[{"volume":64,"author":[{"id":"4668","full_name":"Schramm, Britta","last_name":"Schramm","first_name":"Britta"},{"first_name":"Deborah","last_name":"Weiß","id":"45673","full_name":"Weiß, Deborah"}],"date_updated":"2023-04-27T10:20:38Z","doi":"10.1515/mt-2022-0191","publication_identifier":{"issn":["0025-5300","2195-8572"]},"publication_status":"published","intvolume":" 64","page":"1437-1449","citation":{"ieee":"B. Schramm and D. Weiß, “Fracture mechanical evaluation of the material HCT590X,” Materials Testing, vol. 64, no. 10, pp. 1437–1449, 2022, doi: 10.1515/mt-2022-0191.","chicago":"Schramm, Britta, and Deborah Weiß. “Fracture Mechanical Evaluation of the Material HCT590X.” Materials Testing 64, no. 10 (2022): 1437–49. https://doi.org/10.1515/mt-2022-0191.","ama":"Schramm B, Weiß D. Fracture mechanical evaluation of the material HCT590X. Materials Testing. 2022;64(10):1437-1449. doi:10.1515/mt-2022-0191","apa":"Schramm, B., & Weiß, D. (2022). Fracture mechanical evaluation of the material HCT590X. Materials Testing, 64(10), 1437–1449. https://doi.org/10.1515/mt-2022-0191","mla":"Schramm, Britta, and Deborah Weiß. “Fracture Mechanical Evaluation of the Material HCT590X.” Materials Testing, vol. 64, no. 10, Walter de Gruyter GmbH, 2022, pp. 1437–49, doi:10.1515/mt-2022-0191.","bibtex":"@article{Schramm_Weiß_2022, title={Fracture mechanical evaluation of the material HCT590X}, volume={64}, DOI={10.1515/mt-2022-0191}, number={10}, journal={Materials Testing}, publisher={Walter de Gruyter GmbH}, author={Schramm, Britta and Weiß, Deborah}, year={2022}, pages={1437–1449} }","short":"B. Schramm, D. Weiß, Materials Testing 64 (2022) 1437–1449."},"department":[{"_id":"143"},{"_id":"630"}],"user_id":"45673","_id":"34403","project":[{"grant_number":"418701707","name":"TRR 285: TRR 285","_id":"130"},{"_id":"132","name":"TRR 285 - B: TRR 285 - Project Area B"},{"_id":"143","name":"TRR 285 – B04: TRR 285 - Subproject B04"}],"type":"journal_article","status":"public","date_created":"2022-12-13T15:19:58Z","publisher":"Walter de Gruyter GmbH","title":"Fracture mechanical evaluation of the material HCT590X","issue":"10","quality_controlled":"1","year":"2022","language":[{"iso":"eng"}],"keyword":["Mechanical Engineering","Mechanics of Materials","General Materials Science"],"publication":"Materials Testing","abstract":[{"lang":"eng","text":"For a reliable, strength-compliant and fracture-resistant design of components and technical structures and for the prevention of damage cases, both the criteria of strength calculation and fracture mechanics are essential. In contrast to strength calculation the fracture mechanics assumes the existence of cracks which might further propagate due to the operational load. First, the present paper illustrates the general procedure of a fracture mechanical evaluation of fatigue cracks in order to assess practical damage cases. Fracture mechanical fundamentals which are essential for the calculation of the stress intensity factors K\r\n I and the experimental determination of fracture mechanical material parameters (e.g. threshold ΔK\r\n I,th against fatigue crack growth, crack growth rate curve) are explained in detail. The subsequent fracture mechanical evaluation on the basis of the local stress situation at the crack tip and the fracture mechanical material data is executed for different materials and selected crack problems. Hereby, the main focus is on the material HCT590X as it is the essential material being investigated by TRR285."