F. Ayachi, E. Boulawz-ksayer, A. Zoughaib, and P. Neveu, Methodology and Thermo-Economic Optimization for Integration of Industrial Heat Pumps, Ceres Project, vol.10, 2011.

M. Dumbliauskaite, H. Becker, and F. Marechal, Utility optimization in a brewery process based on energy integration methodology, EPFL, Proceedings ECOS, 2009.

X. Feng and X. X. Zhu, Combining Pinch and exergy analysis for process modifications, Introduction to Pinch Technology, vol.17, pp.1-63, 1990.

R. Murr, H. Thieriot, A. Zoughaib, D. Clodic, S. A. Papoulias et al., Multi-objective optimization of a multi water-to-water heat pump system using evolutionary algorithm, Computers & Chemical Engineering, vol.88, pp.707-721, 1983.
URL : https://hal.archives-ouvertes.fr/hal-00769627

M. Pavlas, P. Stehlik, and J. Oral, Heat integrated pumping for biomass gasification processing, Applied Thermal Engineering, vol.30, pp.30-35, 2010.
URL : https://hal.archives-ouvertes.fr/hal-00589453

F. Thibault, A. Zoughaib, and S. Jumel, An Exergy-based LP algorithm for Heat Pump Integration in industrial processes, Proceedings ECOS, 2013.

A. Zainuddin and L. F. Yee, Maximising utility savings through appropriate implementation of combined heat and power scheme, Jurnal Technologi, vol.41, pp.53-62, 2004.

R. Bibliographie-anantharaman, O. S. Abbas, and T. Gundersen, Energy Level Composite Curvesa new graphical methodology for the integration of energy intensive processes, Applied Thermal Engineering, vol.26, issue.13, pp.1378-1384, 2006.

N. Asante and X. Zhu, An automated approach for heat exchanger network retrofit featuring minimal topology modifications, Computers & Chemical Engineering, issue.96, p.20, 1996.

N. Asante and X. Zhu, An automated and interactive approach for heat exchanger network retrofit, p.75, 1997.

G. Athier, P. Floquet, L. Pibouleau, and S. Domenech, Process optimization by simulated annealing and NLP procedures. Application to heat exchanger network synthesis, Computers & Chemical Engineering, vol.21, issue.97, pp.475-480, 1997.

F. Ayachi, E. Boulawz-ksayer, A. Zoughaib, and P. Neveu, ORC optimization for medium grade heat recovery, Energy, vol.68, pp.47-56, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01176932

A. Barbaro and M. J. Bagajewicz, New rigorous one-step MILP formulation for heat exchanger network synthesis, Computers & Chemical Engineering, vol.29, issue.9, pp.1945-1976, 2005.

M. Bagajewicz, H. Rodera, and M. Savelski, Energy efficient water utilization systems in process plants, Computers & Chemical Engineering, vol.26, issue.1, pp.56-79, 2002.

H. Becker, A. Vuillermoz, and F. Maréchal, Heat pump integration in a cheese factory, Applied Thermal Engineering, vol.43, pp.118-127, 2012.

A. Bejan, Fundamentals of exergy analysis, entropy generation minimization, and the generation of flow architecture, International Journal of Energy Research, vol.26, issue.7, pp.0-43, 2002.

F. Berkhout and R. Howes, The adoption of life-cycle approaches by industry: patterns and impacts. Resources, Conservation and Recycling, vol.20, pp.71-94, 1997.

K. Besbes, A. Zoughaib, F. De-carlan, and J. L. Peureux, Exergy Based Methodology For Optimized Integration Of Vapor Compression Heat Pumps In Industrial Processes, 15th International Refrigeration and Air conditionning Conference, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01299952

K. Björk and R. Nordman, Solving large-scale retrofit heat exchanger network synthesis problems with mathematical optimization methods, Process Intensification, vol.44, pp.869-876, 2005.

J. Cerda, A. W. Westerberg, D. Mason, and B. Linnhoff, Minimum utility usage in heat exchanger network synthesis : A transportation problem, Chemical Engineering Science, vol.38, issue.3, pp.373-387, 1983.

S. Chakraborty and P. Ghosh, Heat exchanger network synthesis: The possibility of randomization, Chemical Engineering Journal, vol.72, issue.3, pp.209-216, 1999.

