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Die Herausforderungen der Zukunft werden geprägt durch digital veredelte Produkte von höchster Qualität und hoher Variantenvielfalt bei gleichzeitig kleiner werdenden Losgrößen. Konventionelle Entwicklungsmethoden stoßen aufgrund zunehmender Komplexität und kürzer werdender Lebenszyklen auf Produktebene an ihre Grenzen. Dadurch werden bei kundenindividueller Produktion die Aufwände in der Arbeitsplanung und -vorbereitung überproportional größer. Eine mögliche Lösung stellt die generative Erstellung der Produktionsstückliste während der Montage dar. Durch das eventbasierte „Mitschreiben der Montage“ werden administrative und planungsintensive Prozesse in der Arbeitsvorbereitung überproportional reduziert und die Erstellung der Stückliste in die manuelle Montage transferiert.
Supply chains form the backbone of modern economies and therefore require reliable information flows. In practice, however, supply chains face severe technical challenges, especially regarding security and privacy. In this work, we consolidate studies from supply chain management, information systems, and computer science from 2010–2021 in an interdisciplinary meta-survey to make this topic holistically accessible to interdisciplinary research. In particular, we identify a significant potential for computer scientists to remedy technical challenges and improve the robustness of information flows. We subsequently present a concise information flow-focused taxonomy for supply chains before discussing future research directions to provide possible entry points.
Companies in high wage countries are increasingly confronted with the challenge of optimizing economies of scope and economies of scale simultaneously to succeed on a global market place. An integrated assessment of production systems facing this challenge is essential to evaluate the actual state of a company and to provide a basis for drawing the right conclusions to reconfigure production systems successfully.
In this paper an integrated model for measuring economies of scope as well as economies of scale is introduced, defining the fundamental domains of a production system. The major objectives resulting from the overall scale-scope dilemma are broken down for each domain and the main dimensions for an assessment of each domain are defined. A new measure named Degree of Efficiency is defined, quantifying the fulfillment of the opposing objectives in each domain and hence, the contribution to an overall resolution of the scale-scope dilemma.
Digital platforms act as mediator for many types of transactions and processes in various areas in business life. Especially, IoT platforms find increased use within companies. Still, the allocation of computation workload between a platform and exist-ing information systems is not clear. At the same time, companies have no guideline, which platform to choose to facilitate intra-com-pany optimizations. The platforms in the market are not fully designed or tailored for meeting the special needs of companies - especially in the manufacturing industry. To tackle these challenges, this article first gives an overview of the Internet of Production reference framework. In that context, it secondly investigates 212 IoT platforms in the market and then chooses the best options by stepwise narrowing down their number. Following, those selected platforms are described in detail. Additionally, the article provides a comparison of selected IoT platforms, which then creates the general framework of a platform especially designed for the manufacturing industry in terms of its features and functionalities. This reference platform architecture is developed for reaching the potential of the Internet of Production. This general framework and the representative reference architecture can help companies and software vendors to implement the Internet of Production reference architecture by creating an IoT platform, which fits its needs.
Numerous start-ups and now even some major corporates are currently trying to improve visibility and foresight in the manufacturing industry through connected supply chains, or in other words, through increased data sharing. This study strives to support companies in leveraging the potential of increased data sharing in supply chain collaborations. Despite the great potential of digitizing manufacturing and automated data sharing throughout the supply chain, most companies are not yet able or willing to implement this kind of openness. The main reason for this lack of transparency in the supply chain is the high complexity and high cost of the required interfaces. In practice, instead of automated and extensive data sharing, companies exchange spreadsheets and PDFs with minimum information. This study supports companies in the pre-stage before automated data sharing is technically implemented. We find that building trustful relationships is a necessary step towards extended and automated data sharing. Moreover, we find that social capital provides a means to partially compensate for a lack of automation in terms of shortening lead times and dealing with disruptions. Introducing a supply chain collaboration typology and showcasing descriptive and qualitative results for 36 firms, we show how to navigate the frontend of the Internet of Production.
