RU2501906C1 - System of protection of water-intake structure - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: system comprises a settling chamber 1 with a flushing gallery placed between the supply 2 and drainage 3 sections of the channel. The chamber is made with rising side slopes 21, in the lower part of which there is an inlet hole 4 of the flushing gallery 5. The system also comprises a centrifugal clarifier made in the form of cylindrical chambers 6 and 7. The bottom of the chamber 6 is made as inclined towards the central flushing hole. The chamber 7 is placed inside the vertical chamber 6. At the inlet to the settling chamber 1 there is a flat sluice gate 23 with a curvilinear screen 24. The flushing gallery 5 adjoins with its inlet to the inlet at the outer side of the cylindrical chamber 6 and is placed inside the chamber 7, equipped by additional nozzles. The second nozzle 13 is made in the form of an attachment 12 with a flow swirler and with development of a directed water flow connected to a source of discharge water pipeline, and is placed as coaxial to the vertical axis of the flushing drainage pipeline. The lower edge of the internal cylindrical chamber 7 is arranged above the bottom of the external cylindrical chamber 6. The inlet end wall of the flushing gallery is equipped with a horizontal screen 20.

EFFECT: simplified design and higher efficiency of water intake protection against ingress of bottom sediments and floating debris.

2 cl, 2 dwg

Description

The invention relates to hydraulic engineering, and in particular to structures for the integrated purification of water from fin, debris, entrained and part of suspended sediment during water intake on systems with a closed pipeline network.

A device for clarifying water is known, comprising a housing with a discharge channel, a spiral chamber located inside the housing and made in the form of an overflow wall, a supply channel connected to the inlet of the spiral chamber, and a washing pipe connected to a washing hole in the bottom of the spiral chamber, while water overflow the wall is outlined along the coil of the Archimedes spiral within the angle of rotation of the radius vector, and the flushing hole is located at the pole of this spiral (USSR copyright certificate No. 1330254, class EB 8/02, 1985).

The disadvantages of this device are due to its complex design, including a spillway wall, outlined in a spiral of Archimedes within the angle of rotation, and the complexity of its hydraulic calculation. The low reliability of the work is a consequence of the arrival of fin and debris in it, since its work is only to prevent the introduction of water intake by bottom sediments transported by the supply channel. Thus, this technical solution does not allow to protect the water intake from getting into it fin, debris and part of suspended sediment. In addition, the need for visual control of a suitable flow of water with fin and debris; lack of control over the effectiveness of such plant residues, i.e. fin, debris and suspended sediment are not protected vertically and are not collected by any device. The problem here is solved only in one technical cycle - protection against bottom sediment.

A device is known for protecting water intake from larvae and juvenile fish, comprising a spiral chamber with a fish outlet installed in its lower part, which is equipped with a regulating chamber with partitions installed at the end, and shutters are attached to the front of them (USSR author's certificate No. 654733, class E02B 8 / 02, 1976).

The disadvantages of the known device:

the limited use of it, following, on the one hand, from the fulfillment of the main task - the passage of fish through the fish drain to the downstream, and, on the other hand, from the restriction of the discharge of part of the water to the minimum level (as there is backwater from the downstream);

lack of a perfect vortex funnel above the wash hole;

inability to automatically flush the pipeline by regulating the water in the chamber;

lack of automatic control of the water level by adjusting the position of the shield (shutter).

The closest in design to the proposed device is a sand gravel box, including a settling chamber with a washing gallery located between the inlet and outlet sections of the channel, a centrifugal clarifier, which is made in the form of a cylindrical chamber with a bottom made inclined toward the washing hole, the camera with the washing gallery is made with rising lateral slopes, in the lower part of which there is an inlet of the washing gallery (USSR author's certificate No. 1546547, class EB02 8/02, 1987).

