Determination and applications of rock quality designation (RQD)

Zhang, Lianyang

06 1900

Characterization of rock masses and evaluation of their mechanical properties are important and challenging tasks in rock mechanics and rock engineering. Since in many cases rock quality designation (RQD) is the only rock mass classification index available, this paper outlines the key aspects on determination of RQD and evaluates the empirical methods based on RQD for determining the deformation modulus and unconfined compressive strength of rock masses. First, various methods for determining RQD are presented and the effects of different factors on determination of RQD are highlighted. Then, the empirical methods based on RQD for determining the deformation modulus and unconfined compressive strength of rock masses are briefly reviewed. Finally, the empirical methods based on RQD are used to determine the deformation modulus and unconfined compressive strength of rock masses at five different sites including 13 cases, and the results are compared with those obtained by other empirical methods based on rock mass classification indices such as rock mass rating (RMR), Q-system (Q) and geological strength index (GSI). It is shown that the empirical methods based on RQD tend to give deformation modulus values close to the lower bound (conservative) and unconfined compressive strength values in the middle of the corresponding values from different empirical methods based on RMR, Q and GSI. The empirical methods based on RQD provide a convenient way for estimating the mechanical properties of rock masses but, whenever possible, they should be used together with other empirical methods based on RMR, Q and GSI. (C) 2016 Institute of Rock and Soil Mechanics, Chinese Academy of Sciences. Production and hosting by Elsevier B.V.

Rock quality designation (RQD)

Rock mass classification

Deformation modulus

Unconfined compressive strength

Empirical methods

An Evaluation of the Confinement provided by PVC and Cardboard Pipes in unconfined detonation velocity measurements

Thomas, Tiju John

14 November 2006

Student Number : 9104308Y - Msc Eng research report - School of Mining Engineering - Faculty of Engineering and the Built Environment / African Explosives Limited (AEL) is involved with the Hybrid Stress Blast Model (HSBM) project in the characterisation of its bulk explosives and part of this involves the collection of unconfined detonation velocities (VoD). Historical methods of unconfined VoD measurements and earlier measurements taken for the HSBM project did not attribute significance to the strength of the light containment media used, which was either cardboard or PVC, in various wall thicknesses. The main focus of this exercise was to investigate this significance and to make recomendations to the HSBM on the choice of pipes for future tests. ANFO was used in order to avoid complexities of manufacturing and density variation, which arise with emulsion explosives. Plastic sleeves were used as a control in defining a medium of negligible confinement in order to compare the results in PVC and cardboard pipes. The cardboard pipes selected had wall thicknesses of 2mm and 4mm, while the PVC pipes had pressure ratings of 4 Bar and 9 Bar with wall thicknesses from 1.5mm to 8.5mm. The inner diameters ranged between 45mm and 253mm. The following findings have been made in this report. - Plastic sleeves were not effective in comparing the effects of confinement, but the results suggests that thin walled carboard pipes are probably very close to unconfined, even near the critical diameter. - PVC pipes affect VoD more than cardboard pipes and the confinement provided by both types of pipes increases with their wall thickness. - Critical diameter increases with weaker confinement and vice versa. - VoDs in the different types of confinement converge as diameter increases. - Future unconfined VoD tests should take cognisance of the findings of this project. A similar confinement investigation would be benificial to determine whether similar trends prevail with Emulsion and Emulsion-ANFO blend explosives. However if such an evaluation is not conducted, the minimum requirements for further tests should be to apply the confinement and diameter relationships as determined for ANFO during this investigation.

unconfined velocity of detonation

VOD

PVC

cardboard

ANFO

light confinement

media

critical diameter

Effect of Fluid Flow on Tissue-Engineered Cartilage in a Novel Bioreactor

Gemmiti, Christopher V.

