@inproceedings{265, abstract = {{The maintenance of a tool for injection molding or forming is usually accompanied by its disassembly and assembly. The duration of the assembly activities is often a large part of the total activity time for the maintenance of the tool. The degree of performance of the employees in the execution of these disassembly and assembly activities is often low. In addition, allowances occur (e.g. searching for work equipment). At the Industrial Engineering Lab of the Ostwestfalen-Lippe University of Applied Sciences, a prototype of an assistance system was developed to support the assembly activities in toolmaking. With the help of this system, the operator is guided step by step through the assembly process. The economic potential of the system exists in the reduction of training times, the avoidance of assembly errors and the increase of labor productivity.}}, author = {{Hinrichsen, Sven and Riediger, Daniel and Unrau, Alexander}}, booktitle = {{2017 IEEE International Conference on Industrial Engineering and Engineering Management (IEEM)}}, isbn = {{978-1-5386-0948-4 }}, keywords = {{injection moulding, machine tools, maintenance engineering, productivity, projection-based assistance system, injection molding tools, assembly activities, assembly process, assembly errors, tool maintenance, disassembly activities, economic potential, Industrial Engineering Lab, Ostwestfalen-Lippe University of Applied Sciences, toolmaking, Tools, Injection molding, Maintenance engineering, Usability, Task analysis, Workstations, Morphology, assembly assistance systems, assistance systems, maintenance of injection molding tools, manual assembly}}, location = {{Singapore}}, number = {{1}}, pages = {{1571--1575}}, title = {{{Development of a Projection-Based Assistance System for Maintaining Injection Molding Tools}}}, doi = {{https://doi.org/10.1109/IEEM.2017.8290157}}, year = {{2017}}, } @inproceedings{574, abstract = {{The increasing industrial digitization is the driver for the fast emergence of many industrial smart products. To stay competitive, the manufacturing companies of these smart products need to optimize their internal lifecycleprocesses. Mainly, they have to converge the software and hardware lifecycleprocesses. However, even if this strategic necessity has been recognized, manufacturing companies struggle to develop and implement a roadmap of such convergence.Starting point for the realization of harmonized lifecycle processes are processmodels describing process activities and the underlying data models. This research addresses the latter one and aims to create a generic lifecycle data model. The research team created and evaluated such data model referring to development artifacts such as requirements, parts or test cases and to lifecycle artifacts such as revisions, versions and baselines. The generic lifecycle management model was evaluated by a practical development of a smart product. By this, the research provides a valuable result to maintain and increase the competitiveness of manufacturing companies.}}, author = {{Deuter, Andreas and Otte, Andreas and Ebert, Marcel}}, booktitle = {{Production Engineering and Management}}, editor = {{Padoano, Elio and Villmer, Franz-Josef}}, isbn = {{978-3-946856-01-6}}, keywords = {{PLM, ALM, Systems Engineering, VDI guideline 2206}}, location = {{Pordenone, Italy}}, number = {{1}}, pages = {{115--125}}, title = {{{Extending the Sliced V-Model to Smart Product Development}}}, year = {{2017}}, } @inproceedings{587, abstract = {{Development engineers are most valued for their excellence in physical product development, but on the flipside, project managers face problems when trying to fit them into effectively running development processes. Because of the advantages of Lean Management in production (Lean Production), process managers often try to transfer lean principles directly to development processes, not considering that major differences exist between well-described production processes and new product development processes which include much more uncertainty and risk. Nevertheless, several lean principals are applicable in product development. This paper describes five lean development insights (LDIs) which were found when optimizing an entire product realization process. Lean principles have been examined and then translated to collaboration between product development and tool manufacturing at a globally operating German family-run company. These LDIs are meant to help project and process managers, consultants and developers to rethink their ways of organizing product development. The application of these insights will result in increased transparency, intensified collaboration, improved processes and quality, shortened lead times, and also eliminate waste.