Mehari Z. Tekeste, Loran R. Balvanz, Jerry L. Hatfield, Sadaf Ghorbani

Journal of Terramechanics, Volume 82, 2019, Pages 1-11, ISSN 0022-4898,

https://doi.org/10.1016/j.jterra.2018.11.001.(http://www.sciencedirect.com/science/article/pii/S0022489818300259)

Abstract: Simulation of tool-to-soil interaction provides opportunities to accelerate new equipment design and evaluate performance of tillage tools. Simulation based evaluation of worn tillage tools performance on soil flow has not been done. Discrete Element Modelling (DEM) has a potential to simulate worn tool to soil interaction problems, where worn tools CAD can be generated using 3D scanning. The DEM parameters of Hertz-Mindlin with Parallel Bond model were calibrated to match draft force and soil failure zone measured from a tool bar moving at 0.22 m/s and 38 mm cutting depth. The draft force and soil forward failure zone were predicted at 7% and 24% relative errors compared to measured values, respectively. Using the optimized DEM soil model, the interaction of three 3D reconstructed sweeps (new sweep, carbide treated-worn, untreated-worn) with soil were simulated to compare their geometric wear dimensional loss, performance on soil forces and soil flow. Results showed that the carbide treated-worn sweep had similar soil draft force and soil forward failure distance as the new sweep. The untreated-worn sweep showed lower vertical force (less suction) and its wing induced soil failure zone (front and lateral) showed poor soil tilth quality compared with the carbide treated-worn sweep and the new sweep.

Keywords: Discrete Element Modeling; 3D scanning; Soil model; Tillage; Carbide treated hardened edge; Wear

Heinz Dieter Kutzbach, Alexander Bürger, Stefan Böttinger,

Journal of Terramechanics, Volume 82, 2019, Pages 13-21, ISSN 0022-4898,

https://doi.org/10.1016/j.jterra.2018.11.002.(http://www.sciencedirect.com/science/article/pii/S0022489818300685)

Abstract: Tractors and self-propelled harvesters are equipped with high volume pneumatic tyres with a low tyre inflation pressure. The contact patch can shift forwards or backwards in reference to the wheel centre as reaction on traction or brake forces because of the elastic tyre wall. Theoretical investigations – as necessary for modelling and simulation of dynamic vehicle behaviour – are complicated, since important tyre metrics cannot directly be measured based on the large deformations. Additionally, different definitions are often used. This is especially valid for the conversion of a drive torque into a traction force. In this context, the moment arm of the wheel load and the rolling radius of the tyre at zero slip condition are especially important. In contrast to the hitherto existing perception, the magnitude and position of the moment arm of the wheel load in reference to the wheel centre is dependent on traction and brake forces in addition to the motion resistance. The rolling radius of an elastic pneumatic tyre can be interpreted as radius of a fictitious rigid substitute wheel. This contribution emphasizes the outstanding importance of the rolling radius rdyn for all calculations on pneumatic tyres and the important roll of the variable moment arm of the wheel load for the moment compensation on the wheel.

Keywords: Pneumatic tyres; Rolling radius; Moment arm of the wheel load; Kinetic radius; Kinematic radius; Torque radius; Inner tyre ratio

Ramon Gonzalez, Samuel Chandler, Dimi Apostolopoulos,

Journal of Terramechanics, Volume 82, 2019, Pages 23-34, ISSN 0022-4898,

https://doi.org/10.1016/j.jterra.2018.12.001.(http://www.sciencedirect.com/science/article/pii/S002248981830065X)

Abstract: This paper presents a comprehensive comparison of well-known machine learning algorithms for estimating discrete slip events associated with individual wheels in planetary exploration rovers. This analysis is performed with various tuning configurations for each algorithm (55 setups). This research also shows the key role that environment plays in the performance of the learning algorithms: rover speed (0.05–0.25 [m/s]), type of terrain (gravel vs. sand), and tire type (off-road tires vs. smooth tires). These contributions are validated by using a broad data set collected using a planetary rover equipped with proprioceptive sensing. This work not only identifies the best algorithm to be deployed for discrete slip estimation, but it also helps with the selection and the mounting position of the sensing systems to be employed in future robotic planetary missions.

