Sage Journals: Discover world-class research

Abstract

The deformable ground could affect the construction vehicle’s comfortable level and working efficiency. To clarify this question, under the interaction between the construction vehicle’s wheel and deformable ground, a three-dimensional nonlinear vehicle model is built to calculate the vibration equations and simulate the vehicle model under various operation conditions. Two indexes of the acceleration responses in the time region and the acceleration-frequency in the frequency region of the seat’s heave, the cab’s pitch, and the cab’s roll angle are used to evaluate the comfortable level. The research shows that the deformable ground greatly affects the vehicle’s comfortable level and driver’s health under different operation conditions. Especially, the soil ground strongly affects the driver’s comfortable level whereas the sand ground remarkably affects the cab’s shaking. Besides, when the construction vehicle is traveling under poor soil ground, the vehicle’s resonance frequencies appear more than when the vehicle is traveling under a rigid road of ISO C-class, particularly at the excitation frequencies from 1.4 Hz to 7.8 Hz. Therefore, the deformable ground greatly affects the driver’s health at these low excitation frequencies.

Keywords

Construction vehicle dynamic model deformable ground rigid ground comfortable level

Get full access to this article

View all access options for this article.

References

Ding

Hao

Zhu

. Evaluation of dynamic vehicle axle loads on bridges with different surface conditions. J Sound Vib 2009; 323: 826–848.

Green

Cebon

. Dynamic interaction between heavy vehicles and highway bridges. Compos Struct 1997; 62: 253–264.

Nguyen

Yuan

. Application of machine learning approach on improving quality of semi-trailer truck air suspensions. Int J Veh Noise Vib 2022; 17: 101–120.

Zha

Nguyen

Mei

, et al. Analyzing isolation capacity of new seat suspension resorting TPS and NSS combined. J Dyn Control 2024; 12: 2190–2202.

. 3-D Dynamic modeling and simulation of a multi-degree of freedom 3-axle rigid truck with trailing arm bogie suspension. Wollongong, NSW: University of Wollongong, 2006.

Yang

, et al. Numerical and experimental investigation on stochastic dynamic load of a heavy duty vehicle. Appl Math Model 2010; 34: 2698–2710.

Jiao

Nguyen

. Studies on the low frequency vibration of the suspension system for heavy trucks under different operation conditions. Noise Vib Worldw 2020; 52: 127–136.

Mitschke

. Dynamik der kraftfahrzeuge. Berlin, Germany: Springer-Verlag, 1972.

Bekker

. Introduction to terrain-vehicle systems. Ann Arbor, MI: Univ Michigan Press, 1969.

10.

Park

Popov

Cole

. Influence of soil deformation on off-road heavy vehicle suspension vibration. J Terramechanics 2004; 41: 41–68.

11.

Wong

. Theory of ground vehicles. New York, NY: John Wiley & Sons Inc, 2001.

12.

Nguyen

Tao

, et al. Analysis of the isolation performance of the optimal NSS added into the vibratory roller’s seat isolator. J Braz Soc Mech Sci Eng 2023; 45: 130.

13.

Yang

Nguyen

Wang

, et al. Performance study of semi-active seat suspension added by quasi-zero stiffness structure under various vibratory roller models. Proc. IMechE, Part D: J Auto Eng 2024; 238: 1129–1143.

14.

Nguyen

Zhang

, et al. Vibration analysis and modeling of an off-road vibratory roller equipped with three different cab’s isolation mounts. Shock Vib 2018; 2018: 17.

15.

Pakowski

Cao

. Effect of soil deformability on off-road vehicle ride dynamics. SAE Int J Com Veh 2013; 6: 362–371.

16.

Gao

Jiang

, et al. Development and numerical validation of an improved prediction model for wheel-soil interaction under multiple operating conditions. J Terramechanics 2018; 79: 1–21.

17.

Zhang

. Modelling, simulation and optimization of ride comfort for off-road articulated dump trucks. Savannah, GA: South University, 2010.

18.

Wang

. Coupling dynamic model of vehicle-wheel-ground for all-terrain distributed driving unmanned ground vehicle. Simulat Model Pract Theor 2023; 128: 102817.

19.

Dallas

Jain

Dong

, et al. Online terrain estimation for autonomous vehicles on deformable terrains. J Terramechanics 2020; 91: 11–22.

20.

Captain

Boghani

Wormley

. Analytical tire models for dynamic vehicle simulation. Veh Syst Dyn 1979; 8: 1–32.

21.

Robson

. Road surface description and vehicle response. Int J Veh Des 1979; 1: 25–35.

22.

ISO/TC108/SC2/WG4 . Reporting vehicle road surface irregularities. Tech. Rep. ISO/TC108/SC2/WG4N57. Stuttgart, Germany: Tieme Medical Publishers, 1982.

23.

ISO 8068 . Mechanical vibration-road surface profiles - reporting of measured data. Geneva, Switzerland: International Organization for Standardization, 1995.

24.

ISO 2631-1:1997 . Mechanical vibration and shock-evaluation of human exposure to whole body vibration-Part 2: general requirements. Tech. Rep. ISO 2631-1:1997. Geneva, Switzerland: ISO, 1997.

25.

Wang

Zeng

, et al. A diagnostic method of freight wagons hunting performance based on wayside hunting detection system. Measurement 2024; 227: 114274.

26.

Zhou

Nguyen

Zha

, et al. Ride performance of driver’s seat suspension system using various dynamics models. Noise Vib Worldw 2022; 53: 498–508.

27.

Song

Wang

. Studying the performance of quasi zero stiffness structure added to seat’s suspension based on various vehicle types. Noise Vib Worldw 2025; 56: 66–75.

A study on analyzing the influence of deformable and rigid grounds on the comfortable level of the construction vehicle

Abstract

Keywords

Get full access to this article

References