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Smart Services
(2018)
Die Nutzung von Informations- und Kommunikationstechnologien in Wirtschaft und Gesellschaft ist inzwischen zur Selbstverständlichkeit geworden. Deutschen Leitbranchen, wie dem Maschinen- und Anlagenbau, stehen durch die Digitalisierung jedoch noch große Umbrüche vor. Die Erfassung von Daten im laufenden Betrieb der Anlagen bietet die Chance durch die Analyse der Daten wertvolle Informationen zu gewinnen. Diese Informationen lassen sich in datenbasierten Dienstleistungen mehrwertstiftend in der Instandhaltung nutzen. In diesem Beitrag wird das Potenzial von datenbasierten Dienstleistungen in der Instandhaltung erläutert und wie dadurch neue Geschäftsmo-dellen für Unternehmen entstehen können. Der Beitrag schließt ab mit einer Beschrei-bung möglicher Einsatzfelder von datenbasierten Dienstleistungen in der Instandhal-tung am Beispiel des Unternehmens BELFOR DeHaDe GmbH.
Smart Service Engineering
(2019)
Industry 4.0 has provided vast opportunities for manufacturing companies whilst simultaneously creating multiple challenges. In this new highly digitized globalized marketplace, manufacturing companies find themselves under pressure to become more service oriented and offer new innovative value offerings such as smart services. These are digital data-driven services that, generally, add value in conjunction with a physical product. However, classical methods of service engineering have not adapted sufficiently to the increasing digital components and requirements of smart services. This paper presents Smart Service Engineering as a novel service-engineering approach for industrial smart services. Smart Service Engineering draws from iterative development models and implements agile and customer-centric methods to decrease the overall development time and achieve an early market success. The paper focuses on the service development steps and presents the interaction and interconnection of different elements of smart services based on a case study research. Finally the paper illustrates the successful application of the Smart Service Engineering approach and its impact on a German medium-sized company in the textile machine industry.
Smart Service Engineering
(2018)
Global manufacturing companies currently face an increasingly turbulent economic environment known as the "VUCA-world" (volatility, uncertainty, complexity and ambiguity). After the transformation of many companies from product to solution providers in the last 15-20 years, the focus of many corporate change processes is on digital solutions such as data-driven services. In this context, service development is of particular relevance for industrial services. Companies develop digital strategies and try to maximize the added value for their customers, by offering, for example, smart services. They are based on smart products, which are connected to the internet, interact with their environment and gather environmental data. The collected data sets are combined with other easily accessible information and processed into so-called smart data. Based on this smart data, smart services are designed. They can be defined as individualized combinations of physical and digital services. They generate added value for providers and customers and offer context-related and demand-oriented value via digital platforms. The contribution of this paper to this research field of data-driven services is a service engineering approach for industrial smart services.
Since the 1990s, service engineering has established itself as a systematic process for the development of services. Currently existing service engineering processes are based on engineering science and business model innovation toolsets. However, the increasing digital components in service engineering reveal deficits in the direct application of the classical methods of service engineering to smart services. We suggest that the successful development and implementation of smart services requires a more agile service engineering process. Studies show that companies who develop services successfully (top-performer) act up to six times faster than those with less success (follower). They involve customers in the first running prototype of their digital service to increase customer centricity and focus their development activities on core functionalities of the service to reduce its development time and test it early with customers.
To strengthen the successful development pf data-driven services in future industrial service development projects, this paper contributes to a more agile service engineering approach. Smart service engineering combines elements of linear phase models and implements agile and customer-centric findings to decrease the overall development time by focussing on core functionalities that offer a high value for customers. The paper focuses on the service development steps and presents strategic scenarios for smart service engineering. It presents the interaction and interconnection of different elements of smart services based on a case study research. In addition to this, it illustrates the implications of a customer-centric engineering approach and possible strategic decisions based on the customer feedback. The paper focuses on the successful application of the smart service engineering approach and its impact in a German medium-size company in the textile machine industry.
Im Rahmen von Industrie 4.0 kommt der prognosebasierten bedarfsgerechten Instandhaltung eine besondere Bedeutung zu. Sie steigert die Wirtschaftlichkeit von Produktionsanlagen beispielsweise durch eine Erhöhung der Verfügbarkeit, Lebensdauer oder Leistung. Dafür sind verschiedene Bausteine notwendig, die in dem Vortrag erläutert werden.
