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Druckverfahren ohne Druckform (NIP-Verfahren)

  • Helmut Kipphan

Zusammenfassung

In diesem Kapitel werden Druckverfahren erläutert, die keine feste Druckform benötigen und prizipiell von Druck zu Druck eine unterschiedlich bedruckte Seite erzeugen können. Derartige Verfahren werden Non-Impact-Druckverfahren (auch NIP-Verfahren werden, NIP für Non-Impact Printing) genannt.

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Literatur zu 5.1

  1. [5.1-1]
    Case, C.; Lawson, T.: History of Liquid Toner Innovation. Pan-Pacific Imaging Conference/Japan Hardcopy ’98 (Proceedings). The Society of Electrophotography of Japan (SEPJ), c/o Tokyo Institute of Polytechnic, Tokyo (Jp) 1998, pp. 26–33.Google Scholar

Ergänzende Literatur zu 5.1

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Literatur zu 5.2

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Literatur zu 5.5

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Ergänzende Literatur zu 5.5

  1. Le, H.: Progress and Trends in Ink Jet Printing Technology. Journal of Imaging Science and Technology, Vol. 42, No. 1, pp. 49–62, 1998.Google Scholar

Literatur zu 5.6

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Literatur zu 5.7

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Literatur zu 5.8

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Ergänzende Literatur zu 5.8

  1. International Congress on Imaging Science (ICPS ’98) (Proceedings, Vol. 1 und 2). The International Committee on the Science of Photography (ICPS) and The Royal Flemish Chemical Society (KVCV), section Photonics, Leuwen (B) 1998.Google Scholar
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Literatur zu 5.9

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    Proceedings of IS&T’s NIP-Conference: The International Conference on Digital Printing Technologies. The Society for Imaging Science and Technology (IS&T), Springfield (VA) (jährlich).Google Scholar
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    Nilsson, D. et al.: Dot Deflection Control — A Noval Multiplexing Method for Tonerjet. NIP 13: International Conference on Digital Printing Technologies (Proceedings). The Society for Imaging Science and Technology (IS&T), Springfield (VA) 1997, pp. 740–745.Google Scholar
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    Starck-Johnson, H. P. et al.: Uniformity in Solid Areas with the Tonerjet Printing Technology. NIP 15: International Conference on Digital Printing Technologies (Proceedings). The Society for Imaging Science and Technology (IS&T), Springfield (VA) 1999, pp. 289–292.Google Scholar
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    Schmidlin, F.: Advances in Traveling Wave Toner Transport. NIP 15: International Conference on Digital Printing Technologies (Proceedings). The Society for Imaging Science and Technology (IS&T), Springfield (VA) 1999, pp. 302–305.Google Scholar
  18. [5.9-18]
    Thompson, M. D. et al.: Aspects of Toner Transport on a Traveling Wave Device. NIP 15: International Conference on Digital Printing Technologies (Proceedings). The Society for Imaging Science and Technology (IS&T), Springfield (VA) 1999, pp. 262–265.Google Scholar
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    United States Patent 5.508.727, Apparatus and Method for Pattern Generation on a dielectric Substrate. Imagine, Ltd. (Israel) 1996.Google Scholar
  20. [5.9-20]
    Kipphan, H.: Status and Trends in Digital Multicolor Printing-Technologies, Materials, Processes, Architecture, Equipment and Market. NIP 13: International Conference on Digital Printing Technologies (Proceedings). The Society for Imaging Science and Technology (IS&T), Springfield (VA) 1997, pp. 11–19.Google Scholar

Copyright information

© Springer-Verlag Berlin Heidelberg 2000

Authors and Affiliations

  • Helmut Kipphan
    • 1
  1. 1.Heidelberger Druckmaschinen AGHeidelbergDeutschland

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