SU1483011A1 - Water intake structure - Google Patents

Abstract

The invention relates to hydraulic structures, in particular to devices for seizing sediment in the channels of the mountain-piedmont zone. The purpose of the invention is to increase the efficiency of sediment capture. The water intake structure includes a retaining structure 2 located in the channel of the channel 1 with a locking device 3 in the form of an autoregulator of the limiting level and a nanosprus washing 4. The retaining structure 2 is located at an angle to the channel axis of the channel 1 and is provided with a wedge-shaped ledge 5, the discharge face 6 of which is adjacent to the head 7 nanospring 4 at an angle of 65 ... 70 °, and to the support structure - at an angle of 20 ... 25 °. The top face of the wedge-shaped ledge 5 is inclined towards the nanospring basin 4. The flow, saturated with sediments, moving along channel 1, approaches the pressure face 6 of the ledge 5, hits the face 6 and, rising up, encounters an obstacle in the form of a wall 10. Further, the flow with sediments creeps along the inclined upper face of step 5 and is directed toward the nanospring opening 4. Through the opening 4 sediments are diverted into the discharge channel 9. 3 sludge.

Description

Fig /

The invention relates to hydraulic structures, in particular to devices for seizing sediment in the channels of the mountain-piedmont zone.

The purpose of the invention is to increase the efficiency of sediment capture.

FIG. 1 shows a water intake structure, general view, plan; in fig. 2 shows a section A-A in FIG. in fig. 3 - the proposed design, a view in axonometry.

In the channel of channel 1 there is a supporting structure 2 with a locking device 3, made in the form of an autoregulator of the limiting level, and a nano-washing opening 4 with a shield. The substructure 2 is located at an angle to the axis of the channel of channel 1 and equipped with a wedge-shaped ledge 5. The discharge face 6 of the wedge shaped ledge 5 adjoins the top of the 7 nanospring basin 4 at an angle Ј, 65–70, and at the supporting structure 2 at an angle Ы4 20 .- 25 ° “The upper wedge 8 of the wedge shaped ledge 5 is inclined toward the nanospring washing hole 4 which tells the mainstream to Nala 1 with discharge channel 9. The wall 10 of retaining structures 2 is pos- the constant adjustment of

Water intake works as follows.

The flow saturated with sediments, moving along channel 1, approaches the pressure side 6 of the wedge-shaped ledge 5, hits the edge 6 and, rising up, encounters an obstacle in the form of a wall 10 of the supporting structure 2, slides along the inclined upper edge 8 of the wedge-shaped ledge 5 and directed towards the nanospring opening 4 "Through the opening 4 the sediments are diverted to the discharge channel 9o. At the same time, the lower layers of the stream saturated with sediments, acquiring a helical-rotating motion when in contact with the pressure face 6, are directed to the opening 4 and about water are in the bleed passage 9. The wall 10 of retaining structures 2 mounted at an angle to the channel axis of the channel 1, directs vzvetennye deposits on the upper face 8 a wedge-shaped shoulder 5 "

During the low-flow period, the locking device 3 is completely closed and all the water flow in the channel passes into transit, overflowing through the wall 10 of the supporting structure 2.

During the flood, part of the flow is diverted through the transit, and part is dropped into the channel 9 with the locking device 3 open.

Placing the wedge-shaped ledge 5 at optimal angles ot (65 - 70 ° and centered around 20 - 25 ° to the tip 7 of the nanospring basin 4 and the supporting structure 2 contributes to weakening the effect of circulating bottom currents.

Claims (1)

Invention Formula A water intake structure including a retaining structure located in the channel channel with a shut-off device made in the form of an autoregulator of the limiting level, and a wash-hole, characterized in that, in order to increase the efficiency of sediment capture, the supporting structure is located at an angle to the channel channel axis and provided a wedge-shaped ledge, the pressure facet of which is adjacent to the top of the nanospring hole at an angle of 65-70, and to the supporting structure at an angle of 20-25 °, with the upper edge of the wedge-shaped ledge not sloped in the direction of the nanosink washer FIG. Z Fig.Z