10 November 2006

Due to its relative avascularity, low cellularity and lack of an undifferentiated cell reservoir, articular cartilage has a limited capacity for self-repair when damaged through trauma or disease. Articular cartilage impairment and the resultant reduced joint function affects millions of people at a substantial cost. In the U.S. alone, over 20 million adults are afflicted with osteoarthritis, costing more than $65 billion per year in health care and lost wages. Surgical techniques have been developed to address small, focal lesions, but more critical sized defects remain without a viable solution. Tissue engineering strategies produce cartilage-like constructs in vitro containing living cells in the hope of replacing damaged cartilage and restoring joint function. However, these constructs lack both sufficient integration into the surrounding tissue following implantation and the mechanical properties capable of withstanding the demanding and complex in vivo loading environment. Our central hypothesis is that exposure of engineered cartilage to fluid-induced shear stress increases the collagen content and mechanical properties (tensile and compressive). The overall objective of this project is to modulate the matrix composition and mechanical properties of engineered cartilage to be more like native tissue using a novel bioreactor. Improving the matrix components and mechanical stability of the tissue to be more similar to that of native tissue may aid in integration into a defect in vivo. The central hypothesis was proven in that shear stress potently altered the matrix composition, gene expression and mechanical properties of both thick and thin engineered cartilage. Modulation was found to be highly dependent on shear stress magnitude, duration, and waveform and affected different matrix constituents and mechanical properties in disparate ways. Our overall objective was satisfied on the basis that the bioreactor created stronger engineered tissues, but with the caveat that the tissues showed an increase in presence of type I collagen. Such an effect would be undesirable for articular cartilage engineered tissues, but could be very beneficial in fibrocartilaginous tissues such as that found in the temporomandibular joint. In conclusion, the novel bioreactor system provides a flexible platform technology for the study of three-dimensional engineered tissues, not just articular cartilage.

Type I collagen

Type II collagen

Young's modulus

Dynamic modulus

Unconfined compression

Complete Recycling and Utilization of Waste Concrete Through Geopolymerization

Ren, Xin

January 2015

This research investigates complete recycling and utilization of waste concrete to produce new structural concrete through geopolymerization. The investigation was conducted through both macro-and micro/nano-scale studies. First the geopolymer paste synthesized using a mixture of waste concrete fines (WCF) and class F fly ash (FA) as the source material and a mixture of NaOH solution (N) and Na2SiO3 solution (SS) as the alkaline activating agent was studied. Various NaOH concentrations, SS/N ratios, and WCF contents were used to produce geopolymer paste specimens in order to study their effect on the properties of the geopolymer paste. Uniaxial compression tests were conducted to measure the strength of the geopolymer paste specimens. X-ray diffraction (XRD), scanning electron microscopy/energy dispersive X-ray spectroscopy (SEM/EDX), and Fourier transform infrared spectroscopy (FTIR) analyses were performed to investigate the micro/nano-structure, morphology and phase/surface elemental compositions of the geopolymer paste and the effect of calcium (Ca) on them. The results indicate that by using 10 M NaOH solution, SS/N of 2 and 50% WCF, the highest geopolymer paste strength can be obtained. Second, the interfacial transition zones (ITZs) between geopolymer (GP) and recycled aggregates (RA) were studied. Considering that RA consist of the stone particles and the attached paste/mortar from the original ordinary Portland cement (OPC) concrete, both the ITZs between GP and natural aggregate (NA) and those between GP and residual OPC paste/mortar (ROPM) were studied. For comparison, the ITZs between OPC paste and NA and those between OPC paste and ROPM were also investigated. 4-point bending tests were conducted to measure the bonding strength of the different types of ITZs at water to solid (W/S) ratio of 0.30, 0.35 and 0.40 for the geopolymer and OPC pastes after 7 and 14 days curing, respectively. SEM imaging was performed to investigate the microstructure of the ITZs. The results indicate that when NA is used, the bonding strength of both the GP-NA and OPC-NA ITZs decreases with higher water to solid (W/S) ratio. When ROPM is used, higher W/S ratio leads to smaller bonding strength for the GP-ROPM ITZ but greater bonding strength for the OPC-ROPM ITZ. Based on the measured bonding strength values for NA- and ROPM-based ITZs, the bonding strength of the GP-RA and OPC-RA ITZs was estimated by considering the average area coverage of ROPM on the RA surface. The GP-RA ITZ has the highest bonding strength among the different ITZs, implying the great potential for utilizing waste concrete (both the WCF and the RA) to produce geopolymer concrete. Third, based on the studies on geopolymer paste and ITZs, geopolymer concrete (GPC) was produced and studied using WCF and FA as the cementitious material and RA as the aggregate. For comparison, GPC using NA was also produced and studied at similar conditions. Various NaOH concentrations, SS/N ratios, and cement (WCF and FA) to aggregate (C/A) ratios were used to produce GPC specimens in order to study their effect on the behavior of GPC. The effect of water content and curing temperature on the initial setting time and 7-day unconfined compressive strength (UCS) of the GPC was also studied. The results show that the GPC produced from RA has higher UCS than the GPC from NA at both room curing temperature and 35°C curing temperature. Based on this study, it can be concluded that waste concrete can be completely recycled and used to produce new structural concrete based on the geopolymerization technology. Fourth, considering that the Si/Al and Na/Al ratios have great effect on the geopolymerization process and the properties of the final geopolymer product, a study was conducted on copper mine tailings (MT)-based geopolymer containing different amount of aluminum sludge (AS). The results indicate that by including AS and utilizing appropriate amount of NaOH, the UCS can be increased significantly. The main reason is because the addition of AS along with utilization of appropriate amount of NaOH makes both the Si/Al and Na/Al ratios reach the optimum values for geopolymerization, leading to higher degree of geopolymerization and more compact geopolymer microstructure. It is noted that although this study is not directly on waste concrete, it provides useful information for optimizing the design on complete recycling and utilization of waste concrete to produce new GPC. Finally, to better understand the effect of Ca on the geopolymerization process and the properties of geopolymer, molecular dynamics (MD) simulations were performed on geopolymer at different Ca contents. The molecular models at different Ca contents were constructed and uniaxial compression test was then performed on the numerical specimens. The results indicate that MD simulation is an effective tool for studying the effect of Ca on the properties of geopolymer at nano-scale.