C. Chen and P. Hung, Multicriteria synthesis of flexible heat-exchanger networks with uncertain source-stream temperatures, Process Intensification, vol.44, pp.89-100, 2005.

D. Chen, S. Yang, X. Luo, Q. Wen, and H. Ma, An explicit solution for thermal calculation and synthesis of superstructure heat exchanger networks, Chinese Journal of Chemical Engineering, vol.15, issue.2, pp.296-301, 2007.

J. Chevalier, Élaboration d'un protocole d'ACV des procédés : application au traitement des fumées d'incinération des déchets ménagers, 1999.

A. Ciric and C. Floudas, Heat exchanger network synthesis without decomposition, Computers & Chemical Engineering, issue.6, p.15, 1991.

W. B. Dolan, P. T. Cummings, and M. D. Van, Algorithmic efficiency of simulated annealing for heat exchanger network design, Computers & Chemical Engineering, vol.14, issue.10, 1990.

M. Dumbliauskaite, Utility optimization in a brewery process based on energy integration methodology, Proceedings of ECOS, pp.1-8, 2010.

R. C. Eberhart and J. Kennedy, A new optimizer using particle swarm theory, Proceedings of the Sixth International Symposium on Micro Machine and Human Science, pp.39-43, 1995.

Y. El-sayed, Application of exergy to design. Energy Conversion and Management, vol.43, pp.1165-1185, 2002.

X. Feng and X. Zhu, Combining pinch and exergy analysis for process modifications, Applied Thermal Engineering, issue.3, pp.249-261, 1997.

G. Fieg, X. Luo, and J. Je?owski, A monogenetic algorithm for optimal design of large-scale heat exchanger networks, Process Intensification, vol.48, pp.1506-1516, 2009.

C. A. Floudas, Nonlinear and Mixed-Integer Optimization: Fundamentals and Applications, 1995.

R. Frazier, An exergy diagnostic methodology for energy management in manufacturing, 2006.

K. Furman and N. Sahinidis, A critical review and annotated bibliography for heat exchanger network synthesis in the 20th century, Industrial & Engineering Chemistry Ressources, pp.2335-2370, 2002.

M. Gorji-bandpy, H. Yahyazadeh-jelodar, and M. Khalili, Optimization of heat exchanger network, Applied Thermal Engineering, vol.31, issue.5, pp.779-784, 2011.

I. Grossmann and R. Sargent, Optimum design of heat exchanger networks, Computers & Chemical Engineering, vol.2, pp.1-7, 1978.

T. Gundersen and I. Grossmann, Improved optimization strategies for automated heat exchanger network synthesis through physical insights, Computer & Chemical Engineering, vol.14, issue.9, pp.925-944, 1990.

T. Gundersen and L. Naess, The synthesis of cost optimal heat exchanger networks: an industrial review of the state of the art, Computers & Chemical Engineering, vol.I, issue.4, pp.301-328, 1988.

J. Jezowski, Area target for heat exchanger networks using linear programming, Industrial & Engineering Chemicals Ressources, pp.1723-1730, 2003.

J. Je?owski, R. Bochenek, and A. Je?owska, Pinch locations at heat capacity flow-rate disturbances of streams for minimum utility cost heat exchanger networks, Applied Thermal Engineering, p.20, 2000.

J. Je?owski, R. Bochenek, and A. Je?owska, Loop breaking in heat exchanger networks by mathematical programming, Applied Thermal Engineering, vol.21, pp.1429-1448, 2001.

J. Je?owski, R. Bochenek, and G. Poplewski, On application of stochastic optimization techniques to designing heat exchanger-and water networks, Process Intensification, vol.46, pp.1160-1174, 2007.

I. Kemp, Pinch analysis and process integration. A User Guide on Process Integration for the Efficient Use, 2007.

S. Kirkpatrick, C. D. Gelatt, and M. P. Vecchi, Optimization by simulated annealing, Science, vol.220, issue.4598, pp.671-680, 1983.

A. E. Konukman, M. C. Çamurdan, and U. Akman, Simultaneous flexibility targeting and synthesis of minimum-utility heat-exchanger networks with superstructurebased MILP formulation, Process Intensification, vol.41, pp.501-518, 2002.

