Experimental data on compressive and flexural strengths of coir fibre reinforced foamed concrete at elevated temperatures

Quantifying the elevated temperature strengths of cement-based material is crucial to the design of building structural systems for fire resistance purpose. This paper collates a database of elevated temperature axial compressive and flexural strengths of coir fibre reinforced foamed concrete exposed to heating temperatures of 105 °C, 200 °C, 300 °C, 400 °C, 500 °C, 600 °C, 700 °C and 800 °C. There were four densities of foamed concrete of 700, 1100, 1500 and 1900 kg/m3 were prepared and tested. The untreated coir fibre was added in foamed concrete in percentages of 0.1%, 0.2%, 0.3%, 0.4%, 0.5%, and 0.6% by mix volume fraction. The database can aid in prediction of elevated temperature strengths of fibre reinforced foamed concrete which can be exploited to assist manufacturers to develop their products without having to perform numerous large-scale elevated temperature tests in the future.


Data
This dataset described herein were acquired from the experimental studies conducted to determine the elevated temperature compressive strength and flexural strength of coir fibre reinforced foamed concrete exposed to heating temperatures of 105 C, 200 C, 300 C, 400 C, 500 C, 600 C, 700 C and 800 C. Figs. 2, 4, 6 and 8 show the compressive strength of 700, 1100, 1500 and 1900 kg/m 3 density foamed concrete respectively as a function of temperature. Figs. 3, 5, 7 and 9 demonstrate the normalized compressive strength of 700, 1100, 1500 and 1900 kg/m 3 density foamed concrete correspondingly as a function of temperature. In Tables 1e4, percentages of compressive strength retained at each predetermined exposed temperature were summarized for 700, 1100, 1500 and 1900 kg/m 3 density foamed concrete respectively. Next, Figs. 10, 12, 14 and 16 display the flexural strength of 700, 1100, 1500 and 1900 kg/m 3 density foamed concrete correspondingly as a function of temperature whereas Figs. 11, 13, 15 and 17 exhibit the normalized flexural strength of 700, 1100, 1500 and 1900 kg/ m 3 density foamed concrete respectively as a function of temperature. In Tables 5e8, percentages of flexural strength retained at each predetermined exposed temperature were tabulated for 700, 1100, 1500 and 1900 kg/m 3 density foamed concrete respectively. Heating temperatures of 105 C, 200 C, 300 C, 400 C, 500 C, 600 C, 700 C and 800 C Experimental features Untreated coir fibre of was added in foamed concrete in percentages of 0.1%, 0.2%, 0.3%, 0.4%, 0.5%, and 0.6% by mix volume. Densities of 700, 1100, 1500 and 1900 kg/m 3 were cast and tested to determine the elevated temperature mechanical properties such as compressive and flexural strengths. The electric furnace temperature exposure profiles were produced by a programmable microprocessor temperature controller attached to the furnace power supply and monitored by a Type K thermocouple located in the furnace chamber. Data source location Penang, Malaysia Data accessibility The data are available within this article Value of the data This database is beneficial because foamed concrete is a widely used material and relevant information on its uses can be very significant particularly when it is exposed to high temperature and fire condition The database can assist as an experimental framework for the analysis of other high temperature properties of foamed concrete The test data allows for exploration on the use of coir fibre as another possible waste material for reinforcement of foamed concrete which tend to be very brittle especially at high temperatures The database may be relevant in the development of standards or codes of practice for foamed concrete exposed to elevated temperatures The database presented can be used to develop an optimum method for production of foamed concrete for fire resistance purpose Table 1 Percentage of 700 kg/m 3 density foamed concrete compressive strength retained at predetermined exposed temperature.

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Exposed temperature ( C)

Experimental design, materials, and methods
The research program started with mix design process and formulation of foamed concrete with the addition of coir fibre (by volume fraction). Moreover, it should be noted that the foamed concrete mix Table 2 Percentage of 1100 kg/m 3 density lightweight foamed concrete compressive strength retained at predetermined exposed temperature.

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Exposed temperature ( C) Table 3 Percentage of 1500 kg/m 3 density foamed concrete compressive strength retained at predetermined exposed temperature.

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Exposed temperature ( C) Table 4 Percentage of 1900 kg/m 3 density foamed concrete compressive strength retained at predetermined exposed temperature.

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Exposed temperature ( C)  Table 5 Percentage of 700 kg/m 3 density lightweight foamed concrete flexural strength retained at predetermined exposed temperature.

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Exposed temperature ( C) proportions (sand: cement: water) was fixed at the ratio of 1:1.5:0.45. Meanwhile, several mixtures were also prepared with different percentages of coir fibre as follows: 0.1%, 0.2%, 0.3%, 0.4%, 0.5%, and 0.6% by mix volume. Next, four different densities of 700, 1100, 1500 and 1900 kg/m 3 were prepared. Small variations in the densities will only produce small values in the properties; thus these four densities were opted in this study to have comparable results for a better understanding of the properties when exposed to elevated temperatures. The 700 kg/m 3 density can be considered for nonstructural application, 1100 and 1500 kg/m 3 densities for semi-structural application and 1900 kg/m 3 density for structural purpose. The next step involved the production of the foamed concrete specimens in substantial quantities which was put through curing process, followed by the exposure to oven drying with the aim of achieving the target densities. Following this process, the specimens underwent moisture curing for specific days (sealed cured with plastic sheets). Elevated temperature test was conducted at day-28.
Electric furnace was used for heating the LFC specimens to the various steady-state temperatures. Heating temperatures were set at 105 C, 200 C, 300 C, 400 C, 500 C, 600 C, 700 C and 800 C. The Table 7 Percentage of 1500 kg/m 3 density lightweight foamed concrete flexural strength retained at predetermined exposed temperature.

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Exposed temperature ( C)  Table 8 Percentage of 1900 kg/m 3 density lightweight foamed concrete flexural strength retained at predetermined exposed temperature.

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Exposed temperature ( C)  Table 6 Percentage of 1100 kg/m 3 density foamed concrete flexural strength retained at predetermined exposed temperature.

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Exposed temperature ( C) electric furnace temperature exposure profiles were produced by a programmable microprocessor temperature controller attached to the furnace power supply and monitored by a Type K thermocouple located in the furnace chamber. The high temperature furnace (Fig. 1) had a maximum operating temperature of 1200 C. Pre-testing checking of the furnace showed that the furnace controllers and furnace power system could maintain furnace operating temperatures within ±1 C over the test range. The elevated temperature compressive strength test was conducted using universal testing machine with the capacity of 3000KN. In the context of the present study, the test was performed in accordance with BS EN 12390-3:2009 [1] using a cubic shaped specimen with the size of 100 mm Â 100 mm x 100mm. The loading rate for compression and flexural tests was set at 0.2 N/sec. Fig. 1. Foamed concrete specimens were exposed to elevated temperatures.               For elevated temperature flexural strength test, rectangular beam of 100mmx100 mm Â 500 mm was employed, while the two points loading arrangement was utilized according to the method BS 1521:1997 [2]. The nominal distance between the supports was 300mmIn addition, the rollers enabled free horizontal movement, while the samples of foamed concrete specimens were applied at a constant displacement rate of 0.2 N/sec based on the optimum value determined experimentally.
Loading was applied after removing the test specimens from the electric furnace. Each specimen was wrapped with insulation sheets immediately after being removed from the electric furnace to minimize heat loss from the specimen to atmosphere. For each set, three replicate tests were carried out to check consistency of results. During the loading process, the temperature of each sample was measured and it was found that the temperature was stable throughout the testing period.