The simulation of fire sprinklers thermal response in presence of water droplets

Ruffino, Paolo; Dimarzo, M.

doi:10.1016/j.firesaf.2004.07.002

Cited by 7 publications

(1 citation statement)

References 12 publications

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“…The water droplet heat and mass transfer at humid atmospheric air is taken into account when assessing atmospheric appearance and creating climate models [1]. Water spray application in air conditioning [2], fire suppression [3][4][5][6][7], gas cooling [8,9] and agricultural irrigation systems [10,11] can be considered as traditional. Heat and mass transfer processes are applied for surface treatment [12][13][14] and protection [15][16][17][18], cooling towers [19][20][21]9,22], washing processes [23][24][25], water freezing and crystallization [26][27][28], aerosols [29,30], gas turbines [31][32][33][34][35], heat recovery from humid flue gas [36,37], NO x reduction in fuel combustion [38][39][40], water and fuel emulsions [41][42][43][44], plasma technique [45]<...>…”

Section: Introductionmentioning

confidence: 99%

Peculiarities of the transit phase transformation regime for water droplets that are slipping in humid gas

Miliauskas

Maziukienė

Ramanauskas

2016

International Journal of Heat and Mass Transfer

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Section: Introductionmentioning

confidence: 99%

Peculiarities of the transit phase transformation regime for water droplets that are slipping in humid gas

Miliauskas

Maziukienė

Ramanauskas

2016

International Journal of Heat and Mass Transfer

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Investigation of the Thermal Characteristics of a Circular Fusible-Type Sprinkler Using the Energy Transport Equation

You

Ryou

2016

Fire Technol

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In this study, we investigate the thermal characteristics of a circular fusible-type sprinkler. Analytic solutions regarding the radial-temperature distribution are obtained by using the energy-transport equation for the heat-responsive element of the sprinkler. When solving the equation, the fitted curves of the measured temperatures derived from the previous correlation of the heat-transfer coefficient are used as the boundary conditions at the element surface. To verify the accuracy of the present approach, the predictions from the use of the analytic solution are compared with the operation-time measurements of the sprinkler; the bulk temperature of the element is then estimated based on these results for the quantification of the operation time of the sprinkler. To verify the present analytic model, we systematically compare the operation time of the sprinkler with those of the response time index (RTI) and modified response time index (RTI v ) models. The results show that the present model can be used for an estimation of both the temperature distribution inside the element and the operation time of the sprinkler. ACross-sectional area per volume of the heat-responsive element (m -1 ) aThermal diffusion coefficient (m 2 /s) C p Specific heat (kJ/kg K) L Length of the heat-responsive element (m) R Radius of the heat-responsive element (m) t Time (s) t r Operation time of the sprinkler head (s) rRadial direction (m) hHeat transfer coefficient (W/m 2 K) uGas velocity (m/s)

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Influence of fire source locations on the actuation of wet-type sprinklers in an office fire

Lai

Tsai

et al. 2010

Building and Environment

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The simulation of fire sprinklers thermal response in presence of water droplets

Cited by 7 publications

References 12 publications

Peculiarities of the transit phase transformation regime for water droplets that are slipping in humid gas

Peculiarities of the transit phase transformation regime for water droplets that are slipping in humid gas

Investigation of the Thermal Characteristics of a Circular Fusible-Type Sprinkler Using the Energy Transport Equation

Influence of fire source locations on the actuation of wet-type sprinklers in an office fire

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