A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Surface Jet Model for Heated Discharges
A system of equations is developed which, when solved numerically, predicts the jet trajectory, width, velocity, and temperature decrease for the case of a two-dimensional surface jet. The results of field and laboratory equipment indicate that entrainment is reduced as the discharge angle is reduced from 90° to 60° and 45°; thus, the drag coefficient decreases as the velocity ratio is increased. The results of five surveys indicate that the entrainment coefficient was reasonably constant for three surveys at one field site even when the velocity ratio was changed. The results also indicate that entrainment is a function of the ratio of the ambient width to the discharge width, which was different at each of the field sites studied. The observed field values of the drag coefficient appear to be a function of the velocity ratio and agreed well with the values observed in the laboratory.
Surface Jet Model for Heated Discharges
A system of equations is developed which, when solved numerically, predicts the jet trajectory, width, velocity, and temperature decrease for the case of a two-dimensional surface jet. The results of field and laboratory equipment indicate that entrainment is reduced as the discharge angle is reduced from 90° to 60° and 45°; thus, the drag coefficient decreases as the velocity ratio is increased. The results of five surveys indicate that the entrainment coefficient was reasonably constant for three surveys at one field site even when the velocity ratio was changed. The results also indicate that entrainment is a function of the ratio of the ambient width to the discharge width, which was different at each of the field sites studied. The observed field values of the drag coefficient appear to be a function of the velocity ratio and agreed well with the values observed in the laboratory.
Surface Jet Model for Heated Discharges
Motz, Louis H. (author) / Benedict, Barry A. (author)
Journal of the Hydraulics Division ; 98 ; 181-199
2021-01-01
191972-01-01 pages
Article (Journal)
Electronic Resource
Unknown
Thermal Fronts in Heated Water Discharges
| ASCE | 2021
Experiments on Coaxial Heated Water Discharges
| ASCE | 2021
3-Dimensional Modelling of Heated Water Discharges into Coastal Waters of Yellow Sea
| British Library Conference Proceedings | 1994