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Klett

Dr.-Ing.

Yves Klett

Wissenschaftlicher Mitarbeiter
Institut für Flugzeugbau

Contact

+49 711 685-62409
Email

Pfaffenwaldring 31
70569 Stuttgart
Deutschland

Subject

Beteiligt an Teilprojekten, inklusive Position:

Sandwichelemente mit kinematischer und bauphysikalischer Funktionalität

Publications

2020
1. Y. Klett, F. Muhs, P. Middendorf, and T. Tachi, “Comparison of Soft Curved Crease Surrogate Hinges,” 2020.
  - BibTeX
  BibTeX
  @inproceedings{klett_comparison_2020, annote = {(akzeptiert)}, author = {Klett, Yves and Muhs, Fabian and Middendorf, Peter and Tachi, Tomohiro}, booktitle = {{ASME} {Int}. {Design} {Engineering} {Technical} {Conf}. and {Computers} and {Information} in {Engineering} {Conf}.}, title = {Comparison of {Soft} {Curved} {Crease} {Surrogate} {Hinges}}, year = 2020 }
2019
1. N. Harder, Y. Klett, S. Park, P. Leistner, and P. Middendorf, “Bauphysikalische Untersuchung von Sandwichelementen,” Bauphysik, 2019.
  - BibTeX
  BibTeX
  @article{harder_bauphysikalische_2019, author = {Harder, Nadine and Klett, Yves and Park, Sumee and Leistner, Philip and Middendorf, Peter}, journal = {Bauphysik}, title = {Bauphysikalische {Untersuchung} von {Sandwichelementen}}, year = 2019 }
2. Y. Klett, P. Middendorf, F. Muhs, S. Weidner, W. Sobek, and W. Haase, “Exploration of compliant hinges in origami-based structures,” 2019.
  - BibTeX
  BibTeX
  @inproceedings{klett_exploration_2019, author = {Klett, Yves and Middendorf, Peter and Muhs, Fabian and Weidner, Stefanie and Sobek, Werner and Haase, Walter}, booktitle = {Form and {Force}, {IASS} {Symposium}}, title = {Exploration of compliant hinges in origami-based structures}, year = 2019 }
3. M. Oei, Y. Klett, N. Harder, D. Flemming, and O. Sawodny, “Modelling the Flow and Heat Transfer Characteristics of Perforated Foldcore Sandwich Composites for Application in Room Air Conditioning,” 2019.
  - BibTeX
  BibTeX
  @inproceedings{oei_modelling_2019, author = {Oei, Marius and Klett, Yves and Harder, Nadine and Flemming, Daniela and Sawodny, Oliver}, booktitle = {{IEEE} {Int}. {Conf}. on {Automation} {Science} and {Engineering} ({CASE})}, title = {Modelling the {Flow} and {Heat} {Transfer} {Characteristics} of {Perforated} {Foldcore} {Sandwich} {Composites} for {Application} in {Room} {Air} {Conditioning}}, year = 2019 }
2018
1. M. Grzeschik, Y. Klett, and P. Middendorf, “Reality check - mechanical potential of tessellation-based foldcore materials,” in 7th International Meeting on Origami in Science, Mathematics and Education (OSME), September 5-7, 2018, Oxford, UK, 2018, vol. 4, pp. 1273--1284.
  - BibTeX
  BibTeX
  @inproceedings{grzeschik_reality_2018, author = {Grzeschik, Marc and Klett, Yves and Middendorf, Peter}, booktitle = {7th {International} {Meeting} on {Origami} in {Science}, {Mathematics} and {Education} ({OSME}), {September} 5-7, 2018, {Oxford}, {UK}}, isbn = {978-1-911093-92-3}, pages = {1273--1284}, title = {Reality check - mechanical potential of tessellation-based foldcore materials}, volume = 4, year = 2018 }
2. Y. Klett, “PALEO: plastically annealed lamina emergent origami,” 2018, doi: 10.1115/DETC2018-85983.
  - BibTeX
  - Link
  BibTeX
  @inproceedings{klett_paleo:_2018, abstract = {Origami is usually folded from a flat sheet of material. Folding mostly works by introduction of plastic deformation into that sheet, resulting in a permanently altered region, viz., the crease. Lamina emergent mechanisms also start by definition from the flat state, but make use of compliant elements to provide mobility by elastic deformation. We introduce a combination of origami tessellations with LEM elements that are annealed in a (partially) collapsed state and retain this shape afterwards, while still offering the elastic deformation potential in the annealed shape. A number of such Plastically Annealed Lamina Emergent Origami structures or PALEOs have been successfully designed and tested.}, author = {Klett, Yves}, booktitle = {{ASME} 2018 {International} {Design} {Engineering} {Technical} {Conferences} and {Computers} and {Information} in {Engineering} {Conference}, {August} 26-29, {Quebec} {City}}, doi = {10.1115/DETC2018-85983}, isbn = {978-0-7918-5181-4}, note = {C01, IFB}, title = {{PALEO}: plastically annealed lamina emergent origami}, url = {https://asmedigitalcollection.asme.org/IDETC-CIE/proceedings/IDETC-CIE2018/51814/V05BT07A062/276140}, urldate = {2019-11-02}, year = 2018 }
