基于K-means与技术生命周期的技术预见方法研究——以水体净化技术为例

doi:10.6049/kjjbydc.2021070453

科技进步与对策

2022, Vol. 39

Issue (6): 11-20 DOI: 10.6049/kjjbydc.2021070453

科技管理创新

本期目录 | 过刊浏览 | 高级检索

基于K-means与技术生命周期的技术预见方法研究——以水体净化技术为例

简兆权¹,赵芸潼¹,张少轩²

（1.华南理工大学工商管理学院，广东广州 510640；2.广东省环境科学研究院，广东广州 510030）

Technology Foresight Methods Based on K-means and Technology Life Cycle：Taking Water Purification Technology as an Example

Jian Zhaoquan¹,Zhao Yuntong¹,Zhang Shaoxuan²

（1. School of Business Administration，South China University of Technology，Guangzhou 510640，China；2. Guangdong Academy of Environmental Sciences，Guangzhou 510030，China）

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (1785 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要预见水体净化技术发展趋势有助于实现“美丽中国”建设目标。已有技术预见方法缺乏定量客观依据，相关评判指标也不够全面。从Innography数据库检索2008-2019年发布的3552个污水处理技术专利，运用多维标度分析和K均值聚类法，基于专利静态指标分析专利技术发展潜力，采用技术生命周期分析法从动态视角判断每类技术的发展前景。研究发现：①污水与污染物双重回收可持续性技术在多个静态评价指标方面均优于其它技术，且处于从引入期到发展期的过渡阶段，具有较大的发展空间；②以去除特定污染物为目标的功能单一技术已被淘汰，市场开始应用污水处理原理不同的多种技术联合处理方式。据此，提出企业应选择污染物回收率高、二次污染物排放少、整体“净效益”为正的污水处理技术，并采取新旧技术联合处理方式降低企业采用新技术的转换成本。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	简兆权
	赵芸潼
	张少轩

关键词 ： K均值聚类, 技术生命周期, 技术预见, 技术专利, 水体净化

收稿日期: 2021-07-19 修回日期: 2021-10-21

ZTFLH:

G303

基金资助:广东省软科学研究计划项目（2019A101002012）

作者简介: 简兆权（1969—），男，福建永定人，博士，华南理工大学工商管理学院教授、博士生导师，研究方向为技术创新；赵芸潼（1995—），女，辽宁大连人，华南理工大学工商管理学院博士研究生，研究方向为技术创新；张少轩（1995—），男，山西吕梁人，广东省环境科学研究院助理工程师，研究方向为水体净化。本文通讯作者：赵芸潼。

引用本文:

简兆权,赵芸潼,张少轩. 基于K-means与技术生命周期的技术预见方法研究——以水体净化技术为例[J]. 科技进步与对策, 2022, 39(6): 11-20.
Jian Zhaoquan,Zhao Yuntong,Zhang Shaoxuan. Technology Foresight Methods Based on K-means and Technology Life Cycle：Taking Water Purification Technology as an Example. SCIENCE & TECHNOLOGY PROGRESS AND POLICY, 2022, 39(6): 11-20.

链接本文:

http://www.kjjb.org/CN/10.6049/kjjbydc.2021070453 或 http://www.kjjb.org/CN/Y2022/V39/I6/11

