Exergy analysis in industrial food processing

F.K. Zisopoulos

doi:10.18174/383689

Exergy analysis in industrial food processing

F.K. Zisopoulos

Research output: Thesis › internal PhD, WU

Abstract

The sustainable provision of food on a global scale in the near future is a very serious challenge. This thesis focuses on the assessment and design of sustainable industrial food production chains and processes by using the concept of exergy which is an objective metric based on the first and second law of thermodynamics. Three case studies are presented, two on a chain level (industrial bread and mushroom production), and one on a process level (conceptual spray drying of a lactose solution). Furthermore, industrial food production chains are categorized as thermodynamic archetypes and general rules are derived for their sustainable design exergy-wise. Additional methodological aspects related to e.g. the impact of system boundaries, the allocation of exergy values to waste streams, and the influence of the selection of the environment of reference on the outcome of the analysis, are also discussed.

Original language	English
Qualification	Doctor of Philosophy
Awarding Institution	Wageningen University
Supervisors/Advisors	Boom, Remko, Promotor van der Goot, Atze Jan, Co-promotor
Award date	7 Sept 2016
Place of Publication	Wageningen
Publisher	Wageningen University
Print ISBNs	9789462578326
DOIs	https://doi.org/10.18174/383689
Publication status	Published - 7 Sept 2016

Keywords

thermodynamics
energy
physical properties
food production
drying
food industry
efficiency

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.18174/383689

Files and links

Download PDF

Valorization of raw materials and process efficiency
Zisopoulos, F. (PhD candidate), Boom, R. (Promotor) & van der Goot, A. J. (Co-promotor)
1/09/12 → 7/09/16
Project: PhD

Cite this

@phdthesis{3fca43b7460b487bbccdd0c38fc57904,

title = "Exergy analysis in industrial food processing",

abstract = "The sustainable provision of food on a global scale in the near future is a very serious challenge. This thesis focuses on the assessment and design of sustainable industrial food production chains and processes by using the concept of exergy which is an objective metric based on the first and second law of thermodynamics. Three case studies are presented, two on a chain level (industrial bread and mushroom production), and one on a process level (conceptual spray drying of a lactose solution). Furthermore, industrial food production chains are categorized as thermodynamic archetypes and general rules are derived for their sustainable design exergy-wise. Additional methodological aspects related to e.g. the impact of system boundaries, the allocation of exergy values to waste streams, and the influence of the selection of the environment of reference on the outcome of the analysis, are also discussed. ",

keywords = "thermodynamics, energy, physical properties, food production, drying, food industry, efficiency, thermodynamica, energie, fysische eigenschappen, voedselproductie, drogen, voedselindustrie, effici{\"e}ntie",

author = "F.K. Zisopoulos",

note = "WU thesis 6435 Includes bibliographic references. - With summary in English",

year = "2016",

month = sep,

day = "7",

doi = "10.18174/383689",

language = "English",

isbn = "9789462578326",

publisher = "Wageningen University",

address = "Netherlands",

type = "internal PhD, WU",

school = "Wageningen University",

}

TY - THES

T1 - Exergy analysis in industrial food processing

AU - Zisopoulos, F.K.

N1 - WU thesis 6435 Includes bibliographic references. - With summary in English

PY - 2016/9/7

Y1 - 2016/9/7

N2 - The sustainable provision of food on a global scale in the near future is a very serious challenge. This thesis focuses on the assessment and design of sustainable industrial food production chains and processes by using the concept of exergy which is an objective metric based on the first and second law of thermodynamics. Three case studies are presented, two on a chain level (industrial bread and mushroom production), and one on a process level (conceptual spray drying of a lactose solution). Furthermore, industrial food production chains are categorized as thermodynamic archetypes and general rules are derived for their sustainable design exergy-wise. Additional methodological aspects related to e.g. the impact of system boundaries, the allocation of exergy values to waste streams, and the influence of the selection of the environment of reference on the outcome of the analysis, are also discussed.

AB - The sustainable provision of food on a global scale in the near future is a very serious challenge. This thesis focuses on the assessment and design of sustainable industrial food production chains and processes by using the concept of exergy which is an objective metric based on the first and second law of thermodynamics. Three case studies are presented, two on a chain level (industrial bread and mushroom production), and one on a process level (conceptual spray drying of a lactose solution). Furthermore, industrial food production chains are categorized as thermodynamic archetypes and general rules are derived for their sustainable design exergy-wise. Additional methodological aspects related to e.g. the impact of system boundaries, the allocation of exergy values to waste streams, and the influence of the selection of the environment of reference on the outcome of the analysis, are also discussed.

KW - thermodynamics

KW - energy

KW - physical properties

KW - food production

KW - drying

KW - food industry

KW - efficiency

KW - thermodynamica

KW - energie

KW - fysische eigenschappen

KW - voedselproductie

KW - drogen

KW - voedselindustrie

KW - efficiëntie

UR - https://edepot.wur.nl/383689

U2 - 10.18174/383689

DO - 10.18174/383689

M3 - internal PhD, WU

SN - 9789462578326

PB - Wageningen University

CY - Wageningen

ER -

Exergy analysis in industrial food processing

Abstract

Keywords

UN SDGs

Access to Document

Files and links

Fingerprint

Projects

Valorization of raw materials and process efficiency

Cite this