Chemical and Radiological Sensors Integration in Unmanned Aerial Systems with ATEX Compliance

Júlio Gouveia-Carvalho; Wilson Talhão Antunes; Tiago Gonçalves; Victor Lobo; Filipe Duarte; Bernardino Veríssimo; Alfredo Baptista; Mário Monteiro Marques

doi:10.4028/www.scientific.net/KEM.893.17

Paper Titles

Reactive Fibrous Materials for Decontamination of Chemical and Biological Threats
p.3

Features of Obtaining ZnO:Ag Thin Films Systems by the Method of Simultaneous Magnetron Sputtering with Subsequent Annealing
p.11

Chemical and Radiological Sensors Integration in Unmanned Aerial Systems with ATEX Compliance
p.17

Scalable Spider Silk Inspired Materials with High Extensibility and Super Toughness
p.31

Thermal Camouflage Clothing in Diurnal and Nocturnal Environments
p.37

Development of Chitosan-Gelatin Nanofibers with Cellulose Nanocrystals for Skin Protection Applications
p.45

Active Thermal Regulation Systems for Footwear: Development of New Innovative Technologies
p.57

Improvement of Biocomposite Performance under Low-Velocity Impact Test - A Review
p.67

HomeKey Engineering MaterialsKey Engineering Materials Vol. 893Chemical and Radiological Sensors Integration in...

Chemical and Radiological Sensors Integration in Unmanned Aerial Systems with ATEX Compliance

Abstract:

Chemical, biological, radiological and nuclear (CBRN) threats pose many challenges to address in terms of reconnaissance, detection, personnel protection and countermeasures comprising a common set of techniques and procedures that fit in the concept of “all hazard” approach. The scientific and technological developments that led to the use of unmanned aerial systems (UAS) in an ubiquitous manner, enables its integration in CBRN operations, as sensors platforms for detection. In this scope, the GammaEx project targets to validate the concepts of operation using a specifically developed UAS with ATmosphères EXplosives (ATEX) compliance, equipped with chemical and radiological sensors for detection in CBRN scenarios. This paper aims to review the main concepts and challenges involving the sensors integration in UAS for specific CBRN environments considering the ATEX compliance, followed by the GammaEx project description and the presentation of the preliminary results of the laboratory and field comparative assays concerning the specifically developed sensors for the project and the commercial of the shelf sensors, follow on activities and future trends.

You might also be interested in these eBooks

Advanced Materials and Technologies for Defense II

View Preview

Info:

Periodical:

Key Engineering Materials (Volume 893)

Pages:

17-27

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.893.17

Citation:

Cite this paper

Online since:

July 2021

Authors:

Júlio Gouveia-Carvalho, Wilson Talhão Antunes*, Tiago Gonçalves, Victor Lobo, Filipe Duarte, Bernardino Veríssimo, Alfredo Baptista, Mário Monteiro Marques

Keywords:

Explosive Atmospheres, Sensors Integration, Unmanned Aerial Systems

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Using Unmanned Aerial Vehicles (UAVs) for CBRN reconnaissance. Available online: http://www.cbrneportal.com/using-unmanned-aerial-vehicles-uavs-for-chemical-biological-radiological-nuclear-cbrn-reconnaissance/ (accessed on 30.05.2019).

DOI: 10.1061/9780784415764.ch4

Google Scholar

[2] Gouveia-Carvalho, J.; Antunes, W.; Gonçalves, T.; Marques, M.M.; Lobo, V., Unmanned aerial vehicles in chemical, biological, radiological and nuclear environment: Sensors review and concepts of operations. In Book of Papers (International symposium Mine Action") Proceedings of the International Symposium "Mine Action 2015,, Biograd, Croatia 27 to 30 April 2015; Editor-in-Chief Dražen Jakopec, Editor Sanja Vakula; Published by HCR-CTRO d.o.o. Zagreb, Croatia, (2015).

DOI: 10.4028/www.scientific.net/kem.893.17

Google Scholar

[3] Austin R, Unmanned Aircraft Systems - UAVs Design, Development and Deployment. Aerospace Series, Wiley (2010).

Google Scholar

[4] Dabringer, G. Unmanned Systems and the Future of Warfare. Available online: https://www.academia.edu/1522482/Unmanned_Systems_and_the_Future_of_Warfare._Key_Aspects_at_a_Glance (accessed on 16.06.2019).

Google Scholar

[5] NATO, Guidelines for first responders to a cabin incident. NATO Civil Emergency Planning Civil Protection Group, (2014).

Google Scholar

[6] Marques, M.M.; Gouveia-Carvalho, J.; Pascoal, M.; Matos, C. ATEX legal and standard framework applied to UAS in Mine Action and other risky interventions. In Book of Papers (International symposium Mine Action") Proceedings of the International Symposium "Mine Action 2016,, Biograd, Croatia 26 to 29 April 2016; Editor-in-Chief Dražen Jakopec, Editor Sanja Vakula; Published by HCR-CTRO d.o.o. Zagreb, Croatia, (2016).

Google Scholar

[7] Marques, M.M.; Lobo, V.; Carapau, R.S.; Rodrigues; A.V.; Gouveia-Carvalho, J.; Batista, A.; Almeida, J.; Matos, C., CBRN remote sensing using unmanned aerial vehicles: Challenges addressed in the scope of the GammaEx project regarding hazardous materials and environments. In Risk Analysis and Management – Trends, Challenges and Emerging Issues. Editors Aleš Bernatik, Chogfu Huang, Olivier Salvi; Published by Taylor & Francis Group. London, United Kingdom, (2017).

DOI: 10.1201/9781315265339

Google Scholar

[8] Marques, M. M., Martins, A., Matos, A., Cruz, N., Almeida, J. M., Carlos, J., Lobo, V., And Silva, E., REX 2014 – Robotic Exercises 2014 Multi-robot field trials. In MTS/IEEE OCEANS 2015. Washington, (2015).

DOI: 10.23919/oceans.2015.7404497

Google Scholar

[9] Morais, F., Ramalho, T., Sinogas, P., Marques, M. M., Santos, N. P., And Lobo, V., Trajectory and Guidance Mode for autonomously landing an UAV on a naval platform using a vision approach. In MTS/IEEE OCEANS 2015 (p.1–7), Génova, (2015).

DOI: 10.1109/oceans-genova.2015.7271423

Google Scholar