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Remote services are services enabled by information and communication components and therefore do not require the physical presence of a service technician at the service object to provide a task. The impact of remote service on the capital goods industry has been increasingly significant over the recent yeas. Still many companies struggle with developing and implemenling successful business model, for remote service. This leads to a lot of unaccomplished benefits for the customer as well as for the companies themselves. A survey throughout companies in Ihe industrial machine and plant production sector was conducted in order to determine what successful companies do differently from those that cannot efficiently implement remote service business models.
The study presented in this chapter identifies key suceess factors of companies that effectively implemented remote services for their products. In order to identify the successful companies a scale for measuring remote service success was developed. Only by the use of this scale further findings regarding the success factors were possible. Key findings include the fact that successful companies actively market their remotle service to their customers. Generally they try to approach their remote service business from the operating company's perspective.
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.
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.
Operation and Maintenance (O&M) is a key value driver for offshore wind farms. Consequently, reducing O&M costs improves their profitability. This paper introduces different typologies of dispositioning maintenance tasks in offshore wind farms, in order to help design the strategies and organization of maintenance. Based on the special requirements of offshore wind farms regarding planning and controlling the O&M activities, a morphological analysis was developed. With this different disposition strategies for offshore wind farms could be generated. The consequences of choosing different characteristics are allegorized in an exemplary fashion. The work presented in the following is the foundation for designing a software-based dispositioning tool for usage in offshore wind farms, which will help to increase the effectiveness of the disposition in offshore wind farms by maximizing the number of accomplished tasks per day and minimizing the time technicians stay on the wind turbine and the ships.
Erfolgsprinzipien der Smart Maintenance – Was wir von den Besten aus der Praxis lernen können
(2019)
Der Industriestandort Deutschland befindet sich im Wandel. Neue, digitale Technologien ermöglichen es, Betriebs-, Zustands- und Ereignisdaten in stetig steigender Menge zu erfassen, aufzubereiten, zu analysieren und für die industrielle Anwendung nutzbar zu machen. Dieser Nutzen zeichnet sich durch die Beschleunigung der unternehmerischen Entscheidungs- und Anpassungsprozesse aus und stellen damit das eigentliche Potenzial von ‚Industrie 4.0‘ dar. An dieser Stelle stehen Unternehmen heute vor der Herausforderung, die Transformation zur Smart Maintenance effektiv und effizient zu gestalten. Zu häufig neigen Unternehmen dazu, „das Rad wiederkehrend neu zu erfinden“, da Praxiseinblicke über die eigenen Standort- und Unternehmensgrenzen hinweg fehlen. Um eben jene benötigten Praxiseinblicke und Erfahrungswerte liefern zu können, wurde am FIR an der RWTH Aachen gemeinsam mit sechs Industriepartnern sowie dem Fraunhofer IML aus Dortmund das „Konsortial-Benchmarking Smart Maintenance“ durchgeführt. Anhand eines eigenen Ordnungsrahmens wurden zentrale Fragestellungen der Smart Maintenance identifiziert und mittels Fragebogenstudie untersucht. Durch die angeknüpfte statistische Auswertung konnte zwischen sogenannten ‚Top-Performern‘ (TP) und ‚Followern‘ (FL) unterschieden werden. In diesem Beitrag werden ausgewählte Ergebnisse der Studie sowie der Interviews den Ebenen des Ordnungsrahmens folgend vorgestellt.
Traditional manufacturing companies increasingly launch data-driven services (DDS) to enhance their digital service portfolio. Nonetheless, data-driven services fail more often than traditional industrial services or products within the first year on the market. In terms of market launch, their digital characteristics differ from traditional industrial services and thus need specific structures and actions, which companies currently lack. Therefore, a process guideline for a six-month market launch phase of DDS is developed. The guideline relies on analogies from product, service and software launches based on the latest literature from service marketing and successful practices from various industries. Finally, the guideline is evaluated within five industrial case studies. Thus, the guideline provides scientific research insights regarding the market launch process of DDS and adds to the research of service marketing. It provides practical guidance for manufacturing companies by serving as a reference process for the market launch and offering a collection of successful practices within this area. [https://link.springer.com/chapter/10.1007/978-3-030-00713-3_14]
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.
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.
Method for a qualitative cost benefit evaluation of process standardisation for industrial services
(2018)
Industrial service providers deliver complex technical services (e.g. inspection, maintenance, repair, improvement, installation and turnarounds) for a wide range of technical assets in process industries such as the chemical industry. Due to the versatility of assets and industries, there is also a variety of the corresponding service offerings. The demand for a high service quality and the general cost pressure leads to the need of a more efficient and standardized design of the service processes. However, cost-benefit ratio related decisions regarding the questions where and how service processes should be standardized entail great challenges for small and medium-sized enterprises. This is because there is often a lack of understanding of cost savings through process standardization, which is caused by a lack of understanding of the correlations between process characteristics and process target values. Because of this, the goal of this paper is to develop a method for a quantitative evaluation of the cost-benefit ratio of process standardization measures. Within this method, the relevant service performance processes are selected first. Next, the process data will be recorded with the help of questionnaires. These are then analyzed by looking for correlations between the process characteristics and the process target values. Afterwards standardization measures are derived on the basis of these findings in order to improve deficit characteristics and thus target values. Finally, the method´s practical applicability is tested and validated by applying it to an industrial service in the chemical industry.
