Global ETD Search

11	Helically-Driven Dynamics in Granular Media January 2019 (has links) abstract: Vehicles traverse granular media through complex reactions with large numbers of small particles. Many approaches rely on empirical trends derived from wheeled vehicles in well-characterized media. However, the environments of numerous bodies such as Mars or the moon are primarily composed of fines called regolith which require different design considerations. This dissertation discusses research aimed at understanding the role and function of empirical, computational, and theoretical granular physics approaches as they apply to helical geometries, their envelope of applicability, and the development of new laws. First, a static Archimedes screw submerged in granular material (glass beads) is analyzed using two methods: Granular Resistive Force Theory (RFT), an empirically derived set of equations based on fluid dynamic superposition principles, and Discrete element method (DEM) simulations, a particle modeling software. Dynamic experiments further confirm the computational method with multi-body dynamics (MBD)-DEM co-simulations. Granular Scaling Laws (GSL), a set of physics relationships based on non-dimensional analysis, are utilized for the gravity-modified environments. A testing chamber to contain a lunar analogue, BP-1, is developed and built. An investigation of straight and helical grousered wheels in both silica sand and BP-1 is performed to examine general GSL applicability for lunar purposes. Mechanical power draw and velocity prediction by GSL show non-trivial but predictable deviation. BP-1 properties are characterized and applied to an MBD-DEM environment for the first time. MBD-DEM simulation results between Earth gravity and lunar gravity show good agreement with theoretical predictions for both power and velocity. The experimental deviation is further investigated and found to have a mass-dependant component driven by granular sinkage and engagement. Finally, a robust set of helical granular scaling laws (HGSL) are derived. The granular dynamics scaling of three-dimensional screw-driven mobility is reduced to a similar theory as wheeled scaling laws, provided the screw is radially continuous. The new laws are validated in BP-1 with results showing very close agreement to predictions. A gravity-variant version of these laws is validated with MBD-DEM simulations. The results of the dissertation suggest GSL, HGSL, and MBD-DEM give reasonable approximations for use in lunar environments to predict rover mobility given adequate granular engagement. / Dissertation/Thesis / Doctoral Dissertation Mechanical Engineering 2019 Engineering Robotics Geophysics Granular Media Lunar Robotics Simulation Space Terramechanics
12	Characterization of Soft Clay and Clay-tire Interaction for the Prediction of Ground Mobility Pandit, Rashna 22 August 2023 (has links) Predicting tire performance on soft, fine-grained soils is required for many off-road explorations in the military, mining, agricultural, and earth-moving sectors. However, the mobility in deformable material is extremely challenging, especially in the presence of water. Although there is a significant amount of research on terrains such as sands, there is a lack of research on fine-grained soils. This research is part of a bigger project that presents a novel approach to improve the mobility of off-road vehicles on wet deformable soils. The approach integrates experimental data from small-scale soil testing, large-scale soil-tire interaction testing, and advanced physics-based numerical simulation techniques. In particular, this thesis attempts to characterize the clay-tire interface by conducting large-scale direct shear tests. In addition to clay-tire contact friction, the properties and strength parameters of the soft clay are determined by conducting various index properties and advanced tests. The testing program accounts for different stresses, loading conditions, and boundary conditions, decided taking into account real field conditions. The results from all these experiments will be used to calibrate and validate the material constitutive models required for the development of a mobility predictive numerical model. Overall, this study contributes to the development of more advanced and accurate terramechanics models that involve deformable terrains like soft clays. / Master of Science / The prediction of Vehicle mobility on soft, fine-grained soils is challenging due to the impact of soil behavior on mobility, which is not taken into account by traditional vehicle simulation software. However, as off-road exploration and resource extraction become increasingly important, particularly in military, agricultural, and earth-moving sectors, the study of vehicle mobility on deformable soils is inevitable. The difficulty in predicting tire performance on soft, fine-grained soils is due to the lack of proper experimental data and numerical modeling techniques that accurately characterize the interaction between soil and vehicle tires, known as "terramechanics." The study forms a constituent part of a broader project, which aims to integrate the experimental research data from small-scale soil testing, large-scale soil-tire interaction testing, and