In order to improve the existing bamboo shoot slicing equipment as well as to meet the requirements of customers, and to reduce the dependence of bamboo shoot slicing equipment on manual labor, the work aims to construct an innovative design model for bamboo shoot slicing equipment. Firstly, the problems of the existing equipment were analyzed, further the user requirements were obtained through interviews, the importance degree was determined through questionnaires, and the QFD "left wall" was constructed. Secondly, the technical characteristics of the product were determined based on the relevant information of the bamboo shoot cutting equipment and the relevant experience of the technicians, and the QFD "ceiling" was constructed. Next, the QFD was used to establish the "user requirements-technical features" relationship matrix to define the design objectives of the bamboo shoot slicing equipment. Then, the function- behavior-structure mapping was completed based on the FBS model. Finally, the functional module structure design was carried out to generate the conceptual scheme of the bamboo shoot slicing equipment and evaluate it to complete the innovative design. Through the QFD-FBS innovative design model, the design of bamboo shoot slicing equipment was completed. The generated innovative scheme could automatically adjust the cutting tool and cutting parameters according to different cutting needs, which improved the slicing ability and adaptability of the equipment. A QFD-FBS-based innovative design model for bamboo shoot slicing equipment is constructed, and an innovative conceptual scheme is generated and verified to be effective and feasible, which provides a new idea for the design of bamboo shoot slicing equipment.
Key words
QFD /
FBS /
bamboo shoot slicing equipment /
innovative design
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References
[1] 李岚, 朱霖, 朱平. 中国竹资源及竹产业发展现状分析[J]. 南方农业, 2017, 11(1): 6-9.
LI L, ZHU L, ZHU P.Analysis of Bamboo Resources and Development Status of Bamboo Industry in China[J]. South China Agriculture, 2017, 11(1): 6-9.
[2] BEHERA P, BALAJI S.Health Benefits of Fermented Bamboo Shoots: The Twenty-First Century Green Gold of Northeast India[J]. Applied Biochemistry and Biotechnology, 2021, 193(6): 1800-1812.
[3] ARIRIGUZO J C, KADURUMBA C H.Innovative Okro Slicing Machine Design and Manufacturing[J]. Procedia Manufacturing, 2018, 17: 363-370.
[4] AJI I S, EMMANUEL M U, ABDULRAHMAN S A, et al.Development of an Electrically Operated Cassava Peeling and Slicing Machine[J]. Arid Zone Journal of Engineering, Technology and Environment, 2016, 12: 40-48.
[5] 王学军, 韩鹏剑, 周光勋, 等. 三七材切片机曲柄连杆结构优化设计研究[J]. 机械设计, 2020, 37(8): 21-26.
WANG X J, HAN P J, ZHOU G X, et al.Study on Structural Optimization of the Panax-Notoginseng Slicing Machine’s Crank Connecting-Rod Mechanism[J]. Journal of Machine Design, 2020, 37(8): 21-26.
[6] 朱权权. 灵芝切片机结构优化设计与控制方法研究[D]. 杭州: 中国计量大学, 2021: 14-50.
ZHU Q Q.Study on Structural Optimization Design and Control Method of Ganoderma Lucidum Slicer[D]. Hangzhou: China University of Metrology, 2021: 14-50.
[7] 刘俊发. 一种竹笋生产加工用自动切片装置: CN219854905U[P].2023-10-20.
Liu J f. An Automatic Slicing Device for Bamboo Shoot Production and Processing: CN219854905U[P].2023- 10-20.
[8] 王志兵. 一种雷竹笋高速切片装置: CN213616885U [P].2021-07-06.
WANG Z B. A High-Speed Slicing Device for Thunder Bamboo Shoots: CN213616885U[P].2021-07-06.
[9] 潘其昌. 一种竹笋批量生产切分装置: 中国, 202320586409.0[P].2023-11-03.
PAN Q C. A Bamboo Shoot Mass Production Slicing Device: China, 202320586409.0[P].2023-11-03.
[10] 韦艳丽, 冀源, 王超凡, 等. 基于QFD&TRIZ的帕金森患者助行器优化设计研究[J]. 包装工程, 2023, 44(2): 158-166.
WEI Y L, JI Y, WANG C F, et al.Design of Walking Aid for Parkinson Patients Based on QFD & TRIZ[J]. Packaging Engineering, 2023, 44(2): 158-166.
[11] GERO J S.Design Prototypes: A Knowledge Representation Schema for Design[J]. AI Magazine, 1990, 11(4): 26-36.
[12] 王军, 刘晓彤, 刘敬妍, 等. 基于QFD-FBS的儿童游泳辅助产品创新设计研究[J]. 包装工程, 2024, 45(4): 200-206.
WANG J, LIU X T, LIU J Y, et al.Innovative Design of Children's Swimming Auxiliary Products Based on QFD-FBS[J]. Packaging Engineering, 2024, 45(4): 200-206.
[13] HU Z G, JIA D Y, QIAO X L, et al.Construction and Application of Product Optimisation Design Model Driven by User Requirements[J]. Scientific Reports, 2024, 14(1): 16381.
[14] ZHAO Q, ZHAO W, GUO X, et al.A Dynamic Customer Requirement Mining Method for Continuous Product Improvement[J]. Autonomous Intelligent Systems, 2022, 2(1): 14.
[15] 王志愿, 闫磊磊, 邓迎寅, 等. 基于熵权与VIKOR方法的设计方案评价与优选[J]. 机械设计, 2022, 39(2): 154-160.
WANG Z Y, YAN L L, DENG Y Y, et al.Evaluation and Optimization of Design Schemes Based on Entropy Weight and VIKOR Method[J]. Journal of Machine Design, 2022, 39(2): 154-160.
[16] 苗艳凤, 孙萌, 徐蕴佳. 基于FAST-GRA-AHP的住院部病房陪护家具设计与评估[J]. 林产工业, 2024, 61(7): 40-47.
MIAO Y F, SUN M, XU Y J.Design and Evaluation of Ward Companion Furniture in Inpatient Department Based on FAST-GRA-AHP[J]. China Forest Products Industry, 2024, 61(7): 40-47.
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