Internformat: Industrial process plants

Industrial process plants: global optimization of utility systems

Removing the barriers to the Global Optimization of Plant Utility Systems by providing practical tools and techniques to deal with these unique challenges is the purpose of this book. The operating cost of a typical Plant Utility System of a typical Industrial Production Process Plant is enormous -...

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1. Verfasser:	Nath, Ravi (VerfasserIn)
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	Berlin ; Boston De Gruyter [2024]
Schriftenreihe:	De Gruyter STEM
Schlagworte:	Apparate und Anlagen Prozeßoptimierung Technische Chemie Verfahrenstechnik TECHNOLOGY & ENGINEERING / Systems Engineering Energietechnische Anlage Ganzzahlige lineare Optimierung Betriebsverhalten Wärmeversorgung Maschine Gemischt-ganzzahlige Optimierung Industrieanlage Kältetechnik Aufsatzsammlung
Online-Zugang:	DE-1043 DE-1046 DE-858 DE-859 DE-860 DE-703 DE-739 URL des Erstveröffentlichers
Zusammenfassung:	Removing the barriers to the Global Optimization of Plant Utility Systems by providing practical tools and techniques to deal with these unique challenges is the purpose of this book. The operating cost of a typical Plant Utility System of a typical Industrial Production Process Plant is enormous - often in tens if not hundreds of millions of dollars per Annum. With so much money at stake, one would expect that heroic optimization efforts would be made to reduce the operating cost, however such is usually not the case. One reason for this complacency is that Plant Utility Systems are usually "cost centers" in Process Plants and their operating cost is prorated amongst the various Production Units, so it suffers from what is at times referred to as "the tragedy of the commons". Another reason for this complacency is that the Plant Utility System structure is significantly different than that of other Production Units, as for flexibility and safety reasons it has a large spare capacity to meet increased utility demand during startups, shutdowns, and emergencies. The existence of a spare equipment necessitates optimization of discrete decisions, whereby traditional optimization techniques do not readily apply. Part of the problem is that the traditional engineering curriculum primarily emphasizes only one of the many optimization methods, called Non-Linear Programming (NLP). Although NLP can address large classes of optimization problems, it has fairly stringent requirements that all describing relationships (or functions) be continuous and have continuous derivatives. Additionally, in general, NLP only guarantees a local but not the global optimum. Another optimization method is particularly well suited for modeling Plant Utility Systems is called Mixed Integer Linear Programming (MILP). And unlike NLP, MILP methods can guarantee global optimum, which is very reassuring. MILP, however, does impose linearity requirements but as discussed in this book there are techniques to overcome this limitation
Beschreibung:	Description based on online resource; title from PDF title page (publisher's Web site, viewed 06. Mrz 2024)
Beschreibung:	1 Online-Ressource (XVI, 241 Seiten)
ISBN:	9783111020679
DOI:	10.1515/9783111020679

