A model for predicting narrow tool behavior under dynamic conditions

Swick, W. Christopher

January 1984

Most models available today for predicting the forces encountered by tillage tools apply to slow moving tools and do not take into account speed effects. However, most tillage operations are performed at speeds in the range of 2-8 km/h, and experimental studies show that tool forces increase significantly with tool speed. This effort of developing a model for predicting the forces on narrow tools under dynamic conditions was carried out in three steps. First, a series of laboratory tests was conducted to determine the effect of shear rate on soil shear strength and soil-metal friction parameters. Second, a model was developed to include dynamic effects. Third, the model was verified experimentally under laboratory conditions. Direct shear tests using a conventional shear box were conducted on an artificial soil at shear rates between 0. 5 and 12 7 cm/min. Experimental results showed that for the soil tested, the angle of internal friction, soil-metal friction angle, cohesion, and adhesion are independent of shear rate. A soil-tillage tool interaction model developed for quasi-static soil failure was modified to include shear rate effects and accelerational force effects. Experimental verification tests for the model were conducted under controlled conditions using an indoor soil bin facility. Tests were conducted with flat tines at speeds from 5. 4 to 120 cm/s. The overall trend was for the model to underpredict the observed total tool force by 16 %. However, the model demonstrated that terms including accelerational force effects can account for a large portion of the increase in tool force observed to occur with an increase in tool speed. / Master of Science

LD5655.V855 1984.S988

Shear strength of soils -- Testing

Tillage -- Testing

A unified elasto-plastic model for saturated loosely compacted completely decomposed granite

To, Chiu-yin., 杜昭彥.

January 2008

published_or_final_version / Civil Engineering / Master / Master of Philosophy

Granite - Mechanical properties.

Granite - Mathematical models.

Shear strength of soils.

Experimental study of shear behavior of soils with abundant coarse particles associated with slip zones of large landslides in the ThreeGorges reservoir, China

Li, Yanrong, 李彥榮

January 2009

published_or_final_version / Earth Sciences / Doctoral / Doctor of Philosophy

Shear strength of soils - Testing.

The influence of halloysite content on the shear strength of kaolinite

Gabor, Reka Katalin

01 January 1981

The objective of this thesis is to determine the relative shear strengths of halloysite, kaolinite, synthetic mixtures, and local soils, to investigate the influence of halloysite content on the shear strength of kaolinite, and to explore the possibility that the strength properties of soil clays might be controlled by the relative content of their component minerals.

Halloysite

Kaolinite

Shear strength of soils

Geology

Materials Science and Engineering

Failure of saturated sandy soils due to increase in pore water pressure

Junaideen, Sainulabdeen Mohamed.

January 2005

published_or_final_version / abstract / toc / Civil Engineering / Doctoral / Doctor of Philosophy

Shear strength of soils

Slopes (Soil mechanics)

Sandy soils - Testing.

Soil property determination through a knowledge-based system with emphasis on undrained shear strength

馮可達, Fung, Ho-tat.

January 1997

published_or_final_version / Civil and Structural Engineering / Doctoral / Doctor of Philosophy

Expert systems (Computer science)

A model of stress distribution and cracking in cohesive soils produced by simple tillage implements /

Ibarra, Sandra.

January 2001

The objective of this research was to further understand the behavior of the soil under the action of a tillage tool, with the purpose of finding a relation between the tool geometry and the resultant soil seed bed. Thus the problem consisted of understanding the mechanics of producing soil break up and to find a logical method of analyzing it. / The problem was solved using fundamental principles of soil mechanics and force equilibrium analyzis. As a result, a mathematical model was developed which describes three failure zones within the cut soil volume. The model can be programmed into a computer to generate maps of normal and shear stresses to visualize the three failure zones. / The failure zones are the shear failure zone, the tensile fracturing zone and the no failure zone. The tensile fracturing zone is delimited by the tensile stress reaching the tensile strength of the soil at the given soil moisture content and soil density. The tensile strength of the soil was measured using an apparatus and method designed in this research. / The mathematical model gives an explanation of the mechanics of crumbling and the shape of the failed volume, but it does not give information concerning soil aggregate quality and arrangement within the soil furrow. Then, a method of analyzing the formed aggregates was developed which considers some soil physical properties of aggregates. / The study concluded that the smaller tool width and the smaller tool rake angle, among the ones used in this research, produced the most efficient geometry in producing the largest amount of soil break up, the most uniform aggregate formation and the most stable aggregate arrangement. The same tool geometry requires less energy per unit volume of soil disturbed. The best performance is produced at the lowest soil water content among those tested.

Tillage -- Equipment and supplies.

Soil structure.

Shear strength of soils.

A critical assessment of moist tamping and its effect on the initial and evolving structure of dilatant triaxial specimens

Park, Jin Young

12 1900

No description available.

Soil moisture Measurement

Soil structure

Shear strength of soils

Strain rate effects in pressuremeter testing and neural network approach for soil modeling

Penumadu, Dayakar

05 1900

No description available.

Shear strength of soils Testing

Soils Testing

Engineering design

Laboratory modeling of reinforced earth

Hornbeck, David Earl

12 1900

No description available.

Soil stabilization

Shear strength of soils

Finite element method