Moisture Content; Chapter 21 Level, Pressure, Flow, and Temperature Indication Methods Chapter 22 Alarm and Trip Design for Safe Plant OperationsChapter 23 Nonlinear Process Responses; ABOUT MY SEMINARS; FURTHER READINGS ON TROUBLESHOOTING PROCESS CONTROLS; THE NORM LIEBERMAN VIDEO LIBRARY OF TROUBLESHOOTING PROCESS OPERATIONS; INDEX |
| Record Nr. | UNINA-9910144393603321 |
Lieberman Norman P
|
||
| Hoboken, N.J., : Wiley, c2009 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Troubleshooting process plant control / / Norman P. Lieberman
| Troubleshooting process plant control / / Norman P. Lieberman |
| Autore | Lieberman Norman P |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Hoboken, N.J., : Wiley, c2009 |
| Descrizione fisica | 1 online resource (257 p.) |
| Disciplina | 665.5028/8 |
| Soggetto topico | Petroleum refineries - Maintenance and repair |
| ISBN |
1-118-21114-6
1-282-26781-7 9786612267819 0-470-43225-X 1-61583-659-4 0-470-43224-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Troubleshooting Process Plant Control; Contents; PREFACE; INTRODUCTION-A HISTORY OF POSITIVE FEEDBACK LOOPS; Chapter 1 Learning from Experience; Chapter 2 Process Control Parameter Measurement; Chapter 3 Dependent and Independent Variables; Chapter 4 Binary Distillation of Pure Components; Chapter 5 Distillation Tower Pressure Control; Chapter 6 Pressure Control in Multicomponent Systems; Chapter 7 Optimizing Fractionation Efficiency by Temperature Profile; Chapter 8 Analyzer Process Control; Chapter 9 Fired Heater Combustion Air Control; Chapter 10 Sizing Process Control Valves
Chapter 11 Control Valve Position on Instrument Air FailureChapter 12 Override and Split-Range Process Control; Chapter 13 Vacuum System Pressure Control; Chapter 14 Reciprocating Compressors; Chapter 15 Centrifugal Compressor Surge vs. Motor Over-Amping; Chapter 16 Controlling Centrifugal Pumps; Chapter 17 Steam Turbine Control; Chapter 18 Steam and Condensate Control; Chapter 19 Function of the Process Control Engineer; Chapter 20 Steam Quality and Moisture Content; Chapter 21 Level, Pressure, Flow, and Temperature Indication Methods Chapter 22 Alarm and Trip Design for Safe Plant OperationsChapter 23 Nonlinear Process Responses; ABOUT MY SEMINARS; FURTHER READINGS ON TROUBLESHOOTING PROCESS CONTROLS; THE NORM LIEBERMAN VIDEO LIBRARY OF TROUBLESHOOTING PROCESS OPERATIONS; INDEX |
| Record Nr. | UNINA-9910828253803321 |
|
Lieberman Norman P
|
||
| Hoboken, N.J., : Wiley, c2009 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Troubleshooting vacuum systems [[electronic resource] ] : steam turbine surface condensers and refinery vacuum towers / / authored by Norman P. Lieberman
| Troubleshooting vacuum systems [[electronic resource] ] : steam turbine surface condensers and refinery vacuum towers / / authored by Norman P. Lieberman |
| Autore | Lieberman Norman P |
| Pubbl/distr/stampa | Salem, Mass., : Scrivener Pub. |
| Descrizione fisica | 1 online resource (282 p.) |
| Disciplina |
621.5/50288
621.55 621.550288 |
| Soggetto topico | Vacuum technology |
| Soggetto genere / forma | Electronic books. |
| ISBN |
1-118-57096-0
1-299-18654-8 1-118-57120-7 1-118-57092-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover; 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
2.2 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 3.6 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 5.4 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 6.12 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 8.3 Fouled Steam Nozzles |
| Record Nr. | UNINA-9910141500403321 |
|
Lieberman Norman P
|
||
| Salem, Mass., : Scrivener Pub. | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Troubleshooting vacuum systems [[electronic resource] ] : steam turbine surface condensers and refinery vacuum towers / / authored by Norman P. Lieberman
| Troubleshooting vacuum systems [[electronic resource] ] : steam turbine surface condensers and refinery vacuum towers / / authored by Norman P. Lieberman |
| Autore | Lieberman Norman P |
| Pubbl/distr/stampa | Salem, Mass., : Scrivener Pub. |
| Descrizione fisica | 1 online resource (282 p.) |
| Disciplina |
621.5/50288
621.55 621.550288 |
| Soggetto topico | Vacuum technology |
| ISBN |
1-118-57096-0
1-299-18654-8 1-118-57120-7 1-118-57092-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover; 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
2.2 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 3.6 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 5.4 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 6.12 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 8.3 Fouled Steam Nozzles |
| Record Nr. | UNINA-9910830293403321 |
|
Lieberman Norman P
|
||
| Salem, Mass., : Scrivener Pub. | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Troubleshooting vacuum systems : steam turbine surface condensers and refinery vacuum towers / / authored by Norman P. Lieberman
| Troubleshooting vacuum systems : steam turbine surface condensers and refinery vacuum towers / / authored by Norman P. Lieberman |
| Autore | Lieberman Norman P |
| Pubbl/distr/stampa | Salem, Mass., : Scrivener Pub. |
| Descrizione fisica | 1 online resource (282 p.) |
| Disciplina | 621.5/50288 |
| Soggetto topico | Vacuum technology |
| ISBN |
1-118-57096-0
1-299-18654-8 1-118-57120-7 1-118-57092-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover; 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
2.2 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 3.6 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 5.4 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 6.12 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 8.3 Fouled Steam Nozzles |
| Record Nr. | UNINA-9910876749103321 |
|
Lieberman Norman P
|
||
| Salem, Mass., : Scrivener Pub. | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||