  Link
  https://asmedigitalcollection.asme.org/IDETC-CIE/proceedings/IDETC-CIE2018/51814/V05BT07A062/276140
3. Y. Klett, “Kleine Falten, großer Unterschied: kostengünstige und leistungsfähige Lösungen für multifunktionalen Leichtbau,” 2018.
  - BibTeX
  BibTeX
  @inproceedings{klett_kleine_2018, author = {Klett, Yves}, booktitle = {2. {Kongress} innovation+: papier, textil \& folie, 31. {Januar} 2018, {Regensburg}}, title = {Kleine {Falten}, großer {Unterschied}: kostengünstige und leistungsfähige {Lösungen} für multifunktionalen {Leichtbau}}, year = 2018 }
4. Y. Klett, M. Grzeschik, and P. Middendorf, “Mechanical Potential of Tessellation-based Foldcore Materials,” 2018.
  - BibTeX
  BibTeX
  @inproceedings{klett_mechanical_2018, author = {Klett, Yves and Grzeschik, Marc and Middendorf, Peter}, booktitle = {{OSME7} {Volume} 4 - {The} proceedings from the seventh meeting of {Origami}, {Science}, {Mathematics} and {Education}}, title = {Mechanical {Potential} of {Tessellation}-based {Foldcore} {Materials}}, year = 2018 }
5. F. Muhs, Y. Klett, and P. Middendorf, “Automated numerical process chain for the design of folded sandwich cores,” in 7th International Meeting on Origami in Science, Mathematics and Education (OSME), September 5-7, 2018, Oxford, UK, 2018, vol. 4, pp. 1043--1058.
  - BibTeX
  BibTeX
  @inproceedings{muhs_automated_2018, author = {Muhs, Fabian and Klett, Yves and Middendorf, Peter}, booktitle = {7th {International} {Meeting} on {Origami} in {Science}, {Mathematics} and {Education} ({OSME}), {September} 5-7, 2018, {Oxford}, {UK}}, isbn = {978-1-911093-92-3}, pages = {1043--1058}, title = {Automated numerical process chain for the design of folded sandwich cores}, volume = 4, year = 2018 }
2017
1. B. Heidenreich, D. Koch, H. Kraft, and Y. Klett, “C/C–SiC sandwich structures manufactured via liquid silicon infiltration,” Journal of Materials Research, vol. 32, no. 17, Art. no. 17, 2017, doi: 10.1557/jmr.2017.208.
  - BibTeX
  - Link
  BibTeX
  @article{heidenreich_c/csic_2017, abstract = {In a new design approach, C/C–SiC sandwich structures have been realized via liquid silicon infiltration and in situ joining methods. In the first process step, the carbon fiber reinforced polymer preforms for the planar skin plates as well as for the core structures were manufactured via warm pressing and autoclave technique, using C fiber fabrics preimpregnated with phenolic resin. Thereby, two types of C/C–SiC core structures were used: foldcore and grid core. In the second process step, the sandwich components were pyrolyzed separately, leading to porous C/C preforms and subsequently joined to a C/C sandwich structure, using an adhesive. In the last process step, the C/C structure was infiltrated with molten Si, and the SiC matrix was built up by a chemical reaction of Si and C, leading to a permanently joined C/C–SiC sandwich structure. For mechanical characterization, sandwich specimens were manufactured and tested in 4 point bending.}, author = {Heidenreich, Bernhard and Koch, Dietmar and Kraft, Harald and Klett, Yves}, doi = {10.1557/jmr.2017.208}, journal = {Journal of Materials Research}, number = 17, pages = {3383--3393}, title = {C/{C}–{SiC} sandwich structures manufactured via liquid silicon infiltration}, url = {https://www.cambridge.org/core/journals/journal-of-materials-research/article/ccsic-sandwich-structures-manufactured-via-liquid-silicon-infiltration/DB3E2B4E88F14B5A277042D0119B6C4F}, urldate = {2019-11-02}, volume = 32, year = 2017 }
