@misc{13703,
  abstract     = {{Mostly in the furniture industry the quality approach is anecdotical. A sys-tematic convergence of specifications for claims of functions and design is missing. A system has now been drafted or agreed in accordance with the aforementioned German standards, which follows the Geometrical Product Specification (GPS, ISO 8015) system and offers new possibilities for coding on technical drawings, as well as in the downstream chain of standards for measuring, testing and process capability analysis. DIN 919-2 as a new drafted German standard for technical drawing in wood industry is opening up the whole tool set of GPS coding elements. DIN 68100 is adding a geomet-rical tolerance system including swelling or shrinkage. DIN68100-2 will pro-pose statistical tolerancing to convolute variances in geometry caused e.g. by production with distributions in moisture con- tent or shrinkage coefficients. VDI 3414 is offering specifications and corresponding verifications for at-tributive quality characteristics of wooden surfaces including a naming and coding system. Finally VDI 3415-2 is referring to measuring and production capability analysis esp. for the wood industry and related research. As far as possible the German standardization activities will be presented in the paper. The selected use case will be the edge banding and profile wrapping where the new guideline VDI 3412 will assist the practitioners and scientists concern-ing specification, verification but as well in trouble shooting.}},
  author       = {{Riegel, Adrian and Kortüm, Christian and Scholz, Frieder and Binninger, Karsten}},
  booktitle    = {{Advances in Wood Machining : Selected Chapters from the 26th International Wood Machining Seminar (IWMS26) }},
  editor       = {{Goli, Giacomo and Sandak, Jakub and Schajer, Gary and Zanetti, Michaela and Bounamici, Fransesco}},
  isbn         = {{ ‎ 978-3032173089}},
  keywords     = {{technical drawing, geometrical product specification and verifica-tion GPS, process capability, standards and guidelines, edge banding}},
  location     = {{Florenz}},
  pages        = {{100--103}},
  publisher    = {{Springer Verlag GmbH}},
  title        = {{{Systematic and comprehesive quality specification and verfication for furniture industry - DIN 919, DIN 68100, VDI 3414, VDI 3415}}},
  volume       = {{26}},
  year         = {{2026}},
}

@inproceedings{550,
  abstract     = {{Additive Manufacturing (AM) technologies are increasingly used for final part production. Especially technologies for processing of metal, like Selective LaserMelting (SLM), arefocusedin this area. The shift from prototyping towards  final  part production results in enhanced requirements for repeatability and predictability of the part quality. Machine  manufacturers offer process monitoring solutions for different aspects of the production process, like the powder bed surface, the melt pool, and the laser energy. Nevertheless, the significance of these systems is not fully proven and threshold values for the monitored process parameters have to be determined for each product individually. This impedes the development of suitable process control systems. The paper gives an overview ofexistingresearch approaches and available process monitoring systems for SLM and their applicability for predicting certain part characteristics. The existing solutions are evaluated based on own research results. Next, AM specific difficulties for the development of process control tools and possible solutions are discussed.}},
  author       = {{Huxol, Andrea and Villmer, Franz-Josef}},
  booktitle    = {{Production Engineering and Management}},
  editor       = {{Villmer, Franz-Josef and Padoano, Elio}},
  isbn         = {{978-3-946856-03-0}},
  keywords     = {{Additive manufacturing, Process capability, Process monitoring, Quality assurance, Final part production}},
  location     = {{Lemgo}},
  number       = {{1}},
  pages        = {{17--28}},
  title        = {{{Process Control for Selective Laser Melting - Opprtunities and Limitations}}},
  year         = {{2018}},
}

@inproceedings{577,
  abstract     = {{A rising number of product variants together with decreasing lot sizes are a result of the trend of individualization. Besides the upcoming organizational issues, changes in the production technologies are required. Direct digital manufacturing contributes to solve this problem by enabling the production of parts right from the CAD data.Process capability analysis is applied in several industries to prove the reliable compliance of products with quality requirements. As it is based on statistical methods, new challenges arise in the context of single-part production.The paper describes and compares different approaches for the adoption of process capability analysis for single-part production with special focus on additive manufacturing technologies. The statistical background and the applicability of different capability parameters are discussed. An overview of existing research work is given and supplemented by own approaches for the adoption of statistical methods for single-part production. The aim of the research work is to establish a first approach for the qualification of new technologies in single-part production.}},
  author       = {{Huxol, Andrea and Davis, Andrea and Villmer, Franz-Josef and Scheideler, Eva}},
  booktitle    = {{Production Engineering and Management}},
  editor       = {{Padoano, Elio and Villmer, Franz-Josef}},
  isbn         = {{978-3-946856-01-6}},
  keywords     = {{Statistical process control, Process capability analysis, Single-part production, Process optimization}},
  location     = {{Pordenone, Italy}},
  number       = {{1}},
  pages        = {{63--74}},
  title        = {{{Deployment of Process Capability Analysis for Single-Part Production}}},
  year         = {{2017}},
}