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520			\|a Removing the barriers to the Global Optimization of Plant Utility Systems by providing practical tools and techniques to deal with these unique challenges is the purpose of this book. The operating cost of a typical Plant Utility System of a typical Industrial Production Process Plant is enormous - often in tens if not hundreds of millions of dollars per Annum. With so much money at stake, one would expect that heroic optimization efforts would be made to reduce the operating cost, however such is usually not the case. One reason for this complacency is that Plant Utility Systems are usually "cost centers" in Process Plants and their operating cost is prorated amongst the various Production Units, so it suffers from what is at times referred to as "the tragedy of the commons".
520			\|a Another reason for this complacency is that the Plant Utility System structure is significantly different than that of other Production Units, as for flexibility and safety reasons it has a large spare capacity to meet increased utility demand during startups, shutdowns, and emergencies. The existence of a spare equipment necessitates optimization of discrete decisions, whereby traditional optimization techniques do not readily apply. Part of the problem is that the traditional engineering curriculum primarily emphasizes only one of the many optimization methods, called Non-Linear Programming (NLP). Although NLP can address large classes of optimization problems, it has fairly stringent requirements that all describing relationships (or functions) be continuous and have continuous derivatives. Additionally, in general, NLP only guarantees a local but not the global optimum.
520			\|a Another optimization method is particularly well suited for modeling Plant Utility Systems is called Mixed Integer Linear Programming (MILP). And unlike NLP, MILP methods can guarantee global optimum, which is very reassuring. MILP, however, does impose linearity requirements but as discussed in this book there are techniques to overcome this limitation
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spelling	Nath, Ravi Verfasser (DE-588)1328151875 aut Industrial process plants global optimization of utility systems Ravi Nath Berlin ; Boston De Gruyter [2024] © 2024 1 Online-Ressource (XVI, 241 Seiten) txt rdacontent c rdamedia cr rdacarrier De Gruyter STEM Description based on online resource; title from PDF title page (publisher's Web site, viewed 06. Mrz 2024) Removing the barriers to the Global Optimization of Plant Utility Systems by providing practical tools and techniques to deal with these unique challenges is the purpose of this book. The operating cost of a typical Plant Utility System of a typical Industrial Production Process Plant is enormous - often in tens if not hundreds of millions of dollars per Annum. With so much money at stake, one would expect that heroic optimization efforts would be made to reduce the operating cost, however such is usually not the case. One reason for this complacency is that Plant Utility Systems are usually "cost centers" in Process Plants and their operating cost is prorated amongst the various Production Units, so it suffers from what is at times referred to as "the tragedy of the commons". Another reason for this complacency is that the Plant Utility System structure is significantly different than that of other Production Units, as for flexibility and safety reasons it has a large spare capacity to meet increased utility demand during startups, shutdowns, and emergencies. The existence of a spare equipment necessitates optimization of discrete decisions, whereby traditional optimization techniques do not readily apply. Part of the problem is that the traditional engineering curriculum primarily emphasizes only one of the many optimization methods, called Non-Linear Programming (NLP). Although NLP can address large classes of optimization problems, it has fairly stringent requirements that all describing relationships (or functions) be continuous and have continuous derivatives. Additionally, in general, NLP only guarantees a local but not the global optimum. Another optimization method is particularly well suited for modeling Plant Utility Systems is called Mixed Integer Linear Programming (MILP). And unlike NLP, MILP methods can guarantee global optimum, which is very reassuring. MILP, however, does impose linearity requirements but as discussed in this book there are techniques to overcome this limitation In English Apparate und Anlagen Prozeßoptimierung Technische Chemie Verfahrenstechnik TECHNOLOGY & ENGINEERING / Systems Engineering bisacsh Energietechnische Anlage (DE-588)4196531-0 gnd rswk-swf Ganzzahlige lineare Optimierung (DE-588)4155949-6 gnd rswk-swf Betriebsverhalten (DE-588)4138142-7 gnd rswk-swf Wärmeversorgung (DE-588)4064214-8 gnd rswk-swf Maschine (DE-588)4037786-6 gnd rswk-swf Gemischt-ganzzahlige Optimierung (DE-588)4156566-6 gnd rswk-swf Industrieanlage (DE-588)4026801-9 gnd rswk-swf Kältetechnik (DE-588)4029166-2 gnd rswk-swf (DE-588)4143413-4 Aufsatzsammlung gnd-content Betriebsverhalten (DE-588)4138142-7 s Energietechnische Anlage (DE-588)4196531-0 s Ganzzahlige lineare Optimierung (DE-588)4155949-6 s Gemischt-ganzzahlige Optimierung (DE-588)4156566-6 s Industrieanlage (DE-588)4026801-9 s Kältetechnik (DE-588)4029166-2 s Maschine (DE-588)4037786-6 s Wärmeversorgung (DE-588)4064214-8 s DE-604 Erscheint auch als Druck-Ausgabe 9783111015316 https://doi.org/10.1515/9783111020679 Verlag URL des Erstveröffentlichers Volltext
spellingShingle	Nath, Ravi Industrial process plants global optimization of utility systems Apparate und Anlagen Prozeßoptimierung Technische Chemie Verfahrenstechnik TECHNOLOGY & ENGINEERING / Systems Engineering bisacsh Energietechnische Anlage (DE-588)4196531-0 gnd Ganzzahlige lineare Optimierung (DE-588)4155949-6 gnd Betriebsverhalten (DE-588)4138142-7 gnd Wärmeversorgung (DE-588)4064214-8 gnd Maschine (DE-588)4037786-6 gnd Gemischt-ganzzahlige Optimierung (DE-588)4156566-6 gnd Industrieanlage (DE-588)4026801-9 gnd Kältetechnik (DE-588)4029166-2 gnd
subject_GND	(DE-588)4196531-0 (DE-588)4155949-6 (DE-588)4138142-7 (DE-588)4064214-8 (DE-588)4037786-6 (DE-588)4156566-6 (DE-588)4026801-9 (DE-588)4029166-2 (DE-588)4143413-4
title	Industrial process plants global optimization of utility systems
title_auth	Industrial process plants global optimization of utility systems
title_exact_search	Industrial process plants global optimization of utility systems
title_exact_search_txtP	Industrial Process Plants Global Optimization of Utility Systems
title_full	Industrial process plants global optimization of utility systems Ravi Nath
title_fullStr	Industrial process plants global optimization of utility systems Ravi Nath
title_full_unstemmed	Industrial process plants global optimization of utility systems Ravi Nath
title_short	Industrial process plants
title_sort	industrial process plants global optimization of utility systems
title_sub	global optimization of utility systems
topic	Apparate und Anlagen Prozeßoptimierung Technische Chemie Verfahrenstechnik TECHNOLOGY & ENGINEERING / Systems Engineering bisacsh Energietechnische Anlage (DE-588)4196531-0 gnd Ganzzahlige lineare Optimierung (DE-588)4155949-6 gnd Betriebsverhalten (DE-588)4138142-7 gnd Wärmeversorgung (DE-588)4064214-8 gnd Maschine (DE-588)4037786-6 gnd Gemischt-ganzzahlige Optimierung (DE-588)4156566-6 gnd Industrieanlage (DE-588)4026801-9 gnd Kältetechnik (DE-588)4029166-2 gnd
topic_facet	Apparate und Anlagen Prozeßoptimierung Technische Chemie Verfahrenstechnik TECHNOLOGY & ENGINEERING / Systems Engineering Energietechnische Anlage Ganzzahlige lineare Optimierung Betriebsverhalten Wärmeversorgung Maschine Gemischt-ganzzahlige Optimierung Industrieanlage Kältetechnik Aufsatzsammlung
url	https://doi.org/10.1515/9783111020679
work_keys_str_mv	AT nathravi industrialprocessplantsglobaloptimizationofutilitysystems

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