Próby potrąceniowe z użyciem manekinów pieszego. Manekin pieszego PRIMUS – konstrukcja i unikalne cechy

Daniel  Wdowicz

Titles

Abstract

W artykule pokrótce przedstawiono modele manekinów zderzeniowych pieszych, dzieląc je na manekiny stosowane typowo na potrzeby projektowania pojazdów oraz stosowane w badaniach rekonstrukcyjnych wypadków drogowych. Przedstawiono wybrane badania z dziedziny rekonstrukcji wypadków drogowych, w których wykorzystywane były manekiny pieszych. W drugiej części artykułu przedstawiono konstrukcję manekina PRIMUS – produktu od niedawna dostępnego na rynku. Opisano budowę manekina i podsumowanie badań weryfikujących jego odpowiedź dynamiczną w warunkach potrącenia oraz wymieniono potencjalne jego zastosowania, takie jak rekonstrukcje wypadków i badania eksperymentalne na potrzeby przemysłu.

The article presents various models of pedestrian crash test dummies, grouping them by their applicability: vehicle manufacture or road accident reconstruction. Selected experiments in the latter area using dummies of pedestrians are presented. The second part of the article is devoted to a description of a PRIMUS dummy – a relatively new product on the market. The structure of the dummy is presented, and studies verifying the dynamic response of the dummy in a collision with pedestrian are summarized. The application of the dummy in road accident reconstruction and R&D experiments are presented.

Keywords

passengers, Testy zderzeniowe, biomechanika, manekiny, PRIMUS, piesi, pasażerowie

Crash tests, biomechanics, crash test dummies, PRIMUS, pedestrians, passengers

References

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[5] Foster, C. D. (2022). Report on Generic Hull Live-Fire Test with PRIMUS Dummy. Pobrano z: https://www.crashtest-service.com/download-file?file_id=2128&file_code=42de3e4d85 (dostęp 15 maja 2022 r.).

[6] Fredriksson, R., Håland, Y., Yang, J. (2001). Evaluation of a new pedestrian head injury protection system with a sensor in the bumper and lifting of the bonnet’s rear part. Proceedings of the 17th International Technical Conference on the Enhanced Safety of Vehicles.

[7] Hartwig, S., Knape, M., Kunze, A., Weyde, M. (2017). Interdisciplinary further development of an optimised anthropomorphic pedestrian surrogate for full-scale crash tests. Proceedings 26th EVU-Congress, Haarlem, Netherlands.

[8] Kasanický, G., Kohut, P. (2009). New Partial Overlap Pedestrian Impact Tests. Proceedings 18th EVU Congress, Hinckley, UK.

[9] Kortmann, A. (2019). The New Biofidelic Dummy In Different Scenarios Of Accidents Involving Pas-senger Cars And Pedestrians. Collision Magazine, 13 (2).

[10] Kortmann, A. (2020). Comparison of occupant load in a frontal collision with different degrees of belt usage. 9. Sachverständigenseminar.

[11] Moser, A., Steffan, H., Kasanický, G. (1999). The pedestrian model in PC-Crash – The introduction of a multi body system and its validation. SAE Technical Papers, 794–802. DOI: 10.4271/1999-01-0445.

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[13] Moser, A., Steffan, H., Strzeletz, R. (2009). Movement of the Human Body versus Dummy after the Collision. Proceedings 18th EVU Congress, Hinckley, UK.

[14] Notsu, M., Nishimoto, T., Konosu, A., Ishikawa, H. (2005). J-MLIT Research onto a Pedestrian Lower Extremity Protection-Evaluation Tests for Pedestrian Legform Impactors. Proceedings: International Technical Conference on the Enhanced Safety of Vehicles, Washington.

[15] Schäuble, A. (2019). Crash test dummies – how realistic are currently used dummies? Master Thesis. TU Wien.

[16] Schäuble, A., Hartwig, S., Weyde, M. (2021). Der Biofidel-Dummy als Fahrradfahrer-Surrogat: Vorläufige Ergebnisse zur Korrelation zwischen Dummybeschädigungen und Verletzungen von Radfahrern. Verkehrsunfall und Fahrzeugtechnik, 12.

[17] UN ECE. (2018). Regulation no. 127/02 (Rev. 2) – Uniform provisions concerning the approval of motor vehicles with regard to their pedestrian safety performance.

Information

Information: Paragraph on the Road, 2022, 3/2022, pp. 57 - 69

DOI: https://doi.org/10.4467/15053520PnD.22.017.16987

Article type: Original article

Titles:

Polish:

Próby potrąceniowe z użyciem manekinów pieszego. Manekin pieszego PRIMUS – konstrukcja i unikalne cechy

English:

Crash tests employing pedestrian dummies. PRIMUS dummy – design and unique properties

Authors

Daniel Wdowicz

https://orcid.org/0000-0001-7334-8110

CYBID sp. z o.o. sp. k. Kraków.

Politechnika Wrocławska

Published at: 2022

Received at: 25.07.2022

Accepted at: 28.11.2022

Article status: Open

Licence: CC BY

Percentage share of authors:

Daniel Wdowicz (Author) - 100%

Article corrections:

-

Publication languages:

Polish

View count: 400

Number of downloads: 527

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