}]},{"page":"493-500","intvolume":" 63","citation":{"apa":"Böhnke, M., Kappe, F., Bobbert, M., & Meschut, G. (2021). Influence of various procedures for the determination of flow curves on the predictive accuracy of numerical simulations for mechanical joining processes. Materials Testing, 63(6), 493–500. https://doi.org/10.1515/mt-2020-0082","mla":"Böhnke, Max, et al. “Influence of Various Procedures for the Determination of Flow Curves on the Predictive Accuracy of Numerical Simulations for Mechanical Joining Processes.” Materials Testing, vol. 63, no. 6, De Gruyter, 2021, pp. 493–500, doi:10.1515/mt-2020-0082.","short":"M. Böhnke, F. Kappe, M. Bobbert, G. Meschut, Materials Testing 63 (2021) 493–500.","bibtex":"@article{Böhnke_Kappe_Bobbert_Meschut_2021, title={Influence of various procedures for the determination of flow curves on the predictive accuracy of numerical simulations for mechanical joining processes}, volume={63}, DOI={10.1515/mt-2020-0082}, number={6}, journal={Materials Testing}, publisher={De Gruyter}, author={Böhnke, Max and Kappe, Fabian and Bobbert, Mathias and Meschut, Gerson}, year={2021}, pages={493–500} }","ama":"Böhnke M, Kappe F, Bobbert M, Meschut G. Influence of various procedures for the determination of flow curves on the predictive accuracy of numerical simulations for mechanical joining processes. Materials Testing. 2021;63(6):493-500. doi:10.1515/mt-2020-0082","ieee":"M. Böhnke, F. Kappe, M. Bobbert, and G. Meschut, “Influence of various procedures for the determination of flow curves on the predictive accuracy of numerical simulations for mechanical joining processes,” Materials Testing, vol. 63, no. 6, pp. 493–500, 2021, doi: 10.1515/mt-2020-0082.","chicago":"Böhnke, Max, Fabian Kappe, Mathias Bobbert, and Gerson Meschut. “Influence of Various Procedures for the Determination of Flow Curves on the Predictive Accuracy of Numerical Simulations for Mechanical Joining Processes.” Materials Testing 63, no. 6 (2021): 493–500. https://doi.org/10.1515/mt-2020-0082."},"publication_identifier":{"issn":["2195-8572","0025-5300"]},"publication_status":"published","doi":"10.1515/mt-2020-0082","volume":63,"author":[{"first_name":"Max","last_name":"Böhnke","full_name":"Böhnke, Max","id":"45779"},{"full_name":"Kappe, Fabian","id":"66459","last_name":"Kappe","first_name":"Fabian"},{"first_name":"Mathias","full_name":"Bobbert, Mathias","id":"7850","last_name":"Bobbert"},{"full_name":"Meschut, Gerson","id":"32056","orcid":"0000-0002-2763-1246","last_name":"Meschut","first_name":"Gerson"}],"date_updated":"2023-04-27T08:53:22Z","status":"public","type":"journal_article","department":[{"_id":"157"},{"_id":"630"}],"user_id":"66459","_id":"22798","project":[{"_id":"130","name":"TRR 285: TRR 285","grant_number":"418701707"},{"_id":"131","name":"TRR 285 - A: TRR 285 - Project Area A"},{"_id":"133","name":"TRR 285 - C: TRR 285 - Project Area C"},{"name":"TRR 285 – A01: TRR 285 - Subproject A01","_id":"135"},{"name":"TRR 285 – C02: TRR 285 - Subproject C02","_id":"146"}],"year":"2021","issue":"6","quality_controlled":"1","title":"Influence of various procedures for the determination of flow curves on the predictive accuracy of numerical simulations for mechanical joining processes","date_created":"2021-07-22T11:27:37Z","publisher":"De Gruyter","abstract":[{"text":"The predictive quality of numerical simulations for mechanical joining processes depends on the implemented material model, especially regarding the plasticity of the joining parts. Therefore, experimental material characterization processes are conducted to determine the material properties of sheet metal and generate flow curves. In this regard, there are a number of procedures which are accompanied by varying experimental efforts. This paper presents various methods of determining flow curves for HCT590X as well as EN AW-6014, including varying specimen geometries and diverse hardening laws for extrapolation procedures. The flow curves thus generated are compared considering the variety of plastic strains occurring in mechanical joining processes. The material data generated are implemented in simulation models for the joining technologies, clinching and self-piercing riveting. The influence of the