Advanced search
Publication Cover
Journal of Industrial and Production Engineering Volume 38, 2021 - Issue 8
Submit an article Journal homepage
4,130
Views
96
CrossRef citations to date
0
Altmetric
Research Article

Sustainable industrial and operation engineering trends and challenges Toward Industry 4.0: a data driven analysis

Ming-Lang Tsenga Institute of Innovation and Circular Economy, Asia University, Taichung, Taiwan;b Department of Medical Research, China Medical University Hospital, China Medical University, Taichung, Taiwan;c Faculty of Economic and Management, University Kebangsaan Malaysia, Bangi, MalaysiaCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0002-2702-3590View further author information
ORCID Icon,
Thi Phuong Thuy Trand Department of Business Administration, College of Management, Asia University, Taichung, Taiwan;e Foreign Trade University, Ho Chi Minh City Campus, Ho Chi Minh City, VietnamView further author information
,
Hien Minh Hae Foreign Trade University, Ho Chi Minh City Campus, Ho Chi Minh City, Vietnam;f Department of Business Administration, Asia University, Taichung, TaiwanView further author information
,
Tat-Dat Buia Institute of Innovation and Circular Economy, Asia University, Taichung, TaiwanORCID Iconhttps://orcid.org/0000-0001-9798-9772View further author information
ORCID Icon &
Ming K. Limg Faculty Research Centre for Business in Society, Coventry University, Coventry, UKView further author information
Pages 581-598 | Received 19 Mar 2021, Accepted 25 Jun 2021, Published online: 11 Jul 2021

References

  • Chauhan A, Jakhar SK, Chauhan C. The interplay of circular economy with industry 4.0 enabled smart city drivers of healthcare waste disposal. J Clean Prod. 2021;279:123854.
  • Junior WTS, Montevechi JAB, Miranda AC, et al. Discrete simulation-based optimization methods for industrial engineering problems: a systematic literature review. Comput Ind Eng. 2019;128:526–540.
  • Enyoghasi C, Badurdeen F. Industry 4.0 for sustainable manufacturing: opportunities at the product, process, and system levels. ResouConserv Recycl. 2021;166:105362.
  • Benitez GB, Ayala NF, Frank AG. Industry 4.0 innovation ecosystems: an evolutionary perspective on value cocreation. Int J Prod Econ. 2020;228:107735. ( Article in Press). .
  • Onu P, Mbohwa C. Industry 4.0 opportunities in manufacturing SMEs: sustainability outlook. Mater Today Proc. 2021;44(1):1925–1930.
  • Alcácer V, Cruz-Machado V. Scanning the Industry 4.0: a literature review on technologies for manufacturing systems. Eng Sci Technol Int J. 2019;22(3):899–919.
  • Sharma R, Jabbour CJC, De Sousa Jabbour ABL. Sustainable manufacturing and Industry 4.0: what we know and what we don’t. J Enterp Inf Manage. 2020;34(1):230–266.
  • Kamble S, Gunasekaran A, Dhone NC. Industry 4.0 and lean manufacturing practices for sustainable organisational performance in Indian manufacturing companies. Int J P Res. 2020;58(5):1319–1337.
  • Ghobakhloo M. Industry 4.0, digitization, and opportunities for sustainability. J Clean Prod. 2020;252:119869.
  • Nara EOB, Da Costa MB, Baierle IC, et al. Expected impact of Industry 4.0 technologies on sustainable development: a study in the context of Brazil’s plastic industry. Sustainable Prod Consumption. 2021;25:102–122.
  • Rosa P, Sassanelli C, Urbinati A, et al. Assessing relations between Circular Economy and Industry 4.0: a systematic literature review. Int J P Res. 2020;58(6):1662–1687.
  • Oztemel E, Gursev S. Literature review of Industry 4.0 and related technologies. J Intell Manuf. 2020;31(1):127–182.
  • Bui TD, Tsai FM, Tseng ML, et al. Sustainable supply chain management towards disruption and organizational ambidexterity: a data driven analysis. Sustainable Prod Consumption. 2021;26:373–410.
