Effect of the high temperatures on the microstructure and compressive strength of high strength fibre concretes

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The high temperatures of fires affect the physical and chemical properties of the concrete and thus influence its mechanical properties. This paper presents the results of an experimental investigation on the compressive strength at high temperatures of high-strength fibre concretes. The influence of the high temperatures on the physical and chemical changes of the concrete was also analysed by Thermo Gravimetric Analysis/Differential Thermal Analysis (TGA/DTA), X-Ray Diffraction (XRD) and Scanning Electron Microscopy with Energy Dispersive Spectrometry (SEM/EDS). Five concrete compositions with different steel fibre contents and types have been tested: one without steel fibres (reference composition), two with Dramix 3D steel fibres and two with Dramix 5D steel fibres (45 and 75 kg/m3 ). This new type of steel fibres, the Dramix 5D, presents a double curvature at its ends, allowing a more efficient anchorage in the cementitious matrix. The behaviour at high temperatures of concretes made with these 5D fibres has been compared with the one of concretes made with the Dramix 3D steel fibres. Therefore, the impact of the high temperatures on the compressive strength and morphology of the high-strength fibre concretes made with the Dramix 3D and 5D steel fibres has been evaluated. The paper proposes also models for the compressive strength at high temperatures of the studied high strength fibre concretes.