varied methods on the predictive accuracy of the simulation model is analysed. The evaluation of the differing flow curves is achieved by comparing the geometric formation of the joints and the required joining forces of the processes with experimentally investigated joints.","lang":"eng"}],"publication":"Materials Testing","language":[{"iso":"eng"}]},{"publication_status":"published","publication_identifier":{"issn":["0025-5300","2195-8572"]},"quality_controlled":"1","year":"2020","citation":{"apa":"Heyser, P., Sartisson, V., Meschut, G., Droß, M., & Dröder, K. (2020). Increased load bearing capacity of mechanically joined FRP/metal joints using a pin structured auxiliary joining element. Materials Testing, 55–60. https://doi.org/10.3139/120.111453","bibtex":"@article{Heyser_Sartisson_Meschut_Droß_Dröder_2020, title={Increased load bearing capacity of mechanically joined FRP/metal joints using a pin structured auxiliary joining element}, DOI={10.3139/120.111453}, journal={Materials Testing}, author={Heyser, Per and Sartisson, Vadim and Meschut, Gerson and Droß, Marcel and Dröder, Klaus}, year={2020}, pages={55–60} }","mla":"Heyser, Per, et al. “Increased Load Bearing Capacity of Mechanically Joined FRP/Metal Joints Using a Pin Structured Auxiliary Joining Element.” Materials Testing, 2020, pp. 55–60, doi:10.3139/120.111453.","short":"P. Heyser, V. Sartisson, G. Meschut, M. Droß, K. Dröder, Materials Testing (2020) 55–60.","ama":"Heyser P, Sartisson V, Meschut G, Droß M, Dröder K. Increased load bearing capacity of mechanically joined FRP/metal joints using a pin structured auxiliary joining element. Materials Testing. 2020:55-60. doi:10.3139/120.111453","chicago":"Heyser, Per, Vadim Sartisson, Gerson Meschut, Marcel Droß, and Klaus Dröder. “Increased Load Bearing Capacity of Mechanically Joined FRP/Metal Joints Using a Pin Structured Auxiliary Joining Element.” Materials Testing, 2020, 55–60. https://doi.org/10.3139/120.111453.","ieee":"P. Heyser, V. Sartisson, G. Meschut, M. Droß, and K. Dröder, “Increased load bearing capacity of mechanically joined FRP/metal joints using a pin structured auxiliary joining element,” Materials Testing, pp. 55–60, 2020."},"page":"55-60","date_updated":"2022-01-06T06:54:24Z","date_created":"2020-10-30T14:30:10Z","author":[{"id":"40450","full_name":"Heyser, Per","last_name":"Heyser","first_name":"Per"},{"first_name":"Vadim","full_name":"Sartisson, Vadim","last_name":"Sartisson"},{"first_name":"Gerson","id":"32056","full_name":"Meschut, Gerson","orcid":"0000-0002-2763-1246","last_name":"Meschut"},{"first_name":"Marcel","last_name":"Droß","full_name":"Droß, Marcel"},{"first_name":"Klaus","full_name":"Dröder, Klaus","last_name":"Dröder"}],"title":"Increased load bearing capacity of mechanically joined FRP/metal joints using a pin structured auxiliary joining element","doi":"10.3139/120.111453","type":"journal_article","publication":"Materials Testing","status":"public","_id":"20235","user_id":"40450","department":[{"_id":"157"}],"language":[{"iso":"eng"}]},{"publication_identifier":{"issn":["2195-8572","0025-5300"]},"publication_status":"published","intvolume":" 62","page":"877-882","citation":{"short":"M. Gollnick, P. Giese, D. Hein, G. Meschut, D. Herfert, Materials Testing 62 (2020) 877–882.","bibtex":"@article{Gollnick_Giese_Hein_Meschut_Herfert_2020, title={Early stage crack detection in mechanically joined steel/aluminum joints by condition monitoring}, volume={62}, DOI={10.3139/120.111558}, number={9}, journal={Materials Testing}, publisher={Walter de Gruyter GmbH}, author={Gollnick, Maik and Giese, Patrick and Hein, David and Meschut, Gerson and Herfert, Daniel}, year={2020}, pages={877–882} }","mla":"Gollnick, Maik, et al. “Early Stage Crack Detection in Mechanically Joined Steel/Aluminum Joints by Condition Monitoring.” Materials Testing, vol. 62, no. 9, Walter de Gruyter GmbH, 2020, pp. 877–82, doi:10.3139/120.111558.","apa":"Gollnick, M., Giese, P., Hein, D., Meschut, G., & Herfert, D. (2020). Early stage crack detection in mechanically joined steel/aluminum joints by condition monitoring. Materials Testing, 62(9), 877–882. https://doi.org/10.3139/120.111558","ama":"Gollnick M, Giese P, Hein D, Meschut G, Herfert D. Early stage crack detection in mechanically joined steel/aluminum joints by condition monitoring. Materials Testing. 