Your search keyword '"Mahyawansi, Pratik"' showing total 2 results

1. Experimental investigation of storm sewer geyser using a large-scale setup.

Author

Mahyawansi, Pratik, Zanje, Sumit R., Sharifi, Abbas, McDaniel, Dwayne, and Leon, Arturo S.

Subjects

STORM drains, GEYSERS, DYNAMIC pressure, HYDROSTATIC pressure, STATIC pressure

Abstract

The storm sewer geyser is a process where an air–water mixture violently erupts from a manhole. Despite the low hydrostatic pressure, violent eruptions can achieve a height of tens of meters above the ground. This current study experimentally investigates large-scale violent geysers using a large air pocket inserted from a pressurized air tank. The total length of the pipe system is approximately 88 m with a 0.1572 m diameter pipe. This large-scale experiment facilitates the investigation of spontaneous geyser eruptions. This study identifies the role of air–water volume ratio and coefficient of pressure (ratio of absolute initial static pressure to initial dynamic pressure) on the geyser intensity using eruption images and pressure plots. A total of 116 cases are tested, in which the volume ratio is parametrically increased from 0 to 1.1 under various operating conditions. A geyser score is defined to quantify the geyser eruption nature based on visual observations. The key findings are as follows: first, a sharp transition in geyser intensity is observed at the critical volume ratio of 0.5, and pre-transition and post-transition intensity exhibit a linear relationship with the volume ratio; and second, the critical volume ratio linearly varies with the coefficient of pressure. [ABSTRACT FROM AUTHOR]

Published

2024

2. Experimental and numerical investigation of a small scale storm sewer geyser.

Author

Mahyawansi, Pratik, Zanje, Sumit R., Sharifi, Abbas, McDaniel, Dwayne, and Leon, Arturo S.

Subjects

STORM drains, GEYSERS, AIR ducts, PIPE, RESEARCH personnel, MULTIPHASE flow

Abstract

The violent nature of storm sewer geysers has been puzzling researchers worldwide for a very long time. This paper investigates the geyser simulation methodology using a small-scale set-up, where important flow structures such as slugs, eruption patterns, and pressure oscillations are compared with experimental results to test the fidelity of the numerical modelling. In this exercise, a geyser-like process is produced using a continuous insertion of air in the horizontal pipe. The established methodology is used to simulate the hypothesized scenario of a finite trapped air pocket in the relatively longer pipe system. A geyser produced from a finitely trapped air pocket shows a different eruption mechanism compared to those found in previous studies. First, no slug is observed in the horizontal pipe, resulting in continuous air release. Second, the interface continuously atomizes in the vertical pipe, creating a churn-slug flow that produces a large number of small eruptions. [ABSTRACT FROM AUTHOR]

Published

2024