The disadvantages of this device are due to its complex design, including weir sections and made in the form of weir section lowering and tapering to the side, ramps with increasing several side slopes, 2 cylindrical chambers separately, the shape of the curved plates above the entrance of the ledge, etc. These devices in difficult field conditions with floating debris and entrained sediments often fail due to the fin retention on them, impacts by large fractions of sediments, which does not allow to ensure reliable operation of the structure during its operation. At the same time, having a significant effect through the curved plate on the formation of enthralling forces with respect to the floating inclusion in the direction of the washing hole, it through the same plate has a small effect on the intensity of the removal of bottom and bottom sediments.

The purpose of the invention is to simplify the design and increase work efficiency.

This goal is achieved by the fact that in the protection system of the intake structure, including a settling chamber with a washing gallery located between the inlet and outlet sections of the channel, a centrifugal clarifier, which is made with a bottom made inclined towards the washing hole, while the camera is made with increasing lateral slopes, in the lower part of which there is an inlet of the washing gallery, it is equipped with a flat shield shutter with a curved visor installed at the entrance to the settling chamber and the washing gallery adjoins its entrance to the entrance from the outside of the cylindrical chamber located inside the chamber equipped with additional nozzles, the second nozzle being made as a nozzle with a flow swirl and creating a directed water flow connected to the source of the pressure water pipe and placed coaxially with the vertical axis flush outlet pipe, while the lower edge of the inner cylindrical chamber is located above the bottom of the outer cylindrical chamber, and the inlet head of the flush gallery abzhen horizontal visor. In addition, a flat shield shutter with a curved visor is mounted with the possibility of vertical movement and vertically to a longitudinal spillway wall adjacent to the discharge chamber with a flat shutter installed on the outlet channel in its inlet part.

This embodiment of the protection system of the intake structure allows, in comparison with the prototype, to automate the protection of the settling chamber and the washing gallery from floating inclusions and with excess water to discharge them through the spillway into the discharge chamber, and from there they enter the discharge channel, at the entrance of which there is a flat gate. Moreover, the protection is carried out separately: for floating inclusions - with a flat shield shutter with a curved visor tuned to the maximum permissible calculated water level mark (its overflow), which plays the role of a “screen”. A more intense group of bottom and bottom sediments, moving in the interval between increasing lateral slopes and entering the cylindrical chamber through the pipeline at a high speed of at least 3 m / s, reaching the nozzle, enters the wash hole of the discharge pipe.

The flow rate of water flowing from the nozzle rotates the flow swirl on the nozzle, and the speed of the swirl flow depends on the size of the nozzle openings, respectively, the flow swirls. The sediment is directly carried away in a rotational movement along the height of the inner cylindrical chamber toward the wash hole. In this case, the placement of the nozzle with the flow swirl and the hydraulic structure of the flow into the device are organized by the inlet flow-forming element so that sediments located in the thickness and at the bottom of the chamber are also discharged to the lower horizon (below the lower edges of the chamber) and transported directly to the wash outlet pipe downstream. For a given discharge of water with fin and debris through the spillway wall, the level is set by a certain opening with a flat shield shutter with a curved peak (screen). Water entering the chamber with the washing gallery through the hole concentrates on its bottom, limited by increasing lateral slopes, in turn, the directed concentrated flow of water with a flat shield shutter creates a backwater to the main stream in the inlet channel, creating conditions for reducing or increasing both the intake and discharged costs, which in turn makes automatic flushing of fin and debris.

Having passed through a chamber with a washing gallery, water with a restored vertical distribution structure, transporting entrained and weighed sediments, enters the transporting pressure pipe, while a visor is installed over the inlet head of the pipe in the form of a horizontal reinforced concrete slab-console or resting on racks and slopes of at least no less than 0.25 d _tr . This design of the visor does not require a special anti-vortex device, since it significantly reduces the curvature of the jets flowing into the pipe, and, consequently, the compression of the flow at the inlet and at a certain pressure the pipe “co-charges” starts to work in full cross section. The visor is simple in shape, small in size, so its device is easier and cheaper than installing special devices.

