RU2404324C1 - Device for protection of water intake structure against fish and garbage ingress - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method consists in formation of controlled summary flow of water developed as a result of water flow supply into jet-forming nozzles arranged along perimetre of through hole provided in waterproof wall, which entrails floating items into motion towards through hole and provides for their subsequent movement from through hole. Summary flow is formed at the side of the main watercourse behind waterproof wall that fences water receiving window from the main watercourse, and it is also sent towards the main watercourse. At the same time summary flow develops a transit garbage and fish diverting stream, which discharges floating items, caught garbage, algae, fishes and its young fishes via through hole arranged in waterproof wall, from the cavity formed by water receiving window and inner side of waterproof wall, downstream the main watercourse relative to water receiving window. At the same time transit garbage and fish diverting stream together with water intake stream forms a whirlpool stream that separates settled garbage, algae and deposits from filtering screen of water receiving window in the area between water receiving window and inner side of waterproof wall. Separated garbage, algae and deposits are also discharged via through hole by means of transit garbage and fish diverting stream downstream the main watercourse relative to water receiving window.

EFFECT: improved efficiency of water intake structure protection against ingress of fish and young fishes in it, as well as domestic and natural debris with minimum operations costs, while observing environmental requirements.

13 cl, 10 dwg

Description

The invention relates to hydraulic engineering, and in particular to methods designed to protect water intake structures, water inlets of hydroelectric power stations and other deep water intakes from the ingress of fish and its juveniles, as well as natural and household waste.

There is a method of protecting fish at water intakes from watercourses [1], which consists in the fact that water is supplied by a group of stream former from the intake area to the transit stream at fish slopes and (or) another group of water source is supplied to the intake area from the horizons of transit stream, where there is no stingray of fish.

The main disadvantage of this method is the significant energy consumption for creating the flow of water jets, necessary to reform the entire supply area of the water intake, requiring large volumes of water.

There is also a known method of controlling the water withdrawal mode [2], which consists in creating an upstream and in the immediate vicinity of the intake of a hydraulic screen forming a whirlpool zone from which water is drawn to the consumer.

The disadvantage of this method is the implementation of water intake directly from the whirlpool. Fish migrations, including and downstream migrations are characterized by constant alternations of fish stay in zones with different flow rates. So, most fish rest and feed in areas with low or whirlpool currents. In addition, whirlpool zones are often the centers of accumulation in them of not only fish, but also floating debris and sediment. Water intake from this zone will inevitably lead to fish entering the water intake.

In addition, there is a method of transporting juvenile fish to a fish outlet [3], which consists in ejecting juvenile fish into the inlet of an ejector installation from a section of a reservoir with a high concentration of juvenile fish, creating an active ejecting working stream in the mixing chamber by involving a volume of water containing juvenile fish, into the stream created by the central ejection hydraulic stream, and further transportation of the water-fish mixture through the pressure pipe to the fish outlet. At the last stage of transportation, juvenile fish are transferred to the fish outlet in a pressure-free mode by forming a hydraulic jet at an angle to the fish outlet tray and dumped onto the surface of the fish outlet stream.

The disadvantage of this method is the low efficiency of protection against ingress of juvenile fish and garbage into the intake structure.

The closest analogue is the method of transporting floating bodies from the first section to the second upstream section [4], which consists in creating a controlled fluid flow resulting from the interaction of two rows of flooded liquid jets and creating counter-pressure to the flow of the second upstream section. The controlled flow involves the movement of floating bodies located in the first section towards the passage opening and ensures their unhindered passage to the second upstream section and further advancement from the passage opening.

The disadvantage of this method is the inability to protect the intake structure from ingress of juvenile fish and garbage.

The aim of the invention is the creation of an effective way to protect the intake structure from the ingress of fish and its young, as well as natural and household waste.

The invention consists in the following

According to claim 1 of the claims. Forming the total flow from the main watercourse behind the waterproof wall that encloses the water intake window from the main watercourse, and directing it also towards the main watercourse, create a transit garbage-discharge flow. The total flow is created as a result of the flow of water into the jet-forming nozzles located around the perimeter of the passage opening made in a waterproof wall. The transit garbage-discharge flow leads out of the area formed by the water intake window and the inner side of the waterproof wall, floating bodies - household and natural garbage, algae, fish and its juveniles from the main watercourse downstream of the main watercourse relative to the water intake window. As a result of the interaction of the water intake flow and the transit waste collection flow in the area between the water intake window and the inner side of the waterproof wall, a whirlpool current is formed that separates the settled debris, algae and the formation of a water intake window from the filter screen. Separated garbage, algae and formations together with trash that has gotten will also be discharged by the garbage-discharge current downstream of the main watercourse relative to the water intake window.

