Modification Method of Longitudinal Bow Structure for
Ice-Strengthened Merchant Ship

doi:10.1007/s12204-022-2442-5

J Shanghai Jiaotong Univ Sci ›› 2022, Vol. 27 ›› Issue (3): 298-306.doi: 10.1007/s12204-022-2442-5

收稿日期:2021-02-20 出版日期:2022-05-28 发布日期:2022-06-23

Modification Method of Longitudinal Bow Structure for Ice-Strengthened Merchant Ship

DING Shifeng¹ (丁仕风), ZHOU Li¹∗ (周利), GU Yingjie¹(顾颖杰), ZHOU Yajun² (周亚军)

(1. School of Naval Architecture and Ocean Engineering, Jiangsu University of Science and Technology, Zhenjiang 212003, Jiangsu, China; 2. Shanghai Rules and Research Institute, China Classification Society, Shanghai 200135, China)

Received:2021-02-20 Online:2022-05-28 Published:2022-06-23

摘要/Abstract

Abstract: Merchant ships, which are quite different from icebreakers, usually require the light ice-strengthened bow under the floe-ice condition. According to ice-class B, requirements of China Classification Society (CCS), intermediate frames and thick hull plates are necessary for the ice belt area to resist floe-ice impact. However, due to the limited space, it is not practical to set so many intermediate longitudinals from manufacture point of view. In this paper, a modification method is proposed to solve the problem by maintaining the frame spacing and increasing the plate thickness. The aim is to make sure that the bow owns the equivalent ice-bearing capacity with the original frame spacing. At first, a bulk carrier with ice-class B is used for case study. According to the requirements of the ice class rule, a designed ice thickness is used to calculate the ice load acting on the bow area due to the impact of ice floe. Two structural models are presented to perform the strength analysis under ice load, including the out-shell plate model and the longitudinal model. The results show that increasing the plate thickness is helpful to remove the negative effect induced by enlarging the spacing of the longitudinal. A reasonable curve is presented to modify the bow for the ice-strengthened merchant ship, which shows the relationship between the increase of plate thickness and the spacing of longitudinal. Moreover, a model test of floe-ice–ship interaction is conducted to measure the dynamic ice load, based on which nonlinear dynamic FE analysis is used to verify the presented plate-thickness–longitudinal spacing curve. The results show that the proposed method can be used to improve the ice-strengthened bow structure effectively, which provides theoretical foundation to modify the requirement of CCS’s ice class rule.

中图分类号:

U 663.5

. [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(3): 298-306.

DING Shifeng (丁仕风), ZHOU Li∗ (周利), GU Yingjie (顾颖杰), ZHOU Yajun (周亚军). Modification Method of Longitudinal Bow Structure for Ice-Strengthened Merchant Ship[J]. J Shanghai Jiaotong Univ Sci, 2022, 27(3): 298-306.

