面向林木家居产品高质量发展的智能制造赋能技术体系构建

doi:10.11707/j.1001-7488.LYKX20230427

摘要/Abstract

摘要：

家居智能制造过程中的赋能技术是加速家居智能制造转型、提升家居行业高质量发展的有效途径。本研究从近30年来家居行业智能制造基本理论和基础技术研究与应用入手，明确高质量发展所需的赋能技术及实施策略。一方面提出面向高质量发展的家居智能制造基础和过程技术创新、前沿和赋能技术推进两大技术体系和要素，搭建面向高质量发展的智能制造技术体系平台，包括总体架构和发展目标、核心内容、理论突破和基础保障、赋能技术、新发展模式、实施策略等，设定面向优质、高效、低耗、绿色、安全的家居高质量发展目标，界定智能家居产品、智能生产、智能工厂、智能物流和智能服务5方面核心内容，提出加快自动数据采集与处理、信息集成、工业互联网/物联网、建模与仿真等基础和过程技术创新思路，阐述大数据技术、工业机器人技术、智能调度和控制技术、虚拟现实和增强现实技术等构成的新型技术应用场景，解读云计算和边缘计算、数字孪生、人工智能、软件定义等前沿技术的实施途径；另一方面对技术体系进行归纳，包括基于家居信息化管控平台搭建的技术体系、基于家居产品全生命周期的数字化技术体系和基于可持续发展的家居制造生态技术体系；最后，对新一代智能制造技术在家居企业高质量发展方面提出未来研究建议：结合家居产品全生命周期数字一体化模式、互联工厂模式、商业模式重塑企业发展模式；利用数据驱动、软件定义、虚实结合和整理联系加强企业新策略的实施。

关键词: 家居智能制造, 技术体系架构, 赋能技术, 发展模式, 实施策略

Abstract:

Enabling technology in the process of intelligent manufacturing is an effective way to accelerate the transformation of furniture intelligent manufacturing and rapidly improve the high-quality development of the furniture industry. This work summarizes the fundamental theory, basic technology research, and application on furniture intelligent manufacturing in the past 30 years, and identifies the enabling technologies and implementation strategies needed for high quality development. On the one hand, two major technical systems are proposed: basic and process technology innovation, frontier and enabling technology for high-quality development of furniture intelligent manufacturing. This work has built an intelligent manufacturing technology system platform for high-quality development, including: overall architecture, core objectives and content, theoretical breakthroughs and basic guarantees, enabling technologies, new development models, implementation strategies, etc. The system is constructed from the aspects of theoretical breakthrough, basic guarantee, basic and process technology innovation, and new enabling technology, and the high-quality development goal of high-quality, efficient, low-consumption, green and safe furniture is set. It defines the core contents of five aspects of intelligent furniture products, intelligent production, intelligent factory, intelligent logistics and intelligent service, and puts forward the ideas of accelerating basic and process technology innovation such as automatic data collection and processing, information integration, industrial Internet/Internet of Things, modeling and simulation, etc. It also expounds the application scenarios of new technologies composed of big data technology, industrial robot technology, intelligent scheduling and control technology, virtual reality and augmented reality technology, and interprets the implementation methods of cutting-edge technologies such as cloud computing and edge computing, digital twin, artificial intelligence, and software-defined. On the other hand, the technical system is summarized, including: the technical system built by the furniture information control platform, the digital technology system based on the whole life cycle of furniture products, and technical system for sustainable development of furniture intelligent manufacturing. Finally, future research proposals are put forward for the high-quality development of new-generation intelligent manufacturing technologies in furniture enterprises: reshaping the enterprise development model by combining the digital integration model of the whole life cycle, the connected factory model, and the business model of home products; using data-driven, software-defined, virtual-real combination and systemic connection to strengthen the implementation of new strategies.

Key words: intelligent manufacturing of furniture, technological architecture, enabling technologies, development model, implementing strategy

中图分类号:

TS664

熊先青,岳心怡,张美,王国坤. 面向林木家居产品高质量发展的智能制造赋能技术体系构建[J]. 林业科学, 2024, 60(11): 177-189.

