Günther Schuh
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TPM hat sich – im Verständnis von Total Productive Management – vom rein auf die Instandhaltung bezogenen Konzept mittlerweile zu einem umfassenden Managementkonzept für das betriebliche Instandhaltungsmanagement weiterentwickelt. Nicht allein nur die Instandhaltungsbereiche sondern alle angrenzenden Organisations- und Unterstützungsbereiche werden in die Betrachtung von TPM integriert. Neben der Ganzheitlichkeit des Konzeptes adressieren die einzelnen TPM-Säulen überdies in einem hohen Maß die gleichen Ziele, die auch in existierenden Ansätzen zur wertorientierten Instandhaltung bzw. wertorientierten Unternehmensführung beschrieben sind. Der Beitrag befasst sich daher zunächst mit der Entwicklung der Wertorientierung in der Instandhaltung und zeigt damit den werterhaltenden und wertsteigernden Beitrag dieses Unterstützungsbereichs auf. Hieran anknüpfend gibt der Beitrag einen Überblick relevanter TPM-Konzepte und Begrifflichkeiten, um letztendlich die erfolgreiche Umsetzung der Wertorientierung in der Instandhaltung durch TPM zu belegen und aufzuzeigen, wie mit TPM die betriebliche Instandhaltung wertorientiert gestaltet werden kann.
Due to shorter product life cycles the number of production ramp-ups is increasing, while customers have a soaring demand for more variable and individualized products. In the future, optimizing the production ramp-up will become an important differentiation criterion for companies. Considering the whole supply chain in the ramp-up process becomes therefore indispensable. This is what the presented research in this paper concentrates on. The intention of the research project is to develop a model of a supply chain in the production ramp-up stage. Through this model, approaches for optimizing the production ramp-up in the whole supply chain will be derived.
Further the research project concentrates on measuring the production ramp-up performance in the supply chain, showing the impact on economic and financial measures. The result of this research is an approach to align the tasks and objectives of Supply Chain Management with the tasks and objectives of ramp-up management in order to optimize the whole supply chain in the ramp-up stage.
The House of Maintenance
(2009)
In order to guarantee an efficient and effective employment of production equipment, it is essential to identify any possible potential for improving performance, not only in the production process, but also in supporting areas such as maintenance. One of the major tasks in increasing maintenance performance consists of systematically identifying the company’s most significant weaknesses in maintenance organisation and thus being able to implement improvements there where they are most needed.
But how is a company to tackle this important task? To answer this question, this paper describes an assessment and improvement approach, based on a capability maturity model (CMM). By means of this approach, the status-quo of a maintenance organisation can be analysed and its individual improvement opportunities identified.
Rebound Logistics
(2009)
Today, the flow of product returns is becoming a significant concern for many manufacturing companies. In this research area, three fundamental aspects of product returns need to be taken into consideration: First, companies become increasingly aware of the fact that product returns may offer an opportunity for enormous profit generation and for improving the competitive advantage of a manufacturing company when taking into account the accretive value of the products and technology. Second, the impact of green laws, legislative provisions and the increasing impact of a sustainable production management due to marketing aspects force companies to design and manage the reverse supply chain actively. Third, the importance of managing the reverse supply chains effectively will be enforced by the currently volatile economic climate. This paper outlines first results of designing a methodological framework for implementing an integrative reverse supply chain for manufacturing companies based on a type-specific Reverse Supply Chain Reference Model.
In the near future, tooling companies will offer their customers not just maintenance services, but complex remote service packages for their engineering asset management, which is the total management of physical – not financial – assets. The overall goal is to enhance the efficiency of the engineering asset, e.g. to reduce TCO, on the customers´ site by means of value creating partnerships. These partnerships may be, e.g. the classical output or reliability partnership, but also process optimizing partnerships or lifecycle partnerships. The process optimizing partnership offers, e.g. the optimization of the system’s performance or the output quality, an optimized ramp-up and restart procedure or optimization of the production process parameters. The lifecycle partnership, on the other hand, accompanies the intelligent tool-machine-system throughout the whole lifecycle, which includes, e.g. provision of spare parts during the entire usage phase, storing, refurbishment, recycling and even the support of relocation of production facilities. Intelligent remote services have great potential for realizing all these partnerships.
To realize such engineering asset-related partnerships, two major tasks have to be done. First, there has to be the intelligent tool-machine system, which delivers the information that is required for these services. And furthermore, this information has to be integrated into the maintenance processes, so that it is delivered at the right place and time and in the required form. Second, the activities and processes that are combined to the engineering asset-related partnerships have to be configured out of standardized service and process modules. Therefore configuration logic is essential.
Industrial companies face tremendous challenges to plan the resources needed to meet future market demands when implementing a PSS based solution portfolio. This paper deals with enhancing the PSS research landscape by presenting an approach to enable better resource-planning in PSS based businesses. In particular, a model is proposed which links resource structures with customer offerings. Linkages are implemented, which connect resources and their use in processes. The model contributes to better understand the complexity in resource structures and elements in the PSS and helps to better understand and describe the structural integration of resources in PSS. This is an important prerequisite for the planning of PSS and allows a qualitative and quantitative description of the service resources allocation enabling companies to build the competence needed to meet customer requirements. A case study based approach was applied for model development.