  Link
  https://www.cambridge.org/core/journals/journal-of-materials-research/article/ccsic-sandwich-structures-manufactured-via-liquid-silicon-infiltration/DB3E2B4E88F14B5A277042D0119B6C4F
2. Y. Klett, P. Middendorf, W. Sobek, W. Haase, and M. Heidingsfeld, “Potential of origami-based shell elements as next-generation envelope components,” in 2017 IEEE International Conference on Advanced Intelligent Mechatronics (AIM), July 3-7, 2017, Munich, 2017, pp. 916--920, doi: 10.1109/AIM.2017.8014137.
  - BibTeX
  BibTeX
  @inproceedings{klett_potential_2017, abstract = {Building envelopes manage several crucial functions, including structural, thermal, hygric and aesthetic functions. Classic fac¸ade concepts usually work with static elements like glass, metal or composite panels that primarily provide protection against the elements, and an additional layer of active systems that manage dynamic tasks like light protection or thermal regulation. Kinematic shell elements offer new ways to incorporate multiple dynamic functionalities into cladding elements, and thus can help to generate new active, efficient and aesthetic envelopes. We will introduce the concept of origami-inspired multifunctional shell elements and discuss potential applications.}, author = {Klett, Yves and Middendorf, Peter and Sobek, Werner and Haase, Walter and Heidingsfeld, Michael}, booktitle = {2017 {IEEE} {International} {Conference} on {Advanced} {Intelligent} {Mechatronics} ({AIM}), {July} 3-7, 2017, {Munich}}, doi = {10.1109/AIM.2017.8014137}, pages = {916--920}, title = {Potential of origami-based shell elements as next-generation envelope components}, year = 2017 }
3. Y. Klett, C. Zeger, and P. Middendorf, “Experimental characterization of pressure loss caused by flow through foldcore sandwich structures,” 2017, doi: 10.1115/DETC2017-67890.
  - BibTeX
  - Link
  BibTeX
  @inproceedings{klett_experimental_2017, abstract = {Folded structures based on different tessellation types have been investigated as alternatives to conventional sandwich core materials like honeycombs and foams. Besides the mechanical performance offered by such foldcores, they feature some unique properties that can be used to integrate additional functionalities. One of these is the possibility to generate large cross-section channels within the sandwich core that can be used for gas and fluid transport. In this study, we present an experimental setup to measure pressure loss within foldcore sandwich panels, and compare results for seven different foldcore configurations.}, author = {Klett, Yves and Zeger, Carla and Middendorf, Peter}, booktitle = {{ASME} 2017 {International} {Design} {Engineering} {Technical} {Conferences} and {Computers} and {Information} in {Engineering} {Conference}, {August} 6-9, {Cleveland}, {Ohio}, {USA}}, doi = {10.1115/DETC2017-67890}, isbn = {978-0-7918-5818-9}, title = {Experimental characterization of pressure loss caused by flow through foldcore sandwich structures}, url = {https://asmedigitalcollection.asme.org/IDETC-CIE/proceedings/IDETC-CIE2017/58189/V05BT08A051/259730}, urldate = {2019-11-02}, year = 2017 }
  Link
  https://asmedigitalcollection.asme.org/IDETC-CIE/proceedings/IDETC-CIE2017/58189/V05BT08A051/259730
4. Y. Klett, “Overview of mechanical properties of foldcore-based sandwich structures,” 2017.
  - BibTeX
  BibTeX
  @inproceedings{klett_overview_2017, author = {Klett, Yves}, booktitle = {2nd {International} {Workshop} on {Origami} {Engineering}, {November} 6-8, 2017, {Tianjin}, {China}}, title = {Overview of mechanical properties of foldcore-based sandwich structures}, year = 2017 }
5. Y. Klett, “Kleine Knicke, große Wirkung - Faltungsbasierte Sandwichkerne,” 2017.
  - BibTeX
  BibTeX
  @inproceedings{klett_kleine_2017, author = {Klett, Yves}, booktitle = {2. {Bremer} {Faserverbundtage}, 31. {August} - 1. {September} 2017, {Bremen}}, title = {Kleine {Knicke}, große {Wirkung} - {Faltungsbasierte} {Sandwichkerne}}, year = 2017 }