Xianqing Xiong,Xinyi Yue,Mei Zhang,Guokun Wang. Intelligent Manufacturing Enabling Technologies System Construction for High-Quality Development of Furniture[J]. Scientia Silvae Sinicae, 2024, 60(11): 177-189.

图/表 5

参考文献 0

	窦延光, 韩维生. 木家具质量问题分析及解决措施. 森林工程, 2022, 38 (2): 74- 79, 86.
	Dou Y G, Han W S. Analysis and solution of quality issues of wood furniture. Forest Engieering, 2022, 38 (2): 74- 79, 86.
	方　巍, 伏宇翔. 2024. 元宇宙: 概念、技术及应用研究综述. 南京信息工程大学学报(自然科学版), 16(1): 30−45.
	Fang W, Fu Y X. 2024. Metaverse: conceptions, key technologies and applications. Journal of Nanjing University of Information Science & Technology(Natural Science Edition), 16(1): 30−45. ［in Chinese］
	谷文慧, 周橙旻, 李明坤. 基于大数据统计的电商家具市场分析. 家具与室内装饰, 2021, (3): 84- 87.
	Gu W H, Zhou C M, Li M K. E-commerce furniture market analysis based on big data statistics. Furniture & Interior Design, 2021, (3): 84- 87.
	胡　蕾. 基于云计算的家具制造企业管理会计发展研究. 林产工业, 2020, 57 (7): 101- 103.
	Hu L. Research on the development of management accounting in furniture manufacturing enterprises based on cloud computing. China Forest Products Industry, 2020, 57 (7): 101- 103.
	惠小雨, 吴智慧, 沈忠民. 定制家具行业数字化设计生产一体化现状的研究与分析. 家具, 2019, 40 (3): 7- 11.
	Hui X Y, Wu Z H, Shen Z M. Status analysis of design and production integration in the customized furniture industry. Furniture, 2019, 40 (3): 7- 11.
	李　静, 戴达鹏, 郭洪武, 等. 面向智能制造的实木家具产品数字化设计技术. 林业工程学报, 2024, 9 (4): 168- 175.
	Li J, Dai D P, Guo H W, et al. Digital design technology of solid wood furniture for intelligent manufacturing. Journal of Forestry Engineering, 2024, 9 (4): 168- 175.
	李荣荣, 姚　倩. 面向智能制造的板式定制家具柔性生产线设备配置. 木材科学与技术, 2021, 35 (2): 23- 29. doi: 10.12326/j.2096-9694.2020151
	Li R R, Yao Q. Research on equipment configurations of the flexible production line for intelligently manufacturing customized panel furnitures. Chinese Journal of Wood Science and Technology, 2021, 35 (2): 23- 29. doi: 10.12326/j.2096-9694.2020151
	李雪瑞, 侯幸刚, 杨　梅, 等. 数字孪生驱动的工业产品CMF设计服务模型构建与应用. 计算机集成制造系统, 2021, 27 (2): 307- 327.
	Li X R, Hou X G, Yang M, et al. Construction and application of CMF design service model for industrial products driven by digital twins. Computer Integrated Manufacturing Systems, 2021, 27 (2): 307- 327.
	刘　英, 庄子龙, 唐　敏. 深度学习在木材加工领域的研究进展. 林业工程学报, 2023, 8 (4): 1- 9.
	Liu Y, Zhuang Z L, Tang M. Research progress on deep learning in wood processing. Journal of Forestry Engineering, 2023, 8 (4): 1- 9.
	刘　强. 智能制造理论体系架构研究. 中国机械工程, 2020, 31 (1): 24- 36.
	Liu Q. Study on architecture of intelligent manufacturing theory. China Mechanical Engineering, 2020, 31 (1): 24- 36.
	芦国桢, 熊先青, 鲁丹婷, 等. 基于统计过程控制的家具封边质量管控方法. 林业工程学报, 2023, 8 (1): 195- 201.
	Lu G Z, Xiong X Q, Lu D T, et al. Research on quality control method of furniture sealing based on SPC. Journal of Forestry Engineering, 2023, 8 (1): 195- 201.
	罗宇峰. 2017. 大数据在制造业的应用研究——以SP公司为例. 厦门: 厦门大学.
