DEVELOPMENT, CHARACTERIZATION, AND MODELING OF PHYSICAL, MECHANICAL, AND DURABILITY PROPERTIES OF SUSTAINABLE ULTRA-HIGH PERFORMANCE CONCRETE

Hasan, Tawsif Mohammad

27 July 2022

No description available.

Civil Engineering

Ultra-High Performance Concrete

Sustainability

Durability

Eco-friendly UHPC

Mechanical Properties and Durability of Sustainable UHPC Incorporated Industrial Waste Residues and Sea/Manufactured Sand

Ge, W., Zhu, S., Yang, J., Ashour, Ashraf, Zhang, Z., Li, W., Jiang, H., Cao, D., Shuai, H.

02 November 2023

Yes / Considering the continuous development of sustainable development, energy saving, and emission reduction concepts, it is very important to reduce concrete's cement content in order to improve its environmental impact. Using reactive admixture to replace part of the cement in ultra-high performance concrete (UHPC) can effectively improve the overall performance of the concrete and reduce carbon dioxide emissions (CO2), which is an important aspect of environmental protection. Here, industrial waste residue (fly ash and slag), sea sand (SS), and manufactured sand (MS) were used to produce UHPC under standard curing condition, to reduce the material cost and make the it more environmentally friendly and sustainable. The effects of water-binder ratio, contents of cementitious materials, types of sands, and content of steel fibers on the mechanical performance of UHPC under standard curing were investigated experimentally. In addition, the effects of various factors on the depth under hydraulic pressure and electric flux of UHPC, mass loss, relative dynamic modulus of elasticity, flexural, and compressive strengths of UHPC specimens after freeze-thaw cycles were conducted to evaluate the impermeability, chloride, and freeze-thaw resistance of various UHPCs produced. The obtained experimental results show that the SS-UHPC and MS-UHPC prepared by standard curing exhibit high strength, excellent impermeability, and chloride resistance. The frost resistant grade of all groups of UHPCs prepared by standard curing are greater than F500 and had excellent freeze-thaw resistance, including those produced with local tap water or artificial seawater. The investigation presented in this paper could contribute to the production of new UHPCs of low cost and environmental-friendly and accelerate the application of UHPC in engineering structures.

Ultra-high performance concrete (UHPC)

Mineral admixtures

Mechanical property

Durability

Standard curing

Flexural performance of prefabricated U-shaped UHPC permanent formwork - concrete composite beams reinforced with FRP bars

Ge, W., Zhang, Z., Ashour, Ashraf, Li, W., Jiang, H., Hu, Y., Shuai, H., Sun, C., Qiu, L., Yao, S., Cao, D.

16 March 2023

Yes / Finite element (FE) analysis of fiber-reinforced polymer (FRP) reinforced concrete beams cast in U-shaped ultra-high performance concrete (UHPC) permanent formworks is presented in this paper. Concrete damage plasticity (CDP) and FRP brittle damage models were used to simulate the damage behavior of concrete and FRP bars. The results of FE simulation are in good agreement with the experimental results. Furthermore, parametric studies were conducted to investigate the effect of concrete and UHPC strengths, yield strength of steel bars, elastic modulus of FRP bars, ultimate tensile strength of FRP bars, types of UHPC normal strength concrete (NSC) interface and thickness of UHPC under different reinforcement conditions. Flexural performances, in terms of cracking, yield, ultimate loads and corresponding deflections, failure mode, energy dissipation and ductility, were investigated. Traction-separation model was used to describe the bonding degradation and the maximum slip of two types of bonding interfaces (smooth surface and medium-rough surface). Both flexural capacity and resistance to deformation of composite beams are significantly improved by the utilization of hybrid FRP/steel reinforcement. The UHPC formwork can also delay the occurrence and development of cracks. By appropriately increasing the strength of UHPC or elastic modulus of FRP bar, the flexural capacity of composite beams is effectively improved. It is expected that the results presented in this paper can guide the design and construction of U-shaped UHPC permanent formwork-concrete composite beams reinforced with FRP bars.