参考文献 26

[1]	China Classification Society. Rules for classification of sea-going steel ships [S]. Shanghai: Class NU, 2018.
[2]	SU B, RISKA K, MOAN T. A numerical method for the prediction of ship performance in level ice [J]. Cold Regions Science and Technology, 2010, 60(3): 177-188.
[3]	CHO S R, JEONG S Y, LEE S, et al. Development of a prediction formula for ship resistance in level ice [C]//ASME 2014 33rd International Conference on Ocean, Offshore and Arctic Engineering. San Francisco, California: ASME, 2014: OMAE2014-23681.
[4]	DING S F, ZHOU L, W ANG Z R, et al. Prediction method of ice resistance and propulsion power for polar ships [J]. Journal of Shanghai Jiao Tong University (Science), 2020, 25(6): 739-745.
[5]	HU J, ZHOU L. Further study on level ice resistance and channel resistance for an icebreaking vessel [J]. International Journal of Naval Architecture and Ocean Engineering, 2016, 8(2): 169-176.
[6]	ZHOU L, LING H J, CHEN L F. Model tests of an icebreaking tanker in broken ice [J]. International Journal of Naval Architecture and Ocean Engineering, 2019, 11(1): 422-434.
[7]	CHO S R, JEONG S Y, LEE S. Development of effective model test in pack ice conditions of square-type ice model basin [J]. Ocean Engineering, 2013, 67: 35-44.
[8]	ZHOU L, RISKA K, JI C Y. Simulating transverse icebreaking process considering both crushing and bending failures [J]. Marine Structures, 2017, 54: 167-187.
[9]	HU J , ZHOU L . Experimental and numerical study on ice resistance for icebreaking vessels [J]. International Journal of Naval Architecture and Ocean Engineering, 2015, 7(3): 626-639.
[10]	SU B, RISKA K, MOAN T. Numerical study of ice-induced loads on ship hulls [J]. Marine Structures, 2011, 24(2): 132-152.
[11]	LIU Z H, AMDAHL J. A new formulation of the impact mechanics of ship collisions and its application to a ship-iceberg collision [J]. Marine Structures, 2010, 23(3): 360-384.
[12]	MATSUI S, UTO S, YAMADA Y, et al. Numerical study on the structural response of energy-saving de- vice of ice-class vessel due to impact of ice block [J]. International Journal of Naval Architecture and Ocean Engineering, 2018, 10(3): 367-375.
[13]	JI X, KARR D G, OTERKUS E. A non-simultaneous dynamic ice-structure interaction model [J]. Ocean Engineering, 2018, 166: 278-289.
[14]	HONG L, AMDAHL J. Plastic design of laterally patch loaded plates for ships [J]. Marine Structures, 2007, 20(3): 124-142.
[15]	DALEY C, HERMANSKI G, PA VIC M, et al. Ultimate strength of frames and grillages subject to lateral loads-an experimental study [C]//10th International Symposium on Practical Design of Ships and Other Floating Structures. Houston, Texas: ABS, 2007: 17.
[16]	KIM H, DALEY C, KIM H. Evaluation of large structural grillages subjected to ice loads in experimental and numerical analysis [J]. Marine Structures, 2018, 61: 467-502.
[17]	KORGESAAR M, KUJALA P, ROMANOFF J. Load carrying capacity of ice-strengthened frames under idealized ice load and boundary conditions [J]. Marine Structures, 2018, 58: 18-30.
[18]	ZHOU L, DIAO F, SONG M, et al. Calculation methods of icebreaking capability for a double-acting polar ship [J]. Journal of Marine Science and Engineering, 2020, 8(3): 179.
[19]	Finnish Transport Safety Agency. Finnish-Swedish ice class rules (FSICR) [S]. Helsinki: FTA, 2017.
[20]	CHEN T Y, CHEN B Z. Structural mechanics for ships [M]. Shanghai: Shanghai Jiao Tong University Press, 1991 (in Chinese).
[21]	DALEY C, TUHKURI J, RISKA K. The role of discrete failures in local ice loads [J]. Cold Regions Science and Technology, 1998, 27(3): 197-211.
[22]	KIM J, KIM D, SONG H. Safety assessment of membrane type cargo containment systems in LNG carrier under the ice-ship repeated impact [C]//22nd (2012 ) International Offshore and Polar Engineering Conference Rhodes. Rhodes: ISOPE, 2012: 1194-1201.
[23]	BOND J, KENNEDY S. Physical testing and finite element analysis of icebreaking ship structures in the post yield region [J]. Proceedings of the International Offshore and Polar Engineering Conference, 1998, 2: 577-585.
[24]	WI′SNIEWSKI K, KOKOWSKI P. The effect of selected parameters on ship collision results by dynamic FE simulations [J]. Finite Elements in Analysis and Design, 2003, 39(10): 985-1006.
[25]	DALEY C G. Derivation of plastic framing requirements for polar ships [J]. Marine Structures, 2002, 15(6): 543-559.
[26]	W ANG B, YU H C, BASU R. Ship and ice collision modeling and strength evaluation of LNG ship structure [C]//ASME 2008 27th International Conference on Offshore Mechanics and Arctic Engineering. Estoril: ASME, 2009: 911-918.

Modification Method of Longitudinal Bow Structure for Ice-Strengthened Merchant Ship

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