	Luo Y F. 2017. A study on the application of the big data in manufacturing industry-case analysis of SP company. Xiamen: Xiamen University. ［in Chinese］
	欧阳劲松, 刘　丹, 汪　烁, 等. 德国工业4.0参考架构模型与我国智能制造技术体系的思考. 自动化博览, 2016, (3): 62- 65. doi: 10.3969/j.issn.1003-0492.2016.03.035
	Ouyang J S, Liu D, Wang S, et al. Reflections on German Industry 4.0 reference architecture model and China’s intelligent manufacturing technology system. Automation Panorama, 2016, (3): 62- 65. doi: 10.3969/j.issn.1003-0492.2016.03.035
	彭晓瑞, 张占宽. 我国家具市场现状与发展趋势分析. 中国人造板, 2020, 27 (5): 1- 6. doi: 10.3969/j.issn.1673-5064.2020.05.001
	Peng X R, Zhang Z K. Status quo and development trend of China’s furniture market. China Wood-Based Panels, 2020, 27 (5): 1- 6. doi: 10.3969/j.issn.1673-5064.2020.05.001
	宋启良, 梁秀兵, 胡振峰, 等. 现代工业机器人的发展、应用及其绿色修复再制造研究现状. 材料保护, 2020, 53 (12): 95- 100.
	Song Q L, Liang X B, Hu Z F, et al. Development and application of modern industrial robots and research status of green repair and remanufacture. Materials Protection, 2020, 53 (12): 95- 100.
	孙庆伟, 熊先青, 彭淑勤, 等. 板式家具智能制造的工艺变型设计方法. 林业工程学报, 2022, 7 (6): 187- 195.
	Sun Q W, Xiong X Q, Peng S Q, et al. Technology analysis and design method research of process variant design for intelligent manufacturing of panel furniture. Journal of Forestry Engineering, 2022, 7 (6): 187- 195.
	唐　堂, 滕　琳, 吴　杰, 等. 全面实现数字化是通向智能制造的必由之路: 解读《智能制造之路: 数字化工厂》. 中国机械工程, 2018, 29 (3): 366- 377. doi: 10.3969/j.issn.1004-132X.2018.03.018
	Tang T, Teng L, Wu J, et al. Comprehensive realization of digitization is the only way to realize intelligent manufacturing: an interpretation of“The road of intelligent manufacturing: the digital factory”. China Mechanical Engineering, 2018, 29 (3): 366- 377. doi: 10.3969/j.issn.1004-132X.2018.03.018
	王　莉. 德国工业4.0对《中国制造2025》的创新驱动研究. 科学管理研究, 2017, 35 (5): 100- 103,107.
	Wang L. German Industry 4.0 (Industry 4.0) “China made 2025” innovation driven research. Scientific Management Research, 2017, 35 (5): 100- 103,107.
	王国坤, 熊先青, 杨路洁, 等. 面向板式家具数字化制造的拆单软件现状与发展分析. 林业工程学报, 2024, 9 (3): 175- 183.
	Wang G K, Xiong X Q, Yang L J, et al. Analysis of current situation and development of splitting software fordigital manufacturing of panel furniture. Journal of Forestry Engineering, 2024, 9 (3): 175- 183.
	王金鑫, 伍占文, 胡　伟, 等. 带有缓冲约束的板式家具混合流水车间调度求解方法. 林业工程学报, 2023, 8 (3): 198- 204.
	Wang J X, Wu Z W, Hu W, et al. Hybrid flow shop scheduling in panel furniture with buffer constraint. Journal of Forestry Engineering, 2023, 8 (3): 198- 204.
	王其朝, 金光淑, 李　庆, 等. 工业边缘计算研究现状与展望. 信息与控制, 2021, 50 (3): 257- 274.
	Wang Q Z, Jin G S, Li Q, et al. Industrial edge computing: vision and challenges. Information and Control, 2021, 50 (3): 257- 274.
	王争光, 刘　英, 丁奉龙, 等. 基于人工智能的木材加工研究进展. 林业机械与木工设备, 2021, 49 (3): 13- 15. doi: 10.3969/j.issn.2095-2953.2021.03.003
