RU2660243C1 - Two-sided water divided for channels with steep slopes - Google Patents

Abstract

FIELD: hydraulic equipment.

SUBSTANCE: invention relates to hydraulic equipment and can be used to draw water from channels with steep slopes, for which there is a significant fluctuation in water levels, as well as in conditions of large bottom-bed loads. Division gate comprises approach (1) and a transit (2) channels connected by intake gallery 3 covered by a splitter in form of plane plate (12) and located in the same plane with the bottom of approach channel (1). Gallery 3 has a slope (4). Splitter, made in form of a plane plate (12), is applied on pipes (13) and has bypass channels (14) in its front part. Short pressure pipes (13) are laid on slope (4) towards the bottom (5) of gallery (3). Front part of splitter under grid (16) with bypass channels (14) is made by a regulator in form of fixed turntable sections of valves (17) on axis (18) with drive (19). Rear part of splitter is made with bafflers (20), which have baffles (21) and cover intake holes (22) in the plate plane (12), and they form depletion curve of flow, which provides attraction of sediment downstream in transit channel (2). Water additionally through intake holes enters in gallery (3), where it mixes with the main flow divertor from short pressure pipes (13), and is taken into tail-water channels (8, 9).

EFFECT: improves efficiency of work by improving conditions for water entry and reducing pressure in front of intake hole, covered with a grid.

5 cl, 4 dwg

Description

The invention relates to hydraulic engineering and can be used to withdraw water from a channel with large slopes, which are characterized by significant fluctuations in water levels, as well as in conditions of abundant bottom sediment.

Known water outlet-stabilizer of water flow from channels with a turbulent flow regime, including a supply and transit channels, a regulating shutter and a bottom water intake gallery having a water intake opening in the upper part blocked by a grill, and in the lower part a dividing wall conjugated to the bottom of the transit channel, and the bottom the water intake gallery is connected to the outlet pipe by means of a culvert, and due to changes in hydraulic resistances, the gallery is equipped with a jetting system in the form of elitelnyh curvilinear walls, and also provided along the length of the projection picture, and a flat plate, forming the individual sections, and a gallery is formed as a zigzag conduit (Patent RU №2484203, E02V 13/00 from 06/10/2013).

A disadvantage of the known stabilizer outlet is its complexity due to the presence of protrusions and plates placed inside the gallery cavity, etc. These devices create a complex diagram of cornering speeds and create difficulty in operation. In this case, they lead to large energy losses due to friction along the gallery.

The closest technical solution is a water outlet from a channel with a large slope, containing a supply and a transit channel, a regulating shutter, a water intake gallery having a water intake opening in the upper part, blocked by a grill, the gallery is made by an inlet head in the form of a pipe, the upper part of the body with an oblique cut located above the slot hole of the gallery, while in front of the slot hole there is an additional V-shaped threshold, and the side walls of the supply channel are equipped with flow guiding elements with the ability to move towards the threshold, and the flow elements are made of L-shaped vertical walls with shelves located above the bottom of the inlet channel, and the lower ends of the vertical walls are installed relative to the bottom of the inlet channel (Patent RU No. 2550421, ЕОВВ 13/00, ЕВВ 8/02 from 05/10/2015).

A disadvantage of the known water outlet from the channel with a large slope is the need for a threshold and the need for the inlet head of the pipe to be positioned above the slot of the gallery, which causes the presence of a concentrated flow in the central part of the supply channel, its rise upward, then entering the slot of the gallery, and this is a source of increased pulsation speed and violation of the change in the hydraulic parameters of the flow above the slotted hole in the gallery and has a limited range of withdrawn costs in the slotted hole; this will contribute to the rapid wear of the threshold during heavy sediment movement in the channel, i.e. the stone can hit the threshold.

The technical result achieved by the present invention is to increase the operating efficiency by improving the conditions of water inlet and reducing backwater in front of the water inlet opening blocked by a grate.