}}, author = {{Riediger, M. and Villmer, Franz-Josef}}, booktitle = {{Production Engineering and Management}}, editor = {{Villmer, Franz-Josef and Padoano, Elio}}, isbn = {{978-3-946856-00-9}}, keywords = {{Lean development, Collaboration, Agile, PLM, Frontloading, Simultaneous engineering}}, location = {{Lemgo}}, number = {{1}}, pages = {{111--122}}, title = {{{Five Insights in Effectively Managing Product Development}}}, year = {{2016}}, } @inproceedings{4329, abstract = {{The term Industrie 4.0 carries the vision of smart factories, which automatically adapt to changes and assist the human as much as possible during operation and maintenance. This includes smart human machine interfaces, which reduce the chances of errors and help to make the right decisions. This paper presents an approach to equip the maintenance software running on a tablet PC with augmented reality functionality to be able to place virtual sticky notes at production modules. Additionally, these sticky notes are enriched with position information. The central element of this approach is an ontology-based context-aware framework, which aggregates and processes data from different sources. As a result, a tablet PC application was implemented, which allows displaying maintenance information as well as live plant process data in the form of augmented reality. More than 100 of those sticky notes can be placed using this system, whereas each note requires a file size of 12 to 16 kilo bytes. After placing a sticky note, the system recognizes it even if the camera's position is not exactly the same as during the placing process.}}, author = {{Flatt, Holger and Koch, Nils and Guenter, Andrei and Röcker, Carsten and Jasperneite, Jürgen}}, booktitle = {{ 2015 IEEE 20th Conference on Emerging Technologies & Factory Automation (ETFA)}}, keywords = {{Maintenance engineering, Augmented reality, Context, Context modelin, Production facilities, Cameras}}, location = {{Luxembourg, Luxembourg}}, publisher = {{IEEE}}, title = {{{A Context-Aware Assistance System for Maintenance Applications in Smart Factories based on Augmented Reality and Indoor Localization}}}, doi = {{10.1109/ETFA.2015.7301586}}, year = {{2015}}, } @inproceedings{4492, abstract = {{In most countries demographic developments tend towards more and more elderly people in single households. Improving the quality of life for elderly people is an emerging issue within our information society. Good user interfaces have tremendous implications for appropriate accessibility. Though, user interfaces should not only be easily accessible, they should also be useful, usable and most of all enjoyable and a benefit for people. Traditionally, Human–Computer Interaction (HCI) bridges Natural Sciences (Psychology) and Engineering (Informatics/Computer Science), whilst Usability Engineering (UE) is anchored in Software Technology and supports the actual implemen-tation. Together, HCI and UE have a powerful potential to help towards making technology a little bit more accessible, useful, useable and enjoyable for everybody.}}, author = {{Holzinger, Andreas and Ziefle, Martina and Röcker, Carsten}}, booktitle = {{Computers Helping People with Special Needs, Part II}}, editor = {{ Miesenberger, K. and Klaus, J. and Zagler, W. and Karshmer, A.}}, isbn = {{978-3-642-14099-0}}, keywords = {{Human–Computer Interaction, Usability Engineering, User Interfaces, Elderly People, Older Adults}}, location = {{Vienna, Austria}}, pages = {{556--559}}, publisher = {{Springer}}, title = {{{Human-Computer Interaction and Usability Engineering for Elderly (HCI4AGING): Introduction to the Special Thematic Session}}}, doi = {{10.1007/978-3-642-14100-3_83}}, volume = {{6180}}, year = {{2010}}, } @book{478, author = {{Hinrichsen, Sven}}, isbn = {{978-3-8322-6636-3 }}, keywords = {{Einzelhandelsbetrieb, Dienstleistungsbetrieb, Industrial Engineering}}, pages = {{IV, 240}}, publisher = {{Shaker Verlag}}, title = {{{Arbeitsrationalisierung mittels Methoden des Industrial Engineering in Dienstleistungsbetrieben}}}, volume = {{2}}, year = {{2007}}, } @inproceedings{4815, abstract = {{In this paper a concept is presented, that supports awareness and emotional communication between family members, distributed over multiple intelligent home environments. A technical communication infrastructure is presented, which allows connecting different types of input and output devices. This platform is extended by several examples of emotional user interfaces, which address the individual needs of different user groups}}, author = {{Etter, Richard and Röcker, Carsten and Gilgen, Daniel}}, booktitle = {{Proceedings of the Second International Conference on Intelligent Environments (IE’06)}}, isbn = {{978-0-86341-663-7}}, issn = {{0537-9989}}, keywords = {{User interfaces, Home computing, Automated buildings, Control engineering computing}}, location = {{Athens, Greece}}, pages = {{41--50}}, publisher = {{IET}}, title = {{{Supporting Emotional Communication between Multiple Users in Intelligent Home Environments}}}, doi = {{10.1049/cp:20060623}}, year = {{2006}}, }