Variation Propagation Analysis of Hull Flat Block Construction Process Based on State Space Model

IF 0.5 4区工程技术 Q4 ENGINEERING, MARINE

Journal of Ship Production and Design Pub Date : 2023-07-06 DOI:10.5957/jspd.06220019

Liang Chen, Naikun Wei, Yu Zheng, Juntong Xi

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引用次数: 0

Abstract

Hull flat block (HFB) construction is a typical discrete manufacturing process, during which block deviation is accumulated. To satisfy the dimensional requirements of shipowners, the variation propagation during HFB construction must be modeled and analyzed. Based on the stream of variation theory, the construction process is analyzed to provide a reference for controlling the deviation. In the hull construction process, the deviation is categorized into part deviation, location deviation, and welding deviation. By analyzing the causes of the different deviations, the different deviations and their accumulations can be calculated. A HFB is used to verify the proposed model, and the results show that the method can be used to calculate the deviation to the HFB. As a typical large-scale complex equipment, the hull construction process is extremely time-consuming and laborious. The final hull is composed of intermediate products, such as subassemblies, unit assemblies, and grand-assemblies (Cho et al. 1999). Since the group technology was applied in hull construction, a series of production lines has been established based on the process similarity of parts, components, blocks, and grand blocks. The actual dimension of parts would inevitably deviate from the theoretical dimension (Mandal 2017), i.e., dimensional and shape deviations will occur owing to many factors (Okumoto 2002). In the hull construction process, the deviation from the previous process will be propagated to the current process and coupled with the deviation in the current process, thereby affecting the accuracy of the product. Hence, the product must be repaired to satisfy the design requirements (Takechi et al. 1998). This will prolong the production cycle and reduce the production efficiency (Heo et al. 2015). It was discovered that the man-hours of the main operations during hull assembly constituted only one-sixth of the total assembly manhours, whereas the man-hours used for adjustment constituted one-third (Chen et al. 2020). Currently, shipyards need to eliminate the adjustment operation to avoid unnecessary rework, as well as reduce human and material resources in subsequent processes. Tanigawa (2003) estimated that an ideal ship construction accuracy control plan can reduce the production cost by 5%. Therefore, the accuracy of the hull construction process must be controlled and improved in shipyards, and a reasonable accuracy control plan should be devised to improve the product quality.

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基于状态空间模型的船体平块施工过程变异传播分析

船体扁块（HFB）施工是一个典型的离散制造过程，在这个过程中，块偏差会累积。为了满足船东的尺寸要求，必须对HFB建造过程中的变化传播进行建模和分析。基于变异流理论，对施工过程进行分析，为控制偏差提供参考。在船体建造过程中，偏差分为零件偏差、位置偏差和焊接偏差。通过分析不同偏差产生的原因，可以计算出不同偏差及其累积量。使用HFB来验证所提出的模型，结果表明该方法可以用于计算与HFB的偏差。作为一种典型的大型复杂设备，船体建造过程极其耗时费力。最终船体由中间产品组成，如子组件、单元组件和大组件（Cho等人，1999）。自成组技术应用于船体建造以来，已经建立了一系列基于零部件、块体和大块体工艺相似性的生产线。零件的实际尺寸将不可避免地偏离理论尺寸（Mandal 2017），即，由于许多因素，将出现尺寸和形状偏差（Okumoto 2002）。在船体建造过程中，与前一过程的偏差会传播到当前过程中，并与当前过程中的偏差相耦合，从而影响产品的精度。因此，必须对产品进行维修以满足设计要求（Takechi等人，1998）。这将延长生产周期并降低生产效率（Heo等人，2015）。研究发现，船体组装期间主要操作的工时仅占总组装工时的六分之一，而用于调整的工时占三分之一（Chen等人，2020）。目前，船厂需要取消调整操作，以避免不必要的返工，并减少后续流程中的人力和物力。Tanigawa（2003）估计，一个理想的船舶建造精度控制计划可以将生产成本降低5%。因此，船厂必须控制和提高船体建造过程的精度，并制定合理的精度控制计划，以提高产品质量。

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来源期刊

Journal of Ship Production and Design ENGINEERING, MARINE-

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： Original and timely technical papers addressing problems of shipyard techniques and production of merchant and naval ships appear in this quarterly publication. Since its inception, the Journal of Ship Production and Design (formerly the Journal of Ship Production) has been a forum for peer-reviewed, professionally edited papers from academic and industry sources. As such it has influenced the worldwide development of ship production engineering as a fully qualified professional discipline. The expanded scope seeks papers in additional areas, specifically ship design, including design for production, plus other marine technology topics, such as ship operations, shipping economics, and safety. Each issue contains a well-rounded selection of technical papers relevant to marine professionals.