Design and Operational Innovations in Adapting the Existing Merchant River Fleet to Cost-Effective Shipping

1. Abramowicz-Gerigk T., Burciu Z., Jachowski J. (2017): An innovative steering system for a river push barge operated in environmentally sensitive areas. Polish Maritime Research, 4 (96) Vol. 24, 27–34.10.1515/pomr-2017-0132 Search in Google Scholar

2. Abramowicz-Gerigk T., Burciu Z. (2018): Manoeuvring characteristics of the push train with an auxiliary steering device. Journal of KONES Powertrain and Transport, Vol. 25 (2), 7–14. Search in Google Scholar

3. Abramowicz-Gerigk T., Burciu Z., Krata P., Jachowski J. (2017): Steering system for a waterborne inland unit. Patent application P. 420664. Search in Google Scholar

4. Abramowicz-Gerigk T., Blachuta J., Burciu Z., Granatowicz J., Jacyna M., Kulczyk J., Mazurek M., Nowakowski T., Picinska-Faltynowicz J., Skupien E., Tubis A., Werbinska-Wojciechowska S., Wieckowska M., Winter J. (2014): INVAPO, European project Upgrading of Inland Waterway and Sea Ports. Report of WP5 coordinated by Gdynia Maritime University, Gdynia 2014. Search in Google Scholar

5. Annual Report Year 2018 (2018): Freight traffic on inland waterways and in ports. Retrieved from http://www.inland-navigation-market.org/en (accessed 01.03.2019). Search in Google Scholar

6. Assumptions for the plans of inland waterways development in Poland in 2016/2020 with the perspective to 2030. (2016): Ministry of Maritime Economy and Inland Navigation. Document accepted by the Council of Ministers 14 June 2016. Search in Google Scholar

7. Bai B., Jawale M., Noche B. (2016): Evaluative Comparison of Inland Shipping with Multimodal Transports for Seasonal Commodity Supplies through Simulation. 16th COTA International Conference of Transportation Professionals.10.1061/9780784479896.048 Search in Google Scholar

8. Bawelska A., Brzezinska J., Radlinska M. (2018): GUS, Inland waterways transport in Poland in 2014–2017. Statistics Poland. Statistical Office in Szczecin. Warszawa, Szczecin 2018. Search in Google Scholar

9. DNVGL (2018): Autonomous and remotely operated ships. CLASS GUIDELINE. Edition DNVGL-CG-0264, September 2018. Search in Google Scholar

10. EMMA Enhancing freight mobility and logistics in the BSR by strengthening inland waterway and river sea transport and promoting new international shipping services – project funded by Interreg Baltic Sea Region Programme 2014–2020 (2019): retrieved from http://project-emma.eu (accessed 12.03.2019). Search in Google Scholar

11. Gerigk M. K. (2015): An Integrated Model of Motion, Steering, Positioning and Stabilization of an Unmanned Autonomous Maritime Vehicle. TransNav – The International Journal on Marine Navigation and Safety of Sea Transp.ortation, Vol. 9 (4), 591–596.10.12716/1001.09.04.18 Search in Google Scholar

12. King K. K., Yasukawa H., Hirata N., Kose K. (2008): Manoeuvring simulations of pusher-barge systems. Journal of Marine Science and Technology, Vol. 13, 117–126.10.1007/s00773-007-0267-4 Search in Google Scholar

13. Kulczyk J., Lisiewicz T., Nowakowski T. (2012): New generation of the fleet on Oder Waterway. Prace Naukowe Politechniki Warszawskiej, 82. Search in Google Scholar

14. Liu J., Hekkenberg R., Rotteveel E. A. (2014): Proposal for Standard Manoeuvres and Parameters for the Evaluation of Inland Ship Manoeuvrability. European Inland Waterway Navigation Conference 2014, Budapest, Hungary. Search in Google Scholar

15. Market Observation Report on Inland Navigation in Europe (2016): First annual report published by the CCNR in collaboration with the European Commission. CCNR Press Release Ref: CC/CP (16)05 | 30. Search in Google Scholar

16. PIANC (2008): Considerations to reduce environmental impacts of vessels navigation. PIANC Report N° 99, 2008. Inland Navigation Commission. www.pianc.org. Search in Google Scholar

17. PRS Rules (2010): Navigability and manoeuvrability tests of inland waterway vessels and convoys. Polish Register of Shipping. Search in Google Scholar

18. Rabant H., Habel M., Babinski Z. (2016): Transport of the oversized goods on the Vistula waterway. The basic waterway parameters and main difficulties. Works of Commission of Communication Geography PTG 2016, 19(3), 7–17. Search in Google Scholar

19. Skupien E., Prokopowicz J. (2014): Methods of calculating ship resistance on limited waterways. Polish Maritime Research, 4, Vol. 21, 2–17.10.2478/pomr-2014-0036 Search in Google Scholar

20. Tabaczek T., Kulczyk J., Zawislak M. (2007): Analysis of hull resistance of pushed barges in shallow water. Polish Maritime Research, 1 (51), Vol. 14, 10-15.10.2478/v10012-007-0002-4 Search in Google Scholar

21. Van Dijk T., Moonen H., van Doorser H., Negenborn R., van den Berg R. (2018): Smart ships and the changing maritime ecosystem. How digitalization and advanced automation of barges, service vessels and sea ships create new opportunities and challenges for the maritime industry. Smart Port 09/2018. Search in Google Scholar

22. www.fabico.pl (accessed 12.03.2019). Search in Google Scholar

23. www.navigartrans.pl (accessed 12.03.2019). Search in Google Scholar

24. www.otlogistics.com.pl (accessed 12.03.2019). Search in Google Scholar

25. www.zegluga.szn.pl (accessed 12.03.2019). Search in Google Scholar