Tytuł artykułu
Autorzy
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Eksperymentalno-numeryczna metoda wyboru modelu emisji wilgoci z lustra wody basenowej
Języki publikacji
Abstrakty
The issue of indoor swimming pool ventilation is very complex, which is a serious problem in their proper design and modernization. The difficulty is that in Poland there are no uniform regulations and standards regarding the required values of ventilation air parameters, the method of calculating moisture emission and the value of me ventilation air volume flow rate. In research, design and modernization of ventilation systems for swimming pools, various methods are used to determine the emission of moisture from the water in the swimming pool basin and there is no complete information as to which of them best reflects the actual thermal-moisture and airflow phenomena. This paper presents a developed and validated research method related to the modeling of moisture emission from the pool water surface, which can be used for the modernization of ventilation systems in the existing indoor swimming pools, due to the need to improve thermal-moisture conditions.
Problematyka wentylacji hal pływalni jest bardzo złożona, co stanowi poważny problem we właściwym ich projektowaniu i modernizacji. Utrudnieniem jest również to, że w Polsce brak jest jednolitych przepisów i norm odnośnie do wymaganych wartości parametrów powietrza wentylacyjnego, sposobu obliczania emisji wilgoci oraz wartości strumienia objętości powietrza wentylacyjnego. W badaniach, projektowaniu i modernizacji systemów wentylacji hal pływalni stosowane są różne metody wyznaczania emisji wilgoci z wody w niecce basenowej i nie ma pełnych informacji, która z nich najlepiej odwzorowuje rzeczywiste zjawiska cieplno-wilgotnościowe oraz przepływu powietrza. W niniejszym artykule zaprezentowano opracowaną i sprawdzoną metodę badawczą związaną z modelowaniem emisji wilgoci z lustra wody basenowej, która może być zastosowana przy modernizacji układów wentylacji w istniejących obiektach krytych pływalni, z uwagi na konieczność poprawy warunków cieplno-wilgotnościowych.
Czasopismo
Rocznik
Tom
Strony
24--31
Opis fizyczny
Bibliogr. 29, rys., tab., wzory
Twórcy
autor
- Department of Heating, Ventilation and Air Removal Technology, The Silesian University of Technology, Gliwice
Bibliografia
- [1] ANSYS, Inc. (2013). Ansys CFX-Solver Theory Guide Release 14.5. Canonsburg, PA.
- [2] Asdrubali F. (2009). A scale model to evaluate water evaporation from indoor swimming pools. Energy and Buildings, 41, 311-319, doi: 10.1016/j.enbuild.2008.10.001.
- [3] ASHRAE (2011). ASHRAE Handbook: HVAC Applications, Atlanta, GA.
- [4] Besler G. (1972). Ventilation of indoor swimming pools. Ciepłownictwo Ogrzewnictwo Wentylacja, 5 (in Polish).
- [5] Biasin K., Krumme W. (1974). Water evaporation in the indoor swimming pool. Elektrowaerme International, 32 (A3), 115-129 (in German).
- [6] Carrier, W. H. (1918). The temperature of evaporation. ASHVE Transactions, 24, 25-50.
- [7] Ciuman P. (2017). Modeling of ventilation air distribution in the indoor swimming pool. PhD thesis, Silesian University of Technology, Gliwice (in Polish).
- [8] Ciuman P. (2020). Application of infrared thermography measurements in thermal diagnostics of the swimming pool. Instal, 5, 22-29, doi:10.36119/15.2020.5.4.
- [9] Ciuman P. (2020). Experimental assessment of thermal, humidity and flow conditions in the indoor swimming pool. Instal, 4, 32-38, doi:10.36119/15.2020.4.6.
- [10] Ciuman P., Lipska B. (2018). Experimental validation of the numerical model of air, heat and moisture flow in an indoor swimming pool. Building and Environment, 145, 1-13, doi:10.1016/j.buildenv.2018.09.009.
- [11] Ciuman P., Lipska B., Burda G. (2015). Numerical modelling of air distribution in the natatorium supported by the experiment. Proceedings from HTFF'15: 2nd International Conference on Heat Transfer and Fluid Flow, Barcelona.
- [12] Garnysz-Rachtan A. (2017). Determining evaporation rate from active indoor swimming pools. Instal, 10, 34-38 (in Polish).
- [13] Hanssen S. O., Mathisen H. M. (1990). Evaporation from swimming pools. Proceedings from ROOMVENT '90: International Conference on Engineering Aero - and Thermodynamics of Ventilated Rooms, Oslo.
- [14] Hyldgard C. E. (1990). Water evaporation in swimming baths. Aalborg: Institut for Bygningsteknik, Aalborg Universitet, Indoor Environmental Technology, 16, Vol. R9045.
- [15] Kappler H. P. (1977). Indoor swimming pools. Warsaw, Arkady (in Polish).
- [16] Lipska B. (2014). Design of ventilation and air conditioning. Basics of air treatment. Gliwice, Publishing house of the Silesian University of Technology (in Polish).
- [17] Lipska B., Palmowska A., Ciuman P., Koper P. (2015). Numerical modelling CFD in the research and design of air distribution in ventilated rooms. Instal, 3, 33-43 (in Polish).
- [18] Malicki M. (1980). Ventilation and air conditioning. Warsaw, PWN (in Polish).
- [19] Nowakowski E. (2003). Ventilation and air conditioning of indoor swimming pools. Chłodnictwo i Klimatyzacja, 9, 50-53 (in Polish).
- [20] Poós T., Varju E. (2020). Mass transfer coefficient for water evaporation by theoretical and empirical correlations. International Journal of Heat and Mass Transfer, Volume 153, 1-10, doi: 10.1016/j.ijheatmasstransfer.2020.119500
- [21] Przybylak J., Ratajczak K. (2019). Moisture gains from evaporation as a design parameter for the ventilation system of indoor swimming pools. Instal, 11, 31-37 (in Polish), doi: 10.36119/15.2019.11.3
- [22] Ratajczak K., Kunicki B. (2016). Evaporation in the indoor swimming pools. Measurements of evaporation at swimming pool facility and the bathers impact on evaporation. Rynek Instalacyjny, 1-2, 40-44 (in Polish).
- [23] Ratajczak K., Szczechowiak E. (2016). Evaporation rate in indoor swimming pools - Monitoring of evaporation at a swimming pool facility and the impact of bathers on evaporation., CUMA 2016 - proceedings of the 12th REHVA World Congress: Volume 5, Aalborg.
- [24] Rzeźnik I. (2017). Study on water evaporation rate from indoor swimming pools. E3S Web of Conferences 22, 00150, International Conference on Advances in Energy Systems and Environmental Engineering (ASEE17).
- [25] Shah, M. M. (2003). Prediction of evaporation from occupied indoor swimming pools. Energy and Buildings, 35, 707-713, doi:10.1016/S0378-7788(02)00211-6.
- [26] Shah, M. M. (2018). Improved model for calculation of evaporation from water pools. Science and Technology for the Built Environment, Volume 24, Issue 10, doi: 10.1080/23744731.2018.1483157.
- [27] Smith et al., C. C., Lof, G. O. G., Jones, R. W. (1999). Rates of evaporation from swimming pools in active use. ASHRAE Transactions, 104(1A), 514-523.
- [28] Turza R., Füri B. B. (2017). Experimental measurements of the water evaporation rate of a physical model. Slovak Journal of Civil Engineering, 25(1), 19-24, doi: 10.1515/sjce-2017-0003.
- [29] VDI 2089 (2010). Part 1: Building Services in swimming baths - Indoor pools.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-cd6d2044-3e81-475d-8518-ee7a4c10732f