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Dissertation
Year: 2021 Publisher: Liège Université de Liège (ULiège)
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The safety of navigation at sea is closely connected to the reasonable operation of the marine power transmission system of a vessel. The propulsion unit inside a ship is considered as one of the most significant on-board systems that is mostly subjected to dynamic loading. The dynamic behavior can cause various vibrations along the propulsion line that will substantially affect the propulsion shaft’s reliability and efficiency. In general, the most vital factor that can influence the shafting design is the shafting vibration behavior, particularly the torsional vibration behavior. The demand for proper vibration analysis grows rapidly in the last decade due to the growing adverse effects of fatigue failures in the shaft machinery systems, and also to define and identify the main torsional vibration characteristics as they differ from other types of vibrations to an extent. Hence the validity of a proper shafting design can only be checked through a detailed torsional vibration analysis.
Dissertation
Year: 2022 Publisher: Liège Université de Liège (ULiège)
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ABSTRACT With the enormous demands and busy schedules of water transportation by the sea-going vessels, the propulsion system and components are taking part in one of significant roles. In order to navigate the ship into the water, the marine propellers are crucial to be efficiently and safely designed. Typically there are two types of propellers: fixed pitch propeller (FPP) and controllable pitch propeller (CPP), depending on application and mission. Unlike CPP, a built-up propeller does not include a hydraulic system to control the pitch of the blades but each blade can be replaced in the case of damage. This thesis is specifically focused on the design of the blade and hub joint for a built-up propeller. Additionally, it is intended for the application of ice class for the ship operating in the Baltic Sea with the ice strengthening materials. There are some obvious benefits of using built-up propellers. It is a comparatively much simpler and faster change of blades than conventional mono-block propellers without the need for dry docking and dismounting facilities if the blades are necessary to be repaired and replaced. For the blade-hub joint design, there are some possible configurations having their own benefits and drawbacks. But finally bolted joint design was selected in the aspects of flexible manufacturing capabilities, easy to mount or dismount the blade on the hub with less effort, with the least impact on vessel operation. Blades are mounted on the hub and the hub assembly is connected to the propeller shaft. There are some available shaft connection methods. Considering the design aspects to support the structure of the hollow hub, and with experiences and suggestions from (MMG personal communication), shrink fit or keyless fitting was chosen. A detailed 3D of the built-up propeller assembly was modelled in Rhino. Also, Siemens NX was used for blade fillet and detailed bolt threads modelling. Blade-hub assembly design was developed complying with GL and Finnish-Swedish Ice Class Rules. The special bolts to connect the blade and hub were designed according to VDI2230, DIN EN ISO 3506-1 and ANSI/ASME B1 standards. Analytical strength calculations for the bolted joint have been performed and the results were compared to Ansys structural analysis for different load cases and FE models to get a safe and efficient design.
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