According to claim 2 of the claims. The transit garbage-discharge flow can be considered as a large hydraulic stream, which, interacting with the main watercourse, creates a powerful hydraulic screen that cuts off and removes fish and its young, as well as natural and household waste located in the main watercourse from the water intake structure.

According to claim 3 of the claims. Distribution of transit garbage disposal, i.e. a large hydraulic stream, leads to the formation of a whirlpool zone between its inner boundary and the coastal edge. This whirlpool zone allows you to select a local section of the main watercourse, in which there are practically no fish and its young, as well as natural and household garbage. Thus, it is possible to take part of the flow from the whirlpool to the needs of the water intake without damaging the ecology of the reservoir.

According to claim 4 of the claims. Due to the fact that the total flow is formed opposite the water intake window, a garbage collection flow is created, which helps to improve the cleaning of the filter screen of the water intake window from settled debris, algae and formations. Indeed, in this case, the interaction with the water intake will be the strongest, which will serve to create a powerful and stable whirlpool between the water intake window and the inner side of the waterproof wall.

According to claim 5, claims. The formation of several total flows will allow you to create one garbage collection flow that receives the same effects as in cases 2, 3, however, in this case, a significant reduction in energy costs is achieved.

According to claim 6, claims. The formation of the total flow in such a way that its initial section parallel to the plane of the filter screen of the water intake window allows creating a whirlpool between the water reception window and the inner side of the waterproof wall, which washes the entire surface of the filter screen of the water intake window with equal intensity.

According to claim 7 of the claims. Due to the creation of a transit garbage discharge flow with a width in the vertical sectional plane passing through the passage hole, a width smaller than the width of the water intake window, a water intake flow greater in width is obtained than the width of the garbage discharge flow in the region between the water intake window and the inside of the waterproof wall. In this case, the garbage discharge does not have any effect on water collection.

According to claim 8 of the claims. By creating a transit waste collection flow with a width in the vertical sectional plane passing through the passage opening equal to the width of the intake window, an intake flow with the same width as the width of the waste collection stream in the region between the intake window and the inside of the waterproof wall is obtained. At the same time, the garbage discharge branch will cover the entire width of the water intake window.

According to claim 9, the claims. Due to the creation of a transit garbage discharge flow with a width in the vertical sectional plane passing through the passage hole, more than the width of the water intake window, a smaller intake water flow is obtained than the width of the garbage discharge flow in the region between the water intake window and the inside of the waterproof wall. In this embodiment, the garbage collection flow will cover the entire area between the water intake window and the inside of the waterproof wall.

According to claim 10 of the claims. The creation of a transit garbage collector flow at the same level as the water intake window will enhance the effect obtained in paragraph 4.

According to claim 11, the claims. The creation of a transit garbage discharge flow above the level of the water intake window will allow the formation of a garbage discharge flow above the layer of water flow into the water intake window.

According to paragraph 12 of the claims. The creation of a transit garbage discharge flow below the level of the water intake window will also allow the formation of garbage disposal flow below the layer of water flow into the water intake window.

According to item 13 of the claims. The creation of a transit garbage discharge flow simultaneously above and below the level of the intake window will allow the formation of the garbage discharge flow simultaneously above and below the layer of water flow into the intake window.

The solution to this problem is achieved by implementing a new method of protecting the water intake structure from the ingress of fish and garbage. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 is a diagram of the creation of a transit garbage collection flow in plan view;

figure 2 - the same, with the help of several total flows;

figure 3 - the same, the initial cross section of the total flow parallel to the plane of the filter screen of the intake window, and the width of the transit garbage discharge stream in the vertical plane of the section passing through the passage hole is less than the width of the intake window;

figure 4 - the same, the width of the transit garbage discharge flow in the vertical plane of the section passing through the through hole is equal to the width of the water intake window;

figure 5 - the same, the width of the transit garbage discharge stream in the vertical plane of the section passing through the passage hole is greater than the width of the water intake window;

6 is the same, the total flow is formed at an angle exceeding 90 ° to the longitudinal axis of the main watercourse;

Fig.7 is a diagram of the creation of a transit garbage discharge flow in the section with a vertical plane, the garbage disposal flow is created at the same level with the water intake window;

Fig - the same, garbage collection flow create above the level of the intake window;

Fig.9 is the same, the waste-discharge current is created below the level of the water intake window;

figure 10 - the same, garbage collection flow create simultaneously above and below the level of the intake window.