Construction and Building Materials 199 (2019) 717–736 Contents lists available at ScienceDirect Construction and Building Materials journal homepage: www.elsevier.com/locate/conbuildmat Effect of the high temperatures on the microstructure and compressive strength of high strength fibre concretes Hugo Caetano a, Gisleiva Ferreira b, João Paulo C Rodrigues a,⇑, Pierre Pimienta c a LAETA, Department of Civil Engineering of University of Coimbra, Portugal Department of Civil Engineering, Faculty of Civil Engineering, Architecture and Urbanism, State University of Campinas, Brazil c CSTB – Centre Scientifique et Technique du Bâtiment, France b h i g h l i g h t s Compressive strength at high temperatures of fibre concretes studied Influence of the high temperatures on the physical and chemical changes of the concrete studied Behavior of the new Dramix 5D steel fibre concretes in fire studied Model for compression strength at high temperatures of fibre concrete proposed a r t i c l e i n f o Article history: Received 11 August 2018 Received in revised form December 2018 Accepted 13 December 2018 Keywords: High strength concrete Fibres Steel Polypropylene High temperatures Compressive strength Thermal analyses a b s t r a c t The high temperatures of fires affect the physical and chemical properties of the concrete and thus influence its mechanical properties This paper presents the results of an experimental investigation on the compressive strength at high temperatures of high-strength fibre concretes The influence of the high temperatures on the physical and chemical changes of the concrete was also analysed by Thermo Gravimetric Analysis/Differential Thermal Analysis (TGA/DTA), X-Ray Diffraction (XRD) and Scanning Electron Microscopy with Energy Dispersive Spectrometry (SEM/EDS) Five concrete compositions with different steel fibre contents and types have been tested: one without steel fibres (reference composition), two with Dramix 3D steel fibres and two with Dramix 5D steel fibres (45 and 75 kg/m3) This new type of steel fibres, the Dramix 5D, presents a double curvature at its ends, allowing a more efficient anchorage in the cementitious matrix The behaviour at high temperatures of concretes made with these 5D fibres has been compared with the one of concretes made with the Dramix 3D steel fibres Therefore, the impact of the high temperatures on the compressive strength and morphology of the high-strength fibre concretes made with the Dramix 3D and 5D steel fibres has been evaluated The paper proposes also models for the compressive strength at high temperatures of the studied high strength fibre concretes Ó 2018 Elsevier Ltd All rights reserved Introduction Fiber-reinforced concrete is a composite material widely used in Civil Engineering, and the compressive strength is a very important parameter on the design of reinforced and pre-stressed concrete structures The concrete elements, when in fire, are subjected to the high temperatures and this may result in significant losses of their load-bearing capacity due to reduction of material’s strength and stiffness [1] The introduction of steel fibres in the normal and high strength concretes, in suitable dosages, may cause improvements ⇑ Corresponding author E-mail address: jpaulocr@dec.uc.pt (J.P.C Rodrigues) https://doi.org/10.1016/j.conbuildmat.2018.12.074 0950-0618/Ó 2018 Elsevier Ltd All rights reserved on the mechanical properties of the concrete either at ambient and high temperatures [2–7] Researches described that high-strength concrete begins to lose compressive strength for temperatures lower than the ones of the normal concrete The high-strength concrete starts to reduce its compressive strength for temperatures of nearly 150 °C (corresponding to a significant loss of nearly 30% of the initial strength) while in the normal strength concrete this reduction only occurs for temperatures of nearly 350 °C This performance results from the higher pore pressure effect caused by the lower permeability of the high-strength concrete [8] Steel fibre reinforced concrete (SFRC) is a composite material that may mitigate the consequences of the high temperatures exposition [3,9] This Steel fibres improve the ductility, energy 718 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Notation CaCO3 CaO Ca(OH)2 CH C-S-H DTA EDS SD SEM SiO2 TGA XRD Calcium carbonate Calcium oxide (Free lime) Portlandite Calcium hydroxide Calcium silicate hydrate Differential thermal analysis Energy dispersive spectrometer Standard deviation Scanning electronic microscopy Quartz Thermogravimetric analysis X-ray diffraction absorption capacity, cracking control and toughness of the concrete [4] Barros et al [10] concluded that the post-cracking residual strength could be much higher in concrete reinforced with steel fibres than in plain concrete with the same strength class, due to the reinforcement mechanisms provided by the fibres on bridging the cracks In consequence, the reinforcement of concrete with steel fibres allows a high level of stress redistribution, providing greater deformation capacity of a structure between the crack beginning to its failure, which increases structural safety Another problem associated with the high-strength concrete is the spalling This phenomenon occurs because of the low permeability and water-cement ratio of the concrete [8,11] Eurocode [12] and some researchers [11,13–16] have suggested that spalling can be minimised by adding polypropylene fibres to the highstrength concrete The sublimation (160–170 °C) and vaporization (350 °C) of the polypropylene fibres create new pores and microcracks in the concrete matrix that may increase the permeability of the concrete [4,17–19] These phenomena reduce the damages and resistance of the concrete subjected to the high temperatures of the fire [17] Yermak et al [4] also confirmed this positive effect of the cocktails of steel and polypropylene fibres by porosity and permeability tests Thus, the simultaneous use of steel and polypropylene fibres reduces the brittle behaviour of the concrete depending obviously on the content of fibres used [20] In order, to prove the performance of the high-strength concrete reinforced with steel and polypropylene fibres, it is necessary more research because of several chemical and physical transformations of the paste and aggregates, which results in changes in the concrete’s mechanical performance and durability [21–26] Khoury [22] mentions that these changes depend from parameters such as the concrete’s composition, moisture content, load level, heating and cooling rates, time of exposure to elevated temperatures, time after cooling and number of thermal cycles with heating and cooling Also, the RILEM TC 200 HTC [27] indicates the endogenous parameters that most affect the compressive strength of the concrete at high temperatures are the type of aggregate, rate of dehydration and sealing of the specimens Well-hydrated Portland cement paste consists mainly of calcium silicate hydrate (C-S-H), calcium hydroxide (CH) and calcium sulfoaluminate hydrate [28] When cement paste is exposed to high temperatures, the hydrated products gradually lose water, which generates in water steam and increases the pore pressure in the concrete [17] This phenomenon starts at approximately 100 °C and continues up to 500 °C, which corresponds to the vaporisation temperature of the crystalline water in the concrete [29–31] At about 300 °C, the W/C b-C2S h fcm,cube fcm fck,cube fc, h fcm, h Water/binder ratio Larnite Temperature Mean value of the cube compressive strength of the