IMPACT OF THE UV LAMP POWER ON THE FORMATION OF SWIMMING POOL WATER TREATMENT BY-PRODUCTS

UV lamps are being increasingly used in the treatment of swimming pool water, mainly due to their abilities to disinfect and effectively remove chloramines (combined chlorine). However, the application of UV lamps in a closed loop system, such as that in which swimming pool water is treated, creates conditions under which chlorinated water is then also irradiated with UV. Thus, the advanced oxidation process occurs, which affects the transformation of organic matter and its increased reactivity, and hence the higher usage of chlorine disinfectant. In addition, UV lamps require electrical power and the periodic replacement of filaments. In order to assess whether the application of a low-pressure UV lamp is justified, water quality tests and an analysis of the operating costs (including the energy consumption) of the water treatment system were carried out for two operation variants—those of the low-pressure UV lamp being turned on and off. The experiments were carried out on the real object of the AGH University of Science and Technology sports swimming pool for one year. The consumption of electricity and water treatment reagents was also measured. The following values of the selected parameters of the swimming pool water quality were observed (for without and with UV lamp, respectively): 0.68 and 0.52 mg/L combined chlorine; 3.12 and 3.02 mg/L dissolved organic carbon; 15.70 and 15.26 µg/L trihalomethanes; 7 and 6 cfu/mL mesophilic bacteria; and 6 and 20 cfu/mL psychrophilic bacteria. Generally, the statistically important differences in water quality parameters were not observed, thus the application of the low-pressure UV lamp in the swimming pool water treatment technology did not bring the expected improvement in water quality. However, the higher consumption of electric energy (by 29%) and chlorine disinfectant (by 15%), and the need to periodically replace the lamp filaments significantly increased the operating costs of the water treatment system (by 21%) and its ecological impact, thus this technology cannot be considered as profitable or ecological.

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Swimming Pool Water Treatment

American Water Works Association ◽

10.1002/j.1551-8833.1940.tb12393.x ◽

1940 ◽

Vol 32 (1) ◽

pp. 105-114

Author(s):

Herbert L. White

Keyword(s):

Water Treatment ◽

Swimming Pool ◽

Pool Water ◽

Swimming Pool Water

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Formation of disinfection by-products in indoor swimming pool water: The contribution from filling water natural organic matter and swimmer body fluids

Water Research ◽

10.1016/j.watres.2010.09.031 ◽

2011 ◽

Vol 45 (2) ◽

pp. 926-932 ◽

Cited By ~ 97

Author(s):

Amer Kanan ◽

Tanju Karanfil

Keyword(s):

Organic Matter ◽

Natural Organic Matter ◽

Body Fluids ◽

Swimming Pool ◽

Pool Water ◽

Indoor Swimming Pool ◽

Filling Water ◽

Swimming Pool Water ◽

By Products

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Impact of swimming pool water treatment system factors on the content of selected disinfection by-products

Environmental Monitoring and Assessment ◽

10.1007/s10661-020-08683-7 ◽

2020 ◽

Vol 192 (11) ◽

Author(s):

Joanna Wyczarska-Kokot ◽

Anna Lempart-Rapacewicz ◽

Mariusz Dudziak ◽

Edyta Łaskawiec

Keyword(s):

Water Treatment ◽

Average Concentration ◽

Swimming Pool ◽

Water Volume ◽

Operational Parameters ◽

Technological Parameters ◽

Pool Water ◽

Limit Value ◽

Hot Tubs ◽

By Products

AbstractRecommendations regarding disinfection by-products (DBPs) in pool waters consider the content of trihalomethanes (THMs) and combined chlorine (CC) as indicators of DBPs based on which the health risk for swimmers and staff of pool facility can be determined. However, the content of DBPs in swimming pools depends on many factors. In this paper, the influence of selected factors (physicochemical parameters of water and technological parameters) on the content of THMs and CC in pool water was determined. During the 6-month period, 9 pools of various functions were analyzed. The water in pools was subjected to the same method of treatment. The content of THMs and CC was compared against the content of organic matter, free chlorine and nitrates, pH, temperature, redox potential and turbidity, technological, and operational parameters. The THM content did not exceed the limit value of 0.1 mg/L. The content of CC varied significantly, from 0.05 to 1.13 mg Cl2/L. It was found that a very large water volume per person, in comparison to a very small one, contributed to the low content of CC and THMs. The high load expressed as m3 of water per person or m2 of water per person and the specific function of hot tubs (HT1 and HT2) led to the average concentration of CC in these pools exceeding 0.3 mg Cl2/L. The THM concentrations in hot tubs (especially in HT1) were also among the largest (0.038–0.058 mg/L). In terms of the analyzed microbiological indicators, the quality of the tested pool water samples was not in doubt. It was found that the purpose of the pool, its volume, and number of swimmers should be the key parameters that determine the choice of methods of water treatment. The research on the pool water quality in the actual working conditions of swimming pool facilities is necessary due to the need to preserve the health safety of swimmers and staff.

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