Innovative Design of Modular Small-scale Aquaponic Equipment Based on KANO/TRIZ

JIAO Xinqi; SHI Yuanwu; ZHANG Peixian; ZHAO Lifan; HAN Zhenhao

doi:10.19554/j.cnki.1001-3563.2025.14.018

PDF(3085 KB)

Packaging Engineering ›› 2025, Vol. 46 ›› Issue (14) : 167-175. DOI: 10.19554/j.cnki.1001-3563.2025.14.018

Industrial Design

Innovative Design of Modular Small-scale Aquaponic Equipment Based on KANO/TRIZ

JIAO Xinqi, SHI Yuanwu^2,*, ZHANG Peixian, ZHAO Lifan, HAN Zhenhao³

Author information +

History +

Abstract

The work aims to combine the KANO (Kano Model) and the TRIZ theory to innovatively design small-scale aquaponic equipment to resolve the issues such as the deviation of existing small-scale aquaponic equipment from the focus of user needs and the complexity of product operation. Based on the KANO model, needs of urban residents for aquaponic equipment were analyzed, and the weights of various design elements were calculated and ranked. The design elements of small-scale aquaponic equipment were analyzed by the TRIZ contradiction analysis method, a conflict matrix was constructed, and the design scheme of small-scale aquaponics equipment was proposed according to the contradiction principles and corresponding methods. A small modular aquaponic equipment that met the needs of diversification of urban hydroponic vegetables and fish farming was designed, which was easy to operate and had an aesthetic appearance. Through the combination of the KANO model and the TRIZ design method, an innovative design method was provided for the integration of urbanization and agricultural space. This method provides theoretical and practical bases for the design of similar small, integrated and modular products.

Key words

aquaponics / KANO / TRIZ / modular design

Cite this article

EndNote

Ris (Procite)

Bibtex

Download Citations

JIAO Xinqi, SHI Yuanwu, ZHANG Peixian, ZHAO Lifan, HAN Zhenhao. Innovative Design of Modular Small-scale Aquaponic Equipment Based on KANO/TRIZ[J]. Packaging Engineering. 2025, 46(14): 167-175 https://doi.org/10.19554/j.cnki.1001-3563.2025.14.018