P. Krummenacher and D. Favrat, Indirect and mixed direct-indirect heat integration of batch processes based on pinch analysis, International Journal of Applied Thermodynamics, vol.4, issue.3, p.136, 2001.

R. Lakshmanan and R. Banares-alcantara, Retrofit by inspection using thermodynamic process visualisation, Computers & Chemical Engineering, p.22, 1986.

D. Lewin, A generalized method for HEN synthesis using stochastic optimization-II.: The synthesis of cost-optimal networks, Computers & Chemical Engineering, vol.22, issue.10, pp.1387-1405, 1998.

D. R. Lewin, H. Wang, and O. Shalev, A generalized method for HEN synthesis using stochastic optimization -I. General framework and MER optimal synthesis, Computers & Chemical Engineering, vol.22, issue.10, pp.1503-1513, 1998.

B. Lin and D. C. Miller, Solving heat exchanger network synthesis problems with Tabu Search, Computers & Chemical Engineering, vol.28, issue.8, pp.1451-1464, 2004.

B. ;. Linnhoff and S. Ahmad, Cost optimum heat exchanger networks-1. Minimum energy and capital using simple models for capital cost, Linnhoff March, 63 pages Linnhoff, 1990.

B. Linnhoff and C. G. Akinradewo, Linking process simulation and process integration, Computers & Chemical Engineering, vol.23, pp.945-953, 1999.

B. Linnhoff and V. R. Dhole, Shaftwork target for low temperature process design, Chemical Engineering Science, vol.47, issue.8, pp.2081-2091, 1992.

B. Linnhoff and E. Hindmarsh, The pinch design method for heat exchanger networks, Chemical Engineering Science, vol.38, issue.5, pp.745-763, 1983.

X. Luo, Q. Wen, and G. Fieg, A hybrid genetic algorithm for synthesis of heat exchanger networks, Computers & Chemical Engineering, vol.33, issue.6, pp.1169-1181, 2009.

X. Ma, P. Yao, X. Luo, and W. Roetzel, Synthesis of multi-stream heat exchanger network for multi-period operation with genetic/simulated annealing algorithms, Applied Thermal Engineering, vol.28, issue.8-9, pp.809-823, 2008.

Z. Manan, Maximising utility savings through appropriate implementation of combined heat and power scheme, Jurnal Teknologi, vol.41, pp.53-62, 2004.

A. H. Masso and D. F. Rudd, The synthesis of systems design. II. Heuristic Structuring, AIChE Journal, vol.15, issue.1, pp.10-17, 1969.

R. Murr, H. Thieriot, . Zoughaib, and D. Clodic, Multi-objective optimization of a multi water-to-water heat pump system using evolutionary algorithm, Applied Energy, vol.88, issue.11, pp.3580-3591, 2011.
URL : https://hal.archives-ouvertes.fr/hal-00769627

H. Odum and N. Peterson, Simulation and evaluation with energy systems blocks, Ecological Modelling, vol.93, pp.155-173, 1996.

S. A. Papoulias and I. E. Grossmann, A structural optimization approach in process synthesis. Department of Chemical Engineering, 1982.

S. A. Papoulias and I. E. Grossmann, A structural optimization approach in process synthesis--II : Heat recovery networks, Computers & Chemical Engineering, vol.7, issue.6, pp.707-721, 1983.

A. Pariyani, A. Gupta, and P. Ghosh, Design of heat exchanger networks using randomized algorithm, Computers & Chemical Engineering, vol.30, issue.6-7, pp.1046-1053, 2006.

W. Paterson, A replacement for the logarithmic mean, Chemical Engineering Science, vol.39, issue.11, pp.1635-1636, 1984.

M. Pavlas, P. Stehlík, J. Oral, J. Kleme?, J. Kim et al., Heat integrated heat pumping for biomass gasification processing, Applied Thermal Engineering, vol.30, issue.1, pp.30-35, 2010.
URL : https://hal.archives-ouvertes.fr/hal-00589453

F. Pettersson, Synthesis of large-scale heat exchanger networks using a sequential match reduction approach, Computers & Chemical Engineering, vol.29, issue.5, pp.993-1007, 2005.