	Wang Z G, Liu Y, Ding F L, et al. Research progress of wood processing based on artificial intelligence. Forestry Machinery & Woodworking Equipment, 2021, 49 (3): 13- 15. doi: 10.3969/j.issn.2095-2953.2021.03.003
	吴智慧. 信息经济时代的家具先进制造技术(上). 家具, 2003a, 24 (2): 13- 16.
	Wu Z H. Advanced technology of furniture manufacturing in industry informationization age. Furniture, 2003a, 24 (2): 13- 16.
	吴智慧. 信息经济时代的家具先进制造技术. 家具, 2003b, 24 (3): 11- 20.
	Wu Z H. Advanced technology of furniture manufacturing in industry informationization age. Furniture, 2003b, 24 (3): 11- 20.
	吴智慧. 服务型制造: 中国家具业转型升级的新模式. 家具, 2013, 34 (2): 1- 7,11.
	Wu Z H. Service manufacturing: new models of transformation and upgrading for Chinese furniture industry. Furniture, 2013, 34 (2): 1- 7,11.
	吴智慧. 工业4.0时代中国家居产业的新思维与新模式. 木材工业, 2017, 31 (2): 5- 9.
	Wu Z H. New thinking and new models of the Chinese home furnishings industry in the industry 4.0 era. China Wood Industry, 2017, 31 (2): 5- 9.
	解晨辉, 李荣荣. 基于ControlNet的儿童床设计效果图生成技术. 林业工程学报, 2024, 9 (2): 184- 191.
	Xie C H, Li R R. Children bed design effect diagram based on ControlNet. Journal of Forestry Engineering, 2024, 9 (2): 184- 191.
	熊先青, 刘　慧, 庞小仁. 大规模定制家具柔性制造系统构建与关键技术. 木材工业, 2019, 33 (2): 20- 24.
	Xiong X Q, Liu H, Pang X R. Flexible manufacturing system for mass customization manufacturing in furniture industry. China Wood Industry, 2019, 33 (2): 20- 24.
	熊先青, 马清如, 袁莹莹, 等. 面向智能制造的家具企业数字化设计与制造. 林业工程学报, 2020, 5 (4): 174- 180.
	Xiong X Q, Ma Q R, Yuan Y Y, et al. Digital design and manufacturing of furniture enterprises oriented to intelligent manufacturing. Journal of Forestry Engineering, 2020, 5 (4): 174- 180.
	熊先青, 吴智慧. 家居产业智能制造的现状与发展趋势. 林业工程学报, 2018, 3 (6): 11- 18.
	Xiong X Q, Wu Z H. Present situation and development trend of intelligent manufacturing in home furnishing industry. Journal of Forestry Engineering, 2018, 3 (6): 11- 18.
	熊先青, 岳心怡. 中国家居智能制造技术研究与应用进展. 林业工程学报, 2022a, 7 (2): 26- 34.
	Xiong X Q, Yue X Y. Research and application progress of home intelligent manufacturing technologies in China. Journal of Forestry Engineering, 2022a, 7 (2): 26- 34.
	熊先青, 周卓蓉. 基于“互联网+” 技术的家具产品物流配送过程管控平台构建. 制造业自动化, 2022b, 44 (1): 6- 9.
	Xiong X Q, Zhou Z R. Construction of control platform for logistics distribution process of furniture products based on Internet plus technology. Manufacturing Automation, 2022b, 44 (1): 6- 9.
	熊先青, 岳心怡. 面向智能制造的家居企业ERP/MES集成管理技术. 木材科学与技术, 2022c, 36 (4): 25- 31.
	Xiong X Q, Yue X Y. ERP/MES integrated management technology for intelligent manufacturing customized furnishings. Chinese Journal of Wood Science and Technology, 2022c, 36 (4): 25- 31.
	熊有伦. 智能制造. 科技导报, 2013, 31 (10): 3.
	Xiong Y L. Intelligent manufacturing. Science & Technology Review, 2013, 31 (10): 3.
	薛继肖, 徐　伟, 王军祥. 基于价值流图的板式定制家具小板件生产线负荷平衡. 林业工程学报, 2023, 8 (6): 176- 185.
