Thrust and Torque Analysis on Propeller C4-40 with The Addition of Kort Nozzle to Pitch Variation

Irfan Syarief Arief, Achmad Baidowi, Maria Ulfa

Abstract


At this time there are various types of propellers, one of which is the CPP propeller (Controllable pitch propeller). The CPP propeller can change pitch angles, and at certain pitches it can pull the ship backwards without having to change the rotation. But keep in mind that the CPP has only one pitch design where changing the pitch position means reducing the efficiency of the propeller. So it takes a kort nozzle to increase efficiency. The addition of a kort nozzle is one of the developments of an Energy Saving Device (ESD) which in addition to increasing efficiency it is also able to increase the thrust. Problem formulation of this research is to find out changes in thrust, torque and efficiency on the propeller CPP C4-40 after the addition of kort nozzle 37. This research begins with determining the dimensions of the propeller, also the types and dimensions of the nozzle. Then the design and drawing of the propeller C4-40 with a kort nozzle 37 was carried out for pitch changes of 0°, 22.5° and 45°. The next step is a meshing process where each pitch the number of meshing ranges from 2.3 to 3.5 million cells. The last step is to simulate the performance of the propeller with the nozzle using software based on Computational Fluid Dynamic.  From this research, it can be concluded that the addition of kort nozzle 37 on the propeller C4-40 changes the thrust, torque and efficiency values significantly. Thrust only increased at pitch 0° J 1.4 and pitch 22.5°. The greatest increase in thrust at pitch 22.5° J 0.6 is 88.74%. Torque is reduced except for pitch 0° J 0.8-1.4. The biggest decrease in torque at pitch 45° J 1.2 is 83%. Meanwhile efficiency has decreased at all pitch angles. Where the biggest decrease in pitch 45° J 1 is 99.83%.

Keywords


CFD; CPP; efficiency; kort nozzle; thrust; torque

Full Text:

PDF

References


Harvald, Sv.Aa. 1983. Resistance and Propulsion of Ship. A Wiley-Interscience Publication: Denmark.

Putra, Pradika Desto, Andi Trimulyono, Eko Sasmito Hadi. 2015. Analisa Pengaruh Pemasangan Energy Saving Device (ESD) Propeller Boss Cap Fins (PBCF) dan Kort Nozzle pada Propeller Type B-Series dan Propeller Type AU Terhadap Gaya Dorong Propeller dengan Metode CFD. Program Study S1 Teknik Perkapalan. Fakultas Teknik, Universitas DIponegoro

Carlton, J. 2007. Marine Propeller And Propulsion Second Edition. Boston: ELSEVIER

Huda, Nurul. 2013. Analisa pengaruh Energy Saving Device pada Propeller dengan Metode CFD. Tugas Akhir, Jurusan Teknik Perkapalan, UNDIP: Semarang

G. Kuiper. 1992. ‘The Wageningen Propeller Series’. MARIN Publication 92-001, published on the occasion of its 60th anniversary, Wageningen, the Netherlands

Elbatran. 2014. Stationary and Low Speed Performance Characteristics of Open and Ducted CPPs. International Marine and Offshore Engineering Conference (IMOC 2014)

Bhattacharyya, Arniban, Vladimir Krasilnikov, Sverre Steen. 2016. Scale effect on open water characteristics of a controllable pitch propeller working within different duct design. Ocean Engineering 112 (2016) 226-242

Carlton, J. 2010. Marine Propeller and Propulsion Second Edition. Selsevier Ltd. USA

Schwer, E. L., 2008. Is Your Mesh Refined Enough? Estimating Discretization Error Using GCI. Bamberg: LS-DYNA Anwenderforum.




DOI: http://dx.doi.org/10.12962/j25481479.v6i3.10631

Refbacks

  • There are currently no refbacks.


Abstracted / Indexed by:
      
  

 

 

 

 

 

P-ISSN: 2541-5972   

E-ISSN: 2548-1479

 

Lisensi Creative Commons

IJMEIR journal published by  Department of Marine Engineering, Faculty of Marine Technology, Institut Teknologi Sepuluh Nopember Surabaya Indonesia under licenced Creative Commons Attribution-ShareAlike 4.0 International Licence. Based on https://iptek.its.ac.id/index.php/ijmeir/