Determination of Water Distribution Network Resistance Coefficient and Hydraulic Capacity

Vaabel, J.; Koppel, Tarmo; Sarv, L.; Annus, Ivar

doi:10.1016/j.proeng.2014.11.494

Cited by 2 publications

(3 citation statements)

References 6 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Расчет гидравлического сопротивления в программе «АэроСеть», как и в других отечественных и зарубежных программах, осуществляется согласно требованиям действующих нормативных документов. Как показывают исследования, расхождение в итоговых значениях гидравлических сопротивлений при выборе разных методик расчета незначительно и находится в пределах инструментальной погрешн ости [12,13].…”

Section: рис 4 графическое отображение рабочей точки насоса на гидравлической характеристикеunclassified

“…Согласно [13], формула (1) применима при средних скоростях движения воды более 1,2 м/с, поэтому при меньших скоростях движения воды к гидравлическому сопротивлению (1) вводится поправочный коэффициент, учитывающий неквадратичность зави-симости потерь напора от средней скорости движения воды и определяющийся выражением:…”

Section: рис 4 графическое отображение рабочей точки насоса на гидравлической характеристикеunclassified

See 1 more Smart Citation

Гидравлический Расчет Противопожарных Трубопроводов В Аналитическом Комплексе «аэросеть»

Попов¹,

Кормщиков²

2021

Гор. эхо

View full text Add to dashboard Cite

Section: рис 4 графическое отображение рабочей точки насоса на гидравлической характеристикеunclassified

Гидравлический Расчет Противопожарных Трубопроводов В Аналитическом Комплексе «аэросеть»

Попов¹,

Кормщиков²

2021

Гор. эхо

View full text Add to dashboard Cite

“…For this type of undesirable events we can include [1][2][3][4][5][6][7][8]: water contamination in the water intake, water intakes failure, failures of water treatment equipment, failure of pumping stations and water pumping, damage of strategic main and transit pipelines or a possible terrorist acts. Previous studies conducted in different operating water supply systems pay attention to the significant effect of the potential safety loss resulting from the failure [9][10][11][12][13][14]. Identification of the dependence between the damage and losses arising from failure is an important aspect of everyday operation water supply system, examples of such studies taking into account the analysis of aforementioned parameters of failure, are among others [15][16][17][18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Simulation Model of Contamination Threat Assessment in Water Network Using the Epanet Software

Studziński

Pietrucha-Urbanik

2016

Ecological Chemistry and Engineering S

View full text Add to dashboard Cite

Abstract:The aim of this study is to assess the risk of failure of group water network in case of raw water contamination. The analysis was based on qualitative simulation performed in hydraulic water network model developed in the EPANET software. It was focused on the quantitative description of the consequences of chemically contaminated water. The methodology of risk assessment relies in determining the consequences of the supply water containing contamination threatening the health and lives of water consumers. The research methodology is as follows: development of a hydraulic model of the water pipeline and it's hydraulic verification, computer simulations of contamination propagation, calculating the dose delivered to the i-th section of the water supply system supplying water to Ni recipients and the mass of a substance that enters the body li. The simulation results indicate the spread of contamination that after 24 h covered most of the area supplied with water. The load delivered to the resident obtaining water from the i-th section of the water supply network, Li/Ni, was up to 18 g·d -1 , at least 15 g·d -1 was received by 34.9% of the population, 10-15 g·d -1 by 12.5% of the residents, 5-10 g·d -1 by 10.7% of the residents, 0-5 g·d -1 by 41.7% of the residents and uncontaminated water was delivered to only 13.3% of the consumers. The dose taken by the statistical consumer (calculated as for adults) l is up to 0.8 g for Li/Ni = 18 g·d -1 and is proportional to Li/Ni.

show abstract

Determination of Water Distribution Network Resistance Coefficient and Hydraulic Capacity

Cited by 2 publications

References 6 publications

Гидравлический Расчет Противопожарных Трубопроводов В Аналитическом Комплексе «аэросеть»

Гидравлический Расчет Противопожарных Трубопроводов В Аналитическом Комплексе «аэросеть»

Simulation Model of Contamination Threat Assessment in Water Network Using the Epanet Software

Contact Info

Product

Resources

About