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Academic literature on the topic 'Swimming pools Victoria Sanitation'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "Swimming pools Victoria Sanitation"

1

Xiao-Juan, Huang, Guan Qing, and Yu Chun-Wei. "Detection of Haloacetic Acid in Swimming Pool in Haikou and Its Influencing Factors." Academic Journal of Chemistry, no. 74 (December 6, 2022): 55–60. http://dx.doi.org/10.32861/ajc.74.55.60.

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Chlorine disinfection is a commonly applied disinfection products due to its effectiveness, strong disinfection ability, and low cost. The objective of this study is to investigate the occurrence of haloacetic acids (HAAs), a group of disinfection byproducts, in swimming pool and spa water, and analyze its influencing factors, so as to provide reference to understand the pollution status of haloacetic acid (HAAs) disinfection byproducts in swimming pool water in Haikou, for the formulation of hygienic standards and sanitation management of HAAs in swimming pool water. The samples were collected from 18 swimming places with sanitary licenses in Haikou. For a period from April to July 2022. High performance liquid chromatography -tandem mass spectrometry (HPLC-MS) was used to detect the concentration of HAAs in swimming pool water, and its influencing factors were also analyzed. . Results indicated that the levels of average concentration of HAAs in indoor and outdoor swimming pools were 176.20 μg•L-1 and 241.53 μg•L-1, respectively. There were differences in the levels of HAAs in indoor and outdoor swimming places (p<0.05). The Pearson correlation analysis showed that the concentration of HAAs was positively correlated with free chlorine and urea (p<0.05). The water quality and sanitation of the swimming pools in this survey were somewhat poor. It is necessary to formulate the regulation of HAAs in the swimming pool sanitation standards, strengthen the water quality sanitation management, and take further effective measures to reduce the concentration of HAAs to protect swimmers.
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2

Pantazidou, G., ME Dimitrakopoulou, C. Kotsalou, J. Velissari, and A. Vantarakis. "Risk Analysis of Otitis Externa (Swimmer’s Ear) in Children Pool Swimmers: A Case Study from Greece." Water 14, no. 13 (June 21, 2022): 1983. http://dx.doi.org/10.3390/w14131983.

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Otitis is an ear inflammation characterized by an accumulation of polluted fluids in the ear, inflating the drum, causing ear pain, and draining the mucous membrane (pus) into the ear canal if the drum is perforated. Swimmer’s otitis, also known as acute external otitis, is a medical condition that frequently affects competitive swimmers. The risk factor analysis study was based on data obtained between May 2018 and May 2019 from four public swimming pools in Patras, Achaia. A checklist was created to evaluate the pools’ operational conditions, and it included information on the pools’ sanitation as well as swimming pool hygiene guidelines. In addition, a questionnaire was devised to collect data on pool swimmers’ use of the pools. Microbiological testing of the pool water was done ahead of time, and data on external otitis cases from hospitals was gathered. Based on this information, a risk factor analysis was conducted. Gender, weight, and age do not appear to have an impact on the number of otitis media cases that occur because of swimming in the pools. There is also no statistically significant link between episodes and the frequency of otitis events in locker rooms, restrooms, or swimming pools. The frequency with which swimmers utilize the pool, rather than the pool’s microbial burden, is the most significant determinant in otitis episodes. Furthermore, there is no statistically significant link between chlorine odor and otitis episodes. Additionally, several abnormalities in the ear or the child’s history do not appear to affect otitis episodes. More research is needed to determine whether infections are linked to microbial load or if other factors are responsible for the emergence of waterborne infections.
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3

Darajat, Endang. "Kesesuaian Risiko Pencemaran Antara Inspeksi Sanitasi dan Pemeriksaan Bakteriologi pada Air Kolam Renang di DKI Jakarta, 2005." Kesmas: National Public Health Journal 1, no. 2 (October 1, 2006): 69. http://dx.doi.org/10.21109/kesmas.v1i2.315.