Geopolymer

Molecular dynamics

Recycled aggregate

Unconfined compressive strength

Waste concrete

Civil Engineering

Fly ash

Έμμεσος προσδιορισμός της θλιπτικής αντοχής πετρωμάτων με την δοκιμή της επιφανειακής διείσδυσης / Indirect measurement of the compressive strength of rocks from the indentation (punch) test

Σκούρας, Νικόλαος

14 May 2007

Παρουσιάζεται μία εναλλακτική μέθοδος έμμεσου προσδιορισμού της θλιπτικής (μονοαξονικής) αντοχής των πετρωμάτων με βάση μία τροποποιημένη μορφή της δοκιμής επιφανειακής διείσδυσης. Χρησιμοποιήθηκαν δύο έμβολα με σφαιρικά άκρα με ακτίνες 1,585mm και 5mm. Τα αποτελέσματα συγκρίνονται με αυτά της διαδεδομένης μεθόδου σημειακής φόρτισης. Αποδεικνύεται πειραματικά ότι για τα τρία ασβεστολιθικά πετρώματα που μελετήθηκαν, η δοκιμή επιφανειακής διείσδυσης δίνει σημαντικά ακριβέστερα αποτελέσματα και μπορεί να εφαρμοστεί τόσο στο εργαστήριο όσο και στο πεδίο. Επιπλέον αποδείχθηκε ότι η δοκιμή προσφέρει την δυνατότητα μη καταστροφικού ελέγχου των δοκιμίων ιδιαίτερα με το άκρο με την μικρή σφαίρα. / An alternative indirect method to determine the unconfined compressive strength of rocks based on a modified Indentation (Punch) test is presented. Two indenters with spherical tips of 1.585mm and 5mm were used. The results are compared with those of the Point Load test that is commonly used in practice. It is experimentally proved that for the three calcareous rock materials tested, this method gives significantly more accurate results and can be applied to the laboratory as well as in situ. In addition it has been proved that this test offers the possibility of non destructive testing especially when the small spherical tip is used.

