Öz
The European Modular System (EMS) is
introduced to allow increased vehicle length and weight for road freight
transport. Directive 96/53EC defines the types of combinations for this modular
concept. This study concentrates on the Type-3 EMS so called "road
train" including truck, dolly and semi-trailer combination. To get an idea
about the effect of this long module combination over the valuable goods transportation,
three cases are defined for the dolly's front and rear suspension parameters,
than 14-degree of freedom (DOF) half vehicle models are generated in order to observe
the dynamic characteristics of the road-train for these three cases. Modal and
transient analyses are performed and vertical displacement responses are
obtained from front , middle and the end of the semi-trailer's nodal points.
Pitch angles of the semi-trailer body are also demonstrated. The change in the
bounce responses and the pitch angles are interpreted for all three cases.
Anahtar Kelimeler
European Modular System Road Train Dolly Half Vehicle Model Modal Analysis Transient Analysis
Kaynakça
- [1] Larsson, S., (2009). Weight and dimensions of heavy commercial vehicles as established by Directive 96/53/EC and the European Modular System (EMS). Workshop on LHVs Report, Brussels.
- [2] Åkerman, I., Jonsson, R. (2007). European Modular System for Road Freight Transport. Experiences and Possibilities. Report 2007:2 E. Stockholm: TFK – TransportForsk AB. 91 p.
- [3] Grislis, A. (2011). Longer Combination Vehicles and Road Safety. Transport. 25(3):336-443
- [4] Aurell, J., Wadman, T. (2007). Vehicle Combinations Based on the Modular Concept: Background and Analysis. Report No 1/2007. Committee 54: Vehicles and Transports. Sweden : Nordiska Vägtekniska Förbundet (NVF). 64 p.
- [5] Eom, J., Schipper L., Thompson L. (2012).We keep on truckin':Trends in freight energy use and carbon emissions in 11 IEA countries. Energy Policy. 45:327-341
- [6] Lundberg, T. (2013). Analysis of simplified dynamic truck models for parameter evaluation. Department of Aeronautical and Vehicle Engineering KTH Royal Institute of Technology. Master Thesis. ISSN 1651-7660.
- [7] Patil, V. (2017). Generic and complete vehicle dynamic models for open-source platforms. Department of Mechanical, Maritime and Material Engineering, Process and Energy, TU Delft, Netherlands. Master Thesis.
- [8] Malgaca, L., Gögen, E. (2015). The Effect of Front and Rear Ride Rate Ratios to the Pitch Angle of a Midibus. International Journal of Natural and Engineering Sciences. 9(1):44-48. ISSN:1307-1149, E-ISSN:2146-0086.
- [9] Philipson, N., Andreasson, J., Gafvert, M., Woodruff, A. (2008). Heavy Vehicles Modeling with the Vehicle Dynamics Library. Modelica. Lund, Sweden.
- [10] Sharma, D., Vora, Y.D. (2017). Design and Vibration Analysis of Heavy Duty Vehicle (Trailer) Chassis Through FEM Software. International Journal of Engineering Science Invention Research & Development. 3(11). e-ISSN:2349-6185.
- [11] Lian, K., Fan, B., Miao, Y., Zhu, X. (2016). Research on Optimal Design and Modal Analysis of the Frame. International Conference on Artificial Intelligence:Technologies and Applications (ICAITA 2016). p:272-274.
- [12] Mahmoodi-k, M., Davoodabadi, I., Visnjic, V., Afkar, A. (2014). Stress and Dynamic Analysis of Optimized Trailer Chassis. Technical Gazette 21. 3(2014):599-608.
- [13] Gillespie, T. (1992). Fundementals of Vehicle Dynamics. Society of Automotive Engineering. Warrandale, PA.
- [14] Karmiadji, D.W. (2005). Analyzing the Bounce and Pitch Phenomenon of Vehicle Model Through XZBM Algorithm. Jurnal Ilmiah Semesta Teknika. 8(2):137-145.
- [15] Penaz, J., Voltr, O. (2013). Dynamic Analysis of Behaviour of Three-axle Semi-trailer Road Tank Going on Special Waved Roadway. Transportation Engineering.41(2):139-142.
- [16] Spivey, C. (2007). Analysis of Ride Quality of Tractor Semi-Trailer. Department of Mechanical Engineering, Clemson University. Master Thesis.