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Di Jakarta, setiap hari diperkirakan 8000 orang melakukan aktifitas berenang yang membutuhkan air bersih dalam jumlah yang besar. Air bersih yang digu-nakan berasal dari air tanah dan Perusahaan Air Minum DKI Jakarta. Jumlah orang yang berenang sangat mempengaruhi kualitas air kolam renang yang harus terus dipertahankan agar terhindar dari risiko pencemaran. Penelitian ini bertujuan mengetahui kesesuaian hasil pengukuran risiko pencemaran de-ngan inspeksi sanitasi dan pemeriksaan bakteriologik pada air kolam renang di DKI jakarta tahun 2005 Penelitian yang menggunakan disain studi cross sec-tional mengamati mengamati 30 kolam renang. Variabel yang didiamati adalah 13 variabel inspeksi sanitasi dengan menggunakan adalah univariat dan bi-variat. Hitemukan bahwa 13 (44 %) air kolam renang menunjukkan tingkat risiko pencemaran rendah dan 17 (56%) air kolam renang menunjukkan tingkatrisiko pencemaran tinggi. Sedangkan untuk kualitas bakteriologik diketahui 11 (36,7%) air kolam renang berkualitas baik dan 19 (63,3%) air kolam renangberkualitas buruk. Kesesuaian yang diperoleh adalah 0,733 yang berarti nilai kesesuaian yang baik. Variabel isi air memiliki tingkat risiko pencemaran pa-ling tinggi. Berdasarkan aspek inspeksi sanitasi didapat 8 aspek prediktif dan 5 aspek non–prediktif. Perlu dilakukan pemeriksaan air kolam renang secara berkala serta penyuluhan dan bimbingan pada pengelola kolam renang dan masyarakat tentang kualitas air kolam renang yang baik terhadap kesehatan.Kata Kunci : Kesesuaian, risiko pencemaran, Inspeksi Sanitasi, Kualitas Bakteriologik, Air Kolam Renang, DKI Jakarta.AbstractIt was estimated in Jakarta, more then 8000 people swim everyday, so it requires height volume of clean water that comes from ground water as well as DKI Jakarta Municipal Water Corporation. The quality of the swimming pool water will affect the people health. By conducting surveillance, we are able to know the quality of the water and recommending intervention when needed. The objective of this research is to obtain information about compatibility pollution risk level between measurement results of sanitary inspection and bacteriological assessment of the swimming pool water in Jakarta 2005. The research used a sectional cross design with total sample of 30 swimming pools. Variable used in this research are 13 sanitation inspection variables and analized using bivariate method of analyses. About 17 (56%) of swimming pool water shows the hight risk level of pollolutan . The study also shown that the quality of bacte-riology is bed, (19; 63, 3%) is in bad quality. The total compatibility of the swimming fool water is in a good value 73. Based on sanitation inspection aspect, there are 8 predictive aspects and 5 non predictive aspects. It is important to inspect the swimming pools water periodically, to explain and to guide the swim-ming pools organizers as well as the society about the importance of swimming pools water quality for health.Keywords: Compatibility, Pollution risk level, Sanitary Inspection, Bacteriological assessment, Swimming pool water, DKI Jakarta.
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4

Breadsmore, Graeme. "Geothermal energy: deep sources in Victoria." Proceedings of the Royal Society of Victoria 126, no. 2 (2014): 23. http://dx.doi.org/10.1071/rs14023.

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Geothermal energy is heat stored naturally within the rocks of the earth. The higher the temperature of the rock, the more thermal energy is potentially available. In general, temperature increases with depth so deeper rocks store larger amounts of geothermal energy. Water has a higher volumetric heat capacity than most solid minerals, so saturated porous rocks tend to store larger amounts of heat than non-porous rocks. Under the right circumstances, geothermal energy can be economically extracted and put to use either directly (for example, to heat buildings) or by converting it to electrical energy. There are already two geothermal power generators in Australia (a 120 kWe plant at Birdsville, Queensland, and one 1 MWe plant at Innamincka, South Australia) and a range of direct applications of geothermal energy (heated buildings, swimming pools and spas)
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5

Prashant S. Smt Radhika, Lanjewar, Parbat D. K., and Kosankar P. T. "Advantages of Trichloro Iso Cyanuric Acid over Commercially Available Liquid Chlorine for Sanitation of Swimming Pools in Nagpur Region." American Journal of Environmental Engineering 2, no. 6 (December 1, 2012): 174–81. http://dx.doi.org/10.5923/j.ajee.20120206.05.

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6

Mirzatika Al-Rosyid, Latifa, Dwi Dita Wahyuning Tiyas, Nur Diana Rofiqoh, and Roby Naufal Abiyyi. "Utilization of Air Conditioning (AC) Wastewater Filtration System as Water Supply for Plants." Jurnal Teknik Lingkungan 28, no. 2 (October 2022): 19–27. http://dx.doi.org/10.5614/j.tl.2022.28.2.3.

