Steps for the Implementation of Equipment Operating on the Principle of Thermal Drying for the Disposal of Waste Water and Bio-Waste Generated on Cruise Ships

Attila Kári-Horváth; Zsolt Lantos; Ákos Sztancsek; Gábor Kristóf

doi:10.4028/p-Tvy75s

Paper Titles

Comparison of Turbulence Models in the Simulation of Fluid Flow in Corrugated Channel
p.53

Design for Modularity (DFM) Theory and Practice Modular Design of Giant 3D-Printer and 3D-Printed Products
p.67

New Design Solution of Reference Device with Model Eye
p.81

An Overview of the Development Process of Universal Gear Reducers with External Helical Gears
p.87

Steps for the Implementation of Equipment Operating on the Principle of Thermal Drying for the Disposal of Waste Water and Bio-Waste Generated on Cruise Ships
p.97

Predicting Remaining Useful Life Using AdaBoost Algorithm
p.107

Manufacturing and Assembling the Components of a Mechanical Seal Testing Bench
p.115

Improvement of Physical Security through Continuous Authentication for SCADA and DCS Systems in Industrial Automation and Control Systems
p.123

Simulation of the Value Stream in the Field of an Industrial Process Using Visual Components
p.129

HomeAdvances in Science and TechnologyAdvances in Science and Technology Vol. 165Steps for the Implementation of Equipment...

Steps for the Implementation of Equipment Operating on the Principle of Thermal Drying for the Disposal of Waste Water and Bio-Waste Generated on Cruise Ships

Abstract:

The majority of passengers on sea cruises do not even think that they endanger the environment and human health more with a cruise of at least one week than if they had chosen another way of travel. The large amount of fuel burned during the journey pollutes the atmosphere and thus endangers health, and all kinds of (dangerous) waste and sewage generated daily on ships cannot remain on board. A ship carrying an approx. 3,000 passengers produces an average of nearly 80 m3 of wastewater per day! Newer ships are often capable of carrying 8,000 passengers, so their daily waste water production is obviously larger than this. It is enough to see these huge floating cities with 10-12 floors (Fig. 1.)

You might also be interested in these eBooks

The 10th International Scientific Conference on Advances in Mechanical Engineering (ISCAME)

View Preview

10th International Scientific Conference on Advances in Mechanical Engineering

View Preview

Info:

Periodical:

Advances in Science and Technology (Volume 165)

Pages:

97-105

DOI:

https://doi.org/10.4028/p-Tvy75s

Citation:

Cite this paper

Online since:

June 2025

Authors:

Attila Kári-Horváth*, Zsolt Lantos, Ákos Sztancsek, Gábor Kristóf

Keywords:

Disposal, MARPOL Convention, Sewage, Ship-Generated Waste, Waste Recovery

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] https://www.travelo.hu/tavol/20220222-florida-a-vilag-legnagyobb-tengerjaro-hajo.html

Google Scholar

[2] Kaszáné Dr. Kiss Magdolna: Hulladékgazdálkodás. Debrecen: Debreceni Egyetem, 2003.

Google Scholar

[3] Szira Zoltán: A települési szilárd hulladék keletkezésének összefüggésvizsgálata, valamint az önkormányzatok által biztosított hulladékkezelési közszolgáltatások elemzése pest megyében. PhD értekezés. Gödöllő: Szent István Egyetem, 2010.

Google Scholar

[4] C.L. Hii, S.V. Jangam, S.P. Ong and A.S. Mujumdar: Solar Drying: Fundamentals, Applications and Innovations. 2012.

Google Scholar

[5] Yuan J, Zhang D, Li Y. , et alEffects of adding bulking agents on biostabilization and drying of municipal solid waste. Waste Manage. 2017;62:52–60.

DOI: 10.1016/j.wasman.2017.02.027

Google Scholar

[6] Ragazzi M, Rada EC, Panaitescu V, Apostol T. Municipal solid waste pre-treatment: A comparison between two dewatering options. WIT Trans Ecol Environ. 2007;102:943–949

DOI: 10.2495/sdp070902

Google Scholar

[7] Water Environment Federation. Residuals and Biosolids Committee Bioenergy Technology Subcommittee. Fact Sheet: Drying of wastewater solids. January2014. [Internet]

Google Scholar

[8] Virág, S; Montvajszki, M; Korzenszky, P (2015) Termikus hulladékkezelési eljárások, 295 p. Szarvas, 2015. TÁMOP-4.2.2.A-11/1/KONV-2012-0015 projekt: Alapkutatás fejlesztés a Szent István Egyetem Pirolízis Technológia Központjában.

Google Scholar

[9] Lányi K; Molnar E; Vanó I; Korzenszky P. (2014) Looking Behind The Process of Pyrolysis in Waste Management: Questions on The Composition and Quality of End-Product and Their Answers by Meas of Analytical Chemistry, Hungarian Agricultural Engineering 26 pp.25-28, 4 p.

DOI: 10.17676/hae.2014.26.25

Google Scholar

[10] Dhaundiyal A., Toth L.: Thermo-economic assessment of a bench-scale pyrolysis unit through a process simulator, BIOFUELS BIOPRODUCTS & BIOREFINING-BIOFPR 17 : 6 pp.1681-1697. , 17 p. (2023)

DOI: 10.1002/bbb.2535

Google Scholar

[11] Korzenszky P.; Lányi K.; Simándi P., (2015) Test Results of a Pyrolysis Pilot Plant in Hungary Hungarian Agricultural Engineering: 28 pp.48-52, 5 p

DOI: 10.17676/hae.2015.28.48

Google Scholar

[12] Martin Jőgeva. (2014): Modularisation of passenger ship hotel areas, Espoo

Google Scholar