  • Bui TD, Tsai FM, Tseng ML, et al. Identifying sustainable solid waste management barriers in practice using the fuzzy Delphi method. ResouConserv Recycl. 2020;154:104625.
  • Tseng ML, Bui TD, Lim MK, et al. Comparing world regional sustainable supply chain finance using big data analytics: a bibliometric analysis. Ind Manage Data Syst. 2021;121(3):657–700.
  • Tseng ML, Tran TPT, Wu KJ, et al. Exploring sustainable seafood supply chain management based on linguistic preferences: collaboration in the supply chain and lean management drive economic benefits. Int J Logistics Res Appl. 2020;1–23.
  • Zupic I, Čater T. Bibliometric methods in management and organization. Organizational Res Methods. 2015;18(3):429–472.
  • Rejeb MA, Simske S, Rejeb K, et al. Internet of Things Research in Supply Chain Management and Logistics: a Bibliometric Analysis. Internet Things. 2020;12:100318.
  • Buer SV, Strandhagen JO, Chan FT. The link between Industry 4.0 and lean manufacturing: mapping current research and establishing a research agenda. Int J P Res. 2018;56(8):2924–2940.
  • Sony M, Naik S. Industry 4.0 integration with socio-technical systems theory: a systematic review and proposed theoretical model. Technol Soc. 2020;61:101248.
  • Khanchanapong T, Prajogo D, Sohal AS, et al. The unique and complementary effects of manufacturing technologies and lean practices on manufacturing operational performance. Int J Prod Econ. 2014;153:191–203.
  • Tortorella GL, Giglio R, Van Dun DH. Industry 4.0 adoption as a moderator of the impact of lean production practices on operational performance improvement. Int J Oper Prod Manage. 2019;39(6/7/8):860–886.
  • Shahin M, Chen FF, Bouzary H, et al. Integration of Lean practices and Industry 4.0 technologies: smart manufacturing for next-generation enterprises. Int J Adv Manuf Technol. 2020;107, 2927–2936.
  • Rosin F, Forget P, Lamouri S, et al. Impacts of Industry 4.0 technologies on Lean principles. Int J P Res. 2020;58(6):1644–1661.
  • Kamble SS, Belhadi A, Gunasekaran A, et al. A large multi-group decision-making technique for prioritizing the big data-driven circular economy practices in the automobile component manufacturing industry. Technol Forecasting Social Change. 2021;165:120567.
  • Majeed A, Zhang Y, Ren S, et al. A big data-driven framework for sustainable and smart additive manufacturing. Rob Comput Integr Manuf. 2021;67:102026.
  • Wang Y, Wang S, Yang B, et al. Big data driven Hierarchical Digital Twin Predictive Remanufacturing paradigm: architecture, control mechanism, application scenario and benefits. J Clean Prod. 2020;248:119299. ( Article in Press). .
  • Srinivasan R, Giannikas V, Kumar M, et al. Modelling food sourcing decisions under climate change: a data-driven approach. Comput Ind Eng. 2019;128:911–919.
  • Zhou Z, Zhao L. Cloud computing model for big data processing and performance optimization of multimedia communication. Comput Commun. 2020;160:326–332.
  • Hajjaji Y, Boulila W, Farah IR, et al. Big data and IoT-based applications in smart environments: a systematic review. Comput Sci Rev. 2021;39:100318.
  • Lau BPL, Marakkalage SH, Zhou Y, et al. A survey of data fusion in smart city applications. Inf Fusion. 2019;52:357–374.
  • Tseng ML, Wu KJ, Lim MK, et al. Data-driven sustainable supply chain management performance: a hierarchical structure assessment under uncertainties. J Clean Prod. 2019;227:760–771.
  • Bag S, Yadav G, Dhamija P, et al. Key resources for Industry 4.0 adoption and its effect on sustainable production and circular economy: an empirical study. J Clean Prod. 2021;281:125233. ( Article in Press). .
  • Okpoti ES, Jeong IJ. A reactive decentralized coordination algorithm for event-driven production planning and control: a cyber-physical production system prototype case study. J Manuf Syst. 2021;58:143–158.
