Shear Capacity of Steel Fibre Reinforced Concrete Beams without Conventional Shear Reinforcement

Mondo, Eleonora

January 2011

While the increase in shear strength of Steel Fibre Reinforced Concrete (SFRC) is well recognized, it has yet to be found common application of this material in building structures and there is no existing national standard that treats SFRC in a systematic manner. The aim of the diploma work is to investigate the shear strength of fibre reinforced concrete beams and the available test data and analyse the latter against the mostpromising equations available in the literature. The equations investigated are:Narayanan and Darwish’s formula, the German, the RILEM and the Italian guidelines. Thirty articles, selected among over one hundred articles taken from literature, have been used to create the database that contains almost 600 beams tested in shear. This large number of beams has been decreased to 371 excluding all those beams and test that do not fall within the limitation stated for this thesis. Narayanan and Darwish’s formula can be utilized every time that the fibre percentage, the type of fibres, the beam dimensions, the flexural reinforcement and the concrete strength class have been defined. On the opposite, the parameters introduced in the German, the RILEM and the Italian guidelines always require a further characterization of the concrete (with bending test) in order to describe the post‐cracking behaviour. The parameters involved in the guidelines are the residual flexural tensile strengths according to the different test set‐ups. A method for predicting the residual flexural tensile strength from the knowledge of the fibre properties, the cylindrical compressive strength of the concrete and the amount of fibres percentage is suggested. The predictions of the shear strength, obtained using the proposed method for the residual flexural tensile strength, showed to be satisfactory when compared with the experimental results. A comparison among the aforementioned equations corroborate the validity of the empirical formulations proposed by Narayanan and Darwish nevertheless only the other equations provide a realistic assessments of the strength, toughness and ductility of structural elements subjected to shear loading. Over the three investigated equations, which work with the post‐cracking characterization of the material, the Italian guideline proposal is the one that, due to its wide domain of validity and the results obtained for the gathered database of beams, has been selected as the most reliable equation.

Steel Fibre Reinforced Concrete

shear

Narayanan and Darwish´s Equation

RILEM

CNR

DafStB

post-cracking

flexural tensile strength

Civil Engineering

Samhällsbyggnadsteknik

Behaviour and design of direct-formed hollow structural section members

Tayyebi, Kamran

06 July 2021

In North America, cold-formed square and rectangular hollow sections (collectively referred to as RHS hereinafter) of commonly specified cross-sectional dimensions are produced using either the indirect-forming approach or the direct-forming approach. The indirect-forming approach, as the conventional approach of the two, consists of three steps: (i) roll-forming the coil material progressively into a circular hollow section; (ii) closing the section using electric resistance welding (ERW); and (iii) reshaping the circular section into the final square or rectangular shape. On the other hand, the direct-forming approach, as the new approach of the two, roll-forms the coil material directly into the final square or rectangular shape. RHS with similar cross-sectional dimensions but different production histories (i.e., different cold-forming approaches and post-production treatments) are expected to have significantly different material and residual stress properties. However, RHS design provisions in the existing North American steel design standards (AISC 360-16 and CSA S16-19) are in general developed based on research on indirect-formed RHS and currently do not differentiate RHS cold-formed by different approaches. Based on the research presented in Chapter 1 of this thesis, comparing to indirect-formed RHS, direct-formed RHS in general contain lower levels of residual stresses around cross sections, since the flat faces are not severely cold worked during production. This in turn affects member behaviours under compressive and flexural loadings. The test results presented in Chapters 2 and 4 show that direct-formed RHS have superior stub column and beam behaviours, comparing to their indirect-formed counterparts. In particular, the stub column and beam testing programs, covering a wide range of cross-section dimensions and two strength grades (nominal yield stresses of 350 and 690 MPa), show that the slenderness limits in the existing North American steel design standards are excessively conservative for direct-formed RHS, resulting in unnecessary penalty and member strength underestimation. As a result, the existing design formulae are not suitable for direct-formed RHS. In response to this, subsequent finite element (FE) parametric investigations are performed and presented in Chapters 3 and 5. Modified stub column and beam design recommendations for direct-formed regular- and high-strength RHS are proposed. The effects of post-cold-forming hot-dip galvanizing on material properties, residual stresses, stub column behaviours and beam behaviours of direct-formed regular- and high-strength RHS are also studied in Chapters 1-5 of this thesis. Similar to the application of the heat treatment per ASTM A1085 Supplement S1 or the Class H finish per CSA G40.20/G40.21, post-cold-forming galvanizing improves the stub column (Chapter 2) and beam (Chapter 4) behaviours of direct-formed RHS via effective reduction of residual stresses (Chapter 1). Based on subsequent FE parametric investigations, modified stub column and beam design recommendations catering to galvanized direct-formed RHS are proposed in Chapters 3 and 5. / Graduate

Rectangular hollow section

Direct forming

Galvanizing

High-strength steel

Flexural design

Compressive design

Cold forming

Material properties

Lateral Stability Analysis of Precast Prestressed Bridge Girders During All Phases of Construction

Sathiraju, Venkata Sai Surya Praneeth

25 July 2019

No description available.