620.112 6

Indentation test

Unconfined compressive strength

The Dynamics of Groundwater Flow and Salinity Transport in Unconfined Coastal Aquifers / 海岸不圧帯水層における地下水流動と塩分輸送過程に関する研究

Kriyo, Sambodho

25 January 2010

Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第15034号 / 工博第3183号 / 新制||工||1479(附属図書館) / 27495 / 京都大学大学院工学研究科社会基盤工学専攻 / (主査)教授 関口 秀雄, 教授 間瀬 肇, 教授 後藤 仁志 / 学位規則第4条第1項該当

Groundwater flow

Saline transport

tide fluctuation

groundwater-level fluctuation

unconfined aquifers

500

Évaluation des propriétés mécaniques d’un sol traité au ciment / Evaluation of the mechanical properties of a soil-mixing material

Szymkiewicz, Fabien

04 October 2011

Le Soil-Mixing consiste à traiter le sol avec un liant hydraulique en le mélangeant mécaniquement en place pour améliorer ses propriétés mécaniques. Son coté économique ainsi que son faible impact environnemental ont fait de cette méthode jusque là cantonnée à l'amélioration de sols compressibles ou à forte teneur en matière organique une alternative attrayante aux méthodes traditionnelles de renforcements des sols, de soutènements (temporaires voire définitifs), de fondations et de travaux d'étanchéités. Mais avec cette augmentation de la demande, les exigences nouvelles concernant la méthode et le matériau sont apparues.De nombreuses études permettent d'apporter des éléments de réponses. Cependant, il n'existe pas d'étude paramétrique globale étudiant à la fois l'impact du type de sol et de la quantité d'eau sur la caractérisation du matériau Soil-Mixing et qui permettrait d'améliorer les méthodes de dosage ainsi que les méthodes de dimensionnement des ouvrages en Soil-Mixing.Un mélange sol-ciment est composé majoritairement de sol. Le ciment ne représentera au maximum que 30% du mélange. L'approche adoptée est donc plutôt celle du domaine de la géotechnique que des bétons hydrauliques. Nous avons pris le parti de baser notre travail sur une étude de laboratoire, en réalisant des mélanges dits “de référence”. Trois sables et cinq sols fins ont été traités en faisant varier à chaque fois les quantités de ciment et d'eau, afin d'observer l'influence de la granulométrie, de l'argilosité et de la quantité d'eau présente dans le mélange sur la résistance, la rigidité et la déformation à la rupture du matériau. Par ailleurs, des sols reconstitués à base de sable et de sol fin ont été traités afin d'étudier l'impact des fines et de leur nature sur la résistance du matériau. En parallèle, le suivi de différents chantiers nous a permis d'étudier la mise en œuvre de la méthode, l'homogénéité du matériau réalisé in situ, et de comparer les résultats obtenus avec ceux de l'étude paramétrique. Les retombées de ce travail sont la création d'abaques reliant la résistance au dosage en ciment et au rapport C/E, ainsi qu'un tableau de synthèse de données expérimentales des différentes propriétés mécaniques du matériau Soil-Mixing (en fonction de la nature du sol rencontré), et des formules permettant pour les sols grenus de prédire la résistance à 7 et 28 jours en fonction du pourcentage de fines dans le sol et du dosage en ciment / The Soil-Mixing consists in mixing a hydraulic binder into the soil mechanically in order to improve its mechanical properties. Because of its economical as well as its sustainable advantages, this method so far confined to the improvement of compressible or high organic content soils has become an attractive alternative to traditional methods for soil reinforcement, retaining walls (temporary or final), foundations and cutoff walls. But these new applications imply new requirements on the method as well as on the material. Many studies on the subject provide some answers. However, there is no comprehensive parametric study examining both the impact of soil type and the amount of water on the characterization of the Soil-Mixing material and would improve the testing methods and methods for design of structures in Soil-Mixing.Soil-cement mixtures are predominantly composed of soil. The cement will represent at most 30% of the mixture. That is why we have chosen to follow a geotechnical approach rather than the concrete approach for this project.We followed an experimental program based on a laboratory study, realizing mixes called "reference" mixes. Three sand soil and five fine soils were treated by varying each time the quantities of cement and water to observe the influence of particle size, clay content and the amount of water present in the mixes on the resistance of the material, stiffness and failure strain. In addition, soils made from sand and fine soils were reconstituted and treated to study the impact of fines and their nature on the strength of the material.In parallel, monitoring of various projects has enabled us to study the implementation of the method, the homogeneity of the material produced in situ, and to compare the results with those of the parametric study. The results of this work are the creation of abaci connecting the resistance to the cement content and C/E ratio, and a summary table of experimental data of different mechanical properties of the Soil-Mixing material (depending on the nature of the soil), and formulas for granular soils predicting the strength after 7 and 28 days of curing depending on the percentage of fines in the soil and on cement content