Prefabricated UHPC formwork

Composite beam

FRP bar

Brittle damage model

Flexural performance

New Approach to Connections Between Members of Adjacent Box Beam Bridges

Halbe, Kedar Ram

04 September 2014

The adjacent box beam bridges (ABBB) are considered as an ideal solution for short to medium span bridges and for routes with low to medium traffic volumes. The ABBB system has been utilized and is popular in several states in the United States. However, this bridge system has long term durability issues caused by shear key failure and reflective cracking in the topping. The means and methods to alleviate the problems in connections between members of the ABBB were researched and the development of new connection details was pursued. Diagnostic tests to study the in-service behavior of ABBBs was performed. Two bridges with varying magnitude of joint deterioration were investigated. Both bridges were instrumented extensively and were subjected to known loads in the form of tandem trucks. The response of these bridges was studied and conclusions were made about the state of the bridges and the behavior after shear key failure. A finite element (FE) model of one of the tested bridges was developed to study the response of an ABBB with sound joints. The results of the finite element analysis (FEA) were compared with the results of the bridge diagnostic test. Conclusions about the FE model were made on the basis of this comparison. Another FE model, referred as the full scale bridge (FSB) was developed. The FSB model was used to simulate the behavior of an ABBB with the proposed connection details. This FSB model was subjected to design truck loads and the response was studied. The behavior of FSB model was replicated through a three beam sub-assembly that was supported on elastic supports. The stiffness of the elastic supports was calibrated such that the state of stress in the joints and the relative displacements between adjacent box beams in the sub-assemblage matched those in the FSB. The three beam sub-assembly was constructed with the proposed connection details. Two new connection details were proposed in this research. A Kevlar and epoxy connection and a spliced connection with fiber reinforced self-consolidating concrete are proposed. A total of six specimens, with different connection details, were constructed and tested for strength and durability in the laboratory. The behavior of the proposed connections and the connection materials were studied in detail. Additional FEA was performed to study the effect of shrinkage and temperature on the proposed connection details. / Ph. D.

Connection details

adjacent box beam bridges

UHPC

VHPC

shear key

diagnostic test

Experimental investigation on flexural performance of steel-UHPC composite beams with steel shear keys

Zhang, Z., Ashour, Ashraf, Ge, W., Ni, Z., Jiang, H., Li, S.

26 July 2024

Yes / Test results of steel-ultra high performance concrete (UHPC) composite beams with welded steel shear keys (SSKs) under four-point bending are presented in this paper. The objective of the investigation is to reduce the self-weight and manufacturing cost of large-span structures. The study investigates the effects of strength of concrete slab, type, spacing and size of SSK, and concrete slab height and width on flexural behavior of composite beams. The experimental results demonstrate that enhancing concrete strength, reducing SSK spacing, increasing concrete slab size, and using large-size SSK can all significantly enhance the flexural performance. The composite beams with welded SSK exhibit a maximum relative slip of less than 4 mm, while the counterpart with welded bolts has a maximum relative slip greater than 4 mm. The study shows that the welded SSK is more effective than welded bolts in improving the interface shear performance of composite beams and improving the stiffness and load capacity. Additionally, the study defines four failure modes of steel-UHPC composite beams, and the formulae for flexural capacity is developed based on the reasonable basic assumptions. The calculated results fit well with the tested results. The research findings can be provided as a technical support for the design and application of steel-UHPC composite beams. / High-End Foreign Experts Project of Ministry of Science and Technology, China (G2022014054L), the Natural Science Foundation of Jiangsu Province, China (BK20201436), the Science and Technology Cooperation Fund Project of Yangzhou City and Yangzhou University (YZ2022194), the Science and Technology Project of Jiangsu Construction System (2023ZD104, 2023ZD105), the Science and Technology Project of Yangzhou Construction System (202309, 202312) / The full-text of this article will be released for public view at the end of the publisher embargo on 29 May 2025.

Steel-UHPC composite beam

Flexural performance

Steel shear key

Bearing capacity

Predicted method

Investigation on flexural behavior of steel-UHPC composite beams with steel shear keys

Dafu,Cao,, Ge, W., Zhang, Z., Ashour, Ashraf, Jiang, H., Liu, Y., Li, S., Cao, D.

