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This research investigates the effects of steel fibers on the concrete breakout of the cast-in-place headed stud anchors in tension. High strength anchors (F1554 G105) is used in this study for varying steel fiber dosage of 0.0%, 0.5% and 1.0% by volume fraction of concrete. The physical properties of steel fiber reinforced concrete were calculated through various test at the Civil Engineering laboratory Building. In total, 9-cylinder specimens of 4" diameter and 8" height, and 9 beam specimens, 6"x6"x20" were made and tested. After 28 days of curing, the specimens were tested for their compressive strength and modulus of rupture, as well as 9-cylinder specimens of 6" diameter and 12" height to test for split tensile test. Nine headed stud anchors were installed and tested in the various mixtures. The depth of anchor embedment is kept constant, and the spacing between anchors is specified as per ACI 318-14. No grouping action was found. CCD method (ACI 318-14) is modified in order to predict the concrete breakout capacity of the cast-in-place anchor. The experiment revealed that the increase in dosage of fiber fraction increases the compressive strength of the concrete by 35% and 48% for 0.5% and 1% respectively compared from normal weight concrete without steel fibers. The breakout strength of concrete in tension increased by 77% for 0.5% volume fraction of steel fiber in concrete and increased 107% for 1.0% volume fractions of steel fiber in concrete in comparison with 0.0% Steel fiber reinforced concrete. It is found that the diameter of cone of concrete reduced as the dosage of steel fibers increased and the failure angle increased as the dosage of steel fibers increased.
Das Buch stellt den aktuellen Stand der kompletten Befestigungstechnik für Beton und Mauerwerk mit Einlegeteilen (Ankerschienen, Kopfbolzen), Dübeln (Metallspreizdübel, Hinterschnittdübel, Verbunddübel, Betonschrauben, Kunststoffdübel) und Setzbolzen umfassend dar. Die Befestigungselemente und ihre Wirkungsmechanismen werden ausführlich beschrieben und das Tragverhalten im ungerissenen und gerissenen Beton untersucht. Weiterhin werden das Korrosionsverhalten, das Verhalten bei Brandbeanspruchung sowie bei Erdbeben- und Schockbeanspruchung behandelt. Von besonderer internationaler Aktualität ist die Bemessung gemäß der europäischen und amerikanischen Normung. Praxisorientierte Kriterien zur Auswahl von Befestigungsmitteln und Bemessungsbeispiele runden das Werk zu einem einzigartigen Handbuch ab.
This research investigates the effect of anchor groups on concrete breakout strength within steel fiber reinforced concrete (SFRC) under tension load. High strength steel headed studs (F1554 Grade 105) in grouping action were cast-in-place within concrete specimens of different amounts of steel fibers. Four types of concrete mix designs were produced in the lab by using different amounts of steel fibers (0%, 0.5%, 1%, and 1.5%) by volume fraction of the mixture. The physical properties of steel fibers reinforced concrete were calculated through testing of specimens at the Civil Engineering Laboratory Building (CELB). In total, 12 cylinder specimens of 4-inch diameter and 8-inch height for compressive strength, 12 cylinder specimens of 6-inch diameter and 12-inch height for split tensile test, 12 beam specimens of 6*6*20 inch for modulus of rupture and flexural behavior. 4 concrete beams of 54*18*10 inch were cast-in-place with 12 sets of anchor groups were installed and tested after 28 days of curing. Embedment depth and distance between anchors for all group sets are kept constant. The effective embedment depth and the spacing between two anchors in grouping action are specified as per ACI 318-19.The experiments revealed that the increase of the amount of the steel fiber fraction increases the concrete breakout strength of anchor groups in tension by 43.33%, 73.42%, and 81.1% for 0.5%, 1.0%, and 1.5% volume fraction of steel fibers respectively. The research shows that the diameter of the concrete failure cone was reduced by increasing steel fibers. The failure angle increased by 14.6%, 48.5%, and 70% for 0.5%, 1.0%, and 1.5%. The concrete breakout strengths for anchor groups were compared with single anchors were tested at the same conditions. The anchors group effect reduces the concrete breakout strength by (19.45%, 16.8%, 15.7%, and 14%) for (0.0, 0.5, 1.0, and 1.5%) steel fiber compared with single anchor. Concrete compressive strength increased by (9.5%, 25.5%, and 17.5%) for (0.5%, 1%, and 1.5%) steel fibers respectively. The split tensile strength increased by (20.5%, 32.63%, and 35.35%) for (0.5%, 1%, and 1.5%) steel fibers and the flexural of concrete increased also by (3.7%, 9.8%, and 16.4%). Finally compare the experimental results of the concrete breakout strength with modified Concrete Capacity Design Method (CCD).