Civil Engineering

Prestress

Lateral stability

zero point 7in prestress strand

Biaxial Flexure

Bridge Girders

Weak axis flexural capacity

Study on Epoxidized Poly (Styrene-butadiene-styrene) Modified Epoxy Resins

Wu, Jiawei

January 2019

No description available.

Chemistry

Polymers

Materials Science

Mechanical Engineering

Krouse Fatigue for Metals with Elevated Mean Stress

Williams, Zachary

January 2020

No description available.

Engineering

Mechanical Engineering

Materials Science

Fatigue

Bending

Flexural

Krouse

Displacement

Axial

Mean Stress

Metal

Stainless Steel

Titanium

Inconel

Böjhållfastheten hos flerskiktade zirkoniamaterial beroende på sintringsprogram / Flexural strength of a multilayer zirconia depending on the sintering program

Tusoh, Anisa, Bischof Tillström, Johanna

January 2022

Aim: The aim of the present study was to evaluate how the material KATANA ™ Zirconia YML is affected in strength depending on two different sintering programs. The evaluation of the strength was made by means of a biaxial flexural strength test.   Material and method: A total of 48 test specimens, 32 specimens were produced by KATANA ™ Zirconia YML and 16 specimen cups that formed the control group, by KATANA ™. Zirconia UTML. The specimens were designed as circular disks and were placed in two different layers in the disk, between Enamel-Body 1 and Body 2-Body 3. The specimens were divided into two subgroups of which 24 specimens were quickly sintered and the remaining (n = 24) specimens were conventionally sintered and the strength was evaluated with a biaxial flexural strength test.   Results: The highest mean value for the biaxial flexural strength test was shown by the test group which was high-speed sintered, with placement in Body 2 - Body 3. This was significant in comparison with other groups (p> 0.001) in addition to conventional sintered with the same placement in the disk. Both control groups showed low mean values ​​in comparison with the test groups, control group K (414 MPa) as the lowest in comparison with all other groups. When comparing the two control groups S and K, no significant difference was shown.   Conclusion: The bending strength varies depending on which layers are loaded regardless of fast and conventional sintering. The sintering parameters are significant for the bending strength. / Syfte: Syftet med föreliggande studie var att utvärdera hur materialet KATANA™ Zirconia YML påverkas i hållfasthet beroende av två olika sintringsprogram. Utvärderingen av hållfastheten gjordes med hjälp av ett biaxialt böjhållfasthetstest.   Material och metod: Totalt framställdes 48 provkroppar, 32 stycken framställdes av KATANA™ Zirconia YML och 16 provkoppar som utgjorde kontrollgrupp, av KATANA™. Zirconia UTML. Provkropparna var utformade som cirkulära diskar och dem placerades i två olika skikt i disken, mellan Enamel-Body 1 och Body 2-Body 3. Provkropparna delades in i två undergrupper varav 24 provkroppar snabbsintrades och resterande (n=24) provkroppar sintrades konventionellt och hållfastheten utvärderades med ett biaxialt böjhållfasthetstest.   Resultat: Högst medelvärde för det biaxiala böjhållfasthetstestet uppvisade testgruppen som snabbsintrats, med placering i Body 2 – Body 3. Detta var signifikant i jämförelse med övriga grupper (p > 0,001) förutom konventionellt sintrat med samma placering i disken. Båda kontrollgrupperna uppvisade låga medelvärden i jämförelse med testgrupperna, kontrollgrupp K (414 MPa) som lägst i jämförelse med alla övriga grupper. Vid jämförelse mellan de två kontrollgrupperna S och K uppvisades inte någon signifikant skillnad.   Slutsats: Böjhållfastheten varierar beroende på vilka skikt som belastas oavsett snabb- respektive konventionell sintring. Sintringsparametrarna är betydande för böjhållfastheten.

Conventional sintering

flexural strength

high-speed sintering

multilayer

zirconia

Böjhållfasthet

flerskiktad zirkonia

konventionell sintring

snabbsintring

zirkonia

Dentistry

Odontologi

The effect of a novel photoinitiator system (RAP) on dental resin composites' flexural strength, polymerization stress, and degree of conversion