The clarified water enters the intake pipe and then to the consumer.

Based on the interconnectedness and interdependence of the main elements of the protection system of the intake structure, conditions are created for the discharge of fin, debris, trailed and suspended sediments.

The proposed protection system for the water intake structure allows for multi-stage protection of the water intake from the entire spectrum of water bodies transported into it - floating garbage, bottom and suspended sediments.

It should be noted that the proposed system for protecting the water intake structure, according to the author, was not previously known and meets the criterion of "Significant differences".

Figure 1 shows the proposed protection system of the water intake structure, plan; figure 2 is a section aa in figure 1.

The protection system of the water intake structure includes a settling chamber 1, located between the inlet and outlet 3 sections of the channel (or pipeline). The bottom of the chamber 1 is made in the form of a lowering and tapering towards the inlet 4 of the pipeline 5, acting as a washing gallery at the same time, which is equipped with water clarifiers, made in the form of cylindrical chambers 6 and 7. In this case, the chamber 6 is made on the side with the inlet 8 with the bottom 9, central flushing hole 10. The chamber 7 is placed inside the vertical chamber 6 - sedimentation tank, and is associated with the outlet of the pipe 5. The lower edge of the inner cylindrical chamber 7 is located above the bottom 9 of the outer cylindrical chamber 6. The output of the pipeline 5 and in the chamber 7 is a horizontal section of the nozzle 11 and the nozzle 12 with nozzles 13 (one or two nozzles). At the bottom of the chamber 7 are installed "dampers" (partitions) 14, which eliminate the rotational movement of water. The bottom 9 of the chamber 6 is made inclined toward the wash hole 10 with a pipe 15 in communication with the discharge channel 16. In the upper part of the chamber 6, the outlet pipe 17 is rigidly installed in the well 18 from the outside so that its outlet end 19 is flooded below the level. Behind the discharge pipe 17 is a pipeline 3 (or channel) of the water management system - the consumer of purified water. The visor 20 is arranged in the form of a horizontal reinforced concrete slab - cantilever or resting on the racks and the wall of the side slopes 21. To ensure the operation of the round pipe 5 with a full cross-section, it is sufficient to have a horizontal visor 20 of length l _k = 0.25 d _tr (where d _tr is the diameter of the pipe), located in a plane tangent to the upper generatrix of the pipe. Between the inlet section of the channel 2 and the settling chamber, a flat shield shutter 23 with a curved visor 24 with a lift 25 is installed in the guides 22. The lower edges of the peak 24 and the shield shutter 23 are located above the bottom of the channel 2. At the entrance to the discharge chamber 26, a drainage wall 27 is installed adjacent to to the shield gate 23. The shield gate 23 with a visor 24 are mounted with the possibility of vertical movement to the longitudinal spillway 27. The discharge chamber 26 is provided with a discharge channel 16 with a shutter 28 mounted on the discharge channel 16 in Khodnev part.

Protection of the water intake is as follows.

When skipping different amounts of water flow in the supply channel 2, a certain relationship is maintained between the openings of the flat shield shutter 23 with a curved peak 24 and the bottom of the channel 2, which is equal to the amount of water entering the settling chamber 1. In this case, the hydraulic structure of the water flowing into the device is organized by the input flow-forming elements 23 and 24 in such a way that objects floating in the surface layer keep their altitude position unchanged and are transported (dumped) over it by water-receiving elements 23 and 24 through the spillway wall 27 into the chamber 26. The presence of a flat shield shutter 23 with a curved peak 24 separating the fin and debris from the settling chamber 1, with a certain (predetermined) backwater transports floating inclusions (grass, leaves from trees and etc.) with excess water through the spillway wall 27 into the discharge chamber 26 and further, the fin and debris are discharged into the channel 16. This leads to the protection of the cylindrical chambers 6 and 7 from the ingress of fin and debris.