concrete at ambient temperature Mean value of the compressive strength of the concrete at ambient temperature Characteristic value of the compressive strength of the concrete at ambient temperature Compressive strength of the concrete at temperature h Mean value of the compressive strength of the concrete at temperature h interlayer and chemically combined water of the C-S-H and sulfoaluminate hydrates would be lost, but under temperatures of around 900 °C, the complete decomposition of C-S-H occurs Further dehydration of the cement paste, due to decomposition of the calcium hydroxide, begins at about 500 °C [32–33] Calcium hydroxide (CH) loses water between 400 and 500 °C, but if CO2 is available, above 400 °C, it may form calcium carbonate (CaCO3) Also, the decomposition of the CH could be quickly undone while it cools down to ambient temperature [30] Some authors [34,35] studied the performance of concrete structures exposed to fire to ascertain the effects of temperature on their microstructure and the properties of the aggregates Initially, the vaporisation of the free water between 100 and 140 °C, increasing the pore pressure of the cementitious matrix At 400 °C, the dehydration of calcium hydroxide and C-S-H gel begins, which leads to shrinkage and reduction in the concrete’s strength [36] Some of the temperature effects are due to chemical changes and moisture transport within the cement paste, and another is due to damage (microcracks) resulting from temperature gradients and deformational incompatibilities between the aggregates and cement paste According to Lim [33], the development of microcracks on the interface between dehydrated cement particles and cement paste matrix and changes in C-S-H microstructure are considered as main factors that cause the thermal degradation of the cement paste Different types of cracks may be found on the concrete after its exposition to high temperatures According to Henry et al [36] and Picandet et al [37] in the first phase of the concrete’s heating (500 °C), the pores and the preexisting microcracks close due to contraction of the concrete’s overall volume However, in the second heating phase (>500 °C), bridge cracks occur because of the different performance between aggregates and mortar matrix Concrete is a heterogeneous material composed of aggregates embedded in the cement paste matrix The heterogeneity of the concrete’s constituents can result in severe thermal damages in the interface, such as the cement paste-aggregate interface, due to the different behaviour of the constituents at high temperatures [38] Siliceous aggregates are predominantly quartz, which changes from trigonal a-quartz to hexagonal b-quartz at 575 °C, causing a volume increasing of approximately 6%, and is decomposed at around 800 °C [38] In the case of carbonate rocks, a similar disturbance can begin at 700 °C as a result of the decarbonisation In addition to possible phase transformations and thermal decomposition of the aggregates, its mineralogy determines the response of the concrete at high temperatures For instance, it determines the differential 719 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 normal and high strength concretes They concluded that for temperatures between 200 and 400 °C the heating rate is a major factor for the decreasing on the weight loss, compression and tensile strengths of both types of concrete In this range of temperatures, the modulus of elasticity is also very affected For temperatures above 600 °C, the compressive strength is almost negligible in agreement with other similar experimental works There is a strong need to establish constitutive relationships and damage microstructure for modelling the fire response of mix fibers (steel and polypropylene) high-strength concretes The creation of theoretical and numerical models that accurately predict the mechanical behaviour of concrete at high temperatures is very complex The classical isotropic theory of nonlocal damage was adequately modified to take into account both the mechanical damage and the deterioration of thermochemical material at high temperatures [41] However, several theoretical models are currently available in the scientific literature to simulate the failure processes of concrete thermal elongation between the aggregate and the cement paste, and the maximum strength of the interfacial transition zone [33] The nature of the aggregates is closely linked to the concrete’s thermal expansion and conductivity coefficients because while siliceous concretes have a slight contraction when subjected to temperatures between 300 and 900 °C, calcareous concrete has an expansion which leads to the development of cracking It happens because of the higher degree of porosity and the coefficient of thermal expansion of the calcareous aggregates In this sense, the author states that the type of aggregate greatly affects the mechanical strength of the concrete at high temperatures and after fire According several authors [5–7], this behavioural difference results from the dense microstructure of the high-strength concrete (because of the low W/C ratio) that gives to the highstrength concrete a low permeability hindering the water vapour in the pores from being released when the temperature increases and with this making concrete more prone to spalling However, in the temperature range of 400–800 °C both concrete lose most of their original strength, especially at temperatures above 600 °C due to the decomposition of the calcium silicate hydrate gel (C-S-H) that is the responsible for the mechanical strength of the cement Above 800 °C, the loss of the original strength for both concrete is almost complete The influence of the long-term loading on the compressive strength and modulus of elasticity of the concrete at high temperatures was also studied by Jonaitis and Papinigis [39] They concluded that the decrease of the compressive strength is less when the concrete is heated first and then subjected to a longterm loading than when is heated after being subjected to a preloading An experimental study conducted by Aidoud and Benouis [40] analysed the effect of the high temperatures on the behaviour of Fig Slabs representative of each concrete composition Table Density (kg/m3) of the materials used in the manufacture of concrete compositions CEM LF S LG1 LG2 LG3 PF SF3D SF5D SP W 3130 2700 2640 2680 2680 2680 910 7850 7850 1060 1000 Fig Fibres used in the concrete compositions: a) polypropylene; b) steel fibres 3D and b) steel fibres 5D Table Concrete compositions (in kg/m3) Concrete Composition CEM LF S LG1 LG2 LG3 PF SF3D SF5D SP W RC 3D_45 3D_75 5D_45 5D_75 400 400 400 400 400 200 200 200 200 200 479 479 479 479 479 543 528 518 528 518 290 290 290 290 290 373 373 373 373 373 2 2 45 75 0 0 45 75 8 8 144 144 144 144 144 720 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Fig Equipment used for: a) drilling the slabs; b) cut and c) rectify the top faces of the concrete specimens Fig Specimens for the compressive strength tests and location of the thermocouples structures subjected at the same time to high temperatures and mechanical loads Recently models for simulating the behavior of materials reinforced with fibres at high temperatures have appeared [42–44] In addition to the mechanical compression tests, thermogravimetry, X-ray diffraction and SEM-EDS tests were also carried out Thermogravimetry is a thermal analysis technique that stands out now of the evaluation of morphological and chemical changes of the compounds formed during the Portland cement hydration In this experimental