Analysis of vehicle stability loss due to strong crosswind gusts using web services in the route planning process

Authors

DOI:

https://doi.org/10.5604/01.3001.0014.0207

Keywords:

crosswind, transportation planning, vehicle stability, web applications, route planning

Abstract

Weather conditions play a significant role in road safety. One of its component is a wind influence, which may be affected the moving vehicle from different angles. The final result of such action can take typical kinds of behavior like overturn, slideslip and rotation. Accordingly, vehicles with high side profile are particularly vulnerable to such specific phenomena, what made the planning process more difficult and complex. The article analyses possibilities of a stability loss of a truck vehicle due to strong crosswind gusts. The authors synthesized the model proposed in the literature with available web technologies and the needs of a transport market. Moreover, a method which evaluate a danger of reaching the friction limit by all of the vehicle wheels (slideslip) was developed and is practicable to use. The proposed solution is based on the RESTful API of the weather and web mapping services which allows to collate a direction and a force of wind with a direction of movement and a side profile of the vehicle moving between two locations. What is more a weather forecast is allowed to adopt appropriate variables to compute the air density and evaluate friction coefficients. From the other hand the method uses actual parameters of a vehicle such as axle loads, distance between axles, center of mass location and kind of axle (driven or not). The assumption, which consist in sequencing routes for smaller parts, made it possible to achieve the high accuracy of results on tested areas. The proposed method is simple to implement in any programming language and it can be extended by new functionalities.  The analyzed issue can also be a starting point for intelligent systems that can be used in autonomous vehicles.

References

AUTO ŚWIAT, 2008. 16 aut w próbie – Kto się boi bocznego wiatru?. Available at: https://www.auto-swiat.pl/wiadomosci/aktualnosci/16-aut-w-probie-kto-sie-boi-bocznego-wiatru/jssgpkr (access date: February 2019)

BAKER C.J., 1986. A Simplified Analysis of Various Types of Wind-induced Road Vehicle Accidents. Journal of Wind Engineering and Industrial Aerodynamics, 22, 69 – 85.

BAKER C.J., 1988. High Sided Articulated Road Vehicles in Strong Cross Winds. Journal of Wind Engineering and Industrial Aerodynamics. 31(1), 67 – 85.

BATISTA M., PERKOVIČ M., 2014. A simple static analysis of moving road vehicle under crosswind. Journal of Wind Engineering and Industrial Aerodynamics, 128, 105 – 113.

BUDZYŃSKI M., TUBIS A., 2019. Assessing The Effects of The Road Surface And Weather Conditions On Road Safety. Journal of KONBiN, Vol. 49, Issue 3, 323 – 349.

BURGER W., BURGE M. J., 2009. Principles of Digital Image Processing – Fundamental Techniques. London: Springer-Verlag.

DAIMLER, 2019. Crosswind Assist – more safety as standard: campers based on the Mercedes-Benz Sprinter with Crosswind Assist. Available at: https://media.daimler.com/marsMediaSite/en/instance/ko/Crosswind-Assist---More-safety-as-standard-campers-based-on-the-Mercedes-Benz-Sprinter-with-Crosswind-Assist.xhtml?oid=9904585 (access date: February 2019)

HABICH E., 1962. Techniczny poradnik samochodowy, Part 2. Warsaw: WNT (Chapter H).

JAGIELSKI A., 2005. Geodezja I. Cracow: GEODPIS Andrzej Jagielski.

JÓŹWIAK A., BETKIER I., 2018. Proces planowania przemieszczania pojazdów nienormatywnych z wykorzystaniem aplikacji webowych. Gospodarka Materiałowa i Logistyka, 12.

LASY PAŃSTWOWE, 2017. Lasy w Polsce 2017. Available at: http://www.lasy.gov.pl (access date: February 2019).

LETSON F., BARTHELMIE R. J., HU W., PRYOR S. C., 2019. Characterizing Wind Gusts In Complex Terrain, Atmospheric Chemistry and Physics, Vol. 19, Issue 6, 3797 – 3819.

MACIOSZEK E., 2019. Conditions of Oversize Cargo Transport, Scientific Journal of Silesian University of Technology. Series Transport, Vol. 102, 109 – 117.

MUSLIM N. H. B., SHAFAGHAT A., KEYVANFAR A., ISMAIL M., 2018. Green Driver: Driving Behaviors Revisited On Safety. Archives of Transport, Vol. 47, Issue 3, 49 – 78.

NASA, 1976. U.S. Standard Atmosphere, 1976. Washington, D.C: Government Printing Office.

OPENWEATHERMAP, 2019. Weather API. Available at: https://openweathermap.org/api (access date: February 2019)

PN-EN 1991-1-4:2008 Eurokod 1: Oddziaływania na konstrukcje - Część 1 – 4: Oddziaływania ogólne – Oddziaływania wiatru.

POLICE REPORT, 2017. Wypadki drogowe w 2017 roku. Available at: http://statystyka.policja.pl/st/ruch-drogowy/76562,Wypadki-drogowe-raporty-roczne.html (access date: February 2019)

PROCHOWSKI L., KOZIOŁ S., 2011. Zagrożenia w ruchu pojazdów z wysoko położonym środkiem masy. Problemy eksploatacji, 2.

PROCHOWSKI L., ŻUCHOWSKI A., 2009. Technika transportu ładunków. Warsaw: Wydawnictwa Komunikacji i Łączności.

SANDA-MARIANA B., CALIN-VASILE P., IACOB-LIVIU S., 2019. The Aerodynamic Study of a Body Truck, Proceedings of the 4th International Congress of Automotive and Transport Engineering (AMMA 2018), 73 – 79.

SEJM RP, 2002. Rozporządzenie Ministrów Infrastruktury oraz Spraw Wewnętrznych i Administracji z dnia 31 lipca 2002r. w sprawie znaków i sygnałów drogowych, Dz.U. 2002 nr 170 poz. 1393.

ŚWIDERSKI A., JÓŹWIAK A, JACHIMOWSKI R., 2018. Operational quality measures of vehicles applied for the transport services evaluation using artificial neural networks. Eksploatacja i Niezawodność – Maintenance and Reliability, 20 (2):2920299

SZCZUCKA – LASOTA B., 2017. City Logistics: Influence of oversized road transport on urban development, Scientific Journal of Silesian University of Technology. Series Transport, 97, 157 – 165.

VENNES, C., 2019. Calculate distance, bearing and more between Latitude/Longitude points. Available at: https://www.movable-type.co.uk/scripts/latlong.html (access date: March 2019)

Downloads

Published

2019-12-31

Issue

Section

Original articles

How to Cite

Betkier, I., Mitkow, S., & Kijek, M. (2019). Analysis of vehicle stability loss due to strong crosswind gusts using web services in the route planning process. Archives of Transport, 52(4), 47-56. https://doi.org/10.5604/01.3001.0014.0207

Share

Most read articles by the same author(s)

<< < 22 23 24 25 26 27 28 29 30 31 > >> 

Similar Articles

1-10 of 273

You may also start an advanced similarity search for this article.

Risk assessment in railway rolling stock planning

Piotr Gołębiowski, Ignacy Góra, Yaroslav Bolzhelarskyi (Author)

PRT simulation research

Maciej Kozłowski, Włodzimierz Choromański (Author)