Akademische Ausbildung mit Abschluss

Luft- und Raumfahrttechnik (1996 – 2002), Hauptstudium mit Vertiefungsrichtungen Regelungstechnik sowie Flugzeugbau, Abschluss: Dipl.-Ing.

Wissenschaftliche Abschlüsse

Promotion zum Dr.-Ing.: Dissertation mit dem Thema „Auslegung multifunktionaler isometrischer Faltstrukturen für den technischen Einsatz“, Universität Stuttgart, 2013, Prof. Peter Middendorf

Beruflicher Werdegang nach Studienabschluss

2012 – heute, Gruppenleiter Sandwichtechnologie

2012 – 2015, Leiter des Teilprojekts A3 innerhalb der Forschergruppe FOR 981 „Hybride Intelligente Konstruktionselemente (HIKE)“

2002 – heute, Wissenschaftlicher Mitarbeiter am Institut für Flugzeugbau, Universität Stuttgart

Content

Speaker

Prof. Dr.-Ing. Dr.-Ing. E. h. Dr. h.c. Werner Sobek

Speaker

Phone: +49 711 685-66227/-63599

Management

Dr.-Ing. Walter Haase

Geschäftsführer

Phone: +49 711 685-66223 oder 66227

Roberta Toscano, M.A.

Finanzverwaltung und Öffentlichkeitsarbeit

Phone: +49 711 685-66548

E-Mail

Manuela Brüggeboes

Sekretariat der Geschäftsführung

Phone: +49 711 685-66223 oder 66227

E-Mail

Principal Investigators

Dr.-Ing. Stefan Albrecht

Teilprojektleiter

Phone: +49 711 970-3170

E-Mail

Prof. Dr.-Ing. Thomas Bauernhansl

Teilprojektleiter

Phone: +49 711 970-1101

E-Mail

Prof. Dr.-Ing. Bernd Bertsche

Teilprojektleiter

Phone: +49 711 685-66165/-66319

E-Mail

Prof. Dr.-Ing. Hansgeorg Binz

Teilprojektleiter

Phone: +49 711 685-66055/-66056

E-Mail

Prof. Dr.-Ing. habil. Manfred Bischoff

Teilprojektleiter

Phone: +49 711 685-66123

E-Mail

Prof. Dr. rer. nat. habil. Michael R. Buchmeiser

Teilprojektleiter

Phone: +49 711 685-64074

E-Mail

Prof. Dr.-Ing. habil. Prof. E. h. Peter Eberhard

Teilprojektleiter

Phone: +49 711 685-66389

E-Mail

Prof. Dr.rer.nat. Dr.techn. h.c. Dr.-Ing. E.h. Thomas Ertl

Teilprojektleiter

Phone: +49 711 685-88331

E-Mail

Dr.-Ing. Tobias Haist

Teilprojektleiter

Phone: +49 711 685-66069

E-Mail

Prof. Dr.-Ing. Philip Leistner

Teilprojektleiter

Phone: +49 711 970-3346

E-Mail

Prof. Dr.-Ing. Mona Mahall

Teilprojektleiterin

Phone: +49 40 42 827 5091

E-Mail

Prof. Dipl AA (Hons) Achim Menges

Teilprojektleiter

Phone: +49 711 685-81919/-81920

E-Mail

Prof. Dr.-Ing. Peter Middendorf

Teilprojektleiter

Phone: +49 711 685-62402/-62411

E-Mail

Dr.-Ing. Sumee Park

Teilprojektleiterin

Phone: +49 8024 643-237

E-Mail

Dr. rer. nat. Guido Reina

Teilprojektleiter

Phone: +49 711 685-88627/-88601

E-Mail

Prof. Dr.-Ing. habil. Dr. h.c. Oliver Sawodny

Stellvertretender Sprecher

Phone: +49 711 685-66302/-66303

E-Mail

Prof. Dr.-Ing. Asli Serbest

Teilprojektleiterin

Phone: +49 421 9595 1340

E-Mail

Prof. Dr.-Ing. Dr.-Ing. E. h. Dr. h.c. Werner Sobek

Speaker

Phone: +49 711 685-66227/-63599

Prof. Dr.-Ing. Cristina Tarín Sauer

Teilprojektleiterin

Phone: +49 711 685-66299/-66302

E-Mail

Research Assistants

Michael Becher, M.Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-88618

