TY  - CHAP
A1  - Gronau, Norbert
A1  - Teichmann, Malte
A1  - Weber, Edzard
ED  - Shishkov, Boris
T1  - Serious game-based haptic modeling
BT  - an application-oriented approach for sequentially developing new business models from tacit knowledge
T2  - Business modeling and software design
N2  - The authors propose that while tacit knowledge is a valuable resource for developing new business models, its externalization presents several challenges. One major challenge is that individuals often don’t recognize their tacit knowledge resources, while another is the reluctance to share one’s knowledge with others. Addressing these challenges, the authors present an application-oriented serious game-based haptic modeling approach for externalize tacit knowledge, which can be used to develop the first versions of business models based on tacit knowledge. Both conceptual and practical design fundamentals are presented based on elaborated theoretical approaches, which were developed with the help of a design science approach. The development of the research process is presented step by step, whereby we focused on the high accessibility of the presented research. Practitioners are presented with guidelines for implementing their serious game projects. Scientists benefit from starting points for their research topics of externalization, internalization, and socialization of tacit knowledge, development of business models, and serious games or gamification. The paper concludes with open research desiderata and questions from the presented research process.
KW  - serious game
KW  - tacit knowledge
KW  - business model
KW  - SECI-model
KW  - conversion sequences
KW  - design science
Y1  - 2023
SN  - 978-3-031-36756-4
U6  - https://doi.org/10.1007/978-3-031-36757-1_3
SP  - 32
EP  - 55
PB  - Springer Nature
CY  - Cham
ER  - 
TY  - CHAP
A1  - Thim, Christof
A1  - Gronau, Norbert
A1  - Haase, Jennifer
A1  - Grum, Marcus
A1  - Schüffler, Arnulf
A1  - Roling, Wiebke
A1  - Kluge, Annette
ED  - Shishkov, Boris
T1  - Modeling change in business processes
T2  - Business modeling and software design
N2  - Business processes are regularly modified either to capture requirements from the organization’s environment or due to internal optimization and restructuring. Implementing the changes into the individual work routines is aided by change management tools. These tools aim at the acceptance of the process by and empowerment of the process executor. They cover a wide range of general factors and seldom accurately address the changes in task execution and sequence. Furthermore, change is only framed as a learning activity, while most obstacles to change arise from the inability to unlearn or forget behavioural patterns one is acquainted with. Therefore, this paper aims to develop and demonstrate a notation to capture changes in business processes and identify elements that are likely to present obstacles during change. It connects existing research from changes in work routines and psychological insights from unlearning and intentional forgetting to the BPM domain. The results contribute to more transparency in business process models regarding knowledge changes. They provide better means to understand the dynamics and barriers of change processes.
KW  - intentional forgetting
KW  - routines
KW  - business processes
KW  - unlearning
Y1  - 2023
SN  - 978-3-031-36756-4
SN  - 978-3-031-36757-1
U6  - https://doi.org/10.1007/978-3-031-36757-1_1
SP  - 3
EP  - 17
PB  - Springer Nature
CY  - Cham
ER  - 
TY  - CHAP
A1  - Teichmann, Malte
A1  - Busse, Jana
A1  - Gonnermann, Jana
A1  - Reimann, Daniela
A1  - Ritterbusch, Georg David
A1  - Langemeyer, Ines
A1  - Gronau, Norbert
ED  - Nitsch, Verena
ED  - Brandl, Christopher
ED  - Häußling, Roger
ED  - Roth, Philip
ED  - Gries, Thomas
ED  - Schmenk, Bernhard
T1  - Konzeption, Erstellung und Evaluation von VR-Räumen für die betriebliche Weiterbildung in KMU
BT  - Erfahrungen und Handlungsempfehlungen aus dem Forschungsprojekt API-KMU
T2  - Digitalisierung der Arbeitswelt im Mittelstand 3