advanced physics-based numerical simulation techniques. The main contribution of this study is to investigate soil-tire interaction to determine the contact friction between the soil and tire by conducting large-scale direct shear tests. It also involves conducting basic index properties tests and advanced shear strength and compression tests. The results from all these tests contribute to developing more accurate soil-tire interaction models in terramechanics. Given the scarcity of research on large deformable terrains like soft clays, this study can make a significant contribution towards developing more advanced and accurate terramechanics models that involve deformable terrain, which can be useful in various applications. Direct Shear tests Tire mud interaction Geotechnical Laboratory testing terramechanics
13	A Three Dimensional Discretized Tire Model For Soft Soil Applications Pinto, Eduardo Jose 02 April 2012 (has links) A significant number of studies address various aspects related to tire modeling; most are dedicated to the development of tire models for on-road conditions. Such models cover a wide range of resolutions and approaches, as required for specific applications. At one end of the spectrum are the very simple tire models, such as those employed in real-time vehicle dynamic simulations. At the other end of the spectrum are the very complex finite element models, such as those used in tire design. In between these extremes, various other models have been developed, at different levels of compromise between accuracy and computational efficiency. Existing tire models for off-road applications lag behind the on-road models. The main reason is the complexity added to the modeling due to the interaction with the soft soil. In such situations, one must account for the soil dynamics and its impact on the tire forces, in addition to those aspects considered for an on-road tire. The goal of this project is to develop an accurate and comprehensive, while also efficient, off-road tire model for soft soil applications. The types of applications we target are traction, handling, and vehicle durability, as needed to support current army mobility goals. Thus, the proposed approach is to develop a detailed semi-analytical tire model for soft soil that utilizes the tire construction details and parallels existing commercially available on-road tire models. The novelty of this project relies in developing a three-dimensional three-layer tire model employing discrete lumped masses and in improving the tire-soil interface model. This will be achieved by enhancing the resolution of the tire model at the contact patch and by accounting for effects and phenomena not considered in existing models. / Master of Science terramechanics soft soil tire model vehicle dynamics off-road
14	A Hybrid Soft Soil Tire Model (HSSTM) For Vehicle Mobility And Deterministic Performance Analysis In Terramechanics Applications Taheri, Shahyar 22 September 2015 (has links) Accurate and efficient tire models for deformable terrain operations are essential for performing vehicle simulations. Assessment of the forces and moments that occur at the tire-terrain interface, and the effect of the tire motion on properties of the terrain are crucial in understanding the performance of a vehicle. In order to model the dynamic behavior of the tire on different terrains, a lumped mass discretized tire model using Kelvin-Voigt elements is developed. To optimize the computational time of the code, different techniques were used in memory allocation, parameter initialization, code sequence, and multi-processing. This has resulted in significant improvements in efficiency of the code that can now run close to real time and therefore it is suitable for use by commercially available vehicle simulation packages. Model parameters are obtained using a validated finite element tire model, modal analysis, and other experimental test procedures. Experimental tests were performed on the Terramechanics rig at Virginia Tech. The tests were performed on different terrains; tire forces and moments, soil sinkage, and tire deformation data were collected for various case studies based on a design of experiment matrix. This data, in addition to modal analysis data were used to validate the tire model. Furthermore, to study the validity of the tire model, simulations at conditions similar to the test conditions were performed on a quarter car model. The results have indicated the superiority of this model as compared to other lumped parameter models currently available. / Ph. D. Tire Model Vehicle Simulation Tire-Terrain Interaction Terramechanics