This study investigates the effects of Polypropylene fibers on the concrete breakout strength of cast in place anchors in shear under different loading rates. The steel headed anchors were cast within concrete specimens of different amounts of Polypropylene fibers. Four differing mixtures were produced using, 0, 0.5, 1, and 1.5% fibers by volume of the mixture. Their physical properties were calculated through testing at the Civil Engineering Laboratory Building. In total, 16 cylindrical specimens, 4" in diameter and 8" in height, and 6 beam specimens, 6"x6"x20" were produced and tested. After 28 days of curing, the specimens were tested for their compressive and tensile strengths, as well as their modulus of rupture. The results of the tests were then analyzed. It was discovered that as the fiber reinforcement approached 1% and over, the compressive strength of the concrete decreased which was attributed to reduce workability and increasing air voids from poor consolidation. In contrast, using Polypropylene fibers leads to increase the concrete tensile strength and the concrete shear breakout capacity for the anchor. Also, it's found that the cone of influence increase as the anchor embedded length or edge distance increase. Cone of influence control the anchor shear mode failure, once the cone of influence is high that leads to steel failure proceeded by concrete spall, for that mode of failure increasing fiber dosage 1.0% leads to decrease load failure 55% and decrease displacement 50%. Loading rate will play a major roll to determine the failure load, once the loading rate is higher that will provide a higher impact load, where increasing loading rate 150% leads to decrease load failure 25% and increase displacement 15%.
Mechanics of Structures and Materials: Advancements and Challenges is a collection of peer-reviewed papers presented at the 24th Australasian Conference on the Mechanics of Structures and Materials (ACMSM24, Curtin University, Perth, Western Australia, 6-9 December 2016). The contributions from academics, researchers and practising engineers from Australasian, Asia-pacific region and around the world, cover a wide range of topics, including: • Structural mechanics • Computational mechanics • Reinforced and prestressed concrete structures • Steel structures • Composite structures • Civil engineering materials • Fire engineering • Coastal and offshore structures • Dynamic analysis of structures • Structural health monitoring and damage identification • Structural reliability analysis and design • Structural optimization • Fracture and damage mechanics • Soil mechanics and foundation engineering • Pavement materials and technology • Shock and impact loading • Earthquake loading • Traffic and other man-made loadings • Wave and wind loading • Thermal effects • Design codes Mechanics of Structures and Materials: Advancements and Challenges will be of interest to academics and professionals involved in Structural Engineering and Materials Science.
There is no substitute for concrete that can be used on the same engineering scale. Its sustainability, exploitation and further development are necessary for a healthy economy and environment worldwide. Concrete must keep evolving to satisfy the increasing demands of all its users.
This volume highlights the latest advances, innovations, and applications in the field of fibre reinforced concrete (FRC) and discusses a diverse range of topics concerning FRC: rheology and early-age properties, mechanical properties, codes and standards, long-term properties, durability, analytical and numerical models, quality control, structural and Industrial applications, smart FRC’s, nanotechnologies related to FRC, textile reinforced concrete, structural design and UHPFRC. The contributions present improved traditional and new ideas that will open novel research directions and foster multidisciplinary collaboration between different specialists. Although the symposium was postponed, the book gathers peer-reviewed papers selected in 2020 for the RILEM-fib International Symposium on Fibre Reinforced Concrete (BEFIB).