Review and Prospect of Shipbuilding Industry Heritage Regeneration Research

QI Huanyue; DU Xiaohui; HUANG Xianming; ZHAO Chaorui; WANG Ting

doi:10.13204/j.gyjzG23083017

Volume 53 Issue 12

Dec. 2023

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Article Navigation > INDUSTRIAL CONSTRUCTION > 2023 > 53(12): 19-28

OU Jiajia, YANG Xuebing, WANG Xijun, LI Zheng. LATERAL PERFORMANCE OF CROSS-LAMINATED TIMBER WALLS WITH TWO DIFFERENT CONSTRUCTION TYPES[J]. INDUSTRIAL CONSTRUCTION, 2020, 50(3): 84-87,113. doi: 10.13204/j.gyjz202003014

Citation:

QI Huanyue, DU Xiaohui, HUANG Xianming, ZHAO Chaorui, WANG Ting. Review and Prospect of Shipbuilding Industry Heritage Regeneration Research[J]. INDUSTRIAL CONSTRUCTION, 2023, 53(12): 19-28. doi: 10.13204/j.gyjzG23083017

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Review and Prospect of Shipbuilding Industry Heritage Regeneration Research

doi: 10.13204/j.gyjzG23083017

1. CSSC International Engineering Co., Ltd., Beijing 100121, China;
2. Architectural Design and Research Institute of Tsinghua University Co., Ltd., Beijing 100084, China

Received Date: 2023-08-30
Available Online: 2024-02-28

Abstract

Abstract

The heritage of the shipbuilding industry is a microcosm of modern industry, witnessing the transformation of modern Chinese society. In the context of traditional industrial model land concessions, production function transformation, and urban stock development, sorting out the current research content on the regeneration of shipbuilding industry heritage and deducing important future development directions can provide theoretical reference and future guidance for the protection and regeneration, good transformation, and cultural heritage inheritance of shipbuilding industry heritage. Through the review and analysis of research results related to the regeneration of shipbuilding industry heritage, it is found that:firstly, the research hotspots of shipbuilding industry heritage regeneration are landscape design, value evaluation, urban renewal, protection and regeneration, sustainable development, etc., and the disciplinary background presents interdisciplinary characteristics. Secondly, there are different research directions and trends in domestic and overseas development. Foreign research has developed faster than domestic research, with a prominent focus on ecological restoration, environmental governance, green sustainability, and circular design, providing guidance for China's future development. Thirdly, the research on the regeneration of shipbuilding industry heritage in the new era should further explore the direction of environmental quality improvement and sustainable development under the general trend of circular economy, and introduce new trends such as intelligent construction, carbon neutrality, and digital technology for research.
- shipbuilding heritage,
- regeneration,
- sustainable development,
- recycle,
- intelligence

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References(34)