Keywords: Discrete slip estimation; Feature selection; Field validation; Ground vehicles; LATUV rover; Model selection

S. Jayalekshmi, Pala Gireesh Kumar,

Journal of Terramechanics, Volume 82, 2019, Pages 35-42, ISSN 0022-4898,

https://doi.org/10.1016/j.jterra.2018.12.002.(http://www.sciencedirect.com/science/article/pii/S0022489818300077)

Abstract: This paper summarises the experimental work and analytical work carried out to determine the wheel sinkage of plain rigid wheels and lugged wheels, traversing on TRI-1 Lunar Soil Simulant (Plain and lugged wheels: small wheel- 160 mm × 32 mm and large wheel- 210 mm × 50 mm) with different number of lugs (N = 8, 12, 16) and lug height (h = 5, 10, 15 mm). Bekker and Reece pressure sinkage models are considered to determine the theoretical sinkage, and outlined in the present study. Comparisons of the analytical results with the experimental results are also carried out. The comparisons hold good for plain rigid wheels and in 2 cases, for lugged wheels (Small and Large), with 16 lugs of height, 5 mm. For all other combinations of lugged wheels (no. of lugs = 8, 12 and height of lugs = 5 mm, 10 mm and 15 mm), the predicted values are found to be less than the experimental values. For efficient functioning of the rover, optimization of wheel dimensions is a must. A new sinkage model accounting gravity effect and aspect ratio is developed, based on experimental results for wheel sinkages on TRI-1 simulant, the range of results obtained for different cases are examined.

Keywords: TRI-1 lunar soil simulant; Sinkage model; Aspect ratio; Lug

Rui He, Corina Sandu, Aamir K. Khan, A. Glenn Guthrie, P. Schalk Els, Herman A. Hamersma,

Journal of Terramechanics, Volume 81, 2019, Pages 3-22, ISSN 0022-4898,

https://doi.org/10.1016/j.jterra.2018.04.003.(http://www.sciencedirect.com/science/article/pii/S0022489817302665)

Abstract: ISTVS embarked on a project in 2016 that aims at updating the current ISTVS standards related to nomenclature, definitions, and measurement techniques for modelling, parameterizing, and, respectively, testing and validation of soft soil parameters and vehicle running gear-terrain interaction. As part of this project, a comprehensive literature review was conducted on the parameterization of fundamental terramechanics models. Soil parameters of the empirical models to assess off-road vehicle mobility, and parameters of the models to characterize the response of the terrain interacting with running gears or plates from the existing terramechanics literature and other researchers’ reports were identified. This review documents and summarizes the modelling approaches that may be applicable to real-time applications of terramechanics in simulation, as well as in controller design.

Keywords: Soil modeling; Pressure-sinkage models; Shear stress-displacement models; Vibration models; ISTVS standards; Terramechanics; Off-road vehicle dynamics

G. Sitkei, G. Pillinger, L. Máthé, L. Gurmai, P. Kiss,

Journal of Terramechanics, Volume 81, 2019, Pages 23-34, ISSN 0022-4898,

https://doi.org/10.1016/j.jterra.2018.05.004.(http://www.sciencedirect.com/science/article/pii/S0022489817302690)

Abstract: Due to the extreme variability of soils and different tillage and settling conditions, measurements made under a single set of conditions have little practical applicability under arbitrary conditions. Results of more general usefulness require systematic measurements to be carried out over suitable ranges of the main influencing variables. The results can then be processed to obtain dimensionally homogeneous equations, i.e. similarity equations. This method was first proposed a century ago (Buckingham, 1914) [1], and one year later, Nusselt published a fundamental paper showing how it could be used to generalize the results of heat transfer experiments and to plan new experiments (Nusselt, 1915) [2]. The method is based on the postulate that all physical processes can be expressed as relationships among dimensionless parameters, and it specifies how to find those parameters. We describe new experimental results and generalize the results using dimensional analysis to obtain similarity plots and equations that are generally applicable within the feasible range of variables.

