Numerical analysis on the effects of water spraying on cooling tower evaporation and drift

Song, Baohong

doi:10.1088/1755-1315/529/1/012004

Cited by 2 publications

(3 citation statements)

References 6 publications

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“…The maximum occurred in group 1 at 0.0061 kg kg −1 . According to Song, 26 d c is greater than d 2 . This indicates that the exhaust air is oversaturated, and that the analysis based on saturated air is correct.…”

Section: Resultsmentioning

confidence: 99%

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Evaluating vaporization heat, thermal performance, and efficiency of a natural draft wet cooling tower

Song

2022

Proceedings of the Institution of Mechanical Engineers, Part A:

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This study aimed to improve the accuracy of the thermal performance analysis of a natural draft wet cooling tower (NDWCT) and explore the effect factors of the decrease water and energy consumption. In this study, we determined the thermal performance and water loss of the NDWCT under dynamic conditions using mass-balance equations, and obtained water loss from 10.4 kg s−1 to 16.9 kg s−1. The analyzed vaporization heat accounted for 71.5%–86.9% of the total heat flow. Furthermore, the total amount of water discharged exceeded the average standard is 33.06 m3 has been spotted for the first time. Increasing the air-water ratio from 0.38 to 0.77, the cooling efficiency is increased by 44%. The change relationship between water temperature drop, water loss, air enthalpy, and air flow in the tower were discovered and established. The thermal performance analysis model based on water loss and air flow was used, compared with the total heat of the measured data, the maximum deviations were by 4.5% and 1.88%, respectively. The validity of the model was fully verified. These two models were combined with the heat balance equation analysis model based on three variables, which can provide support for optimal operation conditions that the energy savings and water reductions in NDWCTs, and providing convenience and a new reference for thermal performance evaluation, design, and research. Finally, we also proposed the suggestion for improving low efficiency of cooling tower is the most economical operation mode.

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Section: Resultsmentioning

confidence: 99%

“…The total water content d c (kg kg −1 DA) in the air at the tower outlet is calculated using Equation (7), as established by Song 26 where the air humidity ratio is d 1 (kg kg −1 DA) at the tower inlet.…”

Section: Methodsmentioning

confidence: 99%

Evaluating vaporization heat, thermal performance, and efficiency of a natural draft wet cooling tower

Song

2022

Proceedings of the Institution of Mechanical Engineers, Part A:

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“…The calculations and measurements show that this loss is at the level of 0.35 − 0.45% of the water load of the cooling tower. The drift loss given in paper [24], determined for the same cooling tower, is specified at 0.084 − 0.28% of the water flow. Depending on the droplet eliminator installed, the drift loss determined in [3] is in the range of 0.01 − 0.39% of the water.…”

Section: Methodsmentioning

confidence: 99%

Impact of Weather Conditions on the Operation of Power Unit Cooling Towers 905 MWe

et al. 2021

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The paper presents the results of measurements and calculations concerning the influence of weather conditions on the operation of wet cooling towers of 905 MWe units of the Opole Power Plant (Poland). The research concerned the influence of temperature and relative humidity of air, wind and power unit load on the water temperature at the outlet from the cooling tower, the level of water cooling, cooling efficiency and cooling water losses. In the cooling water loss, the evaporation loss stream and the drift loss stream were distinguished. In the analyzed operating conditions of the power unit, for example, an increase in Tamb air by 5 °C (from 20–22˚C to 25-27˚C) causes an increase in temperature at the outlet of the cooling tower by 3-4˚C. The influence of air temperature and humidity on the level of water cooling ΔTw and cooling efficiency ε were also found. In the case of ΔTw, the effect is in the order of 0.1-0.2˚C and results from the change in cooling water temperature and the heat exchange in the condenser. The ε value is influenced by air temperature and humidity, which determine the wet bulb temperature value. Within the range of power changes of the unit from 400 to 900 MWe, the evaporated water stream mev, depending on the environmental conditions, increases from 400-600 tons/h to the value of 1000-1400 tons/h. It was determined that in the case of the average power of the unit at the level of 576.6 MWe, the average values of the evaporation and drift streams were respectively 0.78% and 0.15% of the cooling water stream. Using statistical methods, it was found that the influence of wind on the level of water cooling, cooling efficiency and cooling water losses was statistically significant.

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Numerical analysis on the effects of water spraying on cooling tower evaporation and drift

Cited by 2 publications

References 6 publications

Evaluating vaporization heat, thermal performance, and efficiency of a natural draft wet cooling tower

Evaluating vaporization heat, thermal performance, and efficiency of a natural draft wet cooling tower

Impact of Weather Conditions on the Operation of Power Unit Cooling Towers 905 MWe

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