Development of a platform business model for co-creation ecosystems for sustainable furniture
(2023)
Existing design platforms with multi-dimensional value chains currently have deficits in terms of their business models, resulting in insufficient attention to sustainability goals and individual requirements for products of these platforms. Co-creation approaches, such as the Do-It-Together (DIT) approach for furniture, involve customers and manufacturers as equal partners in the design and production process. This allows customers to have more influence on the sustainability and individualization of products. The existing literature addresses sustainability-oriented design principles for platform business models, but concrete platform business models for multidimensional DIT cocreation of furniture are still missing. Therefore, the objective of this paper is to develop a business model for a DIT co-creation platform for the furniture industry based on a four-step business model innovation framework. This method will then be applied to a specific project scenario to derive a project-specific DIT co-creation business model. This generates knowledge about the collaborative manufacture of sustainable and customized furniture and contributes to the cross-sectoral transfer of platform business models for the development of sustainable products.
Business ecosystems have become a novel type of value system in all economic sectors. Many of the world’s largest and most valuable companies operate with business ecosystem approaches. The lack of a uniform understanding of business ecosystems’ features and characteristics make it difficult for decision makers in companies to develop and implement effective business ecosystem strategies. We created a morphology that describes all value systems and applied it to business ecosystems. We link business ecosystem characteristics to current interorganizational research and also help practitioners
operationalize the concept of business ecosystems. Companies can use the managerial implications we provide to leverage ecosystems and co-create value.
Overview: The digital transformation of organizations continues at a frenetic pace. While some companies have achieved trailblazer status, others are finding it difficult to change and therefore are lagging. Digital leaders play a pivotal role in this transition because they can increase the confidence of their organizations behind these often risky and disruptive initiatives. In this article, we present our efforts to i) separate the practices of digitally developing and digitally mature organizations―particularly those of their leaders, ii) determine the specific trust-building actions of digitally mature leaders, iii) develop a scale to measure the human dimensions of digital leaders, and iv) discuss the future development of a reliable scale and self-assessment tool that digital leaders can use to assess their own readiness to accelerate digital initiatives.
Data-driven transparency in end-to-end operations in real-time is seen as a key benefit of the fourth industrial revolution. In the context of a factory, it enables fast and precise diagnoses and corrections of deviations and, thus, contributes to the idea of an agile enterprise. Since a factory is a complex socio-technical system, multiple technical, organizational and cultural capabilities need
to be established and aligned. In recent studies, the underlying broad accessibility of data and corresponding analytics tools are called “data democratization”. In this study, we examine the status quo of the relevant capabilities for data democratization in the manufacturing industry.
(1) and outline the way forward.
(2) The insights are based on 259 studies on the digital maturity of factories from multiple industries and regions of the world using the acatech Industrie 4.0 Maturity Index as a framework. For this work, a subset of the data was selected.
(3) As a result, the examined factories show a lack of capabilities across all dimensions of the framework (IT systems, resources, organizational structure, culture).
(4) Thus, we conclude that the outlined implementation approach needs to comprise the technical backbone for a data pipeline as well as capability building and an organizational transformation.
Industry 4.0 and Smart Maintenance represent a great opportunity to make manufacturing and maintenance more effective, safer, and reliable. However, they also represent massive change and corresponding challenges for industrial companies, as many different options and starting points have to be weighed and the individual right paths for achieving Smart Maintenance need to be identified. In our paper, we describe our approach to evaluating maintenance organizations in a case study for the oil and gas industry, developing a shared vision for the future, and deriving economical and effective measures. We will demonstrate our approach, by showcasing a specific example from the oil and gas industry, where a need for action on HSE-relevant critical flanges in the company's piping systems was identified. We describe the steps, that were taken to identify the need for action, the specifications of the project and the criticality analysis of the piping system. This resulted in the derivation of a digitalization measure for critical flanges, which was first commercially analyzed and then the flanges were equipped with a continuous monitoring solution. Finally, a conclusion is drawn on the performed procedure and the achieved improvements.