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Abstract: Air Conditioning (AC) waste water has quite a lot of quantity, but usually AC waste water is directly discharged into the surrounding environment through AC waste water pipes. The objectives of the study were (1) to determine the discharge of AC waste water produced within 30 minutes and (2) to determine the effectiveness of the filter in reducing the pollutant content of AC waste water so that it is good for plant irrigation. The research was conducted by analyzing the quantity and quality of AC waste water in the CC Building, Muhammadiyah University of Jember. Parameters analyzed include hardness, pH and ammonia. One solution to sterilize AC wastewater is by using a sponge that is able to capture solids in the water before the water enters the container and activated charcoal which is considered to be able to reduce NH4 levels. One of the ingredients for making charcoal comes from coconut shells, which are relatively cheap. In addition to using coconut shell charcoal, exposure to UV rays is felt to reduce the bacteria contained in the AC water. UV light can function as a destroyer of bacteria and microorganisms so it is safe to use, both for living things and the environment. This study uses a descriptive qualitative research with an evaluation approach which aims to determine the amount of air conditioning waste water within 30 minutes and to determine the physical and microbiological quality of AC waste water by analyzing the data and comparing it with the Minister of Health Regulation No. 32 of 2017 concerning Health Quality Standards for Sanitation, Swimming Pools, Solus Per Aqua and Public Baths. Data was collected by measuring the discharge of air conditioning, observation, interviews and documentation. The instrumentation used is a measuring cup, TDS meter, thermometer, turbidity meter, timer, sample bottle, Bunsen, alcohol and ice box. Based on the results of the examination of the quality of the AC wastewater with specifications of AC 1 PK, the results of the examination of physical and microbiological parameters that meet the requirements in accordance with the Minister of Health of the Republic of Indonesia No. 32 of 2017 concerning Health Quality Standards for Sanitation, Swimming Pools, Solus Per Aqua and Public Baths.
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7

Bugeja, Lyndal, and Richard C. Franklin. "An analysis of stratagems to reduce drowning deaths of young children in private swimming pools and spas in Victoria, Australia." International Journal of Injury Control and Safety Promotion 20, no. 3 (September 6, 2012): 282–94. http://dx.doi.org/10.1080/17457300.2012.717086.

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8

Santiari, Made, Yohana Ivana Kedang, and Feliksitas Angel Masing. "Retention Basin Water Quality in Tubuhue Urban Village North Central East Regency." JURNAL PEMBELAJARAN DAN BIOLOGI NUKLEUS 8, no. 3 (November 25, 2022): 703–10. http://dx.doi.org/10.36987/jpbn.v8i3.3211.

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The community carries out bathing and washing activities directly in the retention basin which can cause polluted water. Water quality checks need to be carried out before treatment. The purpose of this study was to determine the quality of water in the retention basin. Determination of the sampling location by purposive sampling. Sampling was carried out once in August 2021. Parameter measurements were carried out in the field and in the laboratory. The measurement results are compared with the quality standards listed in the Regulation of the Minister of Health of the Republic of Indonesia Number 32 of 2017 concerning Environmental Health Quality standards and Water Health Requirements for Sanitary Hygiene, Swimming Pools, Solus Per Aqua and Public Baths. A parameter that passed the quality standard was E-Coli while pH, hardness, nitrate, temperature, and TDS still met the quality standards. Retention basin water in Tubuhue Village seen from the parameters of temperature, pH, TDS, hardness, and nitrate can be used for sanitation hygiene purposes, but judging from the parameter E-Coli cannot be used for sanitary hygiene purposes.
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9

Yulistyorini, Anie, Sanjaya Silvia, and Dian Ariestadi. "OVERHEAD OPERATIONAL WATER FOOTPRINT DAN KUALITAS AIR PADA GEDUNG BERTINGKAT (STUDI KASUS GRAHA REKTORAT UNIVERSITAS NEGERI MALANG)." Jurnal Teknik Sipil 17, no. 1 (October 10, 2022): 1–11. http://dx.doi.org/10.24002/jts.v17i1.5145.

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Graha Rektorat Building at the State University of Malang (UM) significantly contributes to water usage. Water usage in the building must be managed and appropriately considered, so it can highly contribute to UM's ranking of UI Green Metric for water conservation indicators. Water usage can be calculated by analysis of overhead operational water footprint. This research aims to analyse green, blue, and grey water footprint, overhead operational water footprint, and the quality of green water on the Graha Rektorat building. The methods used in this research are the quantitative method. This research showed the blue water footprint, green water footprint, and grey water footprint of Graha Rektorat building each by 5628 m3 during January – September 2021, 4361.43 m3/year 18.575 m3/day. Overhead operational water footprint on Graha Rektorat building equal with the value of blue water footprint which is 5628 m3 during January – September 2021. The quality of green water on the Graha Rektorat building does not meet the requirements of Indonesian Minister of Health No. 32 of 2017 concerning environmental health quality standards and water health requirements for hygienic and sanitation purposes. Swimming Pools, Solus Per Aqua, and Public Baths, so as another alternative, green water can be used as a substitute for flushing toilets and watering plants to reduce blue water usage.
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10

Daramusseng, Andi, and Syamsir Syamsir. "Studi Kualitas Air Sungai Karang Mumus Ditinjau dari Parameter Escherichia coli Untuk Keperluan Higiene Sanitasi." Jurnal Kesehatan Lingkungan Indonesia 20, no. 1 (May 29, 2020): 1–6. http://dx.doi.org/10.14710/jkli.20.1.1-6.