KVD-Service-Studie 2018
(2018)
Digitalisierung ist eine der zentralen Herausforderungen der heutigen Zeit. Aber die Digitalisierung rein technisch zu betrachten, ohne Augenmerk auf die Unternehmenskultur zu legen, wird dazu führen, dass Unternehmen die Potenziale der Digitalisierung nicht vollständig realisieren können. Wer weiterhin wettbewerbsfähig sein will, muss den Wert der Digitalisierung erkennen und sie für sein Unternehmen nutzbar machen. Aber welche Auswirkungen ergeben sich daraus für die Serviceorganisation? Um den aktuellen Stand der digitalen Kultur im Service zu erfassen, die Dimensionen zu verstehen und einen Weg für Unternehmen aufzuzeigen, liegt der Schwerpunkt der diesjährigen Service-Studie, die vom KVD zusammen mit dem FIR durchgeführt wurde, auf dem Themenkomplex Digitale Service-Kultur.
Monetizing Industry 4.0: Design Principles for Subscription Business in the Manufacturing Industry
(2019)
Subscription business models have a major role for monetizing products and services for manufacturing companies in the age of Industry 4.0. As the manufacturing industry has difficulties generating revenues through digitalization, the implementation of innovative business models are essential to remain successful. Physical assets are often capital-intensive and require a more complex manufacturing process than subscription business models. Moreover, subscription models can focus on the individual customer benefit and a consistent service transformation, constituting a unique selling proposition and a competitive advantage. Hence, the following paper provides a management model that enables manufacturing companies to successfully realize the transformation towards a subscription business model. The management model presents four major fields of action, each matched with one design principle that must be considered when dealing with subscription models in the manufacturing industry. These principles were determined by an in-depth case study analysis among various manufacturing companies. Opportunities, challenges and recommendations for action were then systematically derived and integrated into the management model.
Neuland Internet
(2015)
The change from the traditional to the digital service provider is not easy. The digital maturity level of many industrial companies is still too low to successfully place these digital service innovations on the market. One problem of service development is the increasing involvement of information and communication technology in service development and implementation. The additional technology makes the innovation processes for services on the part of manufacturers increasingly complex by involving different internal and external stakeholders (e.g. IT partners, data protection officers or product development departments). In addition to this, data-driven services also require that manufacturers (e.g. data scientists) develop new competencies in order to use the customer data obtained to increase machine productivity and to offer new business models. Furthermore, industrial companies that want to successfully offer data-driven services must develop new market introduction strategies to create a high degree of acceptance and trust among their customers. This is necessary to get access to relevant data. These and other challenges caused the success rate of companies in regarding the development of new, industrial services to shrink.
To change this, this white paper presents six principles that help industrial enterprises to develop new successful data-driven services.
Der Wandel vom traditionellen zum digitalen Dienstleister ist nicht ohne weiteres zu vollziehen. So ist der digitale Reifegrad vieler Industrieunternehmen noch zu gering, um diese digitalen Service-Innovationen erfolgreich am Markt zu platzieren.
Ein Problem der Dienstleistungsentwicklung ist die zunehmende Einbindung von Informations- und Kommunikationstechnologie in die Dienstleistungsentwicklung und -durchführung. Die zusätzliche Technologie lässt die Innovationsprozesse für Dienstleistungen auf Seiten der Hersteller immer komplexer werden, indem unterschiedliche interne und externe Stakeholder einbezogen werden müssen (z. B. IT-Partner, Datenschutzbeauftragte oder die Produktentwicklung). Zudem erfordern datenbasierte Dienstleistungen den Aufbau neuer Kompetenzen beim Hersteller (z. B. Data-Scientists), um die gewonnenen Kundendaten zur Steigerung der Maschinenproduktivität nutzen und neue Geschäftsmodelle anbieten zu können. Darüber hinaus müssen Industrieunternehmen, welche erfolgreich datenbasierte Dienstleistungen anbieten wollen, neue Markteinführungsstrategien entwickeln, um bei den Kunden ein hohes Maß an Akzeptanz und Vertrauen zu schaffen und so an relevante Daten zu gelangen. Diese und weitere Herausforderungen lassen die Erfolgsquote von Unternehmen bei der Entwicklung neuer, industrieller Dienstleistungen stetig schrumpfen. Im vorliegenden Whitepaper werden sechs Prinzipien aufgezeigt, die Industrieunternehmen als Hilfestellung bei der Entwicklung neuer, datenbasierter Dienstleistungen dienen.