  • Tao F, Qi Q, Wang L, et al. Digital twins and cyber-physical systems toward smart manufacturing and Industry 4.0: correlation and comparison. Engineering. 2019;5(4):653–661.
  • Ying KC, Pourhejazy P, Cheng CY, et al. Cyber-physical assembly system-based optimization for robotic assembly sequence planning. J Manuf Syst. 2021;58:452–466.
  • Weber KM, Gudowsky N, Aichholzer G. Foresight and technology assessment for the Austrian parliament — finding new ways of debating the future of Industry 4.0. Futures. 2019;109:240–251.
  • Tuptuk N, Hailes S. Security of smart manufacturing systems. J Manuf Syst. 2018;47:93–106.
  • Kavallieratos G, Katsikas S, Gkioulos V. SafeSec Tropos: joint security and safety requirements elicitation. Comp Stand Interfaces. 2020;70:103429.
  • Lee J, Cameron I, Hassall M. Improving process safety: what roles for Digitalization and Industry 4.0? Process SafEnviron Prot. 2019;132:325–339.
  • Khalid A, Kirisci P, Khan ZH, et al. Security framework for industrial collaborative robotic cyber-physical systems. Comput Ind. 2018;97:132–145.
  • Ogonji MM, Okeyo G, Wafula JM. A survey on privacy and security of Internet of Things. Comput Sci Rev. 2020;38:100312.
  • Bhushan B, Sinha P, Sagayam KM, et al. Untangling blockchain technology: a survey on state of the art, security threats, privacy services, applications and future research directions. Comput Electr Eng. 90(2020);106897. ( Article in Press).
  • Neumann WP, Winkelhaus S, Grosse EH, et al. Industry 4.0 and the human factor – a systems framework and analysis methodology for successful development. Int J Prod Econ. 2021;233:107992. ( Article in Press). .
  • Kadir BA, Broberg O. Human-centered design of work systems in the transition to industry 4.0. Appl Ergon. 2021;92:103334.
  • Liu J, Chang H, Y-l FJ, et al. Influence of artificial intelligence on technological innovation: evidence from the panel data of China’s manufacturing sectors. Technol Forecasting Social Change. 2020;158:120142.
  • Mao S, Wang B, Tang Y, et al. Opportunities and Challenges of Artificial Intelligence for Green Manufacturing in the Process Industry. Engineering. 2019;5(6):995–1002.
  • Nishant R, Kennedy M, Corbett J. Artificial intelligence for sustainability: challenges, opportunities, and a research agenda. Inter J Inf Manage. 2020;53:102104.
  • Loureiro SMC, Guerreiro J, Tussyadiah I. Artificial intelligence in business: state of the art and future research agenda. J Bus Res. 2020;129:911–926.
  • Jimeno-Morenilla A, Azariadis P, Molina-Carmona R, et al. Technology enablers for the implementation of Industry 4.0 to traditional manufacturing sectors: a review. Comput Ind. 2021;125:103390.
  • Lenoir D, Schramm KW, Lalah JO. Green Chemistry: some important forerunners and current issues. Sustainable Chem Pharm. 2020;18:100313. ( Article in Press). .
  • Lenz J, MacDonald E, Harik R, et al. Optimizing smart manufacturing systems by extending the smart products paradigm to the beginning of life. J Manuf Syst. 2020;57:274–286.
  • Duan Y, Luo Y, Li W, et al. A collaborative task-oriented scheduling driven routing approach for industrial IoT based on mobile devices. Ad Hoc Netw. 2018;81:86–99.
  • Frank AG, Dalenogare LS, Ayala NF. Industry 4.0 technologies: implementation patterns in manufacturing companies. Int J Prod Econ. 2019;210:15–26.
  • Ahmad T, Zhang D, Huang C, et al. Artificial intelligence in sustainable energy industry: status Quo, challenges and opportunities. J Clean Prod. 2021;289:125834. ( Article in Press). .
  • Sarja M, Onkila T, Mäkelä M. A systematic literature review of the transition to the circular economy in business organizations: obstacles, catalysts and ambivalences. J Clean Prod. 286(2020);125492.