Sol

Ciment

Résistance à la compression

Soil-Mixing

Soil

Cement

Unconfined compression strength

Soil-Mixing

Evaluation of groundwater flow theories and aquifer parameters estimation

Xiao, Liang

January 2014

Philosophiae Doctor - PhD / This thesis deals with some fundamental aspects of groundwater models. Deterministic mathematical models of groundwater are usually used to simulate flow and transport processes in aquifer systems by means of partial differential equations. Analytical solutions for the deterministic mathematical models of the Theis problem and the transient confined-unconfined flow in a confined aquifer are investigated in the thesis. The Theis equation is a most commonly applied solution for the deterministic mathematical model of the Theis problem. In the thesis, a most simplified similarity transformation method for derivation of the Theis equation is proposed by using the Boltzmann transform. To investigate the transient confined-unconfined flow towards a fully penetrating well in a confined aquifer, a new analytical solution for the deterministic mathematical models of interest is proposed in the thesis. The proposed analytical solution considers a change of hydraulic properties (transmissivity and storativity) during the confined-unconfined conversion. Based on the proposed analytical solution, a practical method to determine distance of the conversion interface from pumping well and diffusivity of the unconfined region is developed by using a constant rate test. Applicability of the proposed analytical solution is demonstrated by a comparison with previous solutions, namely the MP and the Chen models. The results show that the proposed analytical solution can be used to assess the effect of the change of diffusivity on the transient confined-unconfined flow. The MP model is only accepted if the transmissivity during the confined-unconfined conversion is constant. The Chen model, given as a special case of the proposed analytical solution, is limited to the analysis of the transient confined-unconfined flow with a fixed diffusivity. An important application of groundwater models is to estimate parameters, such as hydraulic properties and flow dynamics, of groundwater systems by assessing and analysing field data. For instance, the pumping and the hydrochemistry and environmental tracer tests are two effective ways to obtain such data. To evaluate hydraulic properties of aquifer systems by derivative interpretation of drawdown data from pumping tests, a new diagnostic analysis method is proposed based on a lg-lg drawdown derivative, dlgs/dlgt, and the differentiation algorithm namely Lagrange Interpolation Regression (LIR) in the thesis. Use of a combined plot of dlgs/dlgt and a semi-lg drawdown derivative (ds/dlgt) is made to identify various flow segments during variable discharge tests with infinite conditions, constant rate tests in bounded aquifers and tests involving double-porosity behaviours. These can be applied to further characterize pumped aquifers. Compared to traditional diagnostic analysis method using plot of ds/dlgt alone, the combined drawdown derivative plot possesses certain advantages identified as: (1) the plot of dlgs/dlgt is strikingly sensitive for use in unveiling differences between pumping and its following recovery periods in intermittent variable discharge tests; (2) storativity (S) of pumped aquifers can be evaluated by using the combined plot; and (3) quantitative assessments of double-porosity behaviours can also be achieved. Based on two case studies, advantages and disadvantages of uses of the LIR and other existing differentiation methods in calculations of numerical drawdown derivative are demonstrated in practice. The results suggest that the LIR is a preferred method for numerical differentiation of drawdown data as it can be used to effectively minimise noisy effects. The proposed derivative approach provides hydrologists with an additional tool for characterizing pumped aquifers. Use of hydrochemistry and environmental tracer tests to assess flow dynamics of groundwater systems is demonstrated via a case study in the dolomite aquifer of South Africa. An emphasis is on determining mean residence times (MRTs) of the dolomite aquifer by means of an appropriate box model with time series of 14C values of dissolved inorganic carbon (14C-DIC) and initial 14C activities of spring samples during 1970s and 2010s. To obtain the calibrated 14C MRTs, 13C values of dissolved inorganic carbon (δ13C-DIC) of the spring samples are applied to estimate mineral dissolution in the dolomite aquifer and calculate the initial 14C activities. The results indicate that the spring samples have about 50%-80% initial 14C activities. By using the appropriate box model, the calibrated 14C MRTs of the spring system are given within a range from ≤ 10 to 50 years. Additionally, the flow dynamics, including the recharge source and area, the effect of climate change on the temporal trend of the groundwater MRTs and the groundwater flow circulation, of the dolomitic spring system are also discussed for further possible management interventions in the dolomite aquifer.