N2  - Der Beitrag adressiert die Erstellung von Virtual-Reality gestützten (Lehr- und Lern-) Räumen für die betriebliche Weiterbildung im Rahmen eines Forschungsprojektes. Der damit verbundene Konzeptions- und Umsetzungsprozess ist mit verschiedenen Herausforderungen verbunden: einerseits ist Virtual-Reality ein vergleichsweise neues Lehr- und Lernmedium, womit wenig praktische Handreichungen zur praktischen Umsetzung existieren. Andererseits existieren theoretisch-konzeptionelle Ansätze zur Gestaltung digitaler Lehr- und Lernarrangements, die jedoch 1) oft Gefahr laufen, an den realen Bedürfnissen der Praxis „vorbei“ zu gehen und 2) zumeist nicht konkret Virtual-Reality bzw. damit verbundene Lehr- und Lernumgebungen adressieren. In dieser Folge sind Best-Practice Beispiele basierend auf erfolgreichen Umsetzungsvorhaben, die nachfolgenden Projekten als „Wegweiser“ dienen könnten, äußerst rar. Der Beitrag setzt an dieser Stelle an: basierend auf zwei real existierenden betrieblichen Anwendungsfällen aus den Bereichen Natursteinbearbeitung sowie Einzel- und Sondermaschinenbau werden Herausforderungen und Lösungswege des Erstellungsprozesses von Virtual-Reality gestützten (Lehr- und Lern-)Räumen beschrieben. Ebenfalls werden basierend auf den gemachten Projekterfahrungen Handlungsempfehlungen für die gelingende Konzeption, Umsetzung und Evaluation dieser Räume formuliert. Betriebliche Beschäftigte aus den Bereichen Aus- und Weiterbildung, Management oder Human Ressources, die in eigenen Projekten im Bereich Virtual Reality aktiv werden wollen, profitieren von den herausgestellten praktischen Handreichungen. Forschende Personen sollen Anregungen für weiterführende Forschungsvorhaben erhalten.
Y1  - 2023
SN  - 978-3-662-67023-1
SN  - 978-3-662-67024-8
U6  - https://doi.org/10.1007/978-3-662-67024-8_5
SP  - 155
EP  - 204
PB  - Springer Vieweg
CY  - Berlin
ER  - 
TY  - CHAP
A1  - Gronau, Norbert
A1  - Weber, Edzard
A1  - Wander, Paul
A1  - Ullrich, André
ED  - Plapper, Peter
T1  - A regional remanufacturing network approach
BT  - modeling and simulation of circular economy processes in the era of industry 4.0
T2  - Digitization of the work environment for sustainable production
N2  - Manufacturing companies still have relatively few points of contact with the circular economy. Especially, extending life time of whole products or parts via remanufacturing is an promising approach to reduce waste. However, necessary cost-efficient assessment of the condition of the individual parts is challenging and assessment procedures are technically complex (e.g., scanning and testing procedures). Furthermore, these assessment procedures are usually only available after the disassembly process has been completed. This is where conceptualization, data acquisition and simulation of remanufacturing processes can help. One major constraining aspect of remanufacturing is reducing logistic efforts, since these also have negative external effects on the environment. Thus regionalization is an additional but in the end consequential challenge for remanufacturing. This article aims to fill a gap by providing an regional remanufacturing approach, in particular the design of local remanufacturing chains. Thereby, further focus lies on modeling and simulating alternative courses of action, including feasibility study and eco-nomic assessment.
KW  - regional network
KW  - remanufacturing
KW  - scenario modeling
Y1  - 2022
SN  - 978-3-95545-407-4
U6  - https://doi.org/10.30844/WGAB_2022_8
SP  - 145
EP  - 170
PB  - GITO Verlag
CY  - Berlin
ER  - 
TY  - CHAP
A1  - Teichmann, Malte
A1  - Lass, Sander
A1  - Ullrich, André
A1  - Gronau, Norbert
ED  - Weber, Kristin
ED  - Reinheimer, Stefan
T1  - Modellfabriken als Enabler flexibler Lehr- und Lernsituationen für die Kompetenzentwicklung im Fabrikkontext
BT  - die Lernfabrik des Zentrums Industrie 4.0 Potsdam
T2  - Faktor Mensch
N2  - Dieses Kapitel diskutiert die Notwendigkeit einer stärkeren Praxisorientierung für die Schaffung konkreter Lehr- und Lernräume in Unternehmen und zeigt die Vorteile einer Lernfabrik vor dem Hintergrund der stattfindenden Digitalisierung als Mittel zur Kompetenzentwicklung auf. Die technologiebedingt erweiterten Weiterbildungsziele erfordern die Nutzung geeigneter Konzepte und Lösungen. Dahingehend erfolgt die zielorientierte Konkretisierung der Kreation geeigneter Lehr- und Lernsituationen. Die Darstellung der Nutzbarmachung einer Modellfabrik als Lernfabrik der betrieblichen Weiterbildungspraxis zeigt nicht nur eine Lösung für die intendierte Bereitstellung flexibler Lehr- und Lernsituationen, sondern liefert ebenso Handlungsempfehlungen und Best-Practices für die erfolgreiche Kompetenzentwicklung. Insbesondere Praktiker profitieren von der Darstellung der Lernfabrik: aus dieser können sowohl betriebliche Weiterbildner als auch Geschäftsverantwortliche Implikationen für die didaktische Transformation betrieblicher Arbeitsorte in betriebliche Lern-Orte ableiten. Die detaillierte Darstellung einer Tagesschulung zum Thema Auswirkungen von Industrie 4.0 auf die Arbeit der Mitarbeiter sowie Illustration eines Lernszenarios geben reale Einblicke, wie betriebliche Weiterbildung abseits von Lehr-Lern-Kurzschluss-orientierter Didaktik gelingt.