	Xue J X, Xu W, Wang J X. Load balancing of small production line for customized panel furniture based on value stream map. Journal of Forestry Engineering, 2023, 8 (6): 176- 185.
	杨浚安, 吴智慧. 传统家具企业数字化转型路径及系统架构. 木材科学与技术, 2022, 36 (6): 32- 40. doi: 10.12326/j.2096-9694.2022091
	Yang J A, Wu Z H. Digital transformation path and system architecture for traditional home furniture companies. Chinese Journal of Wood Science and Technology, 2022, 36 (6): 32- 40. doi: 10.12326/j.2096-9694.2022091
	杨文嘉. 新工业革命对家具制造业的影响. 家具, 2013, 34 (1): 5- 7.
	Yang W J. Influence of the new industrial revolution on furniture industry. Furniture, 2013, 34 (1): 5- 7.
	杨　扬, 周桓宇, 郭艳玲. 室内装饰设计界面材料生态学属性 GA-GRNN评价模型对比研究. 森林工程, 2021, 38 (2): 68- 73, 145.
	Yang Y, Zhou H Y, Guo Y L. Comparative of GA-GRNN ecological properties evaluation model of interface materials for interior decoration design. Forest Engineering, 2021, 38 (2): 68- 73, 145.
	杨雪珂, 熊先青. 家具生产线射频识别技术的信息采集与应用. 林业工程学报, 2022, 7 (3): 180- 186.
	Yang X K, Xiong X Q. Information collection and application of furniture production line using radio frequency identification technology. Journal of Forestry Engineering, 2022, 7 (3): 180- 186.
	姚小涛, 亓　晖, 刘琳琳, 等. 企业数字化转型: 再认识与再出发. 西安交通大学学报(社会科学版), 2022, 42 (3): 1- 9.
	Yao X T, Qi H, Liu L L, et al. Enterprise digital transformation: re-understanding and re-starting. Journal of Xi’an Jiaotong University (Social Sciences), 2022, 42 (3): 1- 9.
	曾德麟, 蔡家玮, 欧阳桃花. 数字化转型研究: 整合框架与未来展望. 外国经济与管理, 2021, 43 (5): 63- 76.
	Zeng D L, Cai J W, Ouyang T H. A research on digital transformation: integration framework and prospects. Foreign Economics & Management, 2021, 43 (5): 63- 76.
	赵伟翔, 钟世禄. 定制家具生产线信息化联动改进. 木材科学与技术, 2022, 36 (6): 41- 46. doi: 10.12326/j.2096-9694.2022099
	Zhao W X, Zhong S L. Improving the information system of custom-furniture production. Chinese Journal of Wood Science and Technology, 2022, 36 (6): 41- 46. doi: 10.12326/j.2096-9694.2022099
	周　超, 黄　迅. 增强现实技术在家具定制设计中的应用初探. 家具与室内装饰, 2020, (4): 58- 59.
	Zhou C, Huang X. Application of augmented reality technology in custom furniture design. Furniture & Interior Design, 2020, (4): 58- 59.
	周　济. 智能制造: “中国制造2025” 的主攻方向. 中国机械工程, 2015, 26 (17): 2273- 2284. doi: 10.3969/j.issn.1004-132X.2015.17.001
	Zhou J. Intelligent manufacturing: main direction of “made in China 2025”. China Mechanical Engineering, 2015, 26 (17): 2273- 2284. doi: 10.3969/j.issn.1004-132X.2015.17.001
	周雪松. 2022. 新一代信息技术将深度赋能产业发展. 中国经济时报, 11−16(001).
	Zhou X S. 2022. The new generation of information technology will deeply enable the development of the industry. China Economic Times, 11−16(001). ［in Chinese］
	朱剑刚, 王　旭. 木质家具智能制造赋能技术及发展路径分析. 林业工程学报, 2021, 6 (6): 177- 183.
	Zhu J G, Wang X. Research on enabling technologies and development path of intelligent manufacturing of wooden furniture. Journal of Forestry Engineering, 2021, 6 (6): 177- 183.
