Publication detail
Offshore Conceptual Plastic Waste Collection and Treatment Towards Clean Ocean
NEVRLÝ, V. ŠOMPLÁK, R. SZÁSZIOVÁ, L. PLUSKAL, J. PROCHÁZKA, V.
English title
Offshore Conceptual Plastic Waste Collection and Treatment Towards Clean Ocean
Type
journal article in Web of Science
Language
en
Original abstract
The recent social care about the concentration of plastics in the ocean arises with the necessity of developing solutions to this problem. Some projects are dealing with the technology of collection, however, the follow-up transfer onshore is not usually included in the solution. This study suggests designing a vessel with available waste treatment technologies that can use the waste to recover energy. Simultaneously, the technologic vessel has to regularly visit collectors and ports to supply produced commodities and crew. A mixed integer linear model is developed to find the optimal balance between capacities of considered technologies and also to simulate the voyage with all respective operations. Waste-to-Energy, pyrolysis, desalination, sorting and other mechanical processes are assumed onboard. The vessel is designed to utilize the produced energy and products onboard including heat generation, electricity, water, and oil. The evaluation of suitable technologies is realized through techno-economic models which are needed for all considered subsystems from the complex treatment chain. The analysis of project viability requires detailed multi-disciplinary data. The main output of the presented approach is sensitivity analysis for critical parameters, which gives greater insight into the issue and directs further research from a general level through the concept to refine the input data and boundary conditions of the task in the model. The Pacific Garbage Patch was chosen as the testing area for the case study. The presented approach enables to compare different ways of plastic processing. [GRAPHICS] .
English abstract
The recent social care about the concentration of plastics in the ocean arises with the necessity of developing solutions to this problem. Some projects are dealing with the technology of collection, however, the follow-up transfer onshore is not usually included in the solution. This study suggests designing a vessel with available waste treatment technologies that can use the waste to recover energy. Simultaneously, the technologic vessel has to regularly visit collectors and ports to supply produced commodities and crew. A mixed integer linear model is developed to find the optimal balance between capacities of considered technologies and also to simulate the voyage with all respective operations. Waste-to-Energy, pyrolysis, desalination, sorting and other mechanical processes are assumed onboard. The vessel is designed to utilize the produced energy and products onboard including heat generation, electricity, water, and oil. The evaluation of suitable technologies is realized through techno-economic models which are needed for all considered subsystems from the complex treatment chain. The analysis of project viability requires detailed multi-disciplinary data. The main output of the presented approach is sensitivity analysis for critical parameters, which gives greater insight into the issue and directs further research from a general level through the concept to refine the input data and boundary conditions of the task in the model. The Pacific Garbage Patch was chosen as the testing area for the case study. The presented approach enables to compare different ways of plastic processing. [GRAPHICS] .
Keywords in English
Clean ocean; Garbage patch; Plastic in the ocean; Waste treatment; Optimization; Plastic waste; Energy and material recovery
Released
01.12.2021
Publisher
SPRINGER
Location
DORDRECHT
ISSN
1877-2641
Volume
12
Number
1
Pages from–to
6523–6541
Pages count
19
BIBTEX
@article{BUT171961,
author="Vlastimír {Nevrlý} and Radovan {Šomplák} and Lenka {Szásziová} and Jaroslav {Pluskal} and Vít {Procházka},
title="Offshore Conceptual Plastic Waste Collection and Treatment Towards Clean Ocean",
year="2021",
volume="12",
number="1",
month="December",
pages="6523--6541",
publisher="SPRINGER",
address="DORDRECHT",
issn="1877-2641"
}