References

[1] 蒋金辰, 徐琰斐, 单建军, 等. 鱼菜共生系统中乳酸菌的筛选及其发酵矿化应用[J]. 农业工程学报, 2024, 40(11): 119-127.
JIANG J C, XU Y F, SHAN J J, et al.Screening Lactic Acid Bacteria for Fermentation and Mineralization in Aquaponic System[J]. Transactions of the Chinese Society of Agricultural Engineering, 2024, 40(11): 119-127.
[2] 丁永良, 兰泽桥, 张明华. 工业化封闭式循环水养鱼污水资源化——生态循环经济的典范“鱼菜共生系统”[J]. 中国渔业经济, 2010, 28(01): 124-130.
DING Y L, LAN Z Q, ZHANG M H.Aquaculture Sewage Resources of Industrialized Closed Circulating System--a Typical Eco-circulating Economy Model "Fish and Vegetable Symbiotic System"[J]. Chinese Fisheries Economics, 2010, 28(01):124-130.
[3] 刘爽, 安诗琦, 严子微, 等. 现代鱼菜共生技术研究进展与展望[J]. 中国农业科技导报, 2020, 22(3): 160-166.
LIU S, AN S Q, YAN Z W, et al.Research Progress and Prospect of Modern Aquaponics Technology[J]. Journal of Agricultural Science and Technology, 2020, 22(3): 160-166.
[4] 孙锐康, 付京花, 徐民俊. 鱼菜共生复合系统研究进展[J]. 中国农业科技导报, 2023, 25(9): 227-233.
SUN R K, FU J H, XU M J.Research Progress of Aquaponics System[J]. Journal of Agricultural Science and Technology, 2023, 25(9): 227-233.
[5] BADREY A E A, EL-SAWY M F, MAHDY A, et al. The Impact of Water Quality on the Production of Lettuce (Lactuca sativaL.) Using Polyculture Effluent in ASTAF-Pro Aquaponic System[J]. Journal of Soil Science and Plant Nutrition, 2024, 24(2): 2502-2508.
[6] TAN A S T, UTHAYAKUMAR H, YEO L S, et al. Shapley-Shubik Agents Within Superstructure-Based Recycling Model: Circular Economy Approaches for Fish Waste Eco-Industrial Park[J]. Process Integration and Optimization for Sustainability, 2024, 8(2): 487-501.
[7] HUANG Y, LI L, LI R, et al.Nitrogen Cycling and Resource Recovery from Aquaculture Wastewater Treatment Systems: a Review[J]. Environmental Chemistry Letters, 2024, 22(5): 2467-2482.
[8] THAIPARAMBIL N A, RADHAKRISHNAN V.Challenges in Achieving an Economically Sustainable Aquaponic System: A Review[J]. Aquaculture International, 2022, 30(6): 3035-3066.
[9] SABER M I, MAHGOUB N A, AWAD Y M, et al.Performance of a Recirculating Aquaponic System in Vegetable Production using River Fish (Nile tilapia)[J]. Euro-Mediterranean Journal for Environmental Integration, 2025, 10: 451-462.
[10] KANO N, SERAKU F, TAKAHASHI F, et al.Attractive Quality and Must - Be Quality[J]. The Joumal of Japanese Society for Quality Control, 1984, 41(2): 39-48.
[11] 王南轶, 傅雷, 石畅, 等. 基于Kano模型与TRIZ理论的台灯创新设计研究[J]. 机械设计, 2022, 39(S2): 221-226.
WANG N Y, FU L, SHI C, et al.Innovative Design of Table Lamp based on TRIZ Theory[J]. Journal of Machine Design, 2022, 39(S2): 221-226.
[12] Altshuller G S. The Innovation Algorithm, TRIZ. Systematic Innovation and Technical Creativity[M]. Worcester: Technical Innovation Center, INC, 1999.
[13] 李振鹏. 基于感性工学的植物工厂设计研究[J]. 装饰, 2019, 310(2): 136-137.
LI Z P.Research on Plant Factory Design Based on Kansei Engineering[J]. Zhuangshi, 2019, 310(2): 136-137.
[14] 苗艳凤, 李景婕, 徐蕴佳. 基于Kano-GRA-AHP对儿童输液区家具的设计与评估[J]. 家具与室内装饰, 2023, 30(1): 44-49.
MIAO Y F, LI J J, XU Y J.Design and Evaluation of Furniture in Children's Infusion Area Based on Kano GRA-AHP[J]. Furniture & Interior Design, 2023, 30(1): 44-49.
[15] 陈晨, 曹佳雯, 林昱希, 等. 基于SET、KANO模型的小户型家用智能鱼缸造型设计研究[J]. 包装工程, 2022, 43(S1): 144-160.
[16] 刘宗明, 李倩文. 基于KANO模型与TRIZ理论的儿童家具轻设计研究[J]. 林产工业, 2020, 57(08): 41-46, 52.
LIU Z M, LI Q W.Research on Light Design of Children’s Furniture Based on KANO and TRIZ Theory[J]. China Forest Products Industry, 2020, 57(8): 41-46, 52.
[17] 唐纳德·A·诺曼. 设计心理学 3 情感化设计[M]. 何笑梅, 欧秋杏, 译. 北京:中信出版社. 2015.
NORMAN A D.Design Psychology 3 Emotional Design [M]. HE Xiao-mei, OU Qiu-xing, Translate. Beijing: Citic Press. 2015.
[18] 周祺, 李晓锋, 陈颖阳. 基于KANO模型的家庭鱼菜共生种植产品设计研究[J]. 工业设计, 2022, 11: 64-67.
ZHOU Q, LI X F, CHEN Y Y.Research on the Design of Household Aquaponics Planting Products based on KANO model[J]. Industrial Design, 2022, 11: 64-67.
[19] 赵春林. 工作满意度的测量及其模糊综合评价研究 [D]. 苏州: 苏州大学, 2007.
ZHAO C L.A Study on the Measure and Fuzzy Multifactorial Evaluation ofJob Satisfaction[D]. Suzhou: Suzhou University, 2007.