A device for protecting the water intake from getting fish and garbage into it is placed near the coastal edge 1 of the main watercourse 2 (Fig.1-6). The device includes a waterproof wall 3, enclosing the water intake window 4 from the main watercourse 2. In the downstream side of the waterproof wall 3 there is a through hole 5 with jet nozzle systems 6 (Figs. 7-10). The role of the shielding walls 7 of the barrier visor is played by the faces of the outlet part of the through-hole 5. To supply the systems of the jet-forming nozzles 6, distributing manifolds 8 are used, made inside the waterproof wall 3. In order to clean the incoming water into the intake, the intake window 4 is equipped with a filter screen 9.

A method of protecting a water intake structure from the ingress of fish and debris into it is as follows.

суммарного потока находят из выражения:With the inclusion of the pumping station 10 for water intake to the consumer, a water intake flow 11 is formed (Figs. 1-10). A small part of the flow rate for consumption needs is taken and fed through distributing manifolds 8 to the system of jet-forming nozzles 6 located along the perimeter of the through holes 5, which form behind the waterproof wall 3 hydraulic jets 11 directed towards the main watercourse 2. Interacting with each other, hydraulic jets 11 form from the side of the main stream 2 behind the waterproof wall 3 the total stream 12, which is also directed towards the main stream 2. The initial axial velocity

the total flow is found from the expression:

- начальная осевая скорость суммарного потока (м/с);Where

- initial axial velocity of the total flow (m / s);

φ 'is a dimensionless coefficient determined empirically, its values vary in the range of 0.001-4.00;

V ₀ - the initial velocity of the flow of water jets from the jet-forming nozzles (m / s);

- диаметр струеобразующих насадков (м);

- diameter of jet-forming nozzles (m);

b _e - the distance between the axes of the water jets (m);

n is the number of water jets in a row;

h _E - the distance between the planes of distribution of water jets (m).

The total flow 12, involving the surrounding water in motion, creates a transit garbage-discharge stream 13, the average speed of which at the outlet of the through hole 5 can be determined by the formula (1). The transit garbage collection 13 discharges buoyant bodies through passage 5 - trash, algae, fish and its young from area 14 formed by the intake window 4 and the inner side of the waterproof wall 3, downstream of the main stream 2 relative to the intake window 4. Moreover, the transit waste collection outlet the current 13 together with the water intake 11 forms in the region 14 between the water intake window 4 and the inner side of the waterproof wall 3 a whirlpool current 15. The whirlpool current 15 department There is settled debris, algae and formations from the filter screen 9 of the intake window 4. Separated debris, algae and formations are also discharged through passage hole 5 by a transit garbage-discharge stream 13 downstream of the main watercourse 2 relative to the intake window 4.

In addition, the transit garbage discharge stream 13 along its outer boundary 15 with the main watercourse 2 forms a hydraulic screen that prevents fish and its juveniles, as well as natural and household garbage, from entering the water intake structure (Figs. 1-6).

In addition, the transit garbage discharge stream 13 along its inner boundary 16 with the coastal edge 1 forms a whirlpool zone 17 free from the presence of fish and its juveniles, as well as natural and household garbage, and water is drawn directly to the consumer from this whirlpool zone 17 (Fig. .1-6).

In addition, the total flow 12 is formed opposite the water intake window 4 (Fig.1-10).

In addition, form a few total flows 12, creating one garbage collection stream 13 (figure 2).

In addition, the total flow 12 is formed in such a way that its initial section is parallel to the plane of the filter screen 9 of the water intake window 4 (Fig. 3).

In addition, the transit garbage collection stream 13 is created with a width in the vertical plane of the section passing through the passage hole 5, less than the width of the intake window 4 (figure 3).

In addition, the transit garbage discharge stream 13 is created with a width in the vertical plane of the section passing through the passage hole 5 equal to the width of the intake window 4 (Fig. 4).

In addition, the transit waste collection flow 13 is created with a width in the vertical plane of the section passing through the passage hole 5, greater than the width of the intake window 4 (Fig.5).

In addition, the transit waste collection flow 13 is created at the same level with the intake window 4 (Fig.7).

In addition, the transit garbage discharge stream 13 is created above the level of the intake window 4 (Fig. 8).

In addition, the transit garbage discharge stream 13 is created below the level of the intake window 4 (Fig.9).

In addition, the transit garbage collection stream 13 is created simultaneously above and below the level of the intake window 4 (figure 10).