The specified technical result is achieved by the fact that a two-sided water splitter for channels with a large slope, containing a supply and transit channels, a regulating shutter, a water intake gallery having a water intake opening in the upper part, blocked by a grill, the gallery is made with an inlet head, the water divider is made in the form of a plate plane, superimposed on the movement of the flow of the pipe path and having slots in the front part, and the entrances to the slots below the grating overlap are equipped with a regulator in the form of separate sections of valves, fixed on the axis of rotation, the axis, which is connected to the drive of their vertical movement with the possibility of placement in the niche of the channel wall, while the back of the plane of the plate from above is equipped with spreaders with semi-cones, vertices oriented towards the supply channel.

In addition, the pipes were laid along the slope of the bottom towards the water intake gallery.

In addition, the back of the water intake gallery of the transit channel is made in terms of a curvilinear outline with a threshold in the direction of the transit channel.

In addition, the ends of the slots of the plate plane are connected to the inlet heads of the pipes using a flexible sleeve-insert.

In addition, the rear part of the plane of the plate is equipped with spreaders that are equipped with water intake openings with a threshold placed under the semiconics in the plane of their base.

A comparative analysis of the inventive device with the prototype shows that the inventive device is characterized in that the splitter in the form of a plate plane is installed above the gallery in the same plane as the bottom of the inlet channel so that the flow spread across the width of the inlet channel enters pressure pipes that are blocked from above by the plane of the plate with slots in its front part, where pressure pipes are laid directly along the slope of the bottom towards the water intake gallery. Below the lattice, the slots are equipped with a regulator in the form of rotary valves mounted on the axis of rotation, which, due to the absence of angular zones, creates favorable hydraulic conditions under which water is withdrawn in the absence of jumping phenomena, the pressure loss is the smallest when moving the rotary valves to overlap the splits of the splitter in view of the plane of the plate. Moreover, the described arrangement of the bottom gallery in the form of a curvilinear outline of the threshold, where the flow, leaving the pressure pipes, swirls and turns towards each other, collide with each other and then are sent to the discharge channels with increased throughput. The number of pressure pipes associated with the slits of the splitter set by calculation at the design stage, which depends on the width and flow characteristics of the supply channel. Also, the location of the spreaders above the water inlets with a threshold in the rear part of the plate plane forms a partial smooth back-up of the water level and, accordingly, forms a decay curve with increased flow velocities over the spreaders with a threshold, they transport bottom layers of the stream with sediments downstream into the transit channel without hindrance, accordingly, this allows you to select part of the flow of pure water into the gallery, and, therefore, the flow rate of the gallery increases the additionally formed structure with a splitter in the form the plane of the plate as a whole. In turn, the described phenomena, as well as the fact that the proposed device does not violate the generally stable operation of the water splitter and does not require special barriers. Allows you to improve the quality of the water taken in response to the device responding to changes in external conditions.

In FIG. 1 shows a two-way water splitter for channels with a large slope, plan; in FIG. 2 is a section AA in FIG. one; in FIG. 3 shows a fragment of the design of the spreading device in the form of a semi-cone of the rear of the plane of the plate above the water intake gallery; FIG. 4 shows a fragment of the design of the spreading device with a partition, a cross section.

The two-sided water separator for channels with a large slope contains a water reception gallery located between the supplying channel 1 and the transit channel 2. The water receiving gallery 3 is sloped 4 towards the bottom 5 of the gallery 3. The rear part inside the water receiving gallery is made by curved thresholds 6, 7, the exit from the gallery 3 is connected with outlet channels 8, 9, in the inlet section of which the gates 10, 11 with a lifting mechanism are installed.

The water inlet gallery 3 is blocked in one plane of the bottom of the inlet 1 and transit 2 channels, with a splitter in the form of a plane of the plate 12, short pressure pipes 13 laid down on the slope 4 of the water inlet 3, slots 14 of the splitter, and connected by slots 14 of the flexible coupling-insert 15 with pressure by pipes 13. Under the lattice 16, overlapping the slots 14, on the slope 4 for regulating water intake through the slots 14, rotary sections of the valve 17 are fixed on the axis of rotation 18, the axis, which is connected to the actuator 19 of their vertical movement. The drive 19 is arranged in a niche of the wall of the supply channel 1.

The spreaders 20 form a partial backwater level above the end part of the plane of the plate 12, and occupies a position in the form of a half cone, which are located in the rear part of the plane of the plate 12, overlapping the water inlet gallