SU1137148A1 - Water intake structure - Google Patents

Abstract

I.WATER PUMPING STRUCTURE, including a water intake cap located on the coast below the watercourse with a discharge channel flow regulator, a supporting structure with a locking device, a catastrophic overflow, and a gate valve equipped with a gate and adjacent curved patterns. ., located in the supply channel, and a water intake chamber, located in front of the water intake head and bounded from the channel by a curvilinear threshold, characterized in that The purpose of reducing sediment capture at an increased water intake ratio is that it is equipped with a damper wall installed in the water intake chamber in front of the water intake head inlet, while the curvilinear threshold and dividing wall are curved in plan with a bulge in the direction of the inlet channel, and the locking device of the supporting structure is curved the form of the autoregulator of the limiting level in which the shutter of the industrial aperture is located. 2. The construction according to claim 1, about tl and which is because the water intake cap is equipped with a flow stabilizer.

Description

The invention relates to hydraulic structures, namely to water intake structures, and can be used to draw water from mountain rivers for irrigation.

A water intake structure for mountain rivers is known, including a rozme; an anchorage on the shore of a supply river, a water receiving head with a discharge channel flow regulator, located in the channel of a retaining structure consisting of a frontal T3c-iJ, oc.m -ma, a separating goby and a flood flight with an automatic all-action gate, in which a flat hand-operated gate is installed, while an obliquely directed stepwise threshold is installed in the feed channel in front of the supporting structure New bullhead i.

A disadvantage of the known device is the seizure of sediment by the stream entering the water receiving head, with a higher water intake ratio, in this case, local circulation. along the oblique directional stage threshold and the roll ikten-alongness along the elevated step, the threshold decreases. At the same time, in the limits of the threshold of the threshold, yi iHb, the height of the drum is also increased, and the running costs of water, and the flow rates that flow through this level, increase. exceed the lateral velocities of the drum, and the drum is destroyed. Therefore, the flow, loss in energetics), forms a pile of sediments close to a lower stage of the circulation threshold, through which the sediment flows into the water receiving head.

In addition, when the flood bay is closed, but a partially open small flat gate, the second is in the water gate, the main flow enters the water intake gate. ogolo A backwater zone is formed with a shutter in front of the waterboost: 5 shutter, with a reduction in flow velocity throughout the depth. Therefore, due to the absence of the nano-transporting ability of the flow in this zone and the damping of the drum within the lower threshold level, the currents are bent in the direction of the water inlet and sediment flows into it.

The closest to the proposed technical solution is a water intake structure, including a water intake head placed on the supply channel with a regulator of a diverting channel, about a supporting structure with a locking device, kata, located in the channel. construction (a bluesky weir and a shutter-equipped industrial hole with adjoining pavilinear threshold and a dividing wall located in the supply channel, and a water intake chamber located ahead of the bilge plate and bounded from the curved threshold c 2.

The disadvantage of this device is the capture of sediment by the stream entering the intake cap with an increased intake factor. This is due to the fact that in the period of water shortage, when most of it enters the outflow channel, and the washing hole is completely blocked by the shutter, the transverse circulation of the flow in the channel dies out and the curvilinear threshold does not work efficiently, especially in the terminal part holes, while the reverse bottom currents., formed as a result of the shielding effect of a closed industrial hole, intervening with the circulation flow along the threshold, weaken the nano-transporting obnost flow, making it difficult to cf-jbiB sediment from the upper Zefa in n zhky, whereby the bulk of the river, sediment entering the water inlet head part and discharge channel.

. The purpose of the invention is to reduce sediment capture with an increased intake factor.

