The extended resource task network: a framework for the combined scheduling of batch processes and CHP plants

Théry, Raphaële; Hétreux, Gilles; Agha, Mujtaba Hassan; Haït, Alain; Lann, J.M. Le

doi:10.1080/00207543.2010.545444

Cited by 15 publications

(6 citation statements)

References 11 publications

(10 reference statements)

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“…The proposed formulation is an improvement over the model of Song et al 9 for ethylene plant start-up based on RTN approach, which accounts for different types of cracking furnaces and 15 extended the RTN approach to integrate the production and utility system. In view of the aforementioned formulation, a continuous-time mixed integer linear programming (MILP) model was presented in this paper based on the global time point representation.…”

Section: Mathematical Formulationmentioning

confidence: 99%

Improved Resource-Task Network-Based Flare Minimization Model for Ethylene Plant Start-up: Rigorous Treatment of Cracking Furnace and High-Pressure Steam

Song

Qiu

Chen

2015

Ind. Eng. Chem. Res.

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Energy utilization and environment protection has received increasing attention over the last few decades. Therefore, flare minimization has become one of the main concerns for the ethylene industry. In this study, we present an improved flare minimization model for ethylene plant start-up, which accounts for different types of cracking furnaces and production/consumption of high-pressure steam. The resource-task network approach is used to depict the superstructure of the start-up process of an ethylene plant. On the basis of the superstructure, we develop a mathematic formulation, which, in this study, is a mixed-integer linear programming model. Five instances of an industrial case study with different start-up working medium and high-pressure steam inventories are used to demonstrate the efficacy of the proposed flare minimization model.

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Section: Mathematical Formulationmentioning

confidence: 99%

Improved Resource-Task Network-Based Flare Minimization Model for Ethylene Plant Start-up: Rigorous Treatment of Cracking Furnace and High-Pressure Steam

Song

Qiu

Chen

2015

Ind. Eng. Chem. Res.

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“…An ERTN model is an oriented flow graph composed of a reduced collection of semantic elements (7 types of nodes and 5 types of arcs), whose construction is based on a set of well established rules [10]. These elements make it possible to model the main characteristics of industrial processes such as material and utility flows, manufacturing procedures, resource constraints (unit topology, equipment capacity, fixed or dependent operating times, resource sharing, multimodal equipment, etc.).…”

Section: The Extended Resource Task Network (Ertn) Formalismmentioning

confidence: 99%

A modelling framework for energy system planning: Application to CHP plants participating in the electricity market

Mallier

Hétreux

Baudet³

2021

Energy

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Sbort-term planning Energy management system Mixed integer linear programming Combined beat and power plantsThis article presents a general modelling framework dedicated to the short term planning of energy systems, which supports the fast prototyping of optimization models. Due to the need for its applicability to practical problem instances, the methodology is based on a generic Mixed lnteger Linear Programming (MllP) formulation. In addition, a specific graphical formalism called Extended Resource Task Network (ER1N) is proposed for the configuration step, which enables the modelling of any type of system and the automatic instantiation of the optimization models. The value of implementing such a tool is demon strated through the modelling, operational planning and performance evaluation of a Combined Heat and Power (OEIP) plant that participates in the French Day ahead electricity market. Indeed, while real lime control of utility plants plays an important role in ensuring the balance between production and needs, forecasting and planning these production systems is becoming increasingly necessary to make them more energy and economically efficient The case study shows, on the one band the potentialities of the modelling approach through the ability to achieve rapid development and implementation of complex systems, and on the other band significant opportunities to improve the site's economic profitability as well as its environmental impact.

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“…It constitutes a tool able to plan energy, for a general point of view and particularly in the waste heat context. This framework is an extension of ERTN (Extended Resource Task Network) formalism, introduced in a previous work [23,24] and provides a more detailed account of the influence of temperature on the physicochemical phenomena involved in the process. This section describes the semantic elements of the EERTN while all the con straints of the model are explained in the supplementary materials.…”

Section: The Eertn Formalismmentioning

confidence: 99%

The energy Extended Resource Task Network, a general formalism for the modeling of production systems:Application to waste heat valorization

Hétreux

Floquet

et al. 2021

Energy

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The extended resource task network: a framework for the combined scheduling of batch processes and CHP plants

Cited by 15 publications

References 11 publications

Improved Resource-Task Network-Based Flare Minimization Model for Ethylene Plant Start-up: Rigorous Treatment of Cracking Furnace and High-Pressure Steam

Improved Resource-Task Network-Based Flare Minimization Model for Ethylene Plant Start-up: Rigorous Treatment of Cracking Furnace and High-Pressure Steam

A modelling framework for energy system planning: Application to CHP plants participating in the electricity market

The energy Extended Resource Task Network, a general formalism for the modeling of production systems:Application to waste heat valorization

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