E-Mail

Timon Burghardt, M.Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-60315

E-Mail

Dr. Ing. Michael Böhm

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-66291

E-Mail

Dr. Yavuz Caydamli

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-64049

E-Mail

Daniela Flemming, M. Sc.

Wissenschaftliche Mitarbeiterin

Phone: +49 711 685-66598

E-Mail

Benjamin Fröhlich, M.Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-66281

E-Mail

Jan Gade, M.Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-66123

E-Mail

Florian Geiger, M. Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-66573

E-Mail

Andreas Gienger, M. Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-65934

E-Mail

Flavio Guerra, M. Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-66071

E-Mail

Dipl.-Ing. Nadine Harder

Wissenschaftliche Mitarbeiterin

Phone: +49 711 685-66301

E-Mail

Dipl.-Ing. Christian Kelleter

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-63796

E-Mail

Dr.-Ing. Yves Klett

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-62409

E-Mail

Sophia Leistner, M. Sc.

Wissenschaftliche Mitarbeiterin

Phone: +49 711 685-66225

E-Mail

Mathias Maierhofer, M.Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685 82777

E-Mail

Dipl.-Ing. Raphael Neuhaus

Wissenschaftlicher Mitarbeiter

Phone: +49 711 970-3627

E-Mail

Markus Nitzlader, M. Eng.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-63570

E-Mail

Marius Oei, M. Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-66279

E-Mail

Andreas Ostertag, M. Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-69961

E-Mail

Friederike Schlegl , M. Sc.

Wissenschaftliche Mitarbeiterin

Phone: +49 711 970-3171

E-Mail

Simon Steffen, M.Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-60902

E-Mail

Marie Ulber, Ph.D.

Wissenschaftliche Mitarbeiterin

Phone: +49 40 4282 75397

E-Mail

Michael Voigt, M.Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-65835

E-Mail

Julia Wagner, M. Sc.

Wissenschaftliche Mitarbeiterin

Phone: +49 711 685-69904

E-Mail

Nadine Walker, M. Sc.

Wissenschaftliche Mitarbeiterin

Phone: +49 711 685-66396

E-Mail

Alexander Warsewa, M. Sc.

Wissenschaftlicher Mitarbeiter

Phone: +49 711 685-60504

E-Mail

Dipl.-Ing. Arch. Stefanie Weidner

Wissenschaftliche Mitarbeiterin

Phone: +49 711 685-63705

E-Mail

Public relation

Dipl.-Ing. Arch. Kaja Schelker

Öffentlichkeitsarbeit

Phone: +49 711 685 61700

E-Mail

Roberta Toscano, M.A.

Finanzverwaltung und Öffentlichkeitsarbeit

Phone: +49 711 685-66548

E-Mail

Yves Klett

Contact

Subject

2020

BibTeX

2019

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2018

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Link

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2017

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Content

Speaker

Management

Principal Investigators

Research Assistants

Public relation