Verificação do projeto estrutural de uma máquina de ensaio de fadiga de cadeira de rodas. / Verification of the structural design of a wheelchairs fatigue testing machine.

Moraes Junior, Ronaldo de Souza

28 July 2008

Para realizar ensaios de fadiga, é preciso que a máquina ou equipamento de testes tenha uma durabilidade muito maior que as estruturas ou componentes a serem ensaiados. O presente trabalho propõe-se a investigar a estrutura de uma máquina de ensaio de fadiga de cadeira de rodas, com o objetivo de determinar sua vida em fadiga. Para isto, uma análise da interação entre cadeira de rodas e máquina de ensaio é feita, do ponto de vista dinâmico, através de dados experimentais e modelagem em elementos finitos. A máquina de ensaio é constituída por uma estrutura com dois tambores rotativos, que possuem ressaltos, e suportam as rodas da cadeira de rodas. Estimada a força no tempo que a cadeira exerce sobre os tambores, calculam-se as tensões na estrutura, identificam-se as regiões de maiores tensões e estima-se a vida em fadiga da estrutura. / Fatigue analysis of full-scale structures and components is possible by using appropriated devices and machines which has to be much more durable than the structures or components being tested. The present work is proposed to investigate the structure of a wheelchair fatigue testing machine and predict its fatigue life. To reach this goal a dynamic analysis based on experimental data combined with the finite element method of the testing machine and wheelchair interaction is done. The machine is made of a structure and two turning drums that have slats and support the wheelchairs. With the timedependent force that wheelchair applies to the drums, the stresses are calculated to the whole structure, the sites with higher stresses are identified and the fatigue life of the structure is predicted.

Cadeiras de rodas

Dynamic response

Ensaios de fadiga

Fatigue life

Finite elements

Método dos elementos finitos

Rainflow

S-N Curve

Stress history

Verificação do projeto estrutural de uma máquina de ensaio de fadiga de cadeira de rodas. / Verification of the structural design of a wheelchairs fatigue testing machine.

Ronaldo de Souza Moraes Junior

28 July 2008

Para realizar ensaios de fadiga, é preciso que a máquina ou equipamento de testes tenha uma durabilidade muito maior que as estruturas ou componentes a serem ensaiados. O presente trabalho propõe-se a investigar a estrutura de uma máquina de ensaio de fadiga de cadeira de rodas, com o objetivo de determinar sua vida em fadiga. Para isto, uma análise da interação entre cadeira de rodas e máquina de ensaio é feita, do ponto de vista dinâmico, através de dados experimentais e modelagem em elementos finitos. A máquina de ensaio é constituída por uma estrutura com dois tambores rotativos, que possuem ressaltos, e suportam as rodas da cadeira de rodas. Estimada a força no tempo que a cadeira exerce sobre os tambores, calculam-se as tensões na estrutura, identificam-se as regiões de maiores tensões e estima-se a vida em fadiga da estrutura. / Fatigue analysis of full-scale structures and components is possible by using appropriated devices and machines which has to be much more durable than the structures or components being tested. The present work is proposed to investigate the structure of a wheelchair fatigue testing machine and predict its fatigue life. To reach this goal a dynamic analysis based on experimental data combined with the finite element method of the testing machine and wheelchair interaction is done. The machine is made of a structure and two turning drums that have slats and support the wheelchairs. With the timedependent force that wheelchair applies to the drums, the stresses are calculated to the whole structure, the sites with higher stresses are identified and the fatigue life of the structure is predicted.

Cadeiras de rodas

Ensaios de fadiga

Método dos elementos finitos

Dynamic response

Fatigue life

Finite elements

Rainflow

S-N Curve

Stress history

Geostatic stress state evaluation by directional shear wave velocities, with application towards geocharacterization at Aiken, SC

Ku, Taeseo

09 November 2012

Evaluations of stress history and the geostatic state of stress of soils are ascertained on the basis of field geophysical measurements that provide paired complementary types of shear waves. It is well-established that multiple types of shear waves occur in the ground due to their directional and polarization properties. The shear wave velocity (Vs) provides the magnitude of small strain stiffness (G0) which depends on effective stress, void ratio, stress history, and other factors (cementation, age, saturation). Herein, this study examines a hierarchy of shear wave modes with different directions of propagation and particle motion from in-situ geophysical tests (HH, VH, and HV) and laboratory bender element data. A special compiled database from well-documented worldwide sites is assembled where full profiles of stress state, stress history, and several paired modes of Vs profiles have been obtained from crosshole tests (CHT), downhole tests (DHT), and rotary crosshole (RCHT). Reference profiles of the lateral stress coefficient (K0) are available from direct in-situ measurements (self-boring pressuremeter, hydrofracture, and push-in spade cells). Stress history is documented in terms of yield stress ratio (YSR) from consolidation testing and careful engineering geology studies. A methodology is developed that relates both the YSR and K0 to stiffness ratios obtained from directional shear wave velocities. In further efforts, means to extract reliable shear wave profiles from continuous downhole testing via a new GT autosource and seismic piezocone testing are outlined and applied to results from three test sites in Windsor/VA, Norfolk/VA, and Richmond/BC. A driving impetus to this research involves the geologic conditions at the US Dept. of Energy's Savannah River Site (SRS) in South Carolina. Here, the overburden soils in the upper 60 m depths consist of very old Miocene and Eocene sediments, primarily layered deposits of sands, clayey sands, silty sands, and interbedded clays which exhibit an apparent and unusual stress history profile. Special geologic conditions include the dissolutioning of old calcareous sediments (Santee Formation) at depths of 40 to 50 m below grade, similar to karstic limestone deposits. As a consequence, caves, voids, and infilled soft soil zones occur within the soil matrix at these elevations, probably resulting in localized collapse of the overlying soil column. Based on conventional laboratory and in-situ test data conducted during geotechnical investigations at SRS, available interpretative relationships for assessing the soil stress history and geostatic stress states show scattered and inconsistent results. Complications abound in the systematic assessments of these geomaterials due to effects of very old ageing, cementation, desiccation, and diagenesis, as evidenced by unusual in-situ shear wave velocity profiles that decrease in magnitude with depth, as measured by CHT and DHT. Based on the findings of this study, it is recommended that a new set of shear wave velocity measurements be made at SRS to obtain HH waves (and complementary VH waves) needed for an independent assessment of YSR in the upper soil column.