Smart Maintenance
(2018)
Für die industrielle Produktion haben sich im Verlauf der letzten Jahrzehnte einige Tendenzen ausgebildet, die umfangreiche Veränderungen hervorrufen werden. Die momentane Entwicklung ist vor allem durch die zunehmende Dynamik der Produktlebenszyklen und die Durchdringung industrieller Wertschöpfung mit neuen Technologien geprägt. Hierfür ist die hoch flexible, verfügbare und zuverlässige Produktion zwingende Voraussetzung. Zur Bewältigung dieser Herausforderungen der Industrie 4.0 steht die Smart Factory im Mittelpunkt. Intelligente digital anschlussfähige Maschinen und Produkte sind miteinander vernetzt und können aktiv kommunizieren. Dadurch werden Anlagen technisch immer komplexer und neue Kommunikationssysteme immer umfangreicher. [https://link.springer.com/chapter/10.1007/978-3-662-53135-8_24]
Data-driven services play an important role in
innovative business models of successful manufacturing
companies: They hold great potential for the creation of unique
selling points and improve the differentiation of manufacturing
companies in highly competitive markets. However, the large
number of newly invented digital services that fail shortly after
launching implies that companies struggle with the invention and
implementation of data-driven service solutions, which ends in a
waste of resources. The following paper introduces guideline
principles for successful innovation processes for data-driven
services. The principles were identified during in-depth case
studies with manufacturing companies. They contribute to a
necessary paradigm change for manufacturing companies in
terms of data-driven services for machines. The six identified
principles emphasize new aspects regarding the new dimension of
data-driven solutions and improve the life cycle management of
products and services. They demonstrate how the rules of agile
development can lead to successful and more efficient service
innovations in the industrial sector.
Herr Müller ist wirklich sauer. Es ist bereits das vierte (!) Mal, dass
sein Wagen nicht zum vereinbarten Zeitpunkt abholbereit ist. Ne-
ben der lästigen Wartezeit hat die Unzuverlässigkeit der Werkstatt
weitere negative Konsequenzen, die nicht nur Herrn Müller selbst
betreffen: Dank der Verzögerung schafft es Herr Müller nun schon
wieder nicht, seine Tochter vom Ballett abzuholen und muss,
schon wieder, seine Frau darum bitten, für ihn einzuspringen. Die
wiederum hatte eigentlich schon andere Pläne für den Abend und
muss jetzt spontan umdisponieren.
Erfolgreiche Serviceinnovation im Zeitalter industrieller, datenbasierter Dienstleistungen unterscheidet sich deutlich von bisherigen Ansätzen der klassischen Dienstleistungsentwicklung. Diese Erkenntnis konnte aus einem breit angelegten Benchmarking in der deutschen Industrie gewonnen werden. Die Benchmarking-Studie identifizierte besonders erfolgreiche Unternehmen, deren Methoden und Ansätze zur Gestaltung innovativer Dienstleistungen in Form von Fallstudien im Detail untersucht wurden. Als Kernergebnis ergeben sich sechs Prinzipien, die erfolgreiche Serviceinnovation für datenbasierte Dienstleistungen auszeichnen.
The additive manufacturing technique of "Selective Laser Melting" (SLM) provides the basis for a fundamental paradigm shift in industrial spare part manufacturing, affecting both technological and organizational company prac-tices. To harness the full potential of SLM-technology, considering agility and customizability, decentralized additive production networks need to be estab-lished. According to the principles just in time, just in place and just enough, a global online platform, which efficiently distributes construction orders to local manufacturing hubs could empower the market participants to utilize production capacities at optimal costs and minimal efforts. This work evaluates and selects key factors and creates scenarios for the development of platform-based networks for additive, SLM-based, spare part production. For this purpose, the selected key factors (e. g. material expenses, quality and process management and platform-based business models) are projected into the future, forming the three major scenarios "New distribution of roles in the SLM value chain", "SLM-technology for high wage countries" and "Individualization instead of mass production". These scenarios not only allow estimating the potential of an online network for additive spare part production, but also enable market participants to react pur-posively and agilely to unexpected market developments, and to foster the suc-cess of a platform-based additive spare part production.
The industrial food production is currently caught between the increas-ing demands of numerous stakeholders, economic profitability and the challenges of digitization. A solution to face these various challenges can be seen in the aggregation of data into higher-value, independent data products that can be of-fered and sold on a buyer's market. Large amounts of heterogeneous data are already available in the value chain of the industrial food production, e.g. throughout the data-driven harvesting of primary products, further processing by interconnected production facilities and the information-intensive product distri-bution to end consumers. However, the data is usually only evaluated and used locally for the optimization of internal processes or, at the most, within compre-hensive partnerships. The purpose of this paper is to identify new revenue oppor-tunities for current and future players in the industrial food production by using data as an independent economic good (data products). For this purpose, scenar-ios for the development and use of data products via Industrial Internet of Things platforms are developed for a food technical reference process, the industrial chocolate production and its value chain. On this basis, examples for different types of data products and their value propositions are derived. The results can not only serve food producers and relevant stakeholders but all industrial produc-ers as an input for the future, yield-increasing orientation of their business models.