2020;62(9):877-882. doi:10.3139/120.111558","chicago":"Gollnick, Maik, Patrick Giese, David Hein, Gerson Meschut, and Daniel Herfert. “Early Stage Crack Detection in Mechanically Joined Steel/Aluminum Joints by Condition Monitoring.” Materials Testing 62, no. 9 (2020): 877–82. https://doi.org/10.3139/120.111558.","ieee":"M. Gollnick, P. Giese, D. Hein, G. Meschut, and D. Herfert, “Early stage crack detection in mechanically joined steel/aluminum joints by condition monitoring,” Materials Testing, vol. 62, no. 9, pp. 877–882, 2020, doi: 10.3139/120.111558."},"date_updated":"2023-03-29T08:49:23Z","volume":62,"author":[{"full_name":"Gollnick, Maik","last_name":"Gollnick","first_name":"Maik"},{"first_name":"Patrick","full_name":"Giese, Patrick","last_name":"Giese"},{"first_name":"David","last_name":"Hein","full_name":"Hein, David"},{"full_name":"Meschut, Gerson","last_name":"Meschut","first_name":"Gerson"},{"first_name":"Daniel","last_name":"Herfert","full_name":"Herfert, Daniel"}],"doi":"10.3139/120.111558","type":"journal_article","status":"public","_id":"43162","department":[{"_id":"157"}],"user_id":"53912","issue":"9","year":"2020","publisher":"Walter de Gruyter GmbH","date_created":"2023-03-29T08:48:19Z","title":"Early stage crack detection in mechanically joined steel/aluminum joints by condition monitoring","publication":"Materials Testing","abstract":[{"lang":"eng","text":"Monitoring systems for machines, plants, materials and equipment are increasingly used in production processes. These online condition monitoring systems can detect damage or excessive loads at an early stage and can drastically reduce or prevent long downtimes of plants and machines as well as high repair and maintenance costs. This paper depicts a method for online crack detection with pattern recognition methods for specimens joined by self-pierce riveting under cyclic load in fatigue tests (laboratory application). A software specially conceived for this application was developed. This software, AnrissMF, uses active acoustic testing with a structure-borne sensor to detect cracks in the joints at a very early stage. It is shown in this paper that this software can detect cracks much earlier than classical failure criteria for joints (i. e. before any drop in stiffness or frequency is observed). Furthermore, the successful application of software AnrissMF for online crack detection during the fatigue strength test is presented."}],"keyword":["Mechanical Engineering","Mechanics of Materials","General Materials Science"],"language":[{"iso":"eng"}]},{"language":[{"iso":"eng"}],"user_id":"43720","department":[{"_id":"158"},{"_id":"321"}],"_id":"23906","status":"public","abstract":[{"lang":"eng","text":"Abstract\r\n A device and the basic technology has been developed for tensile testing pipe sections samples (tensile testing PSS) for quantitative estimating ultimate tensile and yield stresses in ring samples (PSS samples) cut from pipes. This tensile testing device provides the opportunity for compensating frictional forces during the tensile test, and using exchangeable bearings, the device can be adapted to a wide assortment of pipes. Research has been carried out regarding the shape and size of a stress concentrator introduced into the sample. Relationships have been derived between the shape of the tensile loading curves and the characteristic forces for different types of stress concentrators. It is proposed to use PSS with stress concentrators to prevent plastic deformation in one of the supporting sections (this also allows to correlate the applied forces to one section). The concentrator should be introduced into the tube wall of the sample as a drilled hole. This method is comparatively simple with respect to established testing methods."