Schaub, Kellie

January 2009

Indiana University-Purdue University Indianapolis (IUPUI) / Objectives: A new technology has been introduced into the field of dental resin composites that professes to enhance light-curing efficiency. Rapid amplified photopolymerization (RAP) initiator technology has not yet been fully compared with resin composites with conventional initiators such as camphorquinone (CQ). The purpose of this study was to compare and contrast the effects of this novel technology (RAP) on properties of two light-cured resin composites. Flowable (EFQ) and microfilled (ESQ) experimental composites were fabricated and supplied from Tokuyama Dental with (w/RAP) and without RAP (w/o RAP). The flexural strength (MPa) and flexural modulus (MPa) were obtained using a three-point bending apparatus (Sintech Renew 1123, Instron Engineering Corp., Canton, MA). Polymerization stress curves were created using a tensometer (American Dental Association Health Foundation, NIST, Gaithersburg, MD) which were then used to calculate the maximum stress rate. Finally, the degree of conversion was measured using infrared spectroscopy (Jassco FT-IR spectrometer, Model: 4100, Jasco Corporation, Tokyo, Japan). When evaluating the flexural strength, the peak stress for EFQ w/RAP was significantly higher than EFQ w/o RAP (p = 0.0001). This was statistically not significant for the ESQ group, even though ESQ w/RAP did have a higher peak stress then ESQ w/o RAP (p = 0.28). The interaction between resin type and RAP was not significant when evaluating the flexural modulus (p = 0.21). Formulations with RAP had a significantly higher flexural modulus then w/o RAP (p = 0.0001). Experimental resins with RAP had significantly higher maximum stress rates than those w/o RAP when evaluating polymerization stress (p = 0.0001). Finally, groups w/ RAP appeared to have a higher degree of conversion than groups without (p = 0.0057). This study showed that the experimental composites with RAP had greater mechanical properties than those without. Unfortunately, the increase in polymerization stress causes concern clinically due to the chance of leakage at the restoration/tooth interface. One of the main potential disadvantages of this new RAP technology is an increase in the polymerization stress. Deciding if this amount of polymerization stress is clinically acceptable is yet to be accomplished.

dental resin composites

flexural strength

polymerization stress

degree of conversion

photoinitiation

Composite Resins -- chemistry

Dental Stress Analysis

Stress, Mechanical

Light

Structural Properties of ICLT Wall Panels Composed of Beetle Killed Wood

Wilson, David Edward

06 June 2012

Interlocking Cross Laminated Timber (ICLT) wall panels are a new wood construction product similar to Cross Laminated Timber panels. Besides being an innovative structural system, they also utilize beetle killed timber from many of the forests that have been devastated by the Mountain Pine Beetle. Three tests were performed on three ply ICLT panels measuring 8 feet (2.44m) wide, 8 feet (2.44m) tall and 8.5 inches (21.6cm) thick to determine the racking, flexural and axial strengths of the wall panels. After each test was performed the walls were disassembled and investigated for cause of failure. Using the data from the tests as a benchmark, simple analytical models to predict the design capacities of the walls for racking, flexural, and axial strengths were established. The analytical models for racking strength, flexural strength and axial strength predicted reasonably well the measured strength values. Additional testing is necessary to increase the available database, further validate the analytical models developed, better understand the structural performance of ICLT panels, and establish acceptable design methodology for ICLT wall panels.

ICLT

beetle killed

blue stain

mechanical properties

analytical model

racking strength

flexural strength compressive strength

Civil and Environmental Engineering

Flexural behavior of ECC–concrete hybrid composite beams reinforced with FRP and steel bars

Ge, W-J., Ashour, Ashraf, Yu, J., Gao, P., Cao, D-F., Cai, C., Ji, X.

09 November 2018

Yes / This paper aims to investigate the flexural behavior of engineered cementitious composite (ECC)-concrete hybrid composite beams reinforced with fiber reinforced polymer (FRP) bars and steel bars. Thirty two hybrid reinforced composite beams having various ECC height replacement ratio and combinations of FRP and steel reinforcements were experimentally tested to failure in flexure. Test results showed that cracking, yield and ultimate moments as well as the stiffness of hybrid and ECC beams are improved compared with traditional concrete beams having the same reinforcement, owing to the excellent tensile properties of ECC materials. The average crack spacing and width decrease with the increase of ECC height replacement ratio. The ductility of hybrid reinforced composite beams is higher than that of traditional reinforced concrete beams while their practical reinforcement ratios are similar. Reinforced ECC beams show considerable energy dissipation capacity owing to ECC’s excellent deformation ability. Considering the constitutive models of materials, compatibility and equilibrium conditions, formulas for the prediction of cracking, yield and ultimate moments as well as deflections of hybrid reinforced ECC-concrete composite beams are developed. The proposed formulas are in good agreement with the experimental results. A comprehensive parametric analysis is, then, conducted to illustrate the effect of reinforcement, ECC and concrete properties on the moment capacity, curvature, ductility and energy dissipation of composite beams. / National Natural Science Foundation of China (51678514, 51308490), the Natural Science Foundation of Jiangsu Province, China (BK20130450), Six Talent Peaks Project of Jiangsu Province (JZ-038, 2016), Graduate Practice Innovation Project of Jiangsu Province (SJCX17-0625), the Jiangsu Government Scholarship for Overseas Studies and Top-level Talents Support Project of Yangzhou University

Engineered cementitious composite (ECC)

Concrete

Composite beams

Hybrid reinforcement

Flexural behavior

Steel bars

Fiber-reinforced polymer (FRP) bars

Development of Methods to Validate the Effectiveness of Self-Healing Concrete and Microbial Nutrients

Dahal, Puskar Kumar

04 December 2022

No description available.

Civil Engineering

Engineering

Materials Science