test, the mass change of a specimen placed in a crucible and controlled atmosphere, as a function of temperature or time, it is continuously recorded as the temperature increases The thermogravimetry with the differential thermal analysis (DTA) are suitable techniques for the hydration study of the concrete X-ray diffraction (XRD) is a technique used for the mineralogical evaluation of concrete and its crystalline structure Also, it allows the qualitative and quantitative chemical identification of the crystalline phases found in the material at high temperatures Acoustic emission could be another non-destructive technique that could be used to evaluate the actual state of damage of the concrete Acoustic Emission (AE) test as can be seen in other research in this area [45] The morphology of the concrete specimen was monitored by scanning electron microscopy (SEM), and energy dispersive X-ray spectroscopy (EDS) was used to identify and quantify the chemical elements present in the compounds identified in the images In this context, an experimental work has been carried out at Coimbra University to investigate the mineralogical and Fig Specimens for the thermal analyses tests a) Cylindrical slice of concrete of mm thickness and 70 mm diameter and b) piece of concrete impregnated with epoxy resin H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Fig Experimental test set-up for the compressive strength tests microstructure changes of the high-strength concretes in study, as well as compressive strength at high temperatures Experimental setup and program 2.1 Materials and compositions In the mix design the following materials were used: Portland cement CEM I 42.5 R (CEM), limestone gravel with 11–18 mm (LG1), limestone gravel with 8–14 mm (LG2), limestone gravel 721 with 4–8 mm (LG3), quartz sand with 0–8 mm (S), limestone filler (LF), polypropylene fibres (PF), steel fibres of Dramix 3D (SF3D), steel fibres of Dramix 5D (SF5D), superplasticizer Sika ViscoCrete 3002 HE (SP) and water (W) Dramix is a trade mark of Bekaert, Belgium In Table it is possible to observe the density of the materials used in the manufacture of the concrete compositions The steel fibres Dramix 3D have 60 mm in length (l), 0.90 mm in diameter (d), 65 length/diameter ratio (l/d), with 1160 MPa of tensile strength and 210 GPa of modulus of elasticity The steel fibres Dramix 5D have 60 mm in length (l), 0.90 mm in diameter (d), 65 length/diameter ratio (l/d), with 2300 MPa of tensile strength and 210 GPa of modulus of elasticity [46,47] The major diferences between Dramix 3D and 5D steel fibres are that the 3D have a single curvature at both ends and the 5D have a double curvature at both ends Fig shows all the used fibres In this research, five concrete compositions were studied (Table 2) The compositions are referenced as RC, 3D_45, 3D_75, 5D_45 and 5D_75, where RC stands for the composition without steel fibres, 3D_45 and 3D_75 for compositions with Dramix 3D steel fibres with amounts of 45 and 75 kg/m3, and 5D_45 and 5D_75 for compositions with Dramix 5D steel fibres, also with amounts of 45 and 75 kg/m3, respectively All tested compositions had a dosage of kg/m3 of polypropylene fibres and 0.36 of water to cement ratio 2.2 Experimental program The experimental program included five different compositions of high-strength fibre concretes The tests were conducted at the Laboratory of Testing Materials and Structures (LEME) of Coimbra University (UC), in Portugal They were carried out mechanical compression and thermal tests The experimental program of the compressive strength consisted of 60 tests at ambient and high temperatures (300, 500 and 700 °C) In the tests at hightemperature an initial pre-load of 20% of the average value of the Fig Schematic experimental test set-up representation for the compressive strength tests 722 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Fig Temperature evolution in the specimen as a function of time for the 300 °C test series Fig Temperature evolution in the specimen as a function of time for the 500 °C test series Fig 10 Temperature evolution in the specimen as a function of time for the 700 °C test series 723 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Table Values of fcm,cube (in MPa) Composition Age of specimens (days) RC 3D_45 3D_75 5D_45 5D_75 14 21 28 150 (first day of testing) 270 (last day of testing) 55.3 60.9 64.9 66.0 67.6 62.0 71.0 72.0 73.0 74.0 61 70.6 74.9 74.0 78.0 66.7 72.0 76.7 79.9 77.0 71.2 77.3 80.7 83.2 82.2 74.2 81.4 81.3 84.8 86.5 compressive strength obtained during the compression tests at ambient temperature (0.2 fcm) For each test series, specimens were tested, to obtain a better correlation of results To evaluate the development of the temperatures inside the specimens it was carried out more 15 simple heating tests The thermal analysis tests were carried out at the Laboratory of Pedro Nunes Institute, in Coimbra, Portugal Twenty-two specimens were used in this experimental program of thermal analyses They were carried out XRD and TGA-DTA tests for the reference concrete composition and SEM/EDS tests for all the concrete compositions in study For each type of test and concrete composition, only one specimen was tested For the TGA-DTA and XRD tests, Table Concrete classes Concrete compositions fcm,cube (MPa) fck,cube (MPa) Resistance classes RC 3D_45 3D_75 5D_45 5D_75 67 72 77 80 77 63 68 73 76 73 C50/60 C55/67 C55/67 C60/75 C55/67 specimens were used (temperature increased from ambient to 1000 °C), while in the SEM/EDS tests only one specimen of each composition was used and for each temperature level (ambient, 200, 500, 800 °C) 2.3 Specimens In this experimental work, the cylindrical specimens used in the compressive strength tests were obtained by core drilling of slabs representative of each concrete composition to obtain a better representation of the material and to avoid interfering in the orientation of the steel fibres during the casting process (Fig 2) Afterwards, the specimens were cut and the top faces rectified in a way that they were parallel among them (Fig 3) The specimens had a height of 210 mm and a diameter of 70 mm The dimensions of these specimens were mainly limited by the size of the furnace’s internal chamber However, although they did not have a standard size, the specimen’s dimensions respect the length/diameter ratio between and (slenderness) and the specimen’s diameter is more than times the size of bigger aggregates, according to the RILEM recommendations [48] Table compressive strength of each concrete composition in function of the temperature Specimen fc, h (MPa) fcm, h (MPa) SD (MPa) 20 °C RC_3 RC_5 RC_10 3D_45_1 3D_45_2 3D_45_17 3D_75_2 3D_75_3 3D_75_17 5D_45_1 5D_45_3 5D_45_16 5D_75_1 5D_75_3 5D_75_5 79 78 79 86 81 84 82 85 84 80 83 85 93 92 95 79 0.47 84 2.05 84 1.25 83 2.05 93 1.25 500 °C RC_11 RC_12 RC_13 3D_45_11 3D_45_12 3D_45_13 3D_75_11 3D_75_12 3D_75_13 5D_45_11 5D_45_12 5D_45_13 5D_75_11 5D_75_13 5D_75_21 45 44 45 51 52 48 54 51 48 51 53 48 55 51 53 44 0.47 50 1.70 51 2.45 51 2.05 53 1.63 Specimen fc, h (MPa) fcm, h (MPa) SD (MPa) 300 °C RC_6 RC_7 RC_15 3D_45_6 3D_45_7 3D_45_16 3D_75_7 3D_75_10 3D_75_16 5D_45_6 5D_45_7 5D_45_8 5D_75_6 5D_75_7 5D_75_8 78 75 75 90 83 84 87 90 93 83 85 83 90 85 80 76 1.41 86 3.09 90 2.45 84 0.94 85 4.08 700 °C RC_17 RC_18 RC_24 3D_45_10 3D_45_24 3D_45_27 3D_75_5 3D_75_8 3D_75_24 5D_45_26 5D_45_27 5D_45_28 5D_75_26 5D_75_27 5D_75_28 18 20 18 28 24 26 26 24 21 25 24 27 31 28 31 19 0.94 26 1.63 24 2.05 25 1.25 30 1.41 724 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Fig 