Your search keyword '"Nemet, Andreja"' showing total 3 results

1. Two-step MILP/MINLP approach for the synthesis of large-scale HENs.

Author

Nemet, Andreja, Isafiade, Adeniyi Jide, Klemeš, Jiří Jaromír, and Kravanja, Zdravko

Subjects

*HEAT exchangers, *CHEMICAL synthesis, *MATHEMATICAL programming, *MIXED integer linear programming, *HEAT transfer

Abstract

Highlights • Large-scale HEN synthesis is a first step towards Total Site synthesis. • Two-step MILP/MINLP approach was developed for larges-scale HEN synthesis. • Number of potential matches is significantly reduced, solutions are directed to global optima using MILP TransHEN model. • MINLP model HENSyn use reduced superstructure for HEN synthesis. • Problem with 173 process streams and multiple hot utilities solved. Abstract Although different methodologies for the synthesis of heat exchanger network (HEN) problems have been introduced in the last forty years, there are still significant challenges to be addressed, such as solving large-scale problems. This study focuses on synthesizing large-scale HENs using mathematical programming to achieve near globally optimal solutions based on a two-step MILP/MINLP approach. In the first step a mixed-integer linear programming (MILP) model, TransHEN, is used that obtains a globally optimal solution at selected Δ T min. By utilisation of this model, the most promising matches are selected based on feasibility and viability. The second step entails using the matches selected in the TransHEN of Step 1 in a mixed-integer nonlinear programming (MINLP) model, HENsyn, using a reduced superstructure, to generate a feasible HEN. This study presents also a simultaneous Total Site synthesis with direct heat transfer between processes, and is the first step in the wider project of synthesising an entire Total Site with direct and indirect heat transfer; and is the first step in the wider scope of synthesising an entire Total Site with direct and indirect heat transfer; however, in order to attain this goal, a tool capable of an appropriately handling large number of streams is required. The newly developed procedure has been tested on several case studies, two of which are presented in this paper. For Case study 1 the results obtained lie within the range of best solutions obtained by other authors. Case study 2, consisting of 173 process stream and involving multiple hot utilities, shows the applicability of the developed method to handle large-scale HEN problems. [ABSTRACT FROM AUTHOR]

Published

2019

2. Safety Analysis Embedded in Heat Exchanger Network Synthesis.

Author

Nemet, Andreja, Klemeš, Jiří Jaromír, Moon, Il, and Kravanja, Zdravko

Subjects

*HEAT exchangers, *STRUCTURAL optimization, *HEAT transfer, *SENSITIVITY analysis, *ECONOMIC efficiency

Abstract

Optimization of Heat Exchanger Networks (HEN) has received considerable attention in last decades, but a few studies on inherent safety. In this paper, risk assessment is considered simultaneously during the synthesis of HENs. As risks depend on the equipment selected, a superstructure enabling selection of direct and indirect heat transfer between hot and cold streams and different types of heat exchangers (HEs) was tested. The individual heat transfer and the overall HEN risk were analyzed. Different individual risk limits have been introduced for certain types of heat transfer, e.g. between two process streams or between utility and process streams. The sensitivity analyses were performed first, considering only toxicity as a risk, but later flammability and explosiveness were also simultaneously tested, in order to consider the most important aspects of safety. The results obtained indicate that rather significant changes in HEN designs can increase safety, while still exhibiting similar economic efficiency. [ABSTRACT FROM AUTHOR]

Published

2017

3. Minimum heat transfer area for Total Site heat recovery.

Author

Boldyryev, Stanislav, Varbanov, Petar Sabev, Nemet, Andreja, Klemeš, Jiří Jaromír, and Kapustenko, Petro

Subjects

*HEAT transfer, *CAPITAL costs, *HEAT recovery, *ESTIMATION theory, *TEMPERATURE effect

Abstract

In this paper a further development of methodology for decreasing the capital cost for Total Site heat recovery by use of different utility levels is proposed. The capital cost of heat recovery system is estimated for certain temperature level of intermediate utility applying Total Site Profiles. Heat transfer area is reduced by selection of appropriate temperature of intermediate utility. Minimum of heat transfer area depends on slopes of Total Site Profiles in each enthalpy interval. This approach allows estimating the minimum of heat transfer area for heat recovery on Total Site level. Case study is performed for fixed film heat transfer coefficients of process streams and intermediate utilities. It indicates that the total heat transfer area of heat recovery can be different up to 49.15% for different utility temperatures. [ABSTRACT FROM AUTHOR]

Published

2014