SU1562402A1 - Water intake structure - Google Patents

Abstract

The invention relates to hydraulic engineering and is intended for use in water supply systems based on rivers with a significant amount of solid flow. The purpose of the invention is to increase work efficiency by ensuring the flushing of sediment load due to the formation of vortex bottom currents. The water intake structure includes a flooded water intake 3 placed at the bottom of the water source 2 along the stream, made in the form of a rectangular goby, mounted at an angle to the flow in front of the water intake 3 of the nano-directing bottom wall 7, water intake 10 mounted at an angle to the flow between the water intake 3 and the bottom wall 7 The sediment transported in the bottom area of the sediment at the approach to the bottom wall 7, located at an angle α to the flow, interact with it and deviate to the channel of water source 2, bypassing the intake 3 and water intake 10. 4 ill.

Description

Schig.1

315

The invention relates to hydraulic engineering and is intended for use in water supply systems based on rivers with a significant amount of solid flow.

The purpose of the invention is to increase the work efficiency by ensuring the flushing of sediment due to the formation of vortex bottom flow

SRI.

FIG. 1 shows a water intake structure, plan; in fig. 2 is a section A-A in FIG. one; in fig. 3 water intake structure, isometric; in fig. k is the pattern of formation of vortex bottom currents.

The water intake structure includes a submerged water intake 39 placed at the bottom 1 of water source 2 along the stream, made in the form of a rectangular goby with rounded smaller edges 4 and water intakes 5 located on large lateral faces x 6, installed at an angle to the stream in front by the water intake 3, the nanoconvolving bottom wall 7, with its upper edge 8 adjacent to the coastal slope 9 of the water source 2, are identically made with water intake 3 of water intake 10 and installed at an angle to the flow between the bottom wall 7 When the upper edge of the water intake 10 is located at the upper edge 11 of the bottom wall 7 at a distance of 8-6.5 times the height of the intake 3, the clear distance between the intake 10 and the receiver 3 is 1.75-1 of their height, and between the lower gras

New water intake 10 and the lower edge 11 of the wall 7 is not less than the height of the water intake 3, in addition, the bottom wall 7 and the water intake 10 are installed at an angle of 130-150 ° to the flow.

Water intake works as follows.

I

Sediment transported by the stream in the bottom area at the approach to the bottom wall 7, located at an angle to the stream, interact with it and deviate to the channel, bypassing the water intake 3 and water.

five

0 5 o

five

five

0

coastal slope 9 leads to counter-clockwise winding and the formation of a screw flow on slope 9 and on bottom 1 of water source 2 at elevated speeds, which flushes the side faces of the water intake 3 and water intake 10 and direct oblique bottom currents discards sediment from the outer side faces 6 of the water intake 3 and the water intake of GO, as well as squeezing sand masses moving along the channel from the water intake 3 and the water intake 10. The inner side faces 6 with the water intake holes 5 are also washed with an intense flow elevated speeds. The overburden walls 7 that have passed through the top are transported from the water intakes 5 to the channel of the water source 2 by an intense propeller flow.

The installation angle of the water intake 10 in relation to the axis of the channel flow avoids the separation of the leaching flow from the front smaller edge k of the water intake 10 and eliminates sediment deposition at the water intake holes 5 and the water intake 10

water intake. The planned position of the water intake 10 with respect to the wall 7 allows the water intakes 5 to be positioned in the zone of the most intense screw flow with maximum bottom velocities and an increased weighing capacity. The planned position of the water intake 10 with respect to the water intake 3 allows for an intensive flushing current at the water receiving holes 5 of the water intake 3. Approximation of the water intake 3 to the end face of the water intake 10 at a distance of less than 1.75 heights of the water intake 3 leads to a decrease in leaching rates in the corridor between the water intake and water intake 10 and the fall in flushing speeds at the water intake 3- Removing the water intake 3 to a distance n greater than four heights of the water intake causes a decrease in flushing speeds along both the outer and inner 6 sides of the water intake 3.

Approximation of water intake 10 to the bottom wall 7 at a distance n, less than 8

sampling 10. Line of current flowing., vyrty he water intake 3 leads

through the wall 7 of the stream, they are bent towards the coastal slope 9, while the specific water consumption increases. The interaction of the current lines significantly reduces the flushing speeds in the middle and end parts of the outer face 6 of the intake link 10, because the water intake 10 shows a significant decrease in the flushing speeds in the middle and end parts of the outer face 6 of the intake link 10, because the water intake 10 is removed from the zone of the most intensive screw current, the same effect is observed when removing the water intake 10 from the wall 7 by a distance t greater than six heights of the water intake, respectively, the washing

speed at the intake 3.

i

The extension of the water intake 10 into the channel of the water source 2 and a decrease in the distance B less than the height hb of the water intake 3 cause the middle and end parts of the water intake 10 to fall into the zone of separated unsteady currents formed when the flow of the end part of the wall 7 flows. No lateral face 6 of water intake 10 is observed, the leaching flow rates are falling and sediments are deposited here.

Claims (1)

Invention Formula Water intake structure, including flooded water intake located at the bottom of the water source along the stream, made in the form of a rectangular 1111 11 I a goby with rounded smaller edges and water intake openings located on the large lateral edges, and a nano-guiding bottom wall mounted at an angle to the flow in front of the water intake its edge is adjacent to the coastal slope of the water source, which is so that, in order to increase efficiency by providing flushing of sediment due to the formation of vortex bottom currents, it is equipped with a water intake, which is identical with the water intake, installed at an angle to the flow between bottom wall and water intake, while the upper face of the water intake is located from the lower 0, the edges of the bottom wall at a distance of 4.8-6.5 height of the water intake, the clear distance between the water intake and the water intake is 1.75 of their height, and the distance between the lower water intake and the lower edge the walls are not less than the height of the water intake, in addition, the bottom wall and the water intake are installed at an angle of 130-150 ° to the flow. Mill Figz FIG. four W