Stress history

Lateral stress coefficient

Cone penetration

Small-strain shear modulus

Shear wave velocity

In-situ testing

Engineering geology

Engineering geology Fieldwork

Shear waves

Static and seismic responses of pile-supported marine structures under scoured conditions

Jiang, Wenyu

30 November 2021

Scour is a process of removing soils around foundations by currents and waves. For the pile-supported marine structures such as the monopile-supported offshore wind turbines (OWTs) and the pile-supported bridges, scour can decrease the pile capacities and alter the dynamic responses of the structures. At present, there is not a widely accepted method to estimate pile axial or lateral capacity under scoured conditions. For example, different recommendations are used among the existing design standards for estimation of the vertical effective stress and the resulting capacities for single piles under different scour conditions. None of the existing standards or design practice has even considered the scour effects on the behavior of pile groups. Furthermore, the investigation into the responses of piles under multiple hazards of scour and earthquakes is rarely reported. To address the foregoing limitations, this study first introduces an analytical solution to determining the vertical effective stress of soils around single isolated piles under scoured conditions and uses it to examine the limitations of the existing standards in estimation of pile tensile capacity (Chapter 1). The effect of soil-pile interface friction is highlighted. Next, the study proposes new approaches to investigating the combined effects of scour and earthquakes on the lateral responses of the monopile-supported OWTs in sand (Chapter 2) and soft clay (Chapter 3). Lastly, simple and practical methods are developed based on the p-y curve framework for analyzing the lateral responses of pile groups in sand (Chapter 4) and soft clay (Chapter 5) subjected to static lateral loading. The proposed methods in this study were encoded into a series of open-source computer scripts for engineering practice. They were verified with the 3D continuum finite element (FE) analyses. Using the proposed methods, standard methods, and 3D FE method, parametric analyses were conducted to investigate the scour effects on the lateral behavior of the monopile-supported OWTs under crustal earthquakes and that of the pile groups under static loading. The factors considered in the parametric study included effects of scour-hole dimensions, soil stress history, soil density, soil-pile interface behavior, soil liquefaction potential, pile group configurations, etc. Through the parametric analyses, the standard methods were critically assessed by comparing the results to those calculated by the proposed methods and 3D FE methods, and some design-related issues were also discussed. / Graduate

Local scour

Pile tension capacity

Vertical effective stress

Scour-hole dimensions

Sand

Offshore wind turbine

monopile

Earthquake

Liquefaction

Soft clay

Soil stress history

Pile group

Lateral capacity

Rapid densification of the oil sands mature fine tailings (MFT) by microbial activity

Guo, Chengmai

11 1900

The Mildred Lake Settling Basin (MLSB) is the largest disposal site for mature fine tailings (MFT) at the Syncrude Canada Ltd oil sands plant. Since 1996, MFT densification in the MLSB has significantly accelerated due to microbial activity. Methane-producing microorganisms, known as methanogens, have become very active. A field and laboratory research program has been performed to study the mechanisms leading to the rapid densification. This research program consisted of historical monitoring data analyses, field investigations, small-scale column tests, and gas MFT densification tests. The field investigations have shown that the rapid densification of the MFT has occurred in the southern part of the pond ranging from 8 m to 15 m below the water surface. A connection existed between the rapid densification zone and the zone with intense microbial activity at the pond. The small-scale column tests demonstrated that, with increases of biogas generation, water drainage from the MFT was enhanced. Gas MFT densification tests showed that, stress histories and total pressure affected MFT densification property during microbial activity. Under high total pressure (6-7 m below pond surface) gas bubbles had difficulty to release. For MFT without pre-consolidation or under a preloading, during rapid gas generation, water was rapidly drained out. For over-consolidated MFT, water flowed back into MFT quickly during intense biogas generation. The concept of operative stress, the difference between the total stress and pore water pressure for the soil with large gas bubbles, was introduced to analyze the densification behavior of gassy MFT. Under high total pressure and under a preloading (1 kPa), excess pore pressure increased and operative stress decreased during rapid gas generation while water drainage from the MFT was accelerated. Total pressure and stress history also affected the structure and permeability of the MFT during microbial activity. Under low total pressure (1 m below pond surface) and without pre-consolidation, the MFT permeability increased after intense microbial activity. / Geotechnical Engineering

rapid densification

microbial activity

oil sands mature fine tailings (MFT)

biological gas generation

self-weight consolidation

stress history

methane-producing microorganisms

operative stress

small-scale column tests

gas MFT densification tests

mildred lake settling basin (MLSB)

Rapid densification of the oil sands mature fine tailings (MFT) by microbial activity

Guo, Chengmai

Unknown Date

No description available.

rapid densification

microbial activity

oil sands mature fine tailings (MFT)

biological gas generation

self-weight consolidation

stress history

methane-producing microorganisms

operative stress

small-scale column tests

gas MFT densification tests

mildred lake settling basin (MLSB)