Deterministic mathematical models

Theis problem

Transient confined-unconfined flow

Groundwater flow

Poroelastic Finite Element Analysis of a Heterogeneous Articular Cartilage Explant Under Dynamic Compression in ABAQUS

Kam, Kelsey Kiyo

01 June 2011

A poroelastic finite element model of a heterogeneous articular cartilage disc was created to examine the tissue response to low amplitude (± 2% strain), low frequency (0.1 Hz) dynamic unconfined compression (UCC). A strong correlation has been made between the relative fluid velocity and stimulation of glycosaminoglycan synthesis. A contour plot of the model shows the relative fluid velocity during compression exceeds a trigger value of 0.25 μm/s at the radial periphery. Dynamic UCC biochemical results have also reported a higher glycosaminoglycan content in this region versus that of day 0 specimens. Fluid velocity was also found not to be the dominant physical mechanism that stimulates collagen synthesis; the heterogeneity of the fluid velocity contour plot conflicts with the homogeneous collagen content from the biochemical results. It was also found that a Tresca (shear) stress trigger of 0.07 MPa could provide minor stimulation of glycosaminoglycan synthesis. A feasibility study on modeling a heterogeneous disc was conducted and found convergence issues with the jump in properties from the superficial to middle layers of the disc. It is believed that the superficial layer contains material properties that allow the tissue to absorb much of the compressive strain, which in turn increases pressure and causes convergence issues in ABAQUS. The findings in this thesis may help guide the development of a growth and remodeling routine for articular cartilage.

poroelastic

FEA

dynamic unconfined compression

fluid velocity

articular cartilage

Biomechanical Engineering

Investigation of granular materials deformations under an unconfined compaction with x-ray computed tomography.

Li, Zhu

January 2013

The behavior of the asphalt mixtures under large deformations, for example an unconfined compaction is of high practical importance. Quantitative measurement of the spatial distribution of internal structure of asphalt mixtures is crucial to study deformation behavior of asphalt mixtures. Deformation of granular material under an unconfined compaction is investigated in this study, as a groundwork for further research on deformation behavior of asphalt mixtures. Two sets of 3D images of specimens are obtained using X-Ray computed tomography (CT) under an unconfined compaction. Digital image analysis procedure is developed to segment different phases for characterizing spatial distribution of internal structure. Comparative volumetric relationship before and after compaction showed that air void distribution is not changed heavily due to absence of interlocking. Initial and final spatial positions of individual granules are investigated to trace their movement under compaction. It is shown that X-Ray CT could be a useful tool to characterize internal structure of asphalt mixtures and its evolution during deformation.

X-Ray Computed Tomography

Unconfined compaction

Digital image

Engineering and Technology

Teknik och teknologier