11 Mean ultimate load and standard deviation for the different concrete compositions and temperature series Fig 12 An example of stress-strain curves selected from each concrete compositions and temperature series For temperature measuring five type K chrome-alumel thermocouples, were placed in the surface and central axis of the specimen as represented in Fig In thermal analyses tests cylinders similar to the ones of the compressive strength tests were first cut in slices of 70 mm diameter and mm thick (Fig 5a) In the TGA-DTA and XRD tests, these slices of concrete were then split into smaller pieces and after crushed with a pestle up to a fine powder of 100 mm fineness The specimens for the SEM/EDS observations were obtained by splitting the slices of concrete into small pieces and then impreg- Table Relative values of compressive strength of each concrete composition in function of the temperature h (°C) 20 300 500 700 Relative compressive strength RC 3D_45 3D_75 5D_45 5D_75 1.00 0.97 0.56 0.24 1.00 1.02 0.60 0.31 1.00 1.08 0.61 0.29 1.00 1.01 0.61 0.31 1.00 0.91 0.57 0.32 725 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 nated with epoxy resin to minimise any damage during the grinding and polishing processes (Fig 5b) These specimens were after grounded with silicon carbide papers of decreasing grit size, and after dried they were sputtered with a gold alloy film 2.4 Experimental Set-ups The compressive strength tests set-up (Fig 6) consisted on a ‘‘SERVOSIS” tensile-compression machine of 600 kN (a) capacity, a cylindrical oven with 90 mm of diameter and 300 mm of height, internal dimensions, capable to reach the maximum temperature of 1200 °C (b), a Datalogger TDS-601 (c) to data acquisition, the universal testing machine controller (d), the furnace controller (e), a laptop computer (f) and a load cell (g) The pull rods of the tensile-compression machine were made of refractory steel Fig shows a schematic representation of the experimental test set-up The TGA-DTA and XRD tests used a Setaram (Setsys Evolution) analyser complemented with a Philips X’Pert diffractometer with cobalt (ka1 = 1.78897 Å) radiation The SEM/EDS observations used a Field Emission Scanning Electron Microscope (FESEM) ZEISS MERLIN coupled with an OXFORD energy dispersive spectrometer X-RAY An EDWARDS EXC 120 sputter coater was used on the coating process with gold alloy film of the polished surfaces of the concrete specimens Fig 13 Relative compressive strength of the different concrete compositions as a function of the temperature Table Tabulated relative compressive strength values for the proposed model of preloaded HSFC with calcareous aggregates h (°C) 20 300 500 700 Results from the experimental data Results from the proposed model RC composition (only PP fibres) 3D_45 and 5D_45 compositions 3D_75 and 5D_75 compositions 0.97 0.56 0.24 1.02 0.61 0.31 0.99 0.62 0.31 0.91 0.56 0.24 Fig 14 Comparison between the proposed model for the prestressed compressive strength of HSFC with calcareous aggregates at high temperatures and test data from others authors 726 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Fig 15 Comparison between the proposed model and models from another’s authors for the stressed compressive strength of HSFC with calcareous aggregates at high temperatures Fig 16 Comparison between the proposed model, tests data and models from others authors for the unstressed compressive strength of HSFC with calcareous aggregate concrete at high temperatures Fig 17 Comparison between the proposed model, tests data and models from others authors for the compressive strength of HSFC at high temperatures 727 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Fig 18 Mean ultimate load of each concrete composition in function of the content and geometry of the fibres for different temperatures Table Specimens after test h (°C) RC 3D_45 3D_75 5D_45 5D_75 20 S03_RC S02_3D_45 S03_3D_75 S01_5D_45 S01_5D_75 300 S07_RC S06_3D_45 S07_3D_75 S07_5D_45 S06_5D_75 500 S12_RC S12_3D_45 S12_3D_75 S11_5D_45 S11_5D_75 700 S24_RC S10_3D_45 S8_3D_75 S27_5D_45 S28_5D_75 728 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 2.5 Test procedure The adopted procedure for the compression tests followed the recommendations of RILEM [48] In the tests carried out at ambient temperature, the pull rods of the tensile-compression machine were aligned vertically with each other, and the concrete specimen was centred in the compression rods Then the load was applied at a speed of 0.25 kN/s until the concrete specimen rupture In the tests carried out at 300, 500 and 700 °C, the pull rods of the tensile-compression machine were aligned vertically with each other, and the concrete specimen was centred in the compression rods Then, a compression load was applied at a speed of 0.25 kN/s until the target load value 20% of the average value of the compressive strength obtained during the compression tests at ambient temperature (0.2 fcm) Subsequently, the furnace was closed and was insulated with ceramic wool to avoid thermal losses during heating Afterwards, the specimens were heated up at a rate of °C/min until the desired level of temperature was reached (300, 500 or 700 °C) The target temperature was then maintained for 60 so that the temperature in the specimen could stable and uniform During this heating process, the load on the specimen was kept constant When the desired temperature level in the specimen was uniform, the load was increased at a speed of 0.25 kN/s up to the concrete rupture (if that had not already happened during the heating process) The displacements and loading forces were also measured and recorded continuously, with the goal of obtaining the curve force-displacement of the specimens from different compositions During the compression tests the displacement that was recorded by the LVDT installed in the tensile-compression machine Servosis, refers to the movement of the machine pull rods that were in contact with the concrete specimen The load level of 0.2 fcm was adopted, because tried to simulate the service loads on concrete structural elements subjected to the compression stresses In heating tests, the evolution of the temperature inside the specimen was measured as well as inside the furnace The evolution of the temperature in the specimens was measured over time to determine the heating time required to uniform the temperature in the specimens for each temperature level The TGA-DTA tests were used to provide information on the chemical reactions of the concrete due to the heating and calculates the calcite and portlandite contents The concrete powder samples were heated from ambient temperature to 1000 °C, at a heating rate of 10 °C/min, in an argon atmosphere (50 ml/min) Fig 20 XRD peak patterns at different temperatures The XRD tests were carried out to allow further insight into the mineralogy of the binder and other constituents of the concrete such as the aggregates The X’Pert diffractometer with cobalt (ka1 = 1.78897 Å) radiation, with steps of 0.025° and s of time per step, between 5° and 80° theta, was used The specimens for the SEM/EDS observations were firstly heated up to the desired temperature level (200, 500 and 800 °C) at a heating rate of °C/min Once the temperature was reached, it was maintained for 60 The specimens were then cooled down inside the furnace up to ambient temperature Meanwhile, unexposed specimens (reference specimens) were left at ambient temperature The polished surfaces of the concrete specimens were then coated with a gold alloy film in the sputter coater