Response of asphalt matrix under multi-axial stress state

Sakib, Nazmus

12 September 2014

The pavement system is subjected to complex stress states under vehicular loading. A combination of axial and shear stress has been identified as a potential cause of top down cracking (or more precisely near surface cracking) in asphalt surface. Therefore, in terms of modeling the material response a pertinent question is whether the typical one-dimensional viscoelastic properties of the material are affected by a multi-axial stress state. Such changes are referred to as interaction non-linearity. The objective of this study was to evaluate whether or not asphalt composites are susceptible to such interaction effects. The study was conducted using fine aggregate matrix (FAM), which comprises graded sand and asphalt binder. To provide multi-modal loading, the rectangular prismatic FAM specimens were used with the Arcan apparatus. This apparatus ensures low bending stress and offers adjustments in the setup to provide different proportions of axial and shear stress. Finite element modeling was done to evaluate the stress state for different orientations of the sample in the Arcan apparatus. For measurement of strain, the study used digital image correlation (DIC), which is an optical, non-contact measurement technology. The strain thus measured was used to compute shear compliance. Fitting parameters of the shear compliances were estimated for power-law and Prony series for different loading orientations. When compared, the measured shear compliances do not show perceivable variation with respect to different proportion of axial stress applied in conjunction. However, further testing with different temperatures and other magnitudes of shear stress is necessary. This study is the first step to allow modeling of stress and crack propagation behavior near the pavement surface where complex stress state is present. / text

FAM

Arcan

Multi-axial

Multi-modal

Complex stress

Interaction nonlinearity

Shear compliance

Creep compliance

DIC

Digital image correlation

Near surface cracking

TDC

Razvoj modela objektivne kontrole površinskih oštećenja premaznih papira u procesu savijanja / Development of a model for objective control of surface damages on coated papers in the folding process

Pal Magdolna

03 September 2014

<p>U disertaciji se predstavljaju istraživanja koja su rezultirala razvojem modela objektivne kontrole otpornosti premaznih papira prema površinskom oštećenju u procesima savijanja. Na bazi analize niza izabranih parametara procesa kontrole, ppedložena su tri obeležja digitalnih uzoraka premaznih papira za opis i ocenu površinskog oštećenja. Rezultati predloženih obeležja, kao i korelacione analize omogućuju primenu tih obeležja u funkciji kontrole kvaliteta kao osnove razvoja objektivne procesne kontrole premaznih papira u procesu savijanja.</p> / <p>The research presented in this dissertation resulted in development of the objective quality control model for fold cracking resistance of coated papers. Based on the analysis of chosen control process parameters, three different features of the digitalised coated paper samples were proposed for describing and classifying surface damages. The results of the proposed features along with their correlation analysis contribute to their usage in objective process quality control of coated papers in the folding process.</p>

A study on wear characteristics of high strength steels under sliding contact

Mussa, Abdulbaset

January 2020

In the last decades, significant improvements regarding the design, materials and technology of rock drills have been made. Likewise, in sheet metal forming, forming tools experience very high contact pressures when processing high strength steel sheets. In both applications components operate under extremely tough contact conditions that result in an accelerated component failure. Enhancements on mechanical properties of components material subjected to extreme contact conditions are highly required in order to withstand the application loads and prevent severe wear. The present thesis was focused on understanding of machinery component damage mechanisms under severe contact conditions. A case study of worn components used in rock drilling and sheet metal cold work was carried out. Thread joints from rock drilling and punches from sheet metal pressing were selected for the investigation. For these components, sliding contact under high contact pressure is a common load condition under the components usage. Then, to understand and quantify the influence of contact parameters, load and surface quality on material performance, laboratory simulations were performed. The results were used for a comparative analysis of the typical damage mechanisms observed in the tests and the case study of the components. The case study results showed that the threaded surfaces underwent severe plastic deformation due to the high-pressure sliding contact. The microstructure beneath the worn surface was altered and surface cracks and delamination were frequently observed at the worn surface. The dominant damage mechanism found on the investigated punches was adhesive wear. Material transfer adds friction stresses at the punch surface and ultimately, with repeated punch strokes, it leads to initiation and propagation of fatigue cracks. Wear process in thread joint and punch wear was simulated using the SOFS. The worn specimens tested experimentally showed similar wear mechanisms obtained in the case study. The thread joint wear simulation showed that the total damage at the worn surface was a result of adhesive wear, plastic deformation, and initiation and propagation of fatigue cracks. In addition, the results showed that the type of motion had a significant influence on the worn volume and crack initiation, and more severe wear was observed at reciprocal motion. The punch wear simulation showed that the friction quickly increased as work material from metal sheets transferred to the disc surface. The rate of the material transfer was strongly dependent on the combination of sheet material and tool steel. Further, the present experimental simulations were applicable to characterize and predict wear of components in the application. / Components used in rock drilling and sheet metal forming operate under harsh contact conditions that result in an early-life component failure. Wear and fatigue are considered as the most common damage mechanism for these components. Commonly, the service life of a component is designed based on its fatigue life. However, wear might have a significant effect on the components life too. Wear results in a surface damage that in turn may cause a fatigue crack initiation. Therefore, knowledge about wear of materials and components is a key factor in design and prediction of the lifetime of the components. In order to predict wear of a certain component, a thorough understanding of the component with regards to its material properties, application loads and working environment, and damage mechanisms is required. The overall aim of the present work was to define the typical wear mechanisms occurred on machinery components used in rock drilling and sheet metal forming. A comparative analysis of the case studies and results from performed laboratory tests simulated wear mechanisms in the applications highlighted wear mechanisms and factors influencing severity of wear in the applications. Obtained information is crucial for ranking and selection of the best material in the applications. / <p>The presentation will will be via zoom. PhD student will together with the supervisors will be in Karlstad while the opponent is in Luleå. </p>

High strength steels

thread joint wear

punch wear

sliding wear

surface cracking

reciprocal sliding

fatigue

surface delamination

white etching layer

nano-structured layer

friction

Materials Engineering

Materialteknik