Die Instandhaltung, konsequent zu Ende gedacht, ist ein zentraler Treiber für den Unternehmenswert und wird damit für viele produzierende Unternehmen zum strategischen Erfolgsfaktor. Da für die meisten Unternehmen ein umfangreicher Mitarbeiter- und Ressourcenaufbau nicht in Frage kommt, stehen diese Unternehmen vor der Herausforderung, den Wertbeitrag vorhandener Mitarbeiter und Ressourcen zu maximieren. Dies führt zum Konzept Return on Maintenance (RoM). Der Wertbeitrag der Instandhaltung geht dabei über die reine Herstellung von Verfügbarkeit zu möglichst geringen Kosten weit hinaus. Zielgrößen wie Ausschussrate, Energieeffizienz, Materialeffizienz aber auch die Minimierung von Rüstzeiten zeigen die vielfältigen Zielgrößen der Instandhaltung auf.
The FIR at the RWTH Aachen University continuously develops the concept and the principles of RoM further. It is already noticeable that the gap between companies that began preparing their maintenance departments for Industrie 4.0 years ago and those that are still struggling with the mere foundations of a professional maintenance organisation is rapidly increasing.
The first driver of the development sparked by Industrie 4.0 is the collection of and work with condition data. It is used to create a digital shadow of a service, e.g. maintenance measures in a specific
context. In the future, critical machine functions will be monitored continuously within production processes.
Based on these observations, the likelihood of machine failures can be predicted, which makes it possible to prioritize data-based maintenance measures. This means that maintenance activities, i.e. production plans, are based on prognoses regarding machine failures. By doing so, the currently existing separation between inspection, maintenance and reactive measures can be overcome, resulting in a holistic approach to maintenance. Maintenance specialists receive support from assistance systems, which give them access to all relevant information (e.g. machine history, spare part availability, proposals for measures, etc.). As a result, they can take on routine tasks in different areas as well and contribute to the increased flexibility of the production process. Although data is becoming an increasingly important driver of successful maintenance strategies,
maintenance employees continue to be central to specific tasks, machines and systems. In the future, it can be expected that they choose to become experts in a certain field and, ideally, actively share their knowledge with others within an open maintenance culture. Systems for interdisciplinary collaboration will be made part of everyday practice.
The maintenance department will be a center and distributor of knowledge in the agile company of the future.Only through the interaction of the outlined success principles, which amount to a paradigm shift within the maintenance department, the potential
benefit of maintenance as defined by RoM can be fully exploited, creating a long-term competitive advantage for those who consistently follow the path towards Industrie 4.0 in maintenance.
Today, maintenance exceeds this definition, it is significantly more.
In many companies, it plays the role of an incubator for development
and drives digital transformation forward. The very essence of
Industrie 4.0 is the optimisation of the flow of information within as
well as outside of a company to accelerate the adjustment of company
organisations in the context of increasing competitive pressure.
Because of the variety of interfaces, information and data that
is available as well as its service character, maintenance lends itself easily as the area of choice for a company to make Industrie 4.0 real. Whilst doing so, the aim is not to equip employees with the
latest “gimmick“ for order processment or to be the company with
the highest number of lighthouse projects. Instead, maintenance
ensures reliable and cost-efficient production and, consequently,
the primary creation of added value of the manufacturing company.
Those who were identified as top performers during the “Smart
Maintenance“ consortium benchmarking by FIR at RWTH Aachen
University gain particular useful ideas twice as often as other follower companies directly from staff, thus releasing the right potential.
Information and data help to reach these goals and transfer the
vision of smart maintenance into actual pratice. But what is smart
maintenance exactly and how far along are you in the development
of your individual smart maintenance concept?
Return on Maintenance
(2017)
Die Instandhaltung, konsequent zu Ende gedacht, ist ein zentraler Treiber für den Unternehmenswert und damit für viele produzierende Unternehmen ein strategischer Erfolgsfaktor. Da für die meisten Unternehmen ein umfangreicher Mitarbeiter- und Ressourcenaufbau nicht in Frage kommt, stehen diese Unternehmen vor der Herausforderung, den Wertbeitrag vorhandener Mitarbeiter und Ressourcen zu maximieren. Dies führt zum Konzept Return on Maintenance (RoM). Der Wertbeitrag der Instandhaltung geht dabei über die reine Herstellung von Verfügbarkeit zu möglichst geringen Kosten weit hinaus. Zielgrößen wie Ausschussrate, Energieeffizienz, Materialeffizienz aber auch die Minimierung von Rüstzeiten zeigen die vielfältigen Zielgrößen der Instandhaltung auf.