[1] LORENZO-TOJA Y, VAZQUEZ-ROWE I, AMORES M J, et al. Benchmarking wastewater treatment plants under an eco-efficiency perspective [J]. Science of the Total Environment, 2016(566-567): 468-479.
[2] HASSON F, KEENEY S. Enhancing rigour in the delphi technique research[J].Technological forecasting and Social Change,2011,78(9): 1695-1704.
[3] 赖朝安, 钱娇. 基于专利挖掘的移动医疗产业技术预见 [J].科研管理,2018,39(10): 138-147.
[4] 简兆权, 柳仪. 技术预见共识形成机制研究 [J].科学学与科学技术管理,2014,35(9): 37-47.
[5] 张振刚, 罗泰晔. 基于知识网络的技术预见研究 [J].科学学研究,2019,37(6): 961-967，985.
[6] KIM G, BAE J. A novel approach to forecast promising technology through patent analysis[J].Technological Forecasting and Social Change,2017(117): 228-237.
[7] KAPOOR R, KARVONEN M, RANAEI S, et al. Patent portfolios of european wind industry:new insights using citation categories [J].World Patent Information,2015(41): 4-10.
[8] 何晓群. 多元统计分析 [M].北京: 中国人民大学出版社, 2012.
[9] 贾俊平, 何晓群, 金勇进. 统计学 [M].北京: 中国人民大学出版社, 2014.
[10] BEKKERS R, CATALINI C, MARTINELLI A, et al. Intellectual property disclosure in standards development [C].NBER Conference on Standards, Patents & Innovation,2012.
[11] CHO H P, LIM H, LEE D, et al. Patent analysis for forecasting promising technology in high-rise building construction [J].Technological Forecasting and Social Change,2018, 128: 144-153.
[12] PETRUZZELLI A M, ROTOLO D, ALBINO V. Determinants of patent citations in biotechnology: an analysis of patent influence across the industrial and organizational boundaries[J].Technological Forecasting and Social Change,2015(91): 208-221.
[13] LANJOUW J O, SCHANKERMAN M. Patent quality and research productivity: measuring innovation with multiple indicators [J].The Economic Journal,2004,114(495): 441-465.
[14] BRIGGS K, WADE M. More is better: evidence that joint patenting leads to quality innovation [J].Applied Economics,2014,46(35): 4370-4379.
[15] SIMCOE T S, GRAHAM S J H, FELDMAN M P. Competing on standards? entrepreneurship, intellectual property, and platform technologies [J].Journal of Economics & Management Strategy,2009,18(3): 775-816.
[16] HARHOFF D, NARIN F, SCHERER F M, et al. Citation frequency and the value of patented inventions [J].Review of Economics and Sstatistics,1999,81(3): 511-515.
[17] BARON J, POHLMANN T, BLIND K. Essential patents and standard dynamics [J].Research Policy,2016,45(9): 1762-1773.
[18] POHLMANN T, NEUHAEUSLER P, BLIND K. Standard essential patents to boost financial returns [J].R & D Management,2016, 46(S2): 612-630.
[19] HAUPT R, KLOYER M, LANGE M. Patent indicators for the technology life cycle development [J].Research Policy,2007,36(3): 387-398.
[20] ANDERSEN B. The hunt for s-shaped growth paths in technological innovation:a patent study [J].Journal of Evolutionary Economics,1999,9(4): 487-526.
[21] ACHILLADELIS B. The dynamics of technological innovation:the sector of antibacterial medicines [J]. Research Policy,1993,22(4): 279-308.
[22] DEBACKERE K, VERBEEK A, LUWEL M, et al. Measuring progress and evolution in science and technology-ii:the multiple uses of technometric indicators [J].International Journal of Management Reviews,2003,4(3): 213-231.
[23] LUTTERBECK C A,COLARES G S, DELL'OSBEL N,et al.Hospital laundry wastewaters:a review on treatment alternatives, life cycle assessment and prognosis scenarios [J].Journal of Cleaner Production,2020, 273: 122851.
[24] QI M, YANG Y, ZHANG X, et al. Pollution reduction and operating cost analysis of municipal wastewater treatment in China and implication for future wastewater management [J].Journal of Cleaner Production,2020, 253: 120003.
[25] NAKKASUNCHI S, HEWITT N J, ZOPPI C, et al. A review of energy optimization modelling tools for the decarbonisation of wastewater treatment plants [J].Journal of Cleaner Production,2021, 279: 123811.
[26] CHANGOTRA R, RAJPUT H, GUIN J P, et al. Techno-economical evaluation of coupling ionizing radiation and biological treatment process for the remediation of real pharmaceutical wastewater [J].Journal of Cleaner Production,2020, 242: 118544.