for following SEM observations Results 3.1 Thermal tests In Figs 8–10 all the thermocouples in the specimen reached 300, 500 and 700 °C at 200, 250 and 300 min, respectively The temperature inside the furnace was kept uniform throughout the whole test, meaning an adequate thermal exposure of the specimen Furthermore, it was also verified a good thermal exposure of the specimen over its entire height, possible to generate a very stable temperature inside the concrete mass, close to the recommended heating rate specified in the RILEM recommendations [48] 3.2 Compressive strength Fig 19 TGA and DTA curves for an RC specimen 3.2.1 Analysis of results For each concrete composition, the compressive strength, at ambient temperature and 7, 14, 21, 28, 150 and 270 days, has been assessed (Table 3) The strength class of the concrete was established by the EN 206-1 (2016) [49] (Table 4) H Caetano et al / Construction and Building Materials 199 (2019) 717–736 In Table 5, it is possible to observe the values of the compressive strength of each concrete composition in function of the testing temperature and Fig 11 it is the graphical representation of these values The values for the tests carried out of each test series are presented They are very close to each other meaning good representativeness of the results It is also possible to verify that at the ambient temperature and 300 °C the compressive strength is practically the same and with the increase of temperature (500 and 700 °C) a marked decrease in the compressive strength is observed In Fig 12 they have presented an example of stress-strain curves selected from each concrete composition and temperature series It is observed that at 20, 300 and 500 °C the curves tend to exhibit a semi-elastic behaviour of the material up to the breaking point while at 700 °C, more properly for the RC compositions, 3D_45 and 5D_75, the curves appear to have a semi-plastic behaviour at the moment before the material rupture 3.2.2 Temperature influence In Table it is possible to observe the mean values of the relative compressive strength of the different concrete compositions tested as a function of the temperature Fig 13 is the graphical representation of these values For the 300 °C test series there was a slight increase on the relative compressive strength for some concrete compositions, in which the 3D_45, 3D_75 and 5D_45 had an increase of 2%, 8% 729 and 1%, respectively However, for the RC and 5D_75 concrete compositions, it was observed a decrease in the relative compressive strength of 3% and 9%, respectively For the 500 °C test series it was observed a decrease in the relative compressive strength for all concrete compositions This happens because at around 400 °C the calcium hydroxide starts dehydrating, being more steam generated, leading to a significant reduction on the material strength Thus, the ultimate strength was 56%, 60%, 61%, 61% and 57% of the value at ambient temperature, respectively for the RC, 3D_45, 3D_75, 5D_45 and 5D_75 concrete compositions For the 700 °C test series, the values of the relative compressive strength decreased even more presenting a value of 24%, 31%, 29%, 31% and 32%, respectively for the RC, 3D_45, 3D_75, 5D_45 and 5D_75 concrete compositions The reason for this further decreasing on the compressive strength with the temperature is due to the fact that at more or less 600 °C the aggregates undergo a sharp thermal elongation (resulting in internal stresses which cause disintegration of the concrete) Due to the high gel decomposition of the calcium silicate hydrate (C-S-H) that is the component responsible for the mechanical strength of the cement 3.2.3 Comparison of constitutive models A few experimental tests exists in the literature about the mechanical behaviour of high-strength fibre concretes at high temperatues, specialy with these 3D and 5D fibres In this sense Fig 21 SEM images at ambient temperature (a) and after exposure to high temperatures: 200 °C (b); 500 °C (c) and 800 °C (d) 730 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Fig 22 SEM images of concrete with the identification of portlandite (1) and C-S-H (2), and EDS spectrum analysis of the aggregates (1) and cementitious matrix (2) at ambient temperature based on the compiled data, the paper proposes a new compressive strength-temperature relationship for high-strength fibre concretes (HSFC) Table shows the values for the relative compressive strength of a HSFC with calcareous aggregates at ambient and high temperatures Also, based on the results of this experimental work, a constitutive model (Eq (1)) is presented to predict the evolution of stressed compressive strength of the HSFC with calcareous aggregates at high temperatures ( f cm ; h ẳ 300 106 h ỵ 20 h < 300 1:67 103 h ỵ 1:4125 300 h < 700 ð1Þ The model proposed in Eq (1) describes the variation of the relative compressive strength of the concrete subjected at high temperatures and can be implemented in a finite element software for the analysis of HSFC structures in fire conditions The proposed model will be then compared with the experimental data collected and the existing models proposed by others researches In Fig 14 it is possible to observe the proposed model and the results obtained by other authors for the compressive strength of HSFC with calcareous aggregates at ambient and high temperatures; Abrams (1971) (reported in [50]), Castillo (1987) [51], Khoury and Algar (1999) (reported in [52]), Phan and Carino (2003) [52] and Kim et al (2009) [53] Up to 300 °C, the proposed model presents compressive strength values slightly higher than those of other authors, and for this temperature range, this increase in the strength is not problematic since the structural elements still present a great range of resistance until their collapse Between 300 and 700 °C, the compressive strength values of the proposed model are slightly lower and therefore more conservative than the results obtained by other authors In this way, the safety of concrete structures is not compromised Under the preloaded condition, the specimens could not sustain the preload beyond 700° C, the temperature at which the specimens collapse Fig 15 compares the proposed model with the models proposed by other authors as Phan and Carino (2003) [52], Aslani (2013) [50] and Hertz (2005) (reported in [50]) for the stressed compressive strength of HSFC with calcareous aggregates at high temperatures Fig 16 shows the comparison between the proposed model and the ones of Phan and Carino (2003) [52], EC calcareous aggregate concrete (2004) [12], Aslani and Bastami (2011) [54] and Xiao and Ezeliel (2013) [55] and the experimental data by Hager (2013) [32] for unstressed compressive strength of HSFC with calcareous aggregate concrete at elevated temperatures Fig 17 compares the proposed model with EC [12], the experimental data by Kim et al (2009) [56] and Santos et al (2009) [57] and with two different patterns proposed by Aslani and Samali (2014) [3] The proposed model presents a reasonable adjustment for the experimental data and the models of the other authors 3.2.4 Influence of the fibre geometry and content The influence of the temperature on the compressive strength is essential for verifying the impact of the geometry and content of the steel fibres on the compressive strength at high temperatures of the concrete (Fig 18) In Fig 18 it can be observed for all tested temperatures that the addition of steel fibers to the concrete contributed to increasing the compressive strength At ambient temperature, it is found that for the dosage