The water drawn to the water consumer, first of all, enters the settling chamber 1. The presence of a visor 20 above the pipe 5 and its location in a plane tangent to the upper generatrix of the pipe significantly increases the flow coefficient, therefore, the throughput of the pressure pipe increases. Round pipe 5 works in full cross section (visor length not less than l _k - 0.25 d _tr ). The visor is lighter and cheaper than if an anti-vortex device were introduced instead. Drawn and suspended sediments, the characteristic size of which does not exceed the size of the holes of the nozzles 11 and 13, enter the cylindrical chamber 7 located coaxially inside the chamber 6, from where the clean water is taken into the pipe 17, rigidly installed in the well 18, the lower end of which 19 is flooded under the level. Behind the discharge pipe 17 is a pipeline 3 (or channel) of the water management system - the consumer of purified water.

The flow rate of water flowing from the nozzles 11 and 13 into the chamber 7 allows these sediments to pass through the horizontal nozzle 11 somewhat larger than the size of the nozzle 13. The flow passes through the nozzles (riser) 12 into the nozzle 13 and due to the forces of the jet of water entering into the chamber at a speed of at least 3 m / s through the pipe 5 through one or two nozzles 13, it rotates. Under pressure of the drive water, the nozzle 13, while rotating, turbulizes the flow in the chamber 7, intensively rotates entrained and suspended sediments in it, and leads it to the conical bottom 9 of the chamber 6 with a washing hole 10. Thus, in the presence of “dampers” (baffles) 14, due to a decrease in the water rotation speed, sediment and suspended sediments fall to the bottom 9 of the chamber 6, their retention does not occur in the indicated niche in the zone of the washing hole 10. The flow rate of water in the zone of the washing hole increases, and the discharge pipe 15 feeds the discharge channel L 16, which is also at an end portion of the discharge chamber is rinsed 26. Lifting upwards purified water promotes the transportation of water into the pipe 17 and out of the well 18 into the conduit 3.

The speed of rotation of the nozzle 13 and the intensity of rotation of the water in the chamber 7 are controlled by changing the angle of installation of the nozzle and the size of the nozzle 12.

Thus, the conditions for water purification are created, consisting in providing a two-stage water purification of all types of objects in the upper layer and at a distance from the protective and water-receiving elements 23 and 24 and the relative position of the overflow wall 26, as well as the arrangement of cylindrical chambers 6 and 7 of different geometric sizes in the vertical plane with the damping effect only in the lower part of the chamber 7, and again increase the speed in the zone of the washing hole 10, i.e. due to the difference in total pressure (N), respectively, the difference in the linear height dimensions of the chambers 6 and 7.

Claims (2)

1. The protection system of the water intake structure, including a settling chamber with a washing gallery located between the inlet and outlet sections of the channel, a centrifugal clarifier, which is made with a bottom made inclined toward the washing hole, while the camera is made with rising side slopes, in the lower part of which the inlet of the washing gallery, characterized in that in order to simplify the design and increase the efficiency of work, it is equipped with a flat shield shutter with a curved trump com installed at the entrance to the settling chamber, and the washing gallery adjoins its entrance to the entrance from the outside of the cylindrical chamber located inside the chamber, equipped with additional nozzles, the second nozzle made in the form of a nozzle with a flow swirl and create a directed water flow connected to the source pressure water pipe, and placed coaxially with the vertical axis of the wash discharge pipe, while the lower edge of the inner cylindrical chamber is located above the bottom of the outer cylindrical amers, and the input head of the washing gallery is equipped with a horizontal visor. 2. The protection system of the water intake structure according to claim 1, characterized in that the flat shield shutter with a curved peak is installed with the possibility of vertical movement and vertically to the longitudinal spillway wall adjacent to the discharge chamber with a flat shutter installed on the outlet channel in its inlet part.

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