13 September 2023

Yes / To investigate the flexural performance of steel-UHPC (ultra-high performance concrete) composite beams with welded steel shear keys (SSK), eight specimens were experimental studied by four-point bending test. The finite element (FE) models were established based on the experimental results, then, the failure mode, load, deflection, strain and relative interface slip were parametric analyzed. The influences of strength, dimensions and configuration of upper concrete slab, steel beams as well as SSK on flexural performance, in terms of load-deflection response, ductility and ultimate energy dissipation, were studied. The experimental results show that steel-UHPC composite beams have superior bearing capacity, deformation capacity, ductility and energy dissipation ability when compared with steel-NSC (normal strength concrete) composite counterparts. Increasing the height of upper concrete slab has a significant effect on improving bending capacity and flexural stiffness, while increasing the width has a significant effect on enhancing deformation, ductility and ultimate energy dissipation. Increasing the yield strength, thickness of web and flange of steel beams has significant effect on improving bending capacity. Reducing the SSK spacing or increasing the yield strength of SSK, height and thickness slightly improve the cracking, yield and ultimate loads, reduce deflections, enhance the flexural stiffness, slightly weakens the ductility and ultimate energy dissipation. Besides, four types of failure modes were defined, based on reasonable assumptions, formulae for bearing capacity were proposed, and the predicted results fit well with experimental results. The results can be taken as reference for the design and application of steel-UHPC composite beams in long-span and heavy-load structures. / The authors would like to acknowledge the financial support to the work by the Natural Science Foundation of Jiangsu Province, China (BK20201436), High-End Foreign Experts Project of Ministry of Science and Technology, China (G2022014054L), Science and Technology Project of Jiangsu Construction System (2021ZD06, 2018ZD047), Science and Technology Cooperation Fund Project of Yangzhou City and Yangzhou University (YZU212105, YZ2022194), Science and Technology Project of Yangzhou Construction System (202309, 202312, 202204).

Steel-UHPC composite beam

Flexural behavior

Steel shear key

Parametric study

Bearing capacity

Seismic performance of ultra-high performance concrete-filled FRP tube composite columns reinforced with SFCBs: Test and modeling

Zhang, Z., Ashour, Ashraf, Ge, W.

02 October 2024

Yes / To reduce residual deformation and address corrosion issues, this paper introduces a novel type of composite columns, utilizing ultra-high-performance concrete (UHPC)-filled fiber reinforced polymer (FRP) tubes (UHPC-FFT) and reinforced with steel-FRP composite bars (SFCBs). The seismic performance of the proposed SFCB-reinforced UHPC-FFT composite columns was evaluated through pseudo-static experiments and numerical analysis in comparison with those of traditional composite columns. Results indicated that the UHPC-FFT composite columns reinforced with SFCB exhibited larger energy dissipation compared with those reinforced with either steel or FRP bars. Increasing the axial compression ratio from 0.15 to 0.25 enhance load-bearing capacity but reduces ductility and energy dissipation. Increasing the yield strength of internal steel bar of SFCBs can improve the load-bearing capacity and deformation of the columns without affecting the ductility, initial stiffness, and stiffness degradation rate. Increasing the elastic modulus of out-wrapped FRP of SFCBs enhanced the seismic performance of UHPC-FFT composite columns but could lead to premature failure due to FRP rupture. It is recommended to set an elastic modulus for the outer FRP wrap at 55 GPa for optimal seismic performance in UHPC-FFT composite columns. / The authors would like to acknowledge the financial support from the High-End Foreign Experts Project of Ministry of Science and Technology, China (G2022014054L), the Natural Science Foundation of Jiangsu Province, China (BK20201436), the Science and Technology Cooperation Fund Project of Yangzhou City and Yangzhou University (YZ2022194), the Science and Technology Project of Jiangsu Construction System (2023ZD104 and 2023ZD105) and the Science and Technology Project of Yangzhou Construction / The full-text of this article will be released for public view at the end of the publisher embargo on 06 Sep 2025.

UHPC-FFT composite column

SFCBs

Seismic performance

Pseudo-static test

Numerical analyze

Experimental and numerical study on flexural performance of ultra-high performance concrete frame beams reinforced with steel-FRP composite bars

Zhang, Z., Ashour, Ashraf, Ge, W., Sushant, S., Yao, S., Luo, L., Cao, D., Li, S.