of 45 kg/m3 the compressive strength presented by the compositions with 3D and 5D steel fibers are very similar to each other However, for the dosage of 75 kg/m3 the 5D steel fibers showed a higher compressive strength than the 3D steel fibers concrete composition At 300 °C, it is seen that the addition of 45 and 75 kg/m3 of steel fibers to the concrete causes an enhancement on the compressive strength, as compared to the compressive strength presented by the composition without steel fibers As far as 3D and 5D steel fibers are concerned, the compositions with 45 and 75 kg/m3 of H Caetano et al / Construction and Building Materials 199 (2019) 717–736 3D steel fibers obtained better results of compressive strength as compared to the respective compositions with 5D steel fibers At 500 °C it is found that for both the 45 and 75 kg/m3, the concrete compositions using the 5D steel fibers showed higher values of compressive strength than the concrete compositions with 3D steel fibers At 700 °C, it is observed that for the 45 kg/m3 content of steel fibers, the compressive strength is practically the same for the 3D and 5D steel fibers concretes However, for the 75 kg/m3 content, the 5D steel fibers have slightly higher values of compressive strength when compared to the 3D fibers concrete 3.2.5 Specimens after compressive tests In Table are illustrated the specimens after compression tests at different temperature levels It is possible to observe the colour change in the test specimens due to their exposure to different temperature levels and to observe that the fibres allowed to keep the two parts of the specimen together after reaching the maximum peak of compressive strength 3.3 TGA-DTA tests The TGA-DTA curves for the RC concrete is shown in Fig 19 The different thermal events can be observed Both the weight loss 731 between the 25 and 200 °C (2.20%) and the broad endothermic peak are due to vaporisation of the free water and decomposition of the C-S-H [32,58] The weight loss between the 200 and 400 °C was 1.21% This slight variation in weight may result from the continuous dehydration of the C–S–H [59–61] According to several authors [62,63] the variation in weight between 200 and 400 °C is mainly due to the loss of water as well as the first stage of dehydration and breakdown of the C–S–H Between 400 and 500 °C, 0.79% weight loss was still observed This weight loss is associated with an endothermic peak as a result of the decomposition of the portlandite (CaOH2) into free lime (dihydroxylation) [60–66] The portlandite content was 1.60% The endothermic peak at 573 °C can be observed and is due to the transformation of quartz-a into quartz-b, corresponding to the transition phase a ? b This transformation occurs with an expansion (microcracks on siliceous aggregates) Between 600 and 900 °C, there is the highest endothermic peak linked with the highest weight loss as well as two phenomena: i) direct result of the decarbonisation of the CaCO3 (mainly from the aggregates) and ii) formation of C2S [60] The last endothermic peak at 850 °C was associated with the decomposition of the dolomite The calcium carbonate content (calcite) was calculated by the Fig 23 SEM images of concrete with the identification of steel fibres (1), calcareous aggregate (2) and cementitious matrix (3) and EDS spectrum analysis, after exposure to 200 °C 732 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Fig 24 SEM images of concrete with the identification of steel fibres (1), calcareous aggregate (2) and cementitious matrix (3) and EDS spectrum analysis, after exposure to 500 °C TGA and is 62% Dollimore et al [67] stated that the portlandite’s dissociation starts at around 780 °C, causing a high variation of mass at about this temperature Subsequently, the breakdown of the CaCO3 occurs near a temperature of 900 °C The decomposition of these two last compounds causes a drastic deterioration of the cementitious matrix and the aggregates 3.4 XRD tests The XRD patterns obtained at ambient temperature and 200, 500 and 1000 °C for the X-ray diffraction of the RC concrete are illustrated in Fig 20 The results obtained in the diffractogram at ambient temperature and of the sample heated up to 200 °C allowed identifying the presence of different crystalline phases, such as portlandite (CaOH), calcite (C) and quartz (Q) The last phase is present in the siliceous aggregate (sand) Although calcium silicate hydrate (C-S-H) is a common product in the hydration of the Portland cement, it has an amorphous structure, which is why it is not detected in the diffractogram Also, the phases found at 20 and 200 °C are the same, so it is possible to conclude that up to 200 °C there are no significant changes in the structure of the concrete It is no longer the case for temperatures of 500 °C since only quartz and calcite can be found These results confirm that portlandite (CaOH2) decomposes before 500 °C, more precisely between 400 and 450 °C, as reported by other authors [60–65] At 1000 °C, the results obtained by X-ray diffraction revealed the presence of different crystalline phases such as quartz, cristobalite, calcium oxide and larnite (Ca2SiO4) Larnite was obtained from the decomposition of the C-S-H, and the calcium oxide was a direct result of the decarbonisation of the CaCO3 [68] Mineral cristobalite is a high-temperature polymorph of silica All XRD results agree with the TGA-DTA ones 3.5 SEM-EDS tests These tests allowed a quick visual determination of the groups of different chemical compositions constituting a complex material, as well as the identification of microcracks, partial dete- H Caetano et al / Construction and Building Materials 199 (2019) 717–736 733 Fig 25 SEM images of concrete with the identification of steel fibres (1), calcareous aggregate (2), and cementitious matrix (3) and EDS spectrum analysis, after exposure to 800 °C rioration of the CH and C-S-H and formation of calcium oxide crystals Fig 21 presents the SEM images obtained with scanning electronic microscopy at ambient and high temperatures with x100 magnification In the SEM images at ambient temperature and 200 °C (Fig 21a, b, 22 and 23), no visible cracking could be distinguished, and the surface of the concrete did not exhibit deterioration Between 500 and 800 °C, physicochemical changes in the cement paste and aggregates occurred (Figs 21c and 24) Sand quartz (SiO2) experiences allotropic transformations from quartza to quartz-b accompanied by an expansion of nearly 0.8% in volume at 573 °C The calcareous aggregates become unstable at 600 °C due to transformation of the calcium carbonate (CaCO3) into calcium oxide (lime – CaO) and carbon dioxide (CO2), and between 600 and 900 °C, calcium carbonate (C–S–H) decomposes into calcium oxide (lime - CaO) and forms b-C2S [69] At 800 °C (Figs 21d and 25) the cracks’ pattern was more pronounced, and the cement matrix was strongly deteriorated Figs 21–24 present some micrographs of concrete specimens at ambient temperature (a) and after exposure to high temperatures: b) 200 °C; c) 500 °C and d) 800 °C (See Fig 25) Fig 26 presents SEM images, with x30000 magnification, of specimens at ambient temperature (a) and after exposure to high temperatures: b) 200 °C; c) 500 °C and d) 800 °C The SEM images (Fig 26a) and b)) allowed to observe the presence of portlandite (CaOH2) and calcium silicate hydrate (C-S-H), and to verify that between 20 and 200 °C, from a microstructural point of view, there was not any sensible degradation of the concrete According to different authors, portlandite and C-S-H remained intact until 