KW  - betriebliche Weiterbildung
KW  - Digitalisierung
KW  - Modellfabrik
KW  - Lehr-Lernsituationen
KW  - Industrie 4.0
KW  - Zentrum Industrie 4.0
Y1  - 2022
SN  - 978-3-658-34523-5
SN  - 978-3-658-34524-2
U6  - https://doi.org/10.1007/978-3-658-34524-2_10
N1  - vollständig überarbeiteter und erweiterter Beitrag basierend auf dem Artikel „Herausforderungen und Handlungsempfehlungen betrieblicher Weiterbildungspraxis in Zeiten der Digitalisierung“ von Malte Teichmann, André Ullrich, Julian Wenz, Norbert Gronau, HMD Heft 333, Stefan Reinheimer, Kristin Weber (Hrsg.): Faktor Mensch, Juni 2020, S. 512–527.
SP  - 173
EP  - 196
PB  - Springer Fachmedien
CY  - Wiesbaden
ER  - 
TY  - CHAP
A1  - Gronau, Norbert
ED  - Roth, Stefan
ED  - Corsten, Hans
T1  - Künstliche Intelligenz in der Produktionssteuerung
T2  - Handbuch Digitalisierung
Y1  - 2022
SN  - 978-3-8006-6562-4
SN  - 978-3-8006-6563-1
SP  - 629
EP  - 650
PB  - Verlag Franz Vahlen
CY  - München
ER  - 
TY  - CHAP
A1  - Gronau, Norbert
A1  - Rojahn, Marcel
ED  - Leupold, Andreas
ED  - Wiebe, Andreas
ED  - Glossner, Silke
T1  - Das Industrial Internet of Things (IIOT)
T2  - IT-Recht : Recht, Wirtschaft und Technik der digitalen Transformation
Y1  - 2021
UR  - https://beck-online.beck.de/Bcid/Y-400-W-LeupoldGlossnerHdbITR-GL-Teil10-1
SN  - 978-3-406-74458-7
SP  - 1115
EP  - 1124
PB  - C.H. Beck
CY  - München
ET  - 4., überarbeitet und erweitert
ER  - 
TY  - CHAP
A1  - Thim, Christof
A1  - Grum, Marcus
A1  - Schüffler, Arnulf
A1  - Roling, Wiebke
A1  - Kluge, Annette
A1  - Gronau, Norbert
ED  - Andersen, Ann-Louise
ED  - Andersen, Rasmus
ED  - Brunoe, Thomas Ditlev
ED  - Larsen, Maria Stoettrup Schioenning
ED  - Nielsen, Kjeld
ED  - Napoleone, Alessia
ED  - Kjeldgaard, Stefan
T1  - A concept for a distributed Interchangeable knowledge base in CPPS
T2  - Towards sustainable customization: cridging smart products and manufacturing systems
N2  - As AI technology is increasingly used in production systems, different approaches have emerged from highly decentralized small-scale AI at the edge level to centralized, cloud-based services used for higher-order optimizations. Each direction has disadvantages ranging from the lack of computational power at the edge level to the reliance on stable network connections with the centralized approach. Thus, a hybrid approach with centralized and decentralized components that possess specific abilities and interact is preferred. However, the distribution of AI capabilities leads to problems in self-adapting learning systems, as knowledgebases can diverge when no central coordination is present. Edge components will specialize in distinctive patterns (overlearn), which hampers their adaptability for different cases. Therefore, this paper aims to present a concept for a distributed interchangeable knowledge base in CPPS. The approach is based on various AI components and concepts for each participating node. A service-oriented infrastructure allows a decentralized, loosely coupled architecture of the CPPS. By exchanging knowledge bases between nodes, the overall system should become more adaptive, as each node can “forget” their present specialization.