- [17] Walhekar, S.B., Burande, D.H. (2015). Modeling of 17-DOF Tractor Semi-Trailer Vehicle. International Engineering Research Journal (IERJ). 2:5089-5093. ISSN:2395-1621.
Öz
Kaynakça
- [1] Larsson, S., (2009). Weight and dimensions of heavy commercial vehicles as established by Directive 96/53/EC and the European Modular System (EMS). Workshop on LHVs Report, Brussels.
- [2] Åkerman, I., Jonsson, R. (2007). European Modular System for Road Freight Transport. Experiences and Possibilities. Report 2007:2 E. Stockholm: TFK – TransportForsk AB. 91 p.
- [3] Grislis, A. (2011). Longer Combination Vehicles and Road Safety. Transport. 25(3):336-443
- [4] Aurell, J., Wadman, T. (2007). Vehicle Combinations Based on the Modular Concept: Background and Analysis. Report No 1/2007. Committee 54: Vehicles and Transports. Sweden : Nordiska Vägtekniska Förbundet (NVF). 64 p.
- [5] Eom, J., Schipper L., Thompson L. (2012).We keep on truckin':Trends in freight energy use and carbon emissions in 11 IEA countries. Energy Policy. 45:327-341
- [6] Lundberg, T. (2013). Analysis of simplified dynamic truck models for parameter evaluation. Department of Aeronautical and Vehicle Engineering KTH Royal Institute of Technology. Master Thesis. ISSN 1651-7660.
- [7] Patil, V. (2017). Generic and complete vehicle dynamic models for open-source platforms. Department of Mechanical, Maritime and Material Engineering, Process and Energy, TU Delft, Netherlands. Master Thesis.
- [8] Malgaca, L., Gögen, E. (2015). The Effect of Front and Rear Ride Rate Ratios to the Pitch Angle of a Midibus. International Journal of Natural and Engineering Sciences. 9(1):44-48. ISSN:1307-1149, E-ISSN:2146-0086.
- [9] Philipson, N., Andreasson, J., Gafvert, M., Woodruff, A. (2008). Heavy Vehicles Modeling with the Vehicle Dynamics Library. Modelica. Lund, Sweden.
- [10] Sharma, D., Vora, Y.D. (2017). Design and Vibration Analysis of Heavy Duty Vehicle (Trailer) Chassis Through FEM Software. International Journal of Engineering Science Invention Research & Development. 3(11). e-ISSN:2349-6185.
- [11] Lian, K., Fan, B., Miao, Y., Zhu, X. (2016). Research on Optimal Design and Modal Analysis of the Frame. International Conference on Artificial Intelligence:Technologies and Applications (ICAITA 2016). p:272-274.
- [12] Mahmoodi-k, M., Davoodabadi, I., Visnjic, V., Afkar, A. (2014). Stress and Dynamic Analysis of Optimized Trailer Chassis. Technical Gazette 21. 3(2014):599-608.
- [13] Gillespie, T. (1992). Fundementals of Vehicle Dynamics. Society of Automotive Engineering. Warrandale, PA.
- [14] Karmiadji, D.W. (2005). Analyzing the Bounce and Pitch Phenomenon of Vehicle Model Through XZBM Algorithm. Jurnal Ilmiah Semesta Teknika. 8(2):137-145.
- [15] Penaz, J., Voltr, O. (2013). Dynamic Analysis of Behaviour of Three-axle Semi-trailer Road Tank Going on Special Waved Roadway. Transportation Engineering.41(2):139-142.
- [16] Spivey, C. (2007). Analysis of Ride Quality of Tractor Semi-Trailer. Department of Mechanical Engineering, Clemson University. Master Thesis.
- [17] Walhekar, S.B., Burande, D.H. (2015). Modeling of 17-DOF Tractor Semi-Trailer Vehicle. International Engineering Research Journal (IERJ). 2:5089-5093. ISSN:2395-1621.
Ayrıntılar
| Birincil Dil | İngilizce |
|---|---|
| Konular | Makine Mühendisliği |
| Bölüm | Research Article |
| Yazarlar | |
| Yayımlanma Tarihi | 20 Aralık 2018 |
| Kabul Tarihi | 6 Kasım 2018 |
| Yayımlandığı Sayı | Yıl 2018 Cilt: 2 Sayı: 4 |
