Jean-Christophe Stefen Gilles Bonhivers

Pós-doutorado

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Áreas de atuação

Orientou

Produções bibliográficas

• BONHIVERS, JEAN-CHRISTOPHE ; REDDICK, CHRISTOPHER ; ROSSELL, CARLOS E. V. ; MARIANO, ADRIANO PINTO ; FILHO, RUBENS MACIEL . Graphical Representation of Chemical Reactions and Heat Cascade Analysis of Biomass Residue Syngasification to Produce Hydrogen. Process Integration And Optimization For Sustainability , v. 7, p. 1241-1264, 2023.

• BONHIVERS, JEAN-CHRISTOPHE ; MACIEL, MARIA REGINA WOLF ; REDDICK, CHRISTOPHER ; ZEMP, ROGER ; MARIANO, ADRIANO PINTO ; FILHO, RUBENS MACIEL . The E-S-T Method Based on the Grand Composite Curve Links Energy Consumption with Number of Stages and Stage Temperatures for Binary Mixture Distillation. Process Integration And Optimization For Sustainability , v. 5, p. 919-946, 2021.

• BONHIVERS, JEAN-CHRISTOPHE ; ORTIZ, PABLO ANDRÉS SILVA ; REDDICK, CHRISTOPHER ; ROSSELL, CARLOS EDUARDO VAZ ; MARIANO, ADRIANO PINTO ; FILHO, RUBENS MACIEL . Graphical Analysis of Plant-Wide Heat Cascade for Increasing Energy Efficiency in the Production of Ethanol and Sugar from Sugarcane. Process Integration And Optimization For Sustainability , v. 5, p. 335-359, 2021.

• DANTAS, ERCÍLIA REGINA SILVA ; BONHIVERS, JEAN-CHRISTOPHE ; MACIEL FILHO, RUBENS ; MARIANO, ADRIANO PINTO . Biochemical conversion of sugarcane bagasse into the alcohol fuel mixture of isopropanol-butanol-ethanol (IBE): Is it economically competitive with cellulosic ethanol?. BIORESOURCE TECHNOLOGY , v. 314, p. 123712, 2020.

• REDDICK, CHRISTOPHER ; SORIN, MIKHAIL ; BONHIVERS, JEAN-CHRISTOPHE ; LAPERLE, DOMINIC . Waste heat and renewable energy integration in buildings. ENERGY AND BUILDINGS , v. 211, p. 109803, 2020.

• BONHIVERS, JEAN'CHRISTOPHE ; MOUSSAVI, ALIREZA ; HACKL, ROMAN ; SORIN, MIKHAIL ; STUART, PAUL R. . Improving the network pinch approach for heat exchanger network retrofit with bridge analysis. CANADIAN JOURNAL OF CHEMICAL ENGINEERING , v. 97, p. 687-696, 2019.

• BONHIVERS, JEAN-CHRISTOPHE ; MOUSSAVI, ALIREZA ; HACKL, ROMAN ; MARIANO, ADRIANO ; REDDICK, JAMES CHRISTOPHER ; SORIN, MIKHAIL ; STUART, PAUL R. . Analysis of Heat Cascade Through Process Components to Reduce the Energy Consumption in Industrial Systems. Process Integration And Optimization For Sustainability , v. 3, p. 237-254, 2018.

• BONHIVERS, JEAN-CHRISTOPHE ; SRINIVASAN, BALASUBRAHMANYAN ; STUART, PAUL R. . New analysis method to reduce the industrial energy requirements by heat-exchanger network retrofit: Part 1 - Concepts. APPLIED THERMAL ENGINEERING , v. 119, p. 659-669, 2017.

• BONHIVERS, JEAN-CHRISTOPHE ; ALVA-ARGAEZ, ALBERTO ; SRINIVASAN, BALASUBRAHMANYAN ; STUART, PAUL R. . New analysis method to reduce the industrial energy requirements by heat-exchanger network retrofit: Part 2 - Stepwise and graphical approach. APPLIED THERMAL ENGINEERING , v. 119, p. 670-686, 2017.

• BONHIVERS, JEAN-CHRISTOPHE ; MOUSSAVI, ALIREZA ; ALVA-ARGAEZ, ALBERTO ; STUART, PAUL R. . Linking pinch analysis and bridge analysis to save energy by heat-exchanger network retrofit. APPLIED THERMAL ENGINEERING , v. 106, p. 443-472, 2016.

• BONHIVERS, JEAN-CHRISTOPHE ; SVENSSON, ELIN ; SORIN, MIKHAIL V. ; BERNTSSON, THORE S. ; STUART, PAUL R. . Energy transfer diagram for site-wide analysis and application to a kraft pulp mill. APPLIED THERMAL ENGINEERING , v. 75, p. 547-560, 2015.

• BONHIVERS, J.C. ; SVENSSON, E. ; BERNTSSON, T. ; STUART, P.R. . Comparison between pinch analysis and bridge analysis to retrofit the heat exchanger network of a kraft pulp mill. APPLIED THERMAL ENGINEERING , v. 70, p. 369-379, 2014.

• BONHIVERS, JEAN-CHRISTOPHE ; KORBEL, MILAN ; SORIN, MIKHAIL ; SAVULESCU, LUCIANA ; STUART, PAUL R. . Energy transfer diagram for improving integration of industrial systems. APPLIED THERMAL ENGINEERING , v. 63, p. 468-479, 2014.

