Wind, Wave, and Current Loads on Semisubmersibles

Walree, Frans van; Boom, H J

doi:10.4043/6521-ms

Cited by 6 publications

(4 citation statements)

References 1 publication

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“…The tension analysis of mooring lines and FSO offsets is carried out regarding the dynamic formulation of floating body motions [19,27,28]. Variables in eq.…”

Section: Mooring Analysismentioning

confidence: 99%

Selection of mooring system configuration of a FSO using multi-criteria methods

Murdjito,

Shidqi,

Wardhana

et al. 2023

IOP Conf. Ser.: Earth Environ. Sci.

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In order to maintain and restrain the movement of a temporary storage tanker during the loading and offloading process, it is necessary to design a mooring system that is safe and reliable for its operation needs. The main problem that must be solved in this research is choosing the appropriate mooring system configuration for the temporary storage tanker equipped with a catenary mooring configuration that can be used for oil loading operations from the storage tanker to a transport tanker using the ship to ship method. This research focusses in the selection of mooring system configurations based on the strength of the anchor chain. There are nine alternatives configurations and predetermined criteria that were carried out in the study. Each alternative configuration will provide a different value of tension in each mooring line and ship movement. The analysis of the mooring tension is carried out using dynamic method with time domain approach. There are many criteria to be considered in the selection of the alternatives. The analytical hierarchical process (AHP) method is used in the selection of the best configuration based on multi criteria conditions. As case study of the study is a temporary storage tanker at Papa Field in Pertamina (Persero) ONWJ operation area as temporary storage taker is an Aframax tanker size.

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“…The tension analysis of mooring lines and FSO offsets is carried out regarding the dynamic formulation of floating body motions [19,27,28]. Variables in eq.…”

Section: Mooring Analysismentioning

confidence: 99%

Selection of mooring system configuration of a FSO using multi-criteria methods

Murdjito,

Shidqi,

Wardhana

et al. 2023

IOP Conf. Ser.: Earth Environ. Sci.

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“…Where, T max = maximum tension of mooring line (tons) T H = horizontal pre-tension (ton) w = chain weight in water (ton/m) h = water depth (m) The analysis of mooring line tension and FSO offset is performed with respect to the dynamic formulation of the floating body motion [13,14,15]. The variables in eq.…”

Section: E Dynamic Analysis Of Mooring Systemmentioning

confidence: 99%

Fatigue Life Analysis of FSO Mooring Chain by Considering the Effects of Offloading Load

Shidqi,

Syahroni,

Rosyid

et al. 2023

IJMEIR

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⎯mooring chains are critical components in the maritime industry used to secure ships and floating oil and gas platforms such as FSOs to stay in their designated positions. The loads exerted on mooring chains during routine operations and additional loads during offloading operations can cause structural fatigue. Therefore, fatigue life analysis of mooring chains is essential to ensure safety and optimal performance. This study aims to conduct fatigue analysis of mooring chains by considering an important factor, namely the influence of offloading. Offloading load refers to the additional load exerted on the mooring chain during loading and unloading operations. The mooring system configuration uses a spread mooring system of 8 chains (4x2), 87 mm in diameter, with 20% pretension. In the fatigue analysis, the "Palmgren-Miner" method was used to evaluate the accumulated damage caused by cyclic loads. Then, the "Rainflow Counting" method is used to identify and count the number of load cycles that occur so that later the fatigue life can be calculated and known. From the research results, it was found that the mooring system configuration design still meets the safety factor requirements recommended by API RP 2 SK both during SLS, ULS, and FLS analysis. In SLS and ULS conditions, the greatest tension value is when the FSO is in the Ballast load condition, with the maximum value of tension that occurs is 2207.4 kN in SLS conditions, and 4151.6 kN in extreme conditions. In the FLS condition analysis, it was found that with an offloading frequency of 24 times per year (1271.89 hours), in the design configuration, the influence of the offloading system can increase up to 7% of the fatigue damage that occurs, and the lowest fatigue life, reduced by 3 years. The least fatigue life occurs in Chain 1.2 at the splash zone segment, which is 67 years.

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“…where: According to van Malree and van de Boom [9] the source of excitation may comprise the firstorder wave (…”

Section: Applied Mechanics and Materials Vol 874 55mentioning

confidence: 99%

Analysis on the Critical Conditions of Side-by-Side Offloading Operation between SSP Type-FPSO and Shuttle Tanker

Murdjito¹,

Rosari

Djatmiko³

2018

AMM

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Evaluation is carried out on the operability of a 87,900 ton Sevan Stabilized Platform (SSP) functioned as an FPSO in the hypothetical operational site of Masela Block. This is to observe the critical conditions when side-by-side (SBS) offloading is performed between the SSP and a 35,000 DWT shuttle tanker. The first stage of analysis conducted on the moored SSP as a single floating body indicates the capability to withstand a 100-year wave, designated by the significant height of 8.0 m. Largest motions are experienced when SSP contains 75% load capacity, resulting in the mooring tension range from 2,000 kN up to 7,000 kN, portraying ample safety factors of 2.0 up to 3.0. The second stage of analysis is conducted for execution of SBS offloading from SSP to shuttle tanker, positioned in a 3.3 m distance. Observation is made when SSP is loaded with 100%, 83%, and 75% capacities correlated to the shuttle tanker loading of 10%, 60%, and 90% capacities. This reveals critical conditions arise when the wave exceeds 2.0 m in height, or the operability level of some 88.5%. Safer operation and higher operability level could be achieved by increasing the distance of SSP and shuttle tanker.

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Wind, Wave, and Current Loads on Semisubmersibles

Cited by 6 publications

References 1 publication

Selection of mooring system configuration of a FSO using multi-criteria methods

Selection of mooring system configuration of a FSO using multi-criteria methods

Fatigue Life Analysis of FSO Mooring Chain by Considering the Effects of Offloading Load

Analysis on the Critical Conditions of Side-by-Side Offloading Operation between SSP Type-FPSO and Shuttle Tanker

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