17 September 2024

Yes / This paper presents the bending tests of four ultra-high performance concrete (UHPC) frame beams and one normal strength concrete (NSC) frame beam, all reinforced with steel-FRP composite bars (SFCBs). A comprehensive analysis was carried out, encompassing evaluation of the failure mode, crack propagation, bearing capacity, deformation, strain response, and plastic rotational capacity of the frame beams. Investigating the effects of concrete type, reinforcement type, and beam-end reinforcement ratio on the flexural performance of the frame beams was a key aspect of this study. A three-dimensional finite element (FE) model of the frame beam was established and rigorously verified. The developed model enabled a detailed parametric analysis involving the steel ratio, the yield strength of the inner core steel bar, the elastic modulus of the FRP, and the ultimate tensile strength of the SFCB. The results indicated a consistent failure mode of all frame beams: crushing of concrete at the beam-end, initiating a sequence of plastic hinge occurrence starting at the beam-end and then progressing to mid-span. The substitution of normal strength concrete with UHPC significantly enhanced various aspects of the frame beams, including the flexural capacity, deformation, ductility, ultimate energy dissipation, and plastic rotational capacity, while inhibiting the generation and expansion of cracks. Notably, the plastic rotation angle of SFCB-UHPC frame beams was 4.9 times greater than those of steel-UHPC frame beams, emphasizing the effectiveness of SFCB in enhancing the beam-end plastic rotational capacity. A decrease in the beam-end reinforcement ratio significantly reduced the flexural capacity, ultimate energy dissipation, and beam-end plastic rotational capacity, while improving ductility. Additionally, the study established a formula for calculating the equivalent plastic hinge length, utilizing the relative compressive zone height and effective section height of the beam-end controlling section as variables, which demonstrated good alignment between predicted and experimental results. / The authors would like to acknowledge the financial support from the High-End Foreign Experts Project of Ministry of Science and Technology, China (G2022014054L), the Natural Science Foundation of Jiangsu Province, China (BK20201436), the Science and Technology Project of Jiangsu Construction System (2023ZD104, 2023ZD105), the Science and Technology Project of Gansu Construction System (JK2021-19), the Science and Technology Cooperation Fund Project of Yangzhou City and Yangzhou University (YZ2022194) and the Science and Technology Project of Yangzhou Construction System (202309, 202312), Graduate Research and Innovation Projects of Jiangsu Province (KYCX24_3750), Jiangsu Provincial Government Scholarship Project (2024), Excellent Doctoral Dissertation Fund of Yangzhou University (2024). / The full-text of this article will be released for public view at the end of the publisher embargo on 22 Sep 2025.

SFCB-UHPC frame beam

Flexural performance

Flexural test

Finite element method

Parametric study

Optimised mix composition and structural behaviour of Ultra-High-Performance Fibre Reinforced Concrete