	朱剑刚, 吴智慧, 黄琼涛. 家具制造企业信息集成平台构建技术研究. 林业工程学报, 2019, 4 (3): 145- 151.
	Zhu J G, Wu Z H, Huang Q T. Constructing technology of enterprise information integration platform for furniture manufacturing enterprise. Journal of Forestry Engineering, 2019, 4 (3): 145- 151.
	朱兆龙, 熊先青, 吴智慧, 等. 面向智能制造的定制家居数字化设计虚拟现实展示技术. 木材科学与技术, 2021, 35 (5): 1- 6. doi: 10.12326/j.2096-9694.2020183
	Zhu Z L, Xiong X Q, Wu Z H, et al. Virtual reality display technology in digital design for intelligent manufacturing customized furnishings. Chinese Journal of Wood Science and Technology, 2021, 35 (5): 1- 6. doi: 10.12326/j.2096-9694.2020183
	John Walker S. Big data: a revolution that will transform how we live, work, and think. International Journal of Advertising, 2014, 33 (1): 181- 183. doi: 10.2501/IJA-33-1-181-183
	Kim K, Li S N, Heydariaan M, et al. Feasibility of LoRa for smart home indoor localization. Applied Sciences, 2021, 11 (1): 415. doi: 10.3390/app11010415
	Li Q, Tang Q L, Chan I, et al. Smart manufacturing standardization: architectures, reference models and standards framework. Computers in Industry, 2018, 101, 91- 106. doi: 10.1016/j.compind.2018.06.005
	McAfee A, Brynjolfsson E. Big data: the management revolution. Harvard Business Review, 2012, 90 (10): 60- 66,68,128.
	Saez M, Maturana F P, Barton K, et al. Real-time manufacturing machine and system performance monitoring using Internet of Things. IEEE Transactions on Automation Science and Engineering, 2018, 15 (4): 1735- 1748. doi: 10.1109/TASE.2017.2784826
	Smith M L, Smith L N, Hansen M F. The quiet revolution in machine vision - a state-of-the-art survey paper, including historical review, perspectives, and future directions. Computers in Industry, 2021, 130, 103472. doi: 10.1016/j.compind.2021.103472
	Wang J B, Wang J J. Single machine group scheduling with time dependent processing times and ready times. Information Sciences, 2014, 275, 226- 231. doi: 10.1016/j.ins.2014.02.034
	Xiong X Q, Lu G Z, Lu D T. Research on children’s customized furniture design based on group technology. Applied Sciences, 2021, 11 (23): 11371. doi: 10.3390/app112311371
	Xiong X Q, Yuan Y Y, Fang L, et al. Status and development trends of intelligent manufacturing in China’s furnishings industry. Forest Products Journal, 2018, 68 (3): 328- 336.
	Xiong X Q, Yue X Y, Dong W H, et al. Current status and system construction of used-furniture recycling in China. Environmental Science and Pollution Research, 2022, 29 (55): 82729- 82739. doi: 10.1007/s11356-022-23532-5
	Xiong X Q, Yue X Y, Wu Z H. Current status and development trends of Chinese intelligent furniture industry. Journal of Renewable Materials, 2023, 11 (3): 1353- 1366. doi: 10.32604/jrm.2022.023447

[1]	王巍,王云婷,宋文龙. 基于FlexSim机群式布置木质家具生产线仿真[J]. 林业科学, 2020, 56(4): 135-142.
[2]	李博, 张占宽. 木门旋杯式静电喷涂漆膜厚度的理论分析[J]. 林业科学, 2018, 54(5): 109-115.