Numerical studies on an accidental flashfire at a water fun park by FLACS software

Ho, Hsin-Hsiu; Ho, San-Ping; Chen, Chin-Feng; Chang, Hui-Pei; Xie, Bin; Cheng, C.S. Agnes; Chow, Wan Ki

doi:10.2298/tsci200718304h

Cited by 3 publications

(5 citation statements)

References 24 publications

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“…The laminar mixed convection heat transfer of a copper-water nanofluid inside a microtube with a curvature angle of 90° was numerically investigated by Akbari et al [24] In this research conducted by Saghir et al [26], a cavity-based approach for the numerical modeling (single-phase & two-phase) of thermo fluidic flow for an Al2O3-water nanofluid has been conducted to compare to the experimental data of Ho et al [27]. The numerical simulation was performed using the finite element method for a range of nanoparticle concentrations of 1 %vol-3%vol.…”

Section: Inlet Temperature Of Water (K) 308mentioning

confidence: 99%

The Effects of Thermophoresis and Brownian Motion on the Flow of a Nanofluid in Rectangular Channels Using Buongiorno’s Model

Ghalayini

2024

Preprint

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Nanofluids is an emerging sector of working fluids that promise to enhance heat transfer by increasing fluids’ thermal conductivity by inputting metal nanoparticles into a base fluid. There are two ways of modelling nanofluids; single-phase and two-phase. Since nanoparticle sedimentation may influence heat extraction, the Buongiorno two-phase model will be of focus to understand Brownian motion as well as thermophoretic effects on nanofluids. This research presents the case of investigating the thermal performance of plain water, as well as Al 2 -3ater and TiO -2ater nanofluids with varying concentrations and flow rates in rectangular channelled configurations. The results revealed that the Nusselt number and thermal efficiency index augmented by increasing the Reynolds number and nanoparticle concentrations. Furthermore, higher Reynolds numbers and nanoparticle concentrations increased homogeneity in nanoparticle distributions. Lastly, 2 and 3-channel configurations were utilized in the study, the 2-channel model yielded symmetrical flow allowing uniform nanoparticle distributions, leading to higher thermal efficiencies.

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Section: Inlet Temperature Of Water (K) 308mentioning

confidence: 99%

The Effects of Thermophoresis and Brownian Motion on the Flow of a Nanofluid in Rectangular Channels Using Buongiorno’s Model

Ghalayini

2024

Preprint

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“…A general correlation was provided by Vafai and Khanafer 14 for the thermal conductivity of CuO/water nanofluids and Al2O3/water as: (12) This correlation is developed for nanoparticle size within the range of 13-80 nm and volume fractions of over 15%. The following empirical correlation was proposed by Ho et al 15 for alumina/water nanofluids' thermal conductivity with the size of nanoparticles just as 33 nm:…”

Section: Experimental Correlationsmentioning

confidence: 99%

“…Based on the experimental data, Ho et al 15 offered a correlation for predicting the viscosity of alumina/water nanofluids in which the nanoparticles'size is 33 nm (valid for Φ 4%):…”

Section: Experimental Correlationsmentioning

confidence: 99%

“…Because of the high effect of thermal conductivity and viscosity on the convection heat transfer coefficient, the required power for pumping, and heat transfer rate, an artificial neural network (ANN) was implemented to predict the mentioned parameters in nanofluids more accurately. 0.0005854 valid for volume fractions of less than 4% Batchelor 18 0.0005915 considered the effect due to the Brownian motion of particles for an isotropic suspension of rigid and spherical particles Maiga 19 0.001331 Al2O3-water and Al2O3-EG nanofluids Ho 15 0.001672 valid for Al2O3-water nanofluids, dp= 33 nm Φ  4% Williams 16 0.0403 γ-Al2O3/water nanofluid Table 3 Comparing the predicted values of thermal conductivity of 𝛾-Al2O3/water nanofluids using different models…”

Section: Specific Heat Capacity (Cpnf)mentioning

confidence: 99%

“…0.866 spherical particles -Φ  1% Bruggeman 7 1.082 considering the interactions between spherical particles Hamilton and Crosser 5 0.866 developing the Maxwell model by adding a shape factor Yu and Choi 8 1.1068 liquid nanolayer Xue et al 11 1.115 nanosuspensions containing carbon nanotubes (CNTs) Maiga 12 0.868 Al2O3/water nanofluid, dp= 28 nm Khanafer and Vafai 14 1.551 CuO/water -Al2O3/water nanofluids, dp = 13-80 nm Williams et al 16 0.953 γ-Al2O3/water nanofluid Ho et al 15 0.979 Al2O3/water nanofluid, dp= 33 nm -(Φ  4%)…”

Section: Model Andcorrelation K (W/m•k) Condition Maxwel L4mentioning

confidence: 99%

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Prediction of some physical properties of nanofluids including various metal oxides using artificial neural network

RAEI,

BOZORGIAN

2024

Rev.Roum.Chim.

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In this study, physical properties of nanofluids such as viscosity and thermal conductivity are investigated. Although there are many experimental and theoretical correlations and models available to predict these parameters, predictions are highly conflicting because the involved mechanisms are not fully understood. For instance, the predicted values of dynamic viscosity of 𝛾-Al2O3/water nanofluids (at a volume fraction of 0.001) by different models range between 0.0005623 and 0.0403 kg/m.s and thermal conductivity ranges within 0.866 and 1.551 W/m.K under the same conditions. In this work, 184 experimental data of thermophysical properties of various metal oxide nanoparticle including Al2O3, SiO2, TiO2, Fe2O3, MgO, and CuO at a temperature range of 30 to 65 oC, diameter range of 10 to 50 nm, and volume fraction between 0.004% to 2% were collected from various publications. In this work, artificial neural network (ANN) has been implemented. The parameters of thermal conductivity and dynamic viscosity have been correlated to nanofluid concentration, temperature, particle size and molecular weight. It has been found that the topography of )4, 4, 4) from the ANN provides about 2% and 1% cross-validating and testing error respectively. Additionally, a sensitivity analysis was performed and the effect of individual parameters was analyzed.

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Discussion of thermal activation on heat collection plate of sprinkler heads

Szeto,

Wu,

Chow

et al. 2024

THERM SCI

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Heat collection plates (HCP) are installed above sprinkler heads in some tall halls in the Asia-Oceania region to give faster thermal actuation. In this study, experiments were thus conducted in a fire chamber to determine thermal activation times of sprinkler heads with and without HCP. Three HCPs with different diameters were selected and tested with pendent fast response liquid-in-bulb sprinkler heads. A total of 48 sprinklers heads were studied under different conditions of height and pool fire size. HCP was found to reduce sprinkler activation time in a fire chamber test by up to 61%. Thermal activation time of sprinkler heads was also investigated by the common plunge test in a wind tunnel. Results indicate that activation was delayed by 5%, 18% and 221% on average by the three HCPs. An HCP of pie plate shape with small diameter would alter the physical scenario of heating up the heat sensing element of sprinkler heads assumed in the plunge test. Therefore, the effect of HCP cannot be appropriately assessed in a wind tunnel.

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Numerical studies on an accidental flashfire at a water fun park by FLACS software

Cited by 3 publications

References 24 publications

The Effects of Thermophoresis and Brownian Motion on the Flow of a Nanofluid in Rectangular Channels Using Buongiorno’s Model

The Effects of Thermophoresis and Brownian Motion on the Flow of a Nanofluid in Rectangular Channels Using Buongiorno’s Model

Prediction of some physical properties of nanofluids including various metal oxides using artificial neural network

Discussion of thermal activation on heat collection plate of sprinkler heads

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