Holistic PLM- Model
(2010)
Product Lifecycle Management (PLM) is a widely discussed topic concerning the increase of efficiency of product development in terms of time to market as well as customizing products to the different needs of customers worldwide adequately. Historically PLM focuses the early phases of the product’s lifecycle, namely the product development phase. Therein the roots of PLM are based in supporting the information logistics of product data: Consistent data sets should be available to all stakeholders in the different departments at all times. Due to the increasing product complexity PLM has to be extended in terms of the temporal dimension (not limited to product development phase) and systemic dimension (not limited to the information logistic aspect). In this paper the authors derive a holistic framework for Product Lifecycle Management by analysing existing integrated management approaches. The framework consists of four dimensions: PLM strategy, PLM process, Product structure and PLM IT-Architecture. The sustainability and benefits of the framework is demonstrated by applying the framework to the communication service provider industry (CSP).
Within each of the three design fields numerous design elements exist (e.g. degree of centralization, number of warehouses etc. in the field network design). Hence, the interdependencies of all design elements have to be analyzed to allow optimal decisions for the design of an efficient and effective spare parts logistics. Nevertheless, the complexity among all interdependencies can hardly be understood. Therefore it is necessary to reduce the complexity of design decisions by focusing on the most important design elements according to the logistical requirements of different spare part categories. In order to achieve this goal, a classification of spare parts in terms of their key characteristics has been developed. For different spare part categories only a smaller set of design elements and their interdependencies has to be taken into account. The reduced number of key design elements per spare part category can be analyzed and understood in depth. Thus a Systems Dynamics approach is used to allow a better configuration of network design, cooperation concepts and inventory management in spare parts Supply Chains on the basis of specific logistics requirements of different spare part categories.
In dynamic markets flexible and efficient production systems are the main success factor for companies. The production system in this context includes all five phases of the SCOR-Model: Source, Make, Deliver, Plan and Return. In a subproject of the cluster of excellence "Integrative Production Technology for High-Wage Countries" at RWTH Aachen University, a configuration logic is being developed that enables companies to configure their production system according to the dynamic requirements of the market. As a major intermediate result, a holistic description model for production systems has been defined. In combination with numerous attributes in the sub-models, a detailed characterization of the production system is possible.
The sub-model for the design of the Supply Chain (mainly Deliver) will be depicted in detail in this paper. Representative for the design of a Supply Chain, spare parts logistics - as one of the most challenging tasks in logistics planning - is analyzed in depth. For this purpose spare parts logistics is divided into three design fields: network design, cooperation concepts (e.g. with logistics providers, customers, suppliers) and inventory management. Decisions in the design fields are highly interdependent, any spare parts logistics configuration has to take these interdependencies into account.
Dynamische Märkte verlangen nach effizienten Produktionssystemen. Um Unternehmen in die Lage zu versetzen, ihre Produktionssysteme auf diese Anforderungen einzustellen, entwickelt der Exzellenzcluster „Integrative Production Technology for High-Wage Countries“ an der RWTH Aachen im Rahmen eines Unterprojekts eine Konfigurationslogik, die eine ganzheitliche und gleichzeitig detaillierte Beschreibung des Produktionssystems erlaubt.
Dieser Artikel stellt das entwickelte Modell zur Gestaltung der Supply-Chain detailliert dar. Als Betrachtungsgegenstand wird die distributionsseitige Lieferkette der Ersatzteillogistik gewählt, da deren Gestaltung und Betrieb eine der größten Herausforderungen der logistischen Planung bilden. Die Ersatzteillogistik wird dazu in drei wesentliche Gestaltungsfelder aufgeteilt: Netzwerkdesign, Kooperationskonzepte und Bestandsmanagement. Im Fokus der Betrachtungen stehen die Interdependenzen zwischen den Gestaltungsfeldern und ihren Elementen, da sie die Entscheidungsfindung häufig erschweren.
Die volle Bandbreite aller Abhängigkeiten ist in der Regel nicht zu erfassen. Daher erfolgt eine Reduzierung der Komplexität durch eine Fokussierung der für verschiedene Ersatzteilkategorien wesentlichen Gestaltungselemente. Hierzu wird zunächst eine Klassifizierung der Ersatzteile im Hinblick auf ihre Schlüsselcharakteristiken durchgeführt. Für jede Kategorie muss im Anschluss nur eine reduzierte Menge von Gestaltungselementen berücksichtigt werden, sodass eine vertiefte Analyse dieser relevanten Elemente möglich wird. Mithilfe eines systemdynamischen Ansatzes wird schließlich eine verbesserte Konfiguration des Netzwerkdesigns, des Kooperationskonzepts und des Bestandsmanagements der Ersatzteillieferkette auf der Basis spezifischer logistischer Anforderungen für die entsprechenden Ersatzteilkategorien erreicht.