Optimized Process Sequences for Prototyping of Molded Interconnect Devices

Christoph Jürgenhake; Christian Fechtelpeter; Roman Dumitrescu; Daniel Heidsiek

doi:10.4028/www.scientific.net/AMR.1038.19

Paper Titles

Method for the Identification and Comparison of Alternative Process Chains Focusing on Economics Efficiency Analysis during the Conceptual Design of Mechatronic Integrated Devices
p.3

Novel Approach for the Implementation of 3D-MID Compatible Routing Functionalities into Computer-Aided Design Tools
p.11

Optimized Process Sequences for Prototyping of Molded Interconnect Devices
p.19

Integration of Functional Circuits into FDM Parts
p.29

Printing of Functional Structures on Molded 3D Devices
p.37

Electrical Functionalization of Thermoplastics by Combining Plasmadust Coating and Aerosol Jet Printing
p.43

Production of Miniaturized Sensor Structures on Polymer Substrates Using Inkjet Printing
p.49

Progress in the Manufacturing of Molded Interconnected Devices by 3D Microcontact Printing
p.57

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1038Optimized Process Sequences for Prototyping of...

Optimized Process Sequences for Prototyping of Molded Interconnect Devices

Abstract:

The MID technology offers a high potential for the development of innovative integrated product solutions. The integration of mechanical and electronic functions on a spatial circuit board allows the realization of modules with a high functional density and a significant degree of miniaturization. MID components are spatial injection molded parts, with their surface selectively patterned and metalized. The conventional production of MID applications by an injection molding process is time consuming and expensive. Therefore, the efforts of industry and research show the significance of MID prototyping. Our objective was to develop process overviews and matching sequences for the methodological-assisted prototyping within our MID-Laboratory (MIDLab). First of all, we developed process overviews for any suitable process operations in accordance to the MID reference process. To enable a methodological approach in the production planning, essential information has been summarized in characteristics. The characteristics include a short description of the process and its unique features and a summary of the advantages and disadvantages compared to alternative methods. In addition, the compatibility of subsequent process steps, if limited or restricted, is illustrated. Afterwards, these process steps were combined to production sequences with a focus on costs, benefits and house production. Based on the requirements of the prototype, two scenarios have been developed, covering a wide spectrum of possibilities. In both sequences emphasis has been placed on cost-optimal combinations with a high house production rate. The validation of the results was carried out by two application examples. For this reason demonstrators were designed. On the basis of these modules, the results of the developed process chains were validated.

You might also be interested in these eBooks

11th International Congress Molded Interconnect Devices – Scientific Proceedings

View Preview

Info:

Periodical:

Advanced Materials Research (Volume 1038)

Pages:

19-27

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1038.19

Citation:

Cite this paper

Online since:

September 2014

Authors:

Christoph Jürgenhake*, Christian Fechtelpeter, Roman Dumitrescu, Daniel Heidsiek

Keywords:

Process Characteristics, Process Sequences, Production Costs, Prototyping

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] , K. Feldmann, MID – Zukunftstechnologie für mechatronisch integrierte Produkte, Produktion von Leiterplatten und Systemen (PLUS) 11/2009, Leuze Verlag, Bad Saulgau, (2009).

Google Scholar

[2] M. Broy (Eds. ), Cyber-Physical Systems – Innovation durch softwareintensive eingebettete Systeme, acatech DISKUTIERT, Springer, Berlin, (2010).

Google Scholar

[3] A. Gebhardt, Generative Fertigungsverfahren: additive manufacturing und 3D-Drucken für Prototyping - Tooling – Produktion. 4., new Edit. and ext. Ed., München, Carl HANSER, (2013).

DOI: 10.3139/9783446436527.fm

Google Scholar

[4] E. Klemp, Der Einfluss des Rapid Prototyping auf die Produktentwicklung. Mitteilung aus dem Institut für Maschinenwesen der Technischen Universität Clausthal, Clausthal, (2000).

DOI: 10.25368/2021.16

Google Scholar

[5] J. Gausemeier, R. Dumitrescu, T. Gaukstern, Chancen der Technologie MID erkennen und nutzen, in: Produktion von Leiterplatten und Systemen (PLUS) 2/2010, Leuze, Bad Saulgau, (2010).

Google Scholar

[6] T. Frick, PROMID - Herstellung funktionaler Schaltungsträger mittels Rapid Prototyping für MID-Anwendungen, final Report, involved research institutes: blz Bayerisches Laserzentrum GmbH; LSP Lehrstuhl für Polymerwerkstoffe; WW3 Lehrstuhl für Werkstoffwissenschaften (Glas und Keramik), Erlangen, (2010).

Google Scholar

[7] J. Franke (Eds. ), Räumliche elektronische Baugruppen (3D-MID) – Werkstoffe Hersteller, Montage und Anwendungen für spritzgegossene Schaltungsträger. Carl HANSER, München, (2013).

DOI: 10.3139/9783446437784.fm

Google Scholar

[8] M. Borges, Innovationsschub auf der productronica: LPKF Pressemittteilung. company publication, LPKF Laser und Electronic AG, Garbsen, (2013).

Google Scholar

[9] LPKF LASER & ELECTRONICS AG, Leiterbahnen aus der Sprühdose: LDS-Beschichtung von 3D-Schaltungstragern mit LPKF ProtoPaint LDS. company publication, Garbsen, on: http: /www. lpkf. de/_mediafiles/3022-broschuere-lpkf-protopaint-lds. pdf, at November 4th (2013).

DOI: 10.1016/s1364-5439(13)70144-8

Google Scholar

[10] LPKF LASER & ELECTRONICS AG, LDS-MID-Designregeln – Technische Informationen. Version 2. 0, at November 10th 2010, company publication, Garbsen, (2010).

Google Scholar