15	Experimental Investigation of the Tractive Performance of an Instrumented Off Road Tire in a Soft Soil Terrain Naranjo, Scott David 10 July 2013 (has links) The main goal of this study is to improve the understanding of the interaction between a pneumatic tire and deformable terrain. A design of experiments has been implemented, that gives insight into the effect of individual tire and soil parameters, specifically wheel slip, normal load, inflation pres-sure, and soil compaction, as well as into the effect of combinations of such parameters on the tire and soil behavior. The results of such test data is exceedingly relevant, providing significant infor-mation to tire design for tire manufacturers, to users for operating conditions selection, as well as providing modeling parameters for tire models. Moreover, experimental investigation of tire-soil interaction provides validation data for tire models operating under similar conditions. In support of the validation of a soft soil tire model currently being developed at Virginia Tech under the auspices of the Automotive Research Center, experimental work has been performed on a low-speed, indoor single-wheel tester built to investigate studies in terramechanics. The terramechanics rig provides a well-controlled environment to assure repeatable testing conditions and void vehicle component ef-fects. The test tire for the rig is instrumented with a wireless sensory system that measures tire de-flection at the contact patch; combining this system with other instruments of the rig allows accurate estimations of wheel sinkage. A methodical soil preparation procedure has rendered great data to analyze several relations, such as the drawbar pull and the sinkage dependency on slip. The data col-lected indicated that, when looking at the effect of individual parameters, by increasing the soil com-paction, the normal load, and by decreasing the inflation pressure will result in a higher normalized drawbar pull. A higher normal load under all conditions consistently lowered the max tire sinkage depth. The sinkage has increased dramatically with the slip ratio, growing threefold larger at high slip (70-90%) when compared to lower slip (0-5%) ratios. / Master of Science terramechanics tires soft soil single wheel tester tire instrumentation
16	Terrain Impacts from Vehicle Operations across Multiple Passes Kane, James Robert 01 December 2010 (has links) This study, conducted on August 12th and 13th, 2008 at Fort Riley, Kansas on a clay loam soil, evaluated the terrain impacts of four commonly used tracked and wheeled military vehicles: the M1A1 Abrams Main Battle Tank, M998 High Mobility Multipurpose Wheeled Vehicle, M985 Heavy Expanded Mobility Tactical Truck, and M113 Armored Personnel Carrier. Disturbed width and impact severity were assessed along 14 spirals subjected to a maximum of eight consecutive passes for a total of 696 impact points. Data indicate that multiple passes produce increased vegetative impacts, with multipass coefficients ranging from 0.98 to 4.44 (compared to the commonly accepted value of 2.00) depending on vehicle type and turn severity. The widely-used MPC of 2.00 fits the M985 HEMTT and M113 at sharp turns, with an MPC of 1.00 fitting the straight and intermediate turning conditions of these vehicles, as well as all turning conditions for the M998 HMMWV. For the M1A1, a MPC of 2.00 is suitable for straight paths, a MPC of 3.00 is suitable for intermediate turns, while sharp turns can be represented by a MPC of 4.00. The data suggests that MPCs should be adjusted depending on the vehicle type and according to the turning radius of the vehicle, as tracked vehicles were found to have a higher multipass coefficient than wheeled vehicles, with multipass coefficients increasing with vehicle weight and the sharpness of turns. vehicle dynamics terramechanics military ITAM Impacts Bioresource and Agricultural Engineering Sustainability
17	Forestry machine and soil interaction for sustainable forestry Pirnazarov, Abdurasul January 2015 (has links) More than 50 percent of the land area of the Nordic countries Finland, Norway, and Sweden are covered by dense forests and they are among the most important producers of forest products in the world. Forestry in these countries is based on sustainable management principles – reforestation follows harvesting. Furthermore, increasing demands for more gentle techniques and technologies with less negative impact on the environment ask for development and implementation of new processes and new machine solutions. The increasing interest in developing forest management approaches that are based on gentleness to the environment requires better understanding of the interaction between the forestry machines and the terrain in the harvesting process. / <p>QC 20150827</p> / Gentle Forest Machines CTL-logging forestry machine forwarder multi-body simulations roots terramechanics wheel-soil interaction WES model
18	Stanovení poloměru otáčení u traktorů Zetor Forterra 140 HSX, Zetor Proxima 120 Power a Zetor 7745 Turbo pro potřeby počítačových modelů ZLOCH, Jan January 2018 (has links) The main aim of this diploma thesis is to determine the radius of rotation of selected tractors (Zetor Forterra 140 HSX, Zetor Proxima 120 Power and Zetor 7745 Turbo) on three different types of surfaces using different speeds. The literary part deals briefly with the importance and historical development of tractors, the basic knowledge of traction theory, the problems of forces acting on the rolling wheel, and last but not least the construction of the tractor parts. The practical part is mainly focused on determining the radii of rotation of individual tractors on three specified types of surfaces using the three given speeds. The discussion is mainly focused on comparing the radii of rotation meeting ČSN 30 0552 with the radii given by the tractor manufacturer.