  • Centobelli P, Cerchione R, Chiaroni D, et al. Designing business models in circular economy: a systematic literature review and research agenda. Business Strat Environ. 2020;29(4):1734–1749.
  • Dutta G, Kumar R, Sindhwani R, et al. Digital transformation priorities of India’s discrete manufacturing SMEs–a conceptual study in perspective of Industry 4.0. Compet Rev. 2020;30(3):289–314. .
  • Fernández-Rovira C, Valdés JÁ, Molleví G, et al. The digital transformation of business. Towards the datafication of the relationship with customers. Technol Forecasting Social Change. 2021;162:120339.
  • Chen Y, Lin Z. Business intelligence capabilities and firm performance: a study in China. Inter J Inf Manage. 2021;57:102232.
  • Papananias M, McLeay TE, Obajemu O, et al. Inspection by exception: a new machine learning-based approach for multistage manufacturing. Appl Soft Comput. 2020;97:106787.
  • Injadat M, Moubayed A, Nassif AB, et al. Machine learning towards intelligent systems: applications, challenges, and opportunities. Artif Intell Rev. 2021;54, 3299–3348.
  • Sharp M, Ak R, Hedberg T Jr. A survey of the advancing use and development of machine learning in smart manufacturing. J Manuf Syst. 2018;48:170–179.
  • Goh GD, Sing SL, Yeong WY. A review on machine learning in 3D printing: applications, potential, and challenges. Artif Intell Rev. 2020;54, 63–94.
  • Gunasekaran A, Subramanian N, Tiwari MK, et al. Information sharing in supply chain of agricultural products based on the Internet of Things. Ind Manage Data Syst. 2016;116(7):1397–1416.
  • Lin SY, Du Y, Ko PC, et al. Fog Computing Based Hybrid Deep Learning Framework in effective inspection system for smart manufacturing. Comput Commun. 2020;160:636–642.
  • Wang J, Ma Y, Zhang L, et al. Deep learning for smart manufacturing: methods and applications. J Manuf Syst. 2018;48:144–156.
  • Guo Z, Zhou D, Zhou Q, et al. A hybrid method for evaluation of maintainability towards a design process using virtual reality. Comput Ind Eng. 2020;140:106227.
  • De Regt A, Barnes SJ, Plangger K. The virtual reality value chain. Bus Horiz. 2020;63(6):737–748.
  • Malik AA, Masood T, Bilberg A. Virtual reality in manufacturing: immersive and collaborative artificial-reality in design of human-robot workspace. Int J Comput Integr Manuf. 2020;33(1):22–37.
  • Luo Y, Song K, Ding X, et al. Environmental sustainability of textiles and apparel: a review of evaluation methods. Environ Impact Assess Rev. 2021;86:106497.
  • Beier G, Niehoff S, Ziems T, et al. Sustainability aspects of a digitalized industry–A comparative study from China and Germany. Int J Precis Eng Manuf Green Technol. 2017;4(2):227–234.
  • Gobbo JA, Busso CM, Gobbo SCO, et al. Making the links among environmental protection, process safety, and Industry 4.0. Process SafEnviron Prot. 2018;117:372–382.
  • Fu Y, Zhu J. Trusted data infrastructure for smart cities: a blockchain perspective. Build Res Inf. 2021;49(1):21–37.
  • Abbate T, Cesaroni F, Cinici MC, et al. Business models for developing smart cities. A fuzzy set qualitative comparative analysis of an IoT platform. Technol Forecasting Social Change. 2019;142:183–193.
  • Cha J, Singh SK, Kim TW, et al. Blockchain-empowered cloud architecture based on secret sharing for smart city. J Inf Secur Appl. 2021;57:102686.
  • Nižetić S, Djilali N, Papadopoulos A, et al. Smart technologies for promotion of energy efficiency, utilization of sustainable resources and waste management. J Clean Prod. 2019;231:565–591.
  • Silva BN, Khan M, Han K. Towards sustainable smart cities: a review of trends, architectures, components, and open challenges in smart cities. Sustainable Cities Soc. 2018;38:697–713.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.