References

[1]	陈丽. 广东船舶工业遗产研究[D].广州:华南理工大学,2021.
[2]	孟璠磊,崔振美,刘伯英.近代北京工业建设史及工业建筑遗产价值研究[J].工业建筑,2021,51(7):78-83 ,112.
[3]	杨滨章.昔日旧码头今朝滨水园:丹麦哥本哈根市港口公园设计艺术探析[J].中国园林,2010,26(2):60-64.
[4]	张浩然. 城市更新视角下船舶工业遗存景观设计研究[D].常州:常州大学,2022.
[5]	黎启国,储石韦,帅新元.我国工业遗产保护与利用地方法律法规及政策比较研究[J].工业建筑,2022,52(11):120-124 ,156.
[6]	刘伯英.美国国家公园保护体系中的工业遗产保护[J].工业建筑,2019,49(7):1-8.
[7]	刘雪娇.国内工业遗产再利用研究综述[J].智能建筑与智慧城市,2021(4):35-38.
[8]	林琳.福建船政建筑的工业遗产价值新探[J].工业建筑,2019,49(7):24-29.
[9]	孟璠磊.论"工业建筑"到"工业建筑遗产"的四个发展阶段[J].工业建筑,2019,49(5):1-6.
[10]	LORENS P, BUGALSKI Ł. Reshaping the gdańsk shipyard:the birthplace of the solidarity movement. The complexity of adaptive reuse in the heritage context[J/OL]. Sustainability, 2021, 13(13)[2021-11-29].https://www.mdpi.com/2071-1050/13/13/7183.
[11]	DALDANISE G, CLEMENTE M. Port Cities Creative Heritage Enhancement (PCCHE) scenario approach:culture and creativity for sustainable development of naples port[J/OL]. Sustainability, 2022, 14(14)[2022-11-29].https://www.mdpi.com/2071-1050/14/14/8603.
[12]	PAZZINI M, CORTICELLI R, LANTIERI C, et al. Multi-criteria analysis and decision-making approach for the urban regeneration:the application to the rimini canal port (Italy)[J/OL]. Sustainability, 2022, 15(1)[2022-11-29].https://www.mdpi.com/2071-1050/15/1/772?src=429271.
[13]	WU Y, LIU Y. Transforming industrial waterfronts into inclusive landscapes:a project method and investigation of landscape as a medium for sustainable revitalization[J/OL]. Sustainability, 2023, 15(6)[2023-11-29].https://www.mdpi.com/2071-1050/15/6/5060.
[14]	ALIHODŽIĆ J E, PEROVIĆ S, PAUNOVIĆ Ž S. Impacts of arsenal brownfield regeneration on urban development of Tivat in Montenegro:from industrial settlement to center of nautical tourism[J/OL]. Sustainability, 2021, 13(15)[2021-11-29].https://www.mdpi.com/2071-1050/13/15/8549.
[15]	彭月. 工业遗产视角下的江南制造局建设发展研究[D].泉州:华侨大学,2022.
[16]	陆双. 工业遗产视角下福建船政研究[D].福州:福州大学,2016.
[17]	陈康琪. 叙事学视角下的澳门荔枝碗旧船厂保护与再生改造[D].广州:仲恺农业工程学院,2022.
[18]	朱伟静.基于雅克·德里达解构主义的南京金陵船厂景观更新设计研究[J].美与时代(城市版),2022(6):52-54.
[19]	张家浩. 我国工业遗产信息采集与管理体系建构研究[D].天津:天津大学,2018.
[20]	张雪津. 我国军用工业遗产的价值评估及保护再利用研究[D].张家口:河北建筑工程学院,2019.
[21]	李建,陈青长,马溪茵."纤维街区"理念下的上海杨浦船厂片区城市设计策略探讨[J].规划师,2021,37(13):43-49.
[22]	金旖旎.基于水陆一体化TOD理念的滨江更新策略:以杨浦滨江船厂更新为例[J].城市建筑,2021,18(11):164-166.
[23]	黄平.基于"绿色再生"理念下的船政文化马尾造船厂片区工业遗产保护实践[J].福建建筑,2021(5):32-35.
[24]	庞定坤. 城市工业棕地再生设计研究[D].天津:天津美术学院,2022.
[25]	王治宜.绿色船舶工业的内涵及评价准则[J].舰船科学技术,2023,45(3):182-185.
[26]	徐苏斌,青木信夫,张松,等.笔谈:变"锈"为"秀",工业遗产保护和再利用新思路新发展[J].中国文化遗产,2022(3):4-18.
[27]	GRAVAGNUOLO A, ANGRISANO M, FUSCO GIRARD L. Circular economy strategies in eight historic port cities:criteria and indicators towards a circular city assessment framework[J/OL]. Sustainability, 2019, 11(13)[2019-11-29].https://www.mdpi.com/2071-1050/11/13/3512.
[28]	NOROUZI M, CHÀFER M, CABEZA L F, et al. Circular economy in the building and construction sector:A scientific evolution analysis[J/OL]. Journal of Building Engineering, 2021, 44[2021-11-29].https://www.sciencedirect.com/science/article/pii/S2352710221005623.
[29]	BADAWY N M, EL SAMATY H S, WASEEF A A E. Relevance of monocrystalline and thin-film technologies in implementing efficient grid-connected photovoltaic systems in historic buildings in Port Fouad city, Egypt[J]. Alexandria Engineering Journal, 2022, 61(12):12229-12246.
[30]	刘雨萌. 产景共融下秦皇岛造船厂景观重塑设计研究[D].秦皇岛:燕山大学,2021.
[31]	杨震宇,李笑寒.船厂工业遗址的再生:悉尼鹦鹉岛景观设计[J].建筑与文化,2021(11):131-132.
[32]	华怡雯,刘源.工业文化传承下的船厂废弃地景观更新研究[J].广东园林,2021,43(5):31-36.
[33]	丁芹.滨海船厂废弃地的植物景观营造:以青岛东风船厂改造段为例[J].现代园艺,2021,44(17):99-102.
[34]	刘伯英.关于中国工业遗产科学技术价值的新思考[J].工业建筑,2018,48(8):1-7 ,60.

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