In addition, the total flow 12 is formed at an angle of 90 ° (Fig.3-5) or at an angle not exceeding 90 ° (Fig.1, 2), or at an angle exceeding 90 (Fig.6), to the longitudinal axis main watercourse 2.

The present invention will significantly increase the efficiency of protection of the water intake structure from the ingress of fish of its juveniles, as well as from household and natural debris with minimal operating costs, subject to environmental protection requirements.

Information sources

1. A.S. 1148935 USSR, IPC ⁴ Е02В 8/08. A method of protecting fish at intakes from watercourses / Yu.M. Kolpachkov, V. M. Sinyavskaya, Yu. E. Kurin, N. A. Yunoshev (USSR). - No. 3554798 / 29-15; Stated 02/21/83; Publ. 04/07/85, Bull. No. 13. - 3 p.

2. Pat. 2245413 RF, IPC ⁷ Е02В 8/08, 9/04. The method of controlling the water withdrawal regime and its device implementing / N.A. Ivanova, V.N. Shkura, V.N. Shkura, A.A. Chistyakov (RF). - No. 2003113371/03; Stated May 6, 2003; Publ. January 27, 2005, Bull. No. 2. - 8 p.

3. Pat. 2250298 RF, IPC ⁷ Е02В 8/08. A method of transporting juvenile fish to a fish breeder and a fish bait and trap device that implements it / A.A. Chistyakov, A.V. Novoydarsky, V.N. Shkura (RF). - No. 2003121539/03; Stated July 10, 2003; Publ. 04/20/2005, Bull. No. 11. - 13 p.

4. Pat. 2306250 RF, IPC ⁸ Е02В 8/08. A method of transporting floating bodies from the first section to the second, upstream section / O.G. Vvedensky, A.Ya. Polyanin (RF). - No. 2005113357/06; Announced on 05/03/2005; Publ. 09/20/2007, Bull. No. 26. - 5 p.

Claims (13)

1. A method of protecting a water intake structure from the ingress of fish and debris, which consists in the formation of a controlled total water flow created by supplying a flow of water to the jet-forming nozzles located around the perimeter of the passage opening made in a waterproof wall that involves floating bodies in motion towards the passage opening and ensures their further advancement from the passage opening, characterized in that the total flow is formed from the side of the main watercourse with a one-tight wall that encloses the water intake window from the main watercourse, and it is also directed towards the main watercourse, while the total flow creates a transit garbage-discharge flow that discharges through the passage hole made in the waterproof wall, floating bodies - trash, algae, fish and its juveniles from the area formed by the water intake window and the inner side of the watertight wall, downstream of the main watercourse relative to the water intake window, with transit garbage the discharge stream together with the intake stream forms in the area between the intake window and the inner side of the waterproof wall a whirlpool current that separates the settled debris, algae and formations from the filter screen of the intake window, the separated debris, algae and formations are also removed through the passage opening by the transit refuse collection downstream the flow of the main watercourse relative to the water intake window. 2. The method according to claim 1, characterized in that the transit garbage discharge along its outer border with the main watercourse forms a hydraulic screen that prevents fish and its juveniles, as well as natural and household waste, from entering the water intake structure. 3. The method according to claim 1, characterized in that the transit garbage discharge along its inner border with the coastal edge forms a whirlpool free from the presence of fish and its juveniles, as well as natural and household waste, and water is drawn directly to the consumer from this whirlpool zone. 4. The method according to claim 1, characterized in that the total flow is formed opposite the water intake window. 5. The method according to claim 1, characterized in that they form several total streams that create one garbage collection flow. 6. The method according to claim 1, characterized in that the total flow is formed in such a way that its initial section is parallel to the plane of the filter screen of the water intake window. 7. The method according to claim 1, characterized in that the transit garbage-discharge stream is created with a width in the vertical plane of the section passing through the passage hole less than the width of the water intake window. 8. The method according to claim 1, characterized in that the transit garbage discharge stream is created with a width in the vertical plane of the section passing through the through hole equal to the width of the water intake window. 9. The method according to claim 1, characterized in that the transit garbage-discharge stream is created with a width in the vertical plane of the section passing through the passage hole greater than the width of the water intake window. 10. The method according to claim 1, characterized in that the transit waste collection flow is created at the same level with the intake window. 11. The method according to claim 1, characterized in that the transit waste-discharge stream is created above the level of the water intake window. 12. The method according to claim 1, characterized in that the transit garbage-discharge stream is created below the level of the water intake window. 13. The method according to claim 1, characterized in that the transit waste-discharge stream is created simultaneously above and below the level of the water intake window.

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