19	Analysis of Soil-Tire Interaction Using a Two-Dimensional Finite Element-Discrete Element Method / 2次元有限要素-離散要素法による土-タイヤ相互作用解析 Nishiyama, Kenta 25 November 2019 (has links) 京都大学 / 0048 / 新制・論文博士 / 博士(農学) / 乙第13294号 / 論農博第2877号 / 新制\|\|農\|\|1073(附属図書館) / 学位論文\|\|R1\|\|N5239(農学部図書室) / (主査)教授清水浩, 准教授中嶋洋, 教授飯田訓久 / 学位規則第4条第2項該当 / Doctor of Agricultural Science / Kyoto University / DFAM Terramechanics FE-DEM Tractive performance Elastic wheel Planetary rover Contact stress Interchangeable modeling 610
20	Conceptual Design of a Powertrain for an Autonomous Golf Ball Collector / Konceptuell konstruktion av drivlinan till en autonom golfbollssamlare Colazio, Stefan January 2018 (has links) I denna uppsats presenteras resultatet av ett examensarbete i maskinkonstruktion på KTH. Arbetet har utförts på uppdrag av Poki Robotics via konsultbolaget Omecon.Poki Robotics vill automatisera uppsamlingen av golfbollar på så kallade driving ranges, genom att nyttja en hjuldriven autonom robot med ett tillhörande uppsamlingssläp. Enligt Poki Robotics samlas 5000 golfbollar upp under en intensiv dag, vilket innebär att en total massa av ca 230 kg måste uppsamlas och förflyttas. Detta ställer höga krav på dragkraften som drivlinan måste förse roboten med.Rapporten beskriver konceptframtagningen av drivlinan till den hjuldrivna autonoma roboten. Konceptet genererades genom att först utvärdera framdrivning inom robotik i en förstudie. Olika styrsystem utvärderades utifrån ställda krav på mjukvarubaserad styrning, mekanisk komplexitet, effektivitet och mobilitet. Styrsystemen utvärderades i en Pugh-matris som mynnade ut i två styrningar som visades mest lovande. Styrningarna utvärderades med en terrängmekanisk beräkningsmodell för att utvärdera framdrivande egenskaper, och därmed bedöma vilken som var mest lämpad för syftet utifrån ställda krav.För den lämpade styrningen genererades och utvärderades koncept för drivlinan med avseende på underhåll, montage, tillverkning, robusthet och förmåga att uppta laster. Det slutgiltiga konceptet bestod av en borstlös likströmsmotor, försedd med ett planetväxelhuvud och en parallell hjulaxel med en kuggremsutväxling.Konceptframtagningen resulterade i en CAD-modell som visade att drivlinan uppfyllde dimensionella krav.Den terrängmekaniska beräkningsmodellen nyttjades enbart som ett verktyg för att ge en indikation på prestanda och som indata för konstruktionen. Beräkningsmodellen har begränsningar i form av att den inte är lämpad för små hjuldiametrar, att den inte tar hänsyn till rotförstärkt mark samt att den utesluter de pneumatiska däckens elastiska egenskaper. / This thesis presents the result of a master thesis in machine design at KTH. The task was performed for Poki Robotics via the consulting firm Omecon.Poki Robotics wants to generate an autonomous solution for the collecting of golf balls on driving ranges, by utilizing a wheeled autonomous mobile robot coupled with a towed collecting unit. According to Poki Robotics, 5000 golf balls are collected on a busy day, yielding a total mass of approximately 230 kg that must be collected and towed. This sets high demands on the towing force that needs to be provided by the powertrain.The report describes the concept generation of the powertrain for a wheeled autonomous robot. A prestudy was done to evaluate wheeled locomotion in mobile robotics. Different steering systems were evaluated by different metrics including mechanical complexity, efficiency, mobility and demand for software-based control. The steering systems were evaluated using Pugh matrices, yielding two steering systems that showed to be promising. A terramechanical analytical model was used to further evaluate tractive performance of the two steering systems, to conclude which steering system was most suitable for the purpose with respect to the set requirements.Concepts were generated and evaluated for the powertrain of the chosen steering system, with respect to maintenance, assembly, manufacturing, robustness and load carrying capacity. The final concept yielded an EC-motor with a planetary gearhead, with a parallel wheel shaft and a timing belt gearing.The concept generation resulted in a CAD-model showing that the powertrain met the targeted dimensional constraints.The terramechanical analytical modelling was used solely as a tool for indication of performance and as input data for design. The model has limitations due to it not being suitable for small wheel diameters, not taking root reinforcement of the soil into account and excluding the pneumatic tire’s elastic properties. Mobile robot Powertrain Terramechanics AMR Mobil robot drivlina terrängmekanik AMR Mechanical Engineering Maskinteknik

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