A Holistic Methodology for Optimizing Industrial Resource Efficiency

Efficient consumption of energy and material resources, including water, is the primary focus for process industries to reduce their environmental impact. The Conference of Parties in Paris (COP21) highlighted the prominent role of industrial energy efficiency in combating climate change by reducing...

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Bibliographic Details
Published in:Energies (Basel) 2019-04, Vol.12 (7), p.1315
Main Authors: Kermani, Maziar, Kantor, Ivan, Wallerand, Anna, Granacher, Julia, Ensinas, Adriano, Maréchal, François
Format: Article
Language:English
Subjects:
Adaptation
Cogeneration
combined heat and power
Cooling
Cooling water
Design optimization
Efficiency
Electric power generation
Electricity
Energy
Environmental impact
Feedwater
Heat exchangers
Heat recovery systems
Heat transfer
heat-integrated water allocation network
High temperature
Industrial plants
industrial symbiosis
kraft pulp process
Linear programming
Low temperature
Mathematical programming
Methods
Parameter estimation
Power plants
process integration
Steam
Storage tanks
Streams
Superheating
Wastewater
Water tanks
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Summary:Efficient consumption of energy and material resources, including water, is the primary focus for process industries to reduce their environmental impact. The Conference of Parties in Paris (COP21) highlighted the prominent role of industrial energy efficiency in combating climate change by reducing greenhouse gas emissions. Consumption of energy and material resources, especially water, are strongly interconnected and, therefore, must be treated simultaneously using a holistic approach to identify optimal solutions for efficient processing. Such approaches must consider energy and water recovery within a comprehensive process integration framework which includes options such as organic Rankine cycles for electricity generation from low–medium-temperature heat. This work addresses the importance of holistic approaches by proposing a methodology for simultaneous consideration of heat, mass, and power in industrial processes. The methodology is applied to a kraft pulp mill. In doing so, freshwater consumption is reduced by more than 60%, while net power output is increased by a factor of up to six (from 3.2 MW to between 10–26 MW). The results show that interactions among these elements are complex and therefore underline the necessity of such comprehensive methods to explore their optimal integration with industrial processes. The potential applications of this work are vast, extending from total site resource integration to addressing synergies in the context of industrial symbiosis.
ISSN:1996-1073
1996-1073
DOI:10.3390/en12071315