}],"type":"journal_article","publication":"Materials Testing","doi":"10.3139/120.110759","title":"Testing of pipe sections","author":[{"last_name":"Andreiev","id":"50215","full_name":"Andreiev, Anatolii","first_name":"Anatolii"},{"first_name":"Oleksandr","full_name":"Golovko, Oleksandr","last_name":"Golovko"},{"first_name":"Iaroslav","full_name":"Frolov, Iaroslav","last_name":"Frolov"},{"last_name":"Nürnberger","full_name":"Nürnberger, Florian","first_name":"Florian"},{"full_name":"Wolf, Lars Oliver","last_name":"Wolf","first_name":"Lars Oliver"},{"first_name":"Mirko","last_name":"Schaper","full_name":"Schaper, Mirko","id":"43720"},{"last_name":"Grydin","id":"43822","full_name":"Grydin, Olexandr","first_name":"Olexandr"}],"date_created":"2021-09-08T07:31:22Z","date_updated":"2023-06-01T14:23:49Z","citation":{"ama":"Andreiev A, Golovko O, Frolov I, et al. Testing of pipe sections. Materials Testing. Published online 2015:643-648. doi:10.3139/120.110759","ieee":"A. Andreiev et al., “Testing of pipe sections,” Materials Testing, pp. 643–648, 2015, doi: 10.3139/120.110759.","chicago":"Andreiev, Anatolii, Oleksandr Golovko, Iaroslav Frolov, Florian Nürnberger, Lars Oliver Wolf, Mirko Schaper, and Olexandr Grydin. “Testing of Pipe Sections.” Materials Testing, 2015, 643–48. https://doi.org/10.3139/120.110759.","apa":"Andreiev, A., Golovko, O., Frolov, I., Nürnberger, F., Wolf, L. O., Schaper, M., & Grydin, O. (2015). Testing of pipe sections. Materials Testing, 643–648. https://doi.org/10.3139/120.110759","short":"A. Andreiev, O. Golovko, I. Frolov, F. Nürnberger, L.O. Wolf, M. Schaper, O. Grydin, Materials Testing (2015) 643–648.","mla":"Andreiev, Anatolii, et al. “Testing of Pipe Sections.” Materials Testing, 2015, pp. 643–48, doi:10.3139/120.110759.","bibtex":"@article{Andreiev_Golovko_Frolov_Nürnberger_Wolf_Schaper_Grydin_2015, title={Testing of pipe sections}, DOI={10.3139/120.110759}, journal={Materials Testing}, author={Andreiev, Anatolii and Golovko, Oleksandr and Frolov, Iaroslav and Nürnberger, Florian and Wolf, Lars Oliver and Schaper, Mirko and Grydin, Olexandr}, year={2015}, pages={643–648} }"},"page":"643-648","year":"2015","publication_status":"published","publication_identifier":{"issn":["2195-8572","0025-5300"]},"quality_controlled":"1"},{"publication":"Materials Testing","type":"journal_article","status":"public","department":[{"_id":"9"},{"_id":"321"},{"_id":"149"}],"user_id":"72008","_id":"16016","language":[{"iso":"ger"}],"publication_identifier":{"issn":["0025-5300","2195-8572"]},"publication_status":"published","page":"537-543","citation":{"ieee":"A. Riemer, S. Leuders, H. A. Richard, and T. Tröster, “Verhalten von lasergeschmolzenen Bauteilen aus der Titan-Aluminium-Legierung TiAl6V4 unter zyklischer Beanspruchung∗,” Materials Testing, pp. 537–543, 2013.","chicago":"Riemer, Andre, S. Leuders, Hans A. Richard, and Thomas Tröster. “Verhalten von lasergeschmolzenen Bauteilen aus der Titan-Aluminium-Legierung TiAl6V4 unter zyklischer Beanspruchung∗.” Materials Testing, 2013, 537–43. https://doi.org/10.3139/120.110468.","ama":"Riemer A, Leuders S, Richard HA, Tröster T. Verhalten von lasergeschmolzenen Bauteilen aus der Titan-Aluminium-Legierung TiAl6V4 unter zyklischer Beanspruchung∗. Materials Testing. 