Weyers, Megan

January 2020

The overall objective of this study was to develop an optimised Ultra-High-Performance Concrete (UHPC) matrix based on the modified Andreasen and Andersen optimum particle packing model by using available South African materials. The focus of this study was to determine the optimum combined fibre and superplasticiser content for UHPC by using a response surface design. The UHPC was appropriately designed, produced and tested. Various changes in mechanical properties resulting from different combinations of steel fibre and superplasticiser contents was investigated. The flowability, density and mechanical properties of the designed UHPC were measured and analysed. Both the fibre and superplasticiser content play a significant role in the flowability of the fresh concrete. The addition of fibres significantly improved the strength of the concrete. The results show that the superplasticiser content can be increased if a more workable mix is required without decreasing the strength significantly. The statistical analysis of the response surface methodology confirms that the designed models can be used to navigate the design space defined by the Central Composite Design. The optimum combined fibre and superplasticiser content depend on the required mechanical properties and cost. Using the modified Andreasen and Andersen particle packing model and surface response design methodology, it is possible to efficiently produce a dense Ultra-High-Performance Fibre Reinforced Concrete (UHPFRC) with a relatively low binder amount, low fibre content and good workability. The effect of heat curing on the mechanical properties was investigated. It was concluded that heat curing is not recommended when considering the long-term strength development. The estimated strength development of concrete obtained by using the fib Model Code 2010 (2013) does not incorporate the detrimental effect of high curing temperatures on long-term strength and therefore overestimate the long-term strengths. The strength estimates for both early and long-term ages can be improved by considering this effect in the strength development functions obtained from fib Model Code 2010 (2013). The effect of specimen size on the compressive and flexural tensile strength of UHPFRC members were established. It was found that the specimen size has a significant effect on the measured cube compressive strength. Smaller beam specimens showed higher ductility compared to those of the larger beam specimens. The crack width decreased as the beam’s depth decreased. A lower variability was experienced in the beams with limited depth (< 45 mm). Further testing is required to determine whether a span-to-depth ratio of 10 would yield optimum results. The utilisation of by-products, such as undensified silica fume and fly ash, as cement replacement materials makes UHPFRC sustainable, leading to a reduced life-cycle cost. The calculated Embodied Energy per unit strength (EE/unit strength) and Embodied Carbon per unit strength (EC/unit strength) values for the UHPFRC mixture yield lower values compared to that of the 30 MPa concrete mixture, indicating that UHPFRC can be used to reduce the environmental footprint of the concrete industry. The inverse analysis method used was successful in providing an improved simplified stress-strain response for the UHPFRC. The analysis provided valuable information into the stress-strain, load-deflection and moment-curvature responses of the UHPFRC. Standard material test results were used to theoretically calculate moment-curvature responses and were then compared to the experimental results obtained. The study demonstrated that it is possible to efficiently produce a dense and workable UHPFRC with relatively low binder amount and low fibre content. This can result in more cost-effective UHPFRC, thus improving the practical application thereof. / Dissertation (MEng)--University of Pretoria, 2020. / Civil Engineering / MEng (Structural engineering) / Unrestricted

Response Surface Design Methodology

Specimen size effect

Ultra-High-Performance Concrete (UHPC)

UCTD

Entwicklung neuartiger Verbindungen für komplexe Stab-, Flächen- und Raumtragelemente aus UHPFRC

Ledderose, Lukas, Lehmberg, Sven, Wirth, Franz, Kloft, Harald, Budelmann, Harald

21 July 2022

Das Institut für Tragwerksentwurf (ITE) und das Institut für Baustof e, Massivbau und Brandschutz (iBMB) der TU Braunschweig bearbeiteten in der ersten Förderperiode des SPP 1542 „Leicht Bauen mit Beton“ gemeinsam das Teilprojekt „Entwicklung neuartiger Verbindungen für geometrisch komplexe Flächen- und Stabwerkselemente aus UHPC“. Schwerpunkt waren umfangreiche Untersuchungen zu geometrisch komplexen und hochpräzise hergestellte trocken gefügten Stoßverbindungen für dünnwandige UHPC-Bauteile zur Übertragung von Druck-, Biege- und Scherkräften. Zur Verbesserung der Zugtragfähigkeit und des Nachbruchverhaltens wurde im Forschungsprojekt stahlfaserverstärkter ultrahochfester Beton (UHPFRC) verwendet. Die einzelnen Arbeitspakete waren entsprechend der Expertisen der beiden Institute aufgeteilt. Während sich das ITE insbesondere mit der Entwicklung der Bauteil- und Fugengeometrien sowie dem Schalungsbaus befasste, lagen Planung und Umsetzung der experimentellen und numerischen Material- und Bauteiluntersuchungen in der Verantwortung des iBMB. [Aus. Einleitung) / The Institute of Structural Design (ITE) and the Institute of Building Materials, Concrete Structures and Fire Safety (iBMB) of the Technical University of Braunschweig worked together in the f rst funding period of the SPP 1542 “Concrete Light” on the subproject “Development of novel jointing systems for complex beam surface and spatial elements made of UHPFRC”. The focus was on extensive investigations of geometrically complex and high-precision dry-jointed connections for thin-walled UHPC components for the transmission of compressive, bending and shear forces. Steel f bre reinforced ultra-high performance concrete (UHPFRC) was used in the research project to improve the tensile strength and post fracture behaviour. The individual work packages were divided according to the expertise of the two institutes. While the ITE was particularly concerned with the development of the component and joint geometries as well as the formwork construction, the iBMB was responsible for the planning and implementation of the experimental and numerical material and element analyses. [Off: Introduction]

info:eu-repo/classification/ddc/624

ddc:624