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Latar belakang : Degradasi kualitas perairan dapat terjadi akibat adanya zat pencemar yang mempengaruhi dan mengubah kondisi lingkungan perairan seperti Escherichia coli (E. coli). Tujuan dalam penelitian ini adalah untuk menganalisis kualitas air sungai Karang Mumus ditinjau dari parameter E. coli untuk Keperluan higiene sanitasi.Metode: Metode dalam penelitian ini adalah observasi dan pemeriksaan laboratorium. Pengambilan sampel air dilakukan di sungai utama sebanyak tujuh titik. Penentuan titik pengambilan sampel air ini berdasarkan potensi sumber pencemar mulai dari hulu sampai ke hilir dengan kriteria terdapat daerah padat penduduk, peternakan, mall, hotel dan pasar. Teknik analisis yang digunakan yaitu dengan membandingkan hasil uji laboratorium dengan Peraturan Menteri Kesehatan Republik Indonesia Nomor 32 Tahun 2017 tentang Standar Baku Mutu Kesehatan Lingkungan dan Persyaratan Kesehatan Air untuk Keperluan Higiene Sanitasi, Kolam Renang, Solus Per Aqua, dan Pemandian Umum. Hasil: Hasil pengukuran Bakteri E. coli Sungai Karang Mumus, Kota Samarinda menunjukan bahwa kandungan bakteri E. coli terendah <30 CFU/100 mL dan yang tertinggi 2100 CFU/100 mLSimpulan: Semua hasil pengukuran bakteri E. coli di Sungai Karang Mumus sudah melebihi baku mutu yang ditetapkan yaitu 0 CFU/100 mL sampel. Langkah untuk meminimalkan kontaminan bakteri ke sungai perlu diambil sehingga penggunaan air Sungai Karang Mumus tidak membahayakan kesehatan masyarakat setempat. ABSTRACTTitle: Study on the Quality of the Karang Mumus River Water in terms of Escherichia coli Parameters For the Purpose of Hygiene SanitationBackground: Water quality degradation can occur due to the presence of pollutants that affect and change the condition of the aquatic environment such as Escherechia coli (E. coli). The purpose of this study was to analysis of Karang Mumus River Water quality in terms of Escherichia coli parameters for the purpose of hygiene sanitation. Method: The method in this research is observation and laboratory examination. Water sampling was taken in the main river for seven points. The determination of this water sampling point is based on potential sources of pollutants from upstream to downstream where there are densely populated areas, farms, malls, hotels, and markets. The analysis technique used is by comparing the results of laboratory tests with the Regulation of the Minister of Health of the Republic of Indonesia Number 32 the year 2017 concerning the Standards of Environmental Health Quality Standards and Water Health Requirements for Sanitary Hygiene, Swimming Pools, Solus Per Aqua, and Public Baths. Result: The measurement results of E. coli Bacteria in Karang Mumus River, Samarinda City showed that the lowest E.Coli bacteria content was <30 CFU / 100 mL and the highest was 2100 CFU / 100 mL. Conclusion: All measurement results of E. coli bacteria in the Karang Mumus River have exceeded the established quality standard of 0 CFU / 100 mL sample. Steps to minimize bacterial contaminants to the river need to be taken so that the use of Karang Mumus river water does not endanger the health of the local community.
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Books on the topic "Swimming pools Victoria Sanitation"

1

Tom, Griffiths. The complete swimming pool reference. St. Louis: Mosby Lifeline, 1994.

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Bonadonna, Lucia, Rossella Colagrossi, and Liliana La Sala. Parametri microbiologici per il controllo delle acque di piscina: Metodi analitici di riferimento. Roma: Istitutio superiore di sanità, 2013.

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Oregon. Center for Environment and Health Systems. Environmental Services & Consultation. Oregon licensed facility statistics, 1999. [Portland, OR]: Health Division, Oregon Dept. of Human Resources, Environmental Services & Consultation, Center for Environment and Health Systems, 1999.

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British Effluent and Water Association. and Pool Water Treatment Advisory Group., eds. Code of practice for ozone plant for swimming pool water treatment. High Wycombe: British Effluent and Water Association, on behalf of BEWA and Pool Water Treatment Advisory Group, 1987.

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Oregon licensed facility statistics, 1994. [Salem, Or.]: Health Division, Oregon Dept. of Human Resources, Environmental Services & Consultation, Center for Environment and Health Systems, 1994.

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