Studies On Fatigue Crack Propagation In Cementitious Materials : A Dimensional Analysis Approach

Ray, Sonalisa

10 1900

Crack propagation in structures when subjected to fatigue loading, follows three different phases namely - short crack growth, stable crack growth and unstable crack growth. Accurate fatigue life prediction demands the consideration of every crack propagation phase rather than only the stable crack growth stage. Further, the use of existing crack growth laws in structures with small cracks under-predicts the growth rate compared to experimentally observed ones, thereby leading to an unsafe design and keeping the structure in a potentially dangerous state. In the present work, an attempt is made to establish fatigue crack propagation laws for plain concrete, reinforced concrete and concrete-concrete jointed interfaces from first principles using the concepts of dimensional analysis and self-similarity. Different crack growth laws are proposed to understand the behavior in each of the three regimes of the fatigue crack growth curve. Important crack growth characterizing material and geometrical parameters for each zone are included in the proposed analytical models. In real life applications to structures, the amplitude of cyclic loading rarely remains constant and is subjected to a wide spectrum of load amplitudes. Furthermore, the crack growth behavior changes in the presence of high amplitude load spikes within a constant amplitude history and this is incorporated in the model formulation. Using scaling laws, an improved understanding of the scaling behavior on different parameters is achieved. The models describing different regimes of crack propagation are finally unified to obtain the entire crack growth curve and compute the total fatigue life. In addition, crack growth analysis is performed for a reinforced concrete member by modifying the model derived for plain concrete in the Paris regime. Energy dissipation occurring due to shake-down phenomenon in steel reinforcement is addressed. The bond-slip mechanism which is of serious concern in reinforced concrete members is included in the study and a method is proposed for the prediction of residual moment carrying capacity as a function of relative crack depth. The application of the proposed analytical model in the computation of fatigue crack growth is demonstrated on three practical problems – beam in flexure, concrete arch bridge and a patch repaired beam. Through a sensitivity study, the influence of different parameters on the crack growth behavior is highlighted.

Cement - Fatigue Crack Propagation

Fatigue Crack Propagation Model

Reinforced Concrete Beams - Crack Growth

Concrete Fracture Mechanics

Concrete - Fatigue Crack Propagation

Crack Growth

Fatigue Crack Growth

Applied Mechanics

Víceúrovňové hodnocení křehkosti vybraných stavebních kompozitů / Complex evaluation of brittleness of selected building composites

Machačová, Denisa

January 2014

Specified topic of the thesis is a multilevel evaluation of brittleness of selected building composites. The work deals with the opinions of fracture parameters of test specimens of lightweight and ordinary concrete. Specimens further differed fibres content in concrete mixtures, their type and length. The work is divided into two parts, theoretical and practical. The theoretical part conceives composite materials and introduction to fracture mechanics. The practical part describes the different steps for fracture-mechanical parameters evaluation using StiCrack and Excel Visual Basic software. The main part of the work is to evaluate the brittleness of different test specimens, taking into account the type of concrete mix and type of fibres.

Rissbreitenentwicklung unter Langzeitbelastung anhand lokaler Verbundbeziehungen

Koschemann, Marc

10 November 2022

Das Rissverhalten von Stahlbeton wird maßgeblich durch die Verbundwirkung zwischen Bewehrung und Beton beeinflusst. Aktuelle Untersuchungen befassen sich mit der Rissbreitenentwicklung und Verbundspannungsverteilung unter Langzeitbelastung. Dabei werden verschiedene Betonsorten (fcm ≈ 30–70 MPa), drei unterschiedliche Probetypen sowie faseroptische Sensoren verwendet. In diesem Artikel sind der experimentelle und messtechnische Aufbau sowie die Ergebnisse der ersten Versuchsreihen im Vergleich zu bestehenden Verbundmodellen dargestellt. Darüber hinaus werden Einflüsse des Prüfkörpers und der Verbundlänge sowie die Möglichkeiten zur Erfassung des lokalen Verbundverhaltens mit faseroptischen Sensoren aufgezeigt.

info:eu-repo/classification/ddc/690

ddc:690

Fracture Characteristics Of Self Consolidating Concrete

Naddaf, Hamid Eskandari

07 1900

Self-consolidating concrete (SCC) has wide use for placement in congested reinforced concrete structures in recent years. SCC represents one of the most outstanding advances in concrete technology during the last two decades. In the current work a great deal of cognizance pertaining to mechanical properties of SCC and comparison of fracture characteristics of notched and unnotched beams of plain concrete as well as using acoustic emission to understand the localization of crack patterns at different stages has been done. An artificial neural network (ANN) is proposed to predict the 28day compressive strength of a normal and high strength of SCC and HPC with high volume fly ash. The ANN is trained by the data available in literature on normal volume fly ash because data on SCC with high volume fly ash is not available in sufficient quantity. Fracture characteristics of notched and unnotched beams of plain self consolidating concrete using acoustic emission to understand the localization of crack patterns at different stages has been done. Considering this as a platform, further analysis has been done using moment tensor analysis as a new notion to evaluate fracture characteristics in terms of crack orientation, direction of crack propagation at nano and micro levels. Analysis of B-value (b-value based on energy) is also carried out, and this has introduced to a new idea of carrying out the analysis on the basis of energy which gives a clear picture of results when compared with the analysis carried out using amplitudes. Further a new concept is introduced to analyze crack smaller than micro (could be hepto cracks) in solid materials. Each crack formation corresponds to an AE event and is processed and analyzed for crack orientation, crack volume at hepto and micro levels using moment tensor analysis based on energy. Cracks which are tinier than microcracks (could be hepto), are formed in large numbers at very early stages of loading prior to peak load. The volume of hepto and micro cracks is difficult to measure physically, but could be characterized using AE data in moment tensor analysis based on energy. It is conjectured that the ratio of the volume of hepto to that of micro could reach a critical value which could be an indicator of onset of microcracks after the formation of hepto cracks.

Concrete - Fracture Mechanics

Self-Consolidating Concrete (SCC)

Plain Concrete Beams - Fracture

Plain Concrete Beams - Acoustic Emission

Self-Consolidating Concrete - Properties

Artificial Neural Network (ANN)

Fly Ash

Un-notched Beams

Notched Beams

Hepto Cracks

Microcracks

Structural Engineering