RU2022100501A - METHOD FOR FLOW MODE CONTROL IN OPEN CHANNEL - Google Patents

Claims (6)

1. A method for controlling the flow regime in an open channel, involving the use of a fast-flow channel with lined walls and a bottom, the formation of flow-guiding elements in the immediate vicinity of the zone of influence, the installation of vertical walls, the hydraulic structure is formed with the flow directly between the side walls of the channel, the flow-guiding elements are made by means of a transitional section, while along the route of the lined flow channel, a flow energy absorber is arranged, made in the form of a damping chamber, and vertical longitudinal walls at the bottom of the chamber quenching, characterized in that along the route of the flow lining channel, a flow quencher is arranged, made in the form of a tapering quenching chamber, which is provided with fixed vertical longitudinal walls, at least three spans are created, at the end of the tapering section of the chamber, after the vertical longitudinal walls, an additionally expanding quenching chamber is arranged, which is made, under conditions of variable flow, a water-overflow wall of constant height, curved in plan, with slots , and in the outlet expanding channel, they are additionally provided with a water overflow direct threshold installed across the longitudinal axis of the outlet expanding channel, and the expanding additional damping chamber is mated with the outlet expanding channel. 2. The method according to p. 1, characterized in that, curvilinear in plan, the water-breaking overflow wall is made of a row with slots between the walls, the length Where - slot length; h _o - water depth in the discharge channel, while the backwater towards the tapering quenching chamber with vertical longitudinal walls, is determined by the formula where R is the radius of the curvilinear water-breaking overflow wall; B' - total width (including the thickness of the vertical longitudinal walls in the tapering damping chamber); θ is the central angle of the additional expanding extinguishing chamber, θ = 60°, while the optimal height of the curvilinear water-breaking wall is h _st = (0.42…0.45)h _o , where h _o is the water depth in the discharge channel. 3. The method according to claim 1, characterized in that the center of curvature of the curvilinear water-breaking overflow wall coincides with the top of the central angle of divergence of the side walls in the additional expanding extinguishing chamber. 4. The method according to claim 1, characterized in that the fixed water overflow threshold, installed across the longitudinal axis of the discharge expansion channel, is arranged at a distance of 3h _o behind the curved water-breaking water overflow wall and a height h _st = 0.3h _o , where h _o is the depth of water in the discharge channel.