KW  - learning
KW  - distributed knowledge base
KW  - artificial intelligence
KW  - CPPS
Y1  - 2021
SN  - 978-3-030-90699-3
SN  - 978-3-030-90702-0
SN  - 978-3-030-90700-6
U6  - https://doi.org/10.1007/978-3-030-90700-6_35
SP  - 314
EP  - 321
PB  - Springer
CY  - Cham
ER  - 
TY  - CHAP
A1  - Grum, Marcus
A1  - Thim, Christof
A1  - Gronau, Norbert
ED  - Andersen, Ann-Louise
ED  - Andersen, Rasmus
ED  - Brunoe, Thomas Ditlev
ED  - Larsen, Maria Stoettrup Schioenning
ED  - Nielsen, Kjeld
ED  - Napoleone, Alessia
ED  - Kjeldgaard, Stefan
T1  - Aiming for knowledge-transfer-optimizing intelligent cyber-physical systems
T2  - Towards sustainable customization : cridging smart products and manufacturing systems
N2  - Since more and more production tasks are enabled by Industry 4.0 techniques, the number of knowledge-intensive production tasks increases as trivial tasks can be automated and only non-trivial tasks demand human-machine interactions. With this, challenges regarding the competence of production workers, the complexity of tasks and stickiness of required knowledge occur [1]. Furthermore, workers experience time pressure which can lead to a decrease in output quality. Cyber-Physical Systems (CPS) have the potential to assist workers in knowledge-intensive work grounded on quantitative insights about knowledge transfer activities [2]. By providing contextual and situational awareness as well as complex classification and selection algorithms, CPS are able to ease knowledge transfer in a way that production time and quality is improved significantly. CPS have only been used for direct production and process optimization, knowledge transfers have only been regarded in assistance systems with little contextual awareness. Embedding production and knowledge transfer optimization thus show potential for further improvements. This contribution outlines the requirements and a framework to design these systems. It accounts for the relevant factors.
KW  - smart automation
KW  - smart production
KW  - human-machine-interaction
Y1  - 2021
SN  - 978-3-030-90699-3
SN  - 978-3-030-90700-6
SN  - 978-3-030-90702-0
U6  - https://doi.org/10.1007/978-3-030-90700-6_16
SP  - 149
EP  - 157
PB  - Springer
CY  - Cham
ER  - 
TY  - CHAP
A1  - Grum, Marcus
A1  - Gronau, Norbert
ED  - Shishkov, Boris
T1  - Adaptable knowledge-driven information systems improving knowledge transfers
BT  - design of context-sensitive, AR-enabled furniture assemblies
T2  - Business modeling and software design : 10th International Symposium, BMSD 2020, Berlin, Germany, July 6-8, 2020, Proceedings
N2  - A growing number of business processes can be characterized as knowledge-intensive. The ability to speed up the transfer of knowledge between any kind of knowledge carriers in business processes with AR techniques can lead to a huge competitive advantage, for instance in manufacturing. This includes the transfer of person-bound knowledge as well as externalized knowledge of physical and virtual objects. The contribution builds on a time-dependent knowledge transfer model and conceptualizes an adaptable, AR-based application. Having the intention to accelerate the speed of knowledge transfers between a manufacturer and an information system, empirical results of an experimentation show the validity of this approach. For the first time, it will be possible to discover how to improve the transfer among knowledge carriers of an organization with knowledge-driven information systems (KDIS). Within an experiment setting, the paper shows how to improve the quantitative effects regarding the quality and amount of time needed for an example manufacturing process realization by an adaptable KDIS.
KW  - augmented reality
KW  - knowledge transfers
KW  - empirical studies
KW  - context-aware computing
KW  - adaptable software systems
KW  - business process improvement
Y1  - 2020
SN  - 978-3-030-52305-3
SN  - 978-3-030-52306-0
U6  - https://doi.org/10.1007/978-3-030-52306-0_13
VL  - 391
SP  - 202
EP  - 220
PB  - Springer International Publishing
CY  - Cham
ER  -