J. Portha, Méthodologie pour tenir compte de l'impact environnemental d'un procédé lors de sa conception, vol.132, p.136, 2008.

M. A. Ravagnani and J. A. Caballero, Optimal heat exchanger network synthesis with the detailed heat transfer equipment design, Computers & Chemical Engineering, vol.31, issue.11, pp.1432-1448, 2007.

M. A. Ravagnani, .. P. Silva, P. A. Arroyo, and . Constantino, Heat exchanger network synthesis and optimisation using genetic algorithm, Applied Thermal Engineering, vol.25, issue.7, pp.1003-1017, 2005.

R. Naturelles and . Canada, L'analyse Pinch : pour une utilisation efficace de l'énergie, de l'eau et de l'hydrogène, vol.74, pp.0-662, 2003.

H. Shethna, J. Jezowski, and F. Castillo, A new methodology for simultaneous optimization of capital and operating cost targets in heat exchanger network design, Applied Thermal Engineering, vol.20, pp.1577-1587, 2000.

R. Smith, State of the art in process integration, Applied Thermal Engineering, vol.20, pp.1337-1345, 2000.

R. Smith, M. Jobson, and L. Chen, Recent development in the retrofit of heat exchanger networks, Applied Thermal Engineering, vol.30, issue.16, pp.2281-2289, 2010.
URL : https://hal.archives-ouvertes.fr/hal-00675409

A. Sor?ak and Z. Kravanja, Simultaneous MINLP synthesis of heat exchanger networks comprising different exchanger types, Computers & Chemical Engineering, vol.26, pp.599-615, 2002.

F. Staine and D. Favrat, Energy integration of industrial processes based on the pinch analysis method extended to include exergy factors, Applied Thermal Engineering, vol.16, issue.6, pp.497-507, 1996.

A. Toffolo, The synthesis of cost optimal heat exchanger networks with unconstrained topology, Applied Thermal Engineering, vol.29, pp.3518-3528, 2009.
URL : https://hal.archives-ouvertes.fr/hal-00573477

W. Alwi, S. R. Manan, Z. A. Misman, M. Chuah, and W. S. , SePTA-A new numerical tool for simultaneous targeting and design of heat exchanger networks, Computers & Chemical Engineering, vol.57, pp.30-47, 2013.

M. Xiangkun, Y. Pingjing, L. Xing, and R. Wilfried, Synthesis of flexible multistream heat exchanger networks based on stream pseudo-temperature with genetic/simulated annealing algorithms, Journal of the Chinese Institute of Chemical Engineers, vol.38, issue.3-4, pp.321-331, 2007.

W. Xiao, H. Dong, X. Li, and P. Yao, Synthesis of large-scale multistream heat exchanger networks based on stream pseudo temperature, Chinese Journal of Chemical Engineers, vol.14, issue.5, pp.574-583, 2006.

X. S. Yang, Engineering optimization : An introduction with Metaheuristic applications, vol.347, 2010.

T. F. Yee, I. E. Grossmann, and Z. Kravanja, Simultaneous optimization models for heat integration-I. Area and energy targeting and modeling of multi-stream exchangers, Computers & Chemical Engineering, vol.14, issue.10, pp.1151-1164, 1990.

T. F. Yee and I. E. Grossmann, Simultaneous optimization models for heat integration-II. Heat exchanger network synthesis, Computers & Chemical Engineering, vol.14, issue.10, pp.1165-1184, 1990.

T. F. Yee, I. E. Grossmann, and Z. Kravanja, Simultaneous optimization models for heat integration-III. Process and heat exchanger network optimization, Computers & Chemical Engineering, vol.14, issue.11, pp.1185-1200, 1990.

J. Zamora and I. Grossmann, A global MINLP optimization algorithm for the synthesis of heat exchanger networks with no stream splits, Computers & Chemical Engineering, vol.22, issue.3, pp.367-384, 1998.

X. X. Zhu, B. K. O'neill, J. R. Roach, and R. M. Wood, Area-targeting methods for the direct synthesis of heat exchanger networks with unequal film coefficients, Computers & Chemical Engineering, vol.19, issue.2, p.136, 1995.