Methodology using process integration for identifying suitable Organic Rankine

Cycles for waste heat valorisationMatthias Bendig*, Prof. François Maréchal, Prof. Daniel Favrat

Industrial Energy Systems Laboratory (LENI)École Polytechnique Fédérale de Lausanne (EPFL)

*corresponding author: matthias.bendig@epfl.ch

World energy-related CO emission savings by policy measure in the 450 scenario of the IEA.

Source:IEA WEO 2009.

ContextEnergy efficiency is essential: CO -abatement Cost efficiency

ProblemThe optimal integration of an electricity production cycle into a process.

ObjectivePropose a methodology in order to identify a pareto-optimal ORC: quantitative criteria: efficiencies, cost, CO2-equivalents, ODP, LCA qualitative criteria: toxicity, flammability

AcknowledgementsThe authors thank Nestlé Suisse SA for all the support and letting us “spook around” their factory. The research, leading to these results, has as well received support from the European Community's Seventh Framework Programme (FP7/2007-2013) under grant agreement n° 256790 (‘LOVE').

References

Methodology

How to adapt the ORC to heat sources and sinks of a process?Which are the relevant Constraints?Many parameters:

Borel, L. and Favrat, D., 2010, Thermodynamics and Energetics for Engineers. EPFL Press, Switzer-land.International Energy Agency, 2009, World Energy Outlook, volume 2009. OECD/IEA, Paris.Maréchal, F., 2008, Pinch analysis, Chapter 3.19.1.7, UNESCO Encyclopedia of Life Support Systems, EOLSS Publishers Co Ltd.Muller, D.C.A., Maréchal, F., Wolewinski, T., Roux, P.J., November 2007, An energy management method for the food industry, Applied Thermal Engineering, Volume 27, Issue 16, Pages 2677-2686.

2

2

>50%

Working Fluids and MixturesSingle- or Multi-Stage, ExtractionOptimal Size

Industrial Process Model for Thermodynamicsof Industrial Process

Technology Models ofLow Temperature Heat Valorisation (LTHV)

Iterate until

optima found.

DataStudies

Measurements

Deduce energy require-ments and integrate with Pinch-Analysis

Evaluation of Objectives

ConstraintsThe number of decision variables can be reduced by: Limiting CO2-equivalents/ GWP Limiting ODP Excluding flammability Excluding toxicity

The decision variable range can be reduced by: Limiting maximum pressure Limiting number of ORC-stages Limiting maximum compo- nents in working fluid

Thermodynamics: - Energy-Efficiency - Exergy-EfficiencyCost (relative and NPV)Global Warming PotentialOzone Depletion PotentialLife Cycle Analysis

Mutations

Alleles from high performing “Parent Con�gu-rations”

“Genes” �xing the Con�guration

Evolutionary MultiobjectiveOptimisation (MOO) Pareto-Optimal Solutions

Obj

ectiv

e A

Objective B

Di�erent solution “families” repre-senting di�erent Technologies

Solutions are pareto-optimal for at least two objectives.

0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000 11000−50

0

50

100

150

200

250

300

Heat (Q) [kW]

corr

ecte

d Te

mpe

ratu

re (T

*) [°

C]

cold MER 1600 kW hot MER 789.2 kW

internal heat recovery 6150 kW

current cold utilities 3600 kW current hot utility 2789.2 kW

current internal heat recovery 4150 kW

ResidualHeat 1237 kW