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Robotic Process Automation (RPA) gewinnt durch die Möglichkeit, repetitive Administrationsprozesse zu automatisieren und Effizienzpotenziale zu heben, zunehmend an Bedeutung. In der Praxis scheitern jedoch viele Implementierungsprojekte. Dies resultiert primär aus dem fehlenden Verständnis darüber, wie sich die Einführung von RPA auf das Gesamtsystem Organisation auswirkt. Es entsteht eine wachsende Kluft zwischen dem Leistungsversprechen von RPA und der Fähigkeit von Unternehmen, jenes auszuschöpfen. Trotz der exponentiellen Geschwindigkeit des technologischen Fortschritts mangelt es vielen Unternehmen an der notwendigen Adaptionsfähigkeit, welche für den nachhaltigen Erfolg einer RPA-Implementierung essenziell ist. In diesem Kontext spielt die Optimierung der im Einklang stehenden Dimensionen Mensch, Technik und Organisation eine zentrale Rolle. Durch eine systematische Literaturrecherche wird aufgezeigt, dass bisherige Ansätze diesen Zusammenhang nur unzureichend betrachten. In der heutigen Forschungslandschaft existiert kein Modell, welches die technischen, sozialen und organisatorischen Komponenten, die im Zuge der RPA-Einführung zu berücksichtigen sind, darlegt. Angelehnt an das soziotechnische Systemdenken und den Prozess der Fallstudienforschung werden theoriegeleitet Dimensionen und Elemente einer RPA-spezifischen soziotechnischen Systemarchitektur identifiziert und erläutert. Das daraus resultierende Modell zur Unterstützung von Unternehmen bei der RPA-Einführung wurde mit einer Vielzahl Industrievertretern im Rahmen des öffentlichen Forschungsprojekts RPAsset des FIR e. V. an der RWTH Aachen validiert.
Ziel des Beitrags ist es, aufzuzeigen, wie produzierende Unternehmen entlang der Customer-Journey systematisch kundenbezogene Daten erheben können. Nach einer Einleitung zur Motivation der Themenstellung, einer Begriffserläuterung und einer Vorstellung des Studiendesigns wird ein Referenzprozessmodell der Kundeninteraktionen produzierender Unternehmen gestaltet, darauf aufbauend ein Datenmodell des digitalen Schattens der Kundeninteraktionen abgeleitet und zuletzt ein Vorgehensmodell zur Implementierung des digitalen Schattens der Kundeninteraktionen präsentiert.
In short-term production management of the Internet of Production (IoP) the vision of a Production Control Center is pursued, in which interlinked decision-support applications contribute to increasing decision-making quality and speed. The applications developed focus in particular on use cases near the shop floor with an emphasis on the key topics of production planning and control, production system configuration, and quality control loops.
Within the Predictive Quality application, predictive models are used to derive insights from production data and subsequently improve the process- and product-related quality as well as enable automated Root Cause Analysis. The Parameter Prediction application uses invertible neural networks to predict process parameters that can be used to produce components with desired quality properties. The application Production Scheduling investigates the feasibility of applying reinforcement learning to common scheduling tasks in production and compares the performance of trained reinforcement learning agents to traditional methods. In the two applications Deviation Detection and Process Analyzer, the potentials of process mining in the context of production management are investigated. While the Deviation Detection application is designed to identify and mitigate performance and compliance deviations in production systems, the Process Analyzer concept enables the semi-automated detection of weaknesses in business and production processes utilizing event logs.
With regard to the overall vision of the IoP, the developed applications contribute significantly to the intended interdisciplinary of production and information technology. For example, application-specific digital shadows are drafted based on the ongoing research work, and the applications are prototypically embedded in the IoP.
Long-term production management defines the future production structure and ensures the long-term competitiveness. Companies around the world currently have to deal with the challenge of making decisions in an uncertain and rapidly changing environment. The quality of decision-making suffers from the rapidly changing global market requirements and the uniqueness and infrequency with which decisions are made. Since decisions in long-term production management can rarely be reversed and are associated with high costs, an increase in decision quality is urgently needed. To this end, four different applications are presented in the following, which support the decision process by increasing decision quality and make uncertainty manageable. For each of the applications presented, a separate digital shadow was built with the objective of being able to make better decisions from existing data from production and the environment. In addition, a linking of the applications is being pursued:
The Best Practice Sharing App creates transparency about existing production knowledge through the data-based identification of comparable production processes in the production network and helps to share best practices between sites. With the Supply Chain Cockpit, resilience can be increased through a data-based design of the procurement strategy that enables to manage disruptions. By adapting the procurement strategy for example by choosing suppliers at different locations the impact of disruptions can be reduced. While the Supply Chain Cockpit focuses on the strategy and decisions that affect the external partners (e.g., suppliers), the Data-Driven Site Selection concentrates on determining the sites of the company-internal global production network by creating transparency in the decision process of site selections. Different external data from various sources are analyzed and visualized in an appropriate way to support the decision process. Finally, the issue of sustainability is also crucial for successful long-term production management. Thus, the Sustainable Footprint Design App presents an approach that takes into account key sustainability indicators for network design. [https://link.springer.com/referenceworkentry/10.1007/978-3-030-98062-7_15-1]