• CHEW, IRENE MEI LENG ; FOO, DOMINIC CHWAN YEE ; BONHIVERS, JEAN-CHRISTOPHE ; STUART, PAUL ; ALVA-ARGAEZ, ALBERTO ; SAVULESCU, LUCIANA ELENA . A model-based approach for simultaneous water and energy reduction in a pulp and paper mill. APPLIED THERMAL ENGINEERING , v. 51, p. 393-400, 2013.

• BONHIVERS, JEAN-CHRISTOPHE ; CHEN, I. ; STUART, P. R. . Simultaneous Water and energy optimization for a pulp and paper mill. CHEMICAL ENGINEERING TRANSACTIONS , v. 25, p. 441-446, 2011.

• BONHIVERS, JEAN-CHRISTOPHE ; PERRIER, M. ; PARIS, J. . Management of broke recirculation in an integrated paper mill. PULP & PAPER-CANADA , v. 1, p. 1, 2002.

• BONHIVERS, JEAN-CHRISTOPHE ; PERRIER, M. ; PARIS, J. . Model predictive control for integrated management of white water tanks. TAPPI JOURNAL , v. 1, p. 15, 2002.

• SORIN, M. ; BONHIVERS, J.-C. ; PARIS, J. . Exergy efficiency and conversion of chemical reactions. ENERGY CONVERSION AND MANAGEMENT , v. 39, p. 1863-1868, 1998.

• BONHIVERS, JEAN-CHRISTOPHE ; REDDICK, C. ; STUART, P. R. ; MOUSSAVI, A. ; MARIANO, A. P. ; MACIEL FILHO, R. . Applications of Process Integration Methodologies in the Pulp and Paper Industry. In: Klemes, Jiri. (Org.). Handbook of Process Integration (PI), 2e Minimisation of Energy and Water Use, Waste and Emissions. 2ed.: , 2022, v. 1, p. 811-844.

• MOUSSAVI, A. ; BONHIVERS, JEAN-CHRISTOPHE ; MARIANO, A. P. ; MACIEL FILHO, R. ; STUART, P. R. . Applications of Process Integration Methodologies in the Pulp and Paper Industry. In: Klemes, Jiri. (Org.). Handbook of Process Integration (PI), 2e Minimisation of Energy and Water Use, Waste and Emissions. 2ed.: , 2022, v. 1, p. 783-810.

• BONHIVERS, JEAN-CHRISTOPHE ; REDDICK, C. ; STUART, P. R. ; MOUSSAVI, A. ; MARIANO, A. P. ; MACIEL FILHO, R. . Applications of Process Integration Methodologies in the Pulp and Paper Industry. In: Klemes, Jiri. (Org.). Handbook of Process Integration (PI). 1ed.: , 2013, v. 1, p. 765-798.

Projetos de pesquisa

• 2018 - Atual

  Technoeconomic analysis of a sugarcane biorefinery with bio-based chemicals and optimized ethanol production, Descrição: The development of integrated biorefineries is still beginning and potential targets includes products already made by the chemical industry (thus, with well-established value chains) as well as new products derived from biorefinery building blocks. Among an array of possibilities, generally considered as separate Greenfield projects, the Thematic Project proposes the development of an integrated process so that maximization of biofuels productivity is accompanied by the production of added-value chemicals from sugarcane molasses, bagasse, straw, and waste streams. The conceptual idea is to use existing first generation ethanol plants as the host for new processes, taking the advantage of mass, energy, and capital integration. As such, the transformation of conventional ethanol mills involves changing the focus of the companies to modified product portfolios through the implementation of emerging technologies. From an investor perspective, decision-making regarding biorefinery product-process combinations that lead to sustainable business models and good economic returns is not obvious. Thus, implementing a successful biorefinery strategy implies identifying and addressing a combination of economic and technical risks. On the technology end, the optimization of complex and interconnected process units must ideally be pursued since its early stages of development, aiming at cost reduction, negative overall CO2 balance, reduction of water and effluent footprints, and so forth. Fine-tuned processes, operating at (near-) optimum conditions and flexible enough to handle market fluctuations will have a significant competitive advantage. In this context, this postdoctoral work aims at developing a computational platform in the process simulator Aspen Plus to design and evaluate from technical and economic perspectives (e.g. profitability, energy efficiency) the different biorefinery options to be studied in the Thematic Project. This research framework will additionally allow to: (a) assess integration risks of new processes to existing mills; (b) optimize the concepts and processes of new biorefineries, taking into account that the optimization of the short term options may lock out better options down the road; (c) characterize technology bottlenecks; and (d) benchmark the development stage of new technologies for production of biofuels and chemicals from sugarcane feedstocks. Since the downstream separation processes are often the bottleneck in industrial bio-based processes and offer a large potential for energy savings, to assess whether the separation/purification processes developed in the project will not (or at least to a lesser extent) compromise process flexibility, which is critical for a successful biorefinery implementation in face of market volatilities and, at the same time, important to meet market demands. In this manner, the trade-offs between process flexibility and separation process intensification, considering overall energy efficiency, will also be explored.. , Situação: Em andamento; Natureza: Pesquisa. , Integrantes: Jean-Christophe Stefen Gilles Bonhivers - Integrante / Adriano Pinto Mariano - Integrante / MACIEL FILHO, RUBENS - Coordenador.

• 2017 - 2023

  Desenvolvimento Integrado de Biorrefinaria e Planta de Bioetanol de Cana-de-Açúcar com Emissão Zero de CO2: Rotas para Converter Recursos Renováveis em Bioprodutos e Bioeletricidade, Situação: Concluído; Natureza: Pesquisa. , Integrantes: Jean-Christophe Stefen Gilles Bonhivers - Integrante / Adriano Pinto Mariano - Integrante / MACIEL FILHO, RUBENS - Coordenador.