Performance Test and Microstructure of Modified PVC Aggregate-Hybrid Fiber Reinforced Engineering Cementitious Composite (ECC)

Hu, Shi; Cai, Haibing; Hong, Rongbao; Li, Mengkai; Yao, Fangxing

doi:10.3390/ma14081856

Cited by 14 publications

(1 citation statement)

References 40 publications

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“…Different types of fibre are used in concrete like steel fibres [4], glass [5], fibres of natural origin [6], carbon fibres [16]; Hybrid fibres [3,12]; as well as polymer fibres, i.e., polypropylene fibres [2,17] made of poly alcohol vinyl [7]. Fibre-reinforced concretes (FRC) increase various properties of concrete, including: compressive strength more than ordinary concrete [5,3,7]; greater tensile strength [6,7,8] higher bending and splitting tensile strength and ductility [12]; greater flexural strength [5]; high impact loading resistance [9]; high dynamic resistance [17], improve unity of structure [11]; crack formation is delayed even after fresh state (post-cracking of concrete) [6,11]; elastic modulus, shrinkage control. The ability of fibre is to reduce cracks at maximum strain and increases its ductility also durability which reduces transport of corrosive material into concrete [2,10].…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation on the Effect Polypropylene Fibre and E-Waste Fibre Embedded in Concrete

Bhat¹,

Vikram²

2022

IJIREM

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The main building material that can’t be ignored even it’s weak in tension and lead to various environmental problems during it’s production is concrete. Properties of concrete can be enhanced using fibre in concrete. Using fibre from waste of plastic in concrete to some percentage increases strength as well as durability of concrete and solve disposal problems of plastic waste in environment. From electronic waste Polyvinyl chloride cables (PVC) are used as fibre and from polypropylene (PP) packing bag of cement are used as fibre in concrete. Both are used in 0%, 0.25%, 0.50%, 0.75% and 1% by weight of cement in concrete. Fresh and harden properties for both concrete with polypropylene fibre and with electronic waste fibre is determined and hybrid of optimum values calculated is used in a single mix and compressive strength is calculated. Results show that 0.75% and 0.50% is optimum value of concrete with electronic waste fibre and concrete with polypropylene fibre with 49% and 17.5% increase in concrete strength compared to normal concrete respectively and can be used in a single mixture. Concrete with hybrid of polypropylene fibre and electronic waste fibre shows enhancement of 56% in compressive strength. The hybrid of PPFRC and EFRC polypropylene fibre keep cracks small and e-waste fibre shows enhancement in mechanical properties.

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Section: Introductionmentioning

confidence: 99%

Experimental Investigation on the Effect Polypropylene Fibre and E-Waste Fibre Embedded in Concrete

Bhat¹,

Vikram²

2022

IJIREM

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Prediction of the compressive strength of strain‐hardening cement‐based composites using soft computing models

Saleh

Jaf

Abdalla

et al. 2023

Structural Concrete

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Strain‐hardening cement‐based composites or engineered cementitious composites (ECC) is concrete produced using randomly distributed short polymer fibers. It is very ductile compared to conventional concrete. Compressive strength (CS) is a critical property used as a quality control tool to evaluate the strength of concrete implemented in the structural provisions and mix designs. Accordingly, to save cost and time for testing, it is essential to provide a predictive model to forecast the CS of the concrete mixtures using machine learning and modeling techniques. In this study, different modeling tools are used to propose analytical models to predict the CS of ECC mixtures, such as linear regression (LR), multi‐expression programming (MEP), artificial neural network (ANN), and Gaussian process regression (GPR). A total of 210 data were collected from the literature and used to train and test the developed model. The fly ash‐to‐cement ratio ranged from 0 to 5.6, water to binder ratio from 0.19 to 0.56, different superplasticizer and fiber content, and curing times of 1 to 180 days. Based on the evaluation of the developed models, the ANN model is superior to other developed models with a high coefficient of determination (R2), root mean squared error (RMSE), mean absolute error (MAE), and scatter index (SI). The sensitivity analysis of the input parameters' effect on the CS prediction indicates that the curing time and the fly ash‐to‐cement ratio are essential in forecasting ECC's CS.

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Prediction of compressive strength and tensile strain of engineered cementitious composite using machine learning

Uddin,

Shanmugasundaram,

Praveenkumar

et al. 2024

Int J Mech Mater Des

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Performance Test and Microstructure of Modified PVC Aggregate-Hybrid Fiber Reinforced Engineering Cementitious Composite (ECC)

Cited by 14 publications

References 40 publications

Experimental Investigation on the Effect Polypropylene Fibre and E-Waste Fibre Embedded in Concrete

Experimental Investigation on the Effect Polypropylene Fibre and E-Waste Fibre Embedded in Concrete

Prediction of the compressive strength of strain‐hardening cement‐based composites using soft computing models

Prediction of compressive strength and tensile strain of engineered cementitious composite using machine learning

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