300 °C At 300 °C, the degradation of these solids started [70–73] in addition to the appearance of nonhydrated cement particles [73] Between 450 and 550 °C, portlandite starts decomposing into free lime (dihydroxylation) [11,18], and in Fig 26 c) it is no longer possible to observe portlandite crystals Wang [71], Kim [73] and Lim [72] pointed out that at 500 °C, the hexagonal portlandite crystals started to deform Between 500 and 800 °C, portlandite and the calcium silicate hydrate (C-S-H) were completely decomposed, producing voids and cracks, increasing the paste’s porosity In Fig 26 d) it is 734 H Caetano et al / Construction and Building Materials 199 (2019) 717–736 Fig 26 SEM images of concrete with the identification of portlandite (1), C-S-H (2) and calcium oxide (3) at ambient temperature (a) and after exposure to high temperatures: 200 °C (b); 500 °C (c) and 800 °C (d) possible to see calcium oxide crystals which are a direct result of the decarbonisation of the CaCO3 Conclusions and discussion This paper presents the results of experimental work on the behaviour in compression at high temperatures of five high strength fibre concrete compositions (ambient, 300, 500 and 700 °C) The main objective was to evaluate the influence of various parameters that may interfere on the compressive strength of the concrete, such the temperature, the effect of adding steel fibres as well as the steel fibres geometry and amount In addition to compression tests, it was carried out complementary tests to analyse the temperature effect on the concrete microstructure transformation on testing and its implication in the compressive strength at high temperatures The following conclusions can be drawn from the results of this research: - The furnace and test procedure adopted in the tests at high temperatures allowed proper distribution and thermal exposure of the concrete specimens during the tests - As regards the influence of temperature on the variation of the compressive strength, it is verified that at 300 °C the compressive strength tends to be the same as that presented at ambient temperature with a variation of ±10% However, at 500 and 700 °C, a reduction in the value of the compressive strength is observed when compared to the values obtained at ambient temperature between 39 and 44% and 68 and 76%, respectively - In relation to the influence that the steel fibre contents on the compressive strength, except for the temperature of 700 °C and for the 3D steel fibre concrete, all the results showed that the adoption of 75 kg/m3 of steel fibres equals or increases its compressive strength when compared with the ones with 45 kg/m3 or without steel fibres - In relation to the 5D steel fibre concretes and its influence on the compressive strength, it was concluded that at 45 kg/m3 the results of the compressive strength for the concretes with 5D steel fibres are equal or smaller than the results for the ones with 3D steel fibres, except for the 500 °C Regarding the content of 75 kg/m3, the results showed that there is a slight advantage in the adoption of 5D steel fibres compared to the 3D steel fibres, except for the 500 °C - The proposed model for preloaded HSFC with calcareous aggregates at ambient and high temperatures fit well with the experimental results obtained and also show close agreement with other existing models for HSFC - The proposed model has two crucial temperature zones which reflect the practical design needs and main concrete behaviour changes in fire, and it becomes simple for both manual design calculations and finite element computational analysis - The proposed model can be implemented in a finite element software to perform the analysis of structural elements subjected to high temperatures - Between 20 and 200 °C, it is not possible to microscopically identify any significant change in the concrete structure since the crystalline phases identified in the XRD tests are the same H Caetano et al / Construction and Building Materials 199 (2019) 717–736 However, there is a small loss of mass of the concrete, found in the TGA-DTA tests due to the evaporation of water and the existence of an endothermic reaction linked to the decomposition of the calcium silicate hydrate (C-S-H) - Between 200 and 400 °C, the dehydration process of the calcium silicate hydrate (C-S-H) continued gradually and the loss of mass decreased slightly, however, except for a significant increase in cracking, there is no endothermic reaction in the thermogravimetry graph, which means that significant microstructural changes in the concrete’s morphology are not identified - For temperatures between 400 and 700 °C, more precisely between 420 and 500 °C, an endothermic peak is observed in the TGA-DTA tests, accompanied by a reduction in mass, which results in the dihydroxylation of the portlandite (CaCO3) leading to calcium oxide The absence of the crystalline phase of the portlandite in the XRD tests and its absence in the SEM observations confirm the occurrence of this transformation - Between 700 and 900 °C, although the loss in mass increases with the temperature, it is at 700 °C that the greatest loss in mass occurs and in a more abrupt way This phenomenon is essential for the decarbonisation of the limestone aggregates, generating more calcium oxide Also, it is in this temperature range that another endothermic reaction takes place, and new crystalline phases originate as in the case of the cristobalite and larnite Since the decarbonisation of the limestone aggregates occurs, the microstructural strength of the concrete is seriously compromised, and the main consequence of this transformation is the inability of the concrete to provide mechanical resistance to the pressure that is exerted on it Conflict of interest None Acknowledgements The authors gratefully acknowledge to SECIL S.A (www.secil pt), BEKAERT (www.bekaert.com), SIKA (pt.sika.com) for their support in this investigation and Brazilian National Council for Scientific and Technological Development – CNPq (http://cnpq.br/) for the post-doc scholarship given to the second author References [1] F Aslani, B Samali, Predicting the bond between concrete and reinforcing steel at elevated temperatures, Struct Eng Mech 48 (5) (2013) 643–660 [2] F Aslani, B Samali, Flexural toughness characteristics of self-compacting concrete incorporating steel and polypropylene fibres, Aust J Struct Eng 15 (3) (2014) 269–286 [3] F Aslani, B Samali, Constitutive relationships for steel fibre reinforced concrete at elevated temperatures, Fire Technol 50 (5) (2014) 1249–1268 [4] N Yermak, P Pliya, A.L Beaucour, A Simon, A Noumowé, Influence of steel and/or polypropylene fibres on the behaviour of concrete at high temperature: spalling, 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and Papinigis [39] They concluded

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Effect of the high temperatures on the microstructure and compressive strength of high strength fibre concretes

1 Introduction

2 Experimental setup and program

2.1 Materials and compositions

2.2 Experimental program

2.3 Specimens

2.4 Experimental Set-ups

2.5 Test procedure

3 Results

3.1 Thermal tests

3.2 Compressive strength

3.2.1 Analysis of results

3.2.2 Temperature influence

3.2.3 Comparison of constitutive models

3.2.4 Influence of the fibre geometry and content

3.2.5 Specimens after compressive tests

3.3 TGA-DTA tests

3.4 XRD tests

3.5 SEM-EDS tests

4 Conclusions and discussion

Conflict of interest

Acknowledgements

References

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