This goal is achieved by the fact that a water intake structure, including a water receiving head located on the shore of an inlet channel with a discharge flow rate regulator, a retaining structure located in a channel, a stop device, catastrophic, a weir and a curved curtain wall adjacent to it. and a dividing wall, located in the landing channel, and a water intake chamber., located in front of the intake head and limiting. From the channel, the curvilinear threshold m, is provided with a damper wall installed in the water intake chamber in front of the inlet of the water intake tip, the curvilinear threshold and the dividing wall of the discharge curved in plan with the convexity toward the supply channel, and the locking device of the supporting structure is made in the form of an automatic regulator of the limiting level, which is located the gate of the washing hole. In addition, the intake cap is equipped with a flow stabilizer. Figure 1 shows the intake structure, plan; figure 2 - section aa in figure 1; on fig.Z - section bb in figure 1. The water intake structure includes a water intake cap 3 located on the shore of the first inlet channel 2 with a flow regulator 4 inlet caly 5 ,. a supporting structure 5 located in channel 2, having a locking device 7, a catastrophic weir 8 and an industrial opening 0 equipped with a shutter 9 with a curvilinear threshold 11 adjacent to it and a dividing wall 12 located in the supply channel 2, and a water intake chamber 13 ny before water-receiving head 3 and bounded from the channel 2 by the curvillet tttiM threshold} i. In addition, the water intake structure is provided with a wall by an extinguisher 14 installed in the water intake chamber 13 in front of the inlet 5 of the water intake tip 3, while the curvilinear threshold il and the separating wall 2 are curved in plan with a bulge in the direction of the inlet channel 2, and the locking wall 7 is retained structure 6 is made in the form of an automatic regulator of the limit level 16, in which the shutter 9 of the protruding hole 10 is located. The water intake tip 3 is equipped with a flow stabilizer 17 and in the supporting structure 6 lifting mehanizg s-l. 18 of the locking device 7 and the shutter 9. The water intake extinguishing works as follows. The river stream enters the retaining structure ka 1484 6 along the supply channel 2, while the autoregulator of the limit level 16 creates the necessary rise in the water level before the retaining structure 6, as a result of which water overflows through the curvilinear threshold 1 and enters the water intake chamber 13. the water intake chamber 13 is provided with a damper wall 14. When the water level exceeds the water level in the water intake chamber 13 of its calculated value, the excess water and floating objects will fall from the chamber 13 by overflowing over the catastrophic overburden 8. The bottom sediments are removed through the washing path formed by the curvilinear threshold 11 and the dividing wall 12, which are curved in plan with a bulge in the direction of the inlet channel 2 and straightened to the sponge hole 10. During the low-flow period the autoregulator of the level 16 completely lowered and the entire discharge of the river is taken into the water intake chamber I3. During this period, the flow rates in the inlet channel 2 weaken and before the retaining structure 6 and the curvilinear threshold 11 a large amount of dredging sediments of ospace BIG accumulates, which is removed into the downstream of the retaining structure 6 along the narrow washing path formed by the curvilinear threshold 1J and the separation wall 12 , when the valve 9 is opened, the washing hole 10. The small width of the washing channel and its isolation from the shielding effect of the lowered automatic regulator of the -16 level limit contributes to an increase in bottom flow rates in the tract and ensure unimpeded removal of Nanos by small ores of the water supply hole 10, while in the water receiving chamber 13 the flow of water devoid of sediment enters. When aiming at the reception chamber 13, a part of the river discharge is taken, and the rest of the discharge is discharged to the downstream of the structure 6 with the autoregulator at the maximum level. 16, which maintains the required water level before the supporting structure 6. During this period, the transverse circulation of the flow increases in the channel 2 and along the curvilinear threshold 11, and sediments are deflected to the supporting structure 6 and discharged into it

The bottom flow through the washing section 10 and the open automatic regulator of the limit level 16, while the receiving chamber 13 through the curvilinear threshold 1 receives the flow of sediment water.

When the flow of a river changes, the water dispersion changes over the threshold 1 into the water receiving chamber, the water level in chamber 13 fluctuates, and the flow stabilizer 17, installed by the water intake head 3, ensures that the flow of water to the outlet of the brushes, gpe 5 ,

Such constructive and kontonovochny execution of the intake structure due to the presence of a narrow and isolated industrial tract formed by a curvilinear threshold and a dividing wall, curved in plan with convexity towards the inlet channel and adjacent to the washing hole, reduces the seizure of the inlet channel flow, post- in the receiving cap.

Claims (2)

1. WATER INTAKE CONSTRUCTION, including a water intake head located on the shore of the inlet channel with an outlet channel flow regulator, a retaining structure located in the channel, having a locking device, a catastrophic spillway and a washing hole equipped with a shutter with a curved threshold adjacent to it and a dividing wall channel, and a water intake chamber located in front of the water intake head and limited from the channel by a curvilinear threshold, characterized in that, for the purpose of To reduce sediment capture at an increased coefficient of water intake, it is equipped with a damper wall installed in the water intake chamber in front of the inlet opening of the water intake head, while the curved threshold and the dividing wall are curved in plan with a bulge towards the inlet channel, and the locking device of the retaining structure is made in the form of the autoregulator of the maximum level in which the shutter of the washing hole is located. 2. The construction of rto p. 1, characterized in that. the water intake head is equipped with a flow stabilizer.