Viviani C. Onishi scite author profile

The optimal integration between heat and work may significantly reduce the energy demand and consequently the process cost. This paper introduces a new mathematical model for the simultaneous synthesis of heat exchanger networks (HENs) in which the pressure levels of the process streams can be adjusted to enhance the heat integration. A superstructure is proposed for the HEN design with pressure recovery, developed via generalized disjunctive programming (GDP) and mixed-integer nonlinear programming (MINLP) formulation. The process conditions (stream temperature and pressure) must be optimized. Furthermore, the approach allows for coupling of the turbines and compressors and selection of the turbines and valves to minimize the total annualized cost, which consists of the operational and capital expenses. The model is tested for its applicability in three case studies, including a cryogenic application. The results indicate that the energy integration reduces the quantity of utilities required, thus decreasing the overall cost.

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Simultaneous synthesis of work exchange networks with heat integration

Onishi

Ravagnani

Caballero

2014

Chemical Engineering Science

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The optimal integration of work and its interaction with heat can represent large energy savings in industrial plants. This paper introduces a new optimization model for the simultaneous synthesis of work exchange networks (WENs), with heat integration for the optimal pressure recovery of process gaseous streams. The proposed approach for the WEN synthesis is analogous to the well-known problem of synthesis of heat exchanger networks In all case studies, the heat integration between WEN stages is essential to improve the pressure recovery, and to reduce the total costs involved in the process.

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Mathematical programming model for heat exchanger design through optimization of partial objectives

Onishi

Ravagnani

2013

Energy Conversion and Management

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Mathematical programming can be used for the optimal design of shell-and-tube heat exchangers (STHEs). This paper proposes a mixed integer non-linear programming (MINLP) model for the design of STHEs, following rigorously the standards of the Tubular Exchanger Manufacturers Association (TEMA). Bell-Delaware Method is used for the shell-side calculations. This approach produces a large and non-convex model that cannot be solved to global optimality with the current state of the art solvers. Notwithstanding, it is proposed to perform a sequential optimization approach of partial objective targets through the division of the problem into sets of related equations that are easier to solve. For each one of these problems a heuristic objective function is selected based on the physical behavior of the problem. The global optimal solution of the original problem cannot be ensured even in the case in which each of the sub-problems is solved to global optimality, but at least a very good solution is always guaranteed. Three cases extracted from the literature were studied.The results showed that in all cases the values obtained using the proposed MINLP model containing multiple objective functions improved the values presented in the literature.

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Shale gas flowback water desalination: Single vs multiple-effect evaporation with vapor recompression cycle and thermal integration

et al. 2017

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Desalination of shale gas produced water: A rigorous design approach for zero-liquid discharge evaporation systems

Onishi

Carrero‐Parreño

Reyes‐Labarta

et al. 2017

Journal of Cleaner Production

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Optimal Pretreatment System of Flowback Water from Shale Gas Production

Carrero‐Parreño¹,

Onishi²,

Salcedo‐Díaz³

et al. 2017

Ind. Eng. Chem. Res.

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Shale gas has emerged as a potential resource to transform the global energy market. Nevertheless, gas extraction from tight shale formations is only possible after horizontal drilling and hydraulic fracturing, which generally demand large amounts of water. Part of the ejected fracturing fluid returns to the surface as flowback water, containing a variety of pollutants. For this reason, water reuse and water recycling technologies have received further interest for enhancing overall shale gas process efficiency and sustainability. Water pretreatment systems (WPSs) can play an important role for achieving this goal. This paper introduces a new optimization model for WPS simultaneous synthesis, especially developed for flowback water from shale gas production. A multistage superstructure is proposed for the optimal WPS design, including several water pretreatment alternatives. The mathematical model is formulated via generalized disjunctive programming (GDP) and solved by re-formulation as a mixed-integer nonlinear programming (MINLP) problem, to minimize the total annualized cost. Hence, the superstructure allows identifying the optimal pretreatment sequence with minimum cost, according to inlet water composition and wastewater-desired destination (i.e., water reuse as fracking fluid or recycling). Three case studies are performed to illustrate the applicability of the proposed approach under specific composition constraints. Thus, four distinct flowback water compositions are evaluated for the different target conditions. The results highlight the ability of the developed model for the cost-effective WPS synthesis, by reaching the required water compositions for each specified destination.

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Optimal synthesis of work and heat exchangers networks considering unclassified process streams at sub and above-ambient conditions

Onishi

Quirante

Ravagnani³

2018

Applied Energy

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Retrofit of heat exchanger networks with pressure recovery of process streams at sub-ambient conditions

Onishi

Ravagnani

Caballero

2015

Energy Conversion and Management

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Viviani C. Onishi

Simultaneous synthesis of heat exchanger networks with pressure recovery: Optimal integration between heat and work

Simultaneous synthesis of work exchange networks with heat integration

Mathematical programming model for heat exchanger design through optimization of partial objectives

Shale gas flowback water desalination: Single vs multiple-effect evaporation with vapor recompression cycle and thermal integration

Desalination of shale gas produced water: A rigorous design approach for zero-liquid discharge evaporation systems

Optimal Pretreatment System of Flowback Water from Shale Gas Production

Optimal synthesis of work and heat exchangers networks considering unclassified process streams at sub and above-ambient conditions

Retrofit of heat exchanger networks with pressure recovery of process streams at sub-ambient conditions

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