Keywords: Terramechanics; Generalization; Tyre-soil interaction

Devin K. Johnson, Theunis R. Botha, P. Schalk Els,

Journal of Terramechanics, Volume 81, 2019, Pages 35-42, ISSN 0022-4898,

https://doi.org/10.1016/j.jterra.2018.08.001.(http://www.sciencedirect.com/science/article/pii/S002248981730263X)

Abstract: In vehicle dynamics there are many parameters that are desired for vehicle control and modelling. One of the most important parameters for handling and stability is the vehicle side-slip angle. The ability to directly measure the vehicle side-slip in real-time will aid and improve many driver assist systems such as stability control schemes and roll-over mitigation, especially over rough terrain. Commercial side-slip angle solutions are available but they are prohibitively expensive and are only suitable for use during vehicle development and performance evaluation. They are also restricted to small side-slip angles and give unsatisfactory results at low speeds and over uneven terrain. Previous research has proven that digital image correlation can be used to accurately measure vehicle side-slip angle over rough off-road terrain using inexpensive, off-the-shelf cameras. However, side-slip angle calculations were performed in post processing from pre-recorded footage and not implemented in real time due to the large computational times of the novel algorithms developed. This paper describes the improvements made to the algorithms that enable real-time implementation. The side-slip angle is measured using a single camera pointing downwards to the terrain and digital image correlation. The sensor is tested on a flat surface using a rig that allows for validation. The maximum sampling frequency and accuracy are investigated. The system is shown to measure accurately and in real-time up to 100 km/h speeds.

Keywords: Computer vision; Side-slip angle; Off road; Image correlation

Emilio Jimenez, Corina Sandu,

Journal of Terramechanics, Volume 81, 2019, Pages 43-56, ISSN 0022-4898

https://doi.org/10.1016/j.jterra.2018.04.004.(http://www.sciencedirect.com/science/article/pii/S0022489817302653)

Abstract: Icy road conditions and tire operational parameters play a vital role in determining the overall performance of a vehicle. This study builds on prior work in the researchers’ group. The Advanced Tire-Ice Interface Model (ATIIM) simulates the temperature rise in the contact patch based on the measured pressure distribution and the thermal properties of the tread compound and of the ice surface. It has the capability to simulate the height of the thin water film created from the melted ice, to predict the tractive performance, and to estimate the viscous friction due to the water layer and the influence of braking operations, including the locked wheel condition. The experimental investigation included measuring the bulk temperature distribution in the contact patch to validate the temperature rise simulations of the ATIIM. As shown by the simulations and the test data, a rise in temperature was observed from the leading edge to the trailing edge of the contact patch. As the wheel load increases, the difference in temperature rise increases, as also reflected in the experimental study. When the temperature difference was significant, a thin water film was observed that resulted in a reduction of friction, which was simulated using the ATIIM.

Keywords: Tire-ice interface; Contact patch temperature; Traction performance

László Gurmai, Péter Kiss,

Journal of Terramechanics, Volume 81, 2019,Pages 57-65, ISSN 0022-4898,

https://doi.org/10.1016/j.jterra.2018.06.002.

(http://www.sciencedirect.com/science/article/pii/S0022489817302719)

Abstract: The more extreme conditions the vehicle is exposed to, the sooner it wears out and deteriorates. In order to determine the forces affecting the lifespan of vehicles we need to know the environmental conditions eliciting these forces. This research aims at elaborating and testing a method which can help to conduct a comparative analysis of forces acting on towed vehicles used in different terrain conditions. Excitation forces acting on a vehicle being towed across terrain cause vibrations which lead to wear and structural deterioration. The rate of deterioration depends on the activating forces resulting from the road profile geometry and the dynamic properties of the vehicle. A knowledge of the relationship between the towed vehicle and the terrain profile will enable the design of an artificial road profile for fatigue testing with which similar stresses arise as during normal use. With the developed comparative method, a connection can be established between stochastic road profiles and road profiles containing artificially built obstacles.

Keywords: Towed vehicle; Terrain profile; Transfer function; Fatigue test; Power spectral density; Root mean square; Characteristic frequency