2013:537-543. doi:10.3139/120.110468","bibtex":"@article{Riemer_Leuders_Richard_Tröster_2013, title={Verhalten von lasergeschmolzenen Bauteilen aus der Titan-Aluminium-Legierung TiAl6V4 unter zyklischer Beanspruchung∗}, DOI={10.3139/120.110468}, journal={Materials Testing}, author={Riemer, Andre and Leuders, S. and Richard, Hans A. and Tröster, Thomas}, year={2013}, pages={537–543} }","short":"A. Riemer, S. Leuders, H.A. Richard, T. Tröster, Materials Testing (2013) 537–543.","mla":"Riemer, Andre, et al. “Verhalten von lasergeschmolzenen Bauteilen aus der Titan-Aluminium-Legierung TiAl6V4 unter zyklischer Beanspruchung∗.” Materials Testing, 2013, pp. 537–43, doi:10.3139/120.110468.","apa":"Riemer, A., Leuders, S., Richard, H. A., & Tröster, T. (2013). Verhalten von lasergeschmolzenen Bauteilen aus der Titan-Aluminium-Legierung TiAl6V4 unter zyklischer Beanspruchung∗. Materials Testing, 537–543. https://doi.org/10.3139/120.110468"},"year":"2013","date_created":"2020-02-24T12:57:04Z","author":[{"last_name":"Riemer","full_name":"Riemer, Andre","first_name":"Andre"},{"full_name":"Leuders, S.","last_name":"Leuders","first_name":"S."},{"first_name":"Hans A.","full_name":"Richard, Hans A.","last_name":"Richard"},{"last_name":"Tröster","full_name":"Tröster, Thomas","id":"553","first_name":"Thomas"}],"date_updated":"2022-01-06T06:52:42Z","doi":"10.3139/120.110468","title":"Verhalten von lasergeschmolzenen Bauteilen aus der Titan-Aluminium-Legierung TiAl6V4 unter zyklischer Beanspruchung∗"},{"author":[{"full_name":"Böke, Johannes","last_name":"Böke","first_name":"Johannes"},{"last_name":"Erhardt","full_name":"Erhardt, Rüdiger","first_name":"Rüdiger"},{"first_name":"Wilfried","full_name":"Rostek, Wilfried","last_name":"Rostek"},{"first_name":"Thomas","id":"553","full_name":"Tröster, Thomas","last_name":"Tröster"}],"date_created":"2020-02-21T13:22:34Z","date_updated":"2022-01-06T06:52:41Z","doi":"10.3139/120.110002","title":"Einsatz von Simulationswerkzeugen in der Entwicklungskette von ultrahochfesten warmgeformten Strukturkomponenten im Fahrzeugleichtbau*","publication_identifier":{"issn":["0025-5300","2195-8572"]},"publication_status":"published","page":"22-27","citation":{"mla":"Böke, Johannes, et al. “Einsatz von Simulationswerkzeugen in der Entwicklungskette von ultrahochfesten warmgeformten Strukturkomponenten im Fahrzeugleichtbau*.” Materials Testing, 2009, pp. 22–27, doi:10.3139/120.110002.","short":"J. Böke, R. Erhardt, W. Rostek, T. Tröster, Materials Testing (2009) 22–27.","bibtex":"@article{Böke_Erhardt_Rostek_Tröster_2009, title={Einsatz von Simulationswerkzeugen in der Entwicklungskette von ultrahochfesten warmgeformten Strukturkomponenten im Fahrzeugleichtbau*}, DOI={10.3139/120.110002}, journal={Materials Testing}, author={Böke, Johannes and Erhardt, Rüdiger and Rostek, Wilfried and Tröster, Thomas}, year={2009}, pages={22–27} }","apa":"Böke, J., Erhardt, R., Rostek, W., & Tröster, T. (2009). Einsatz von Simulationswerkzeugen in der Entwicklungskette von ultrahochfesten warmgeformten Strukturkomponenten im Fahrzeugleichtbau*. Materials Testing, 22–27. https://doi.org/10.3139/120.110002","ieee":"J. Böke, R. Erhardt, W. Rostek, and T. Tröster, “Einsatz von Simulationswerkzeugen in der Entwicklungskette von ultrahochfesten warmgeformten Strukturkomponenten im Fahrzeugleichtbau*,” Materials Testing, pp. 22–27, 2009.","chicago":"Böke, Johannes, Rüdiger Erhardt, Wilfried Rostek, and Thomas Tröster. “Einsatz von Simulationswerkzeugen in der Entwicklungskette von ultrahochfesten warmgeformten Strukturkomponenten im Fahrzeugleichtbau*.” Materials Testing, 2009, 22–27. https://doi.org/10.3139/120.110002.","ama":"Böke J, Erhardt R, Rostek W, Tröster T. Einsatz von Simulationswerkzeugen in der Entwicklungskette von ultrahochfesten warmgeformten Strukturkomponenten im Fahrzeugleichtbau*. Materials Testing. 2009:22-27. doi:10.3139/120.110002"},"year":"2009","department":[{"_id":"9"},{"_id":"321"},{"_id":"149"}],"user_id":"72008","_id":"15953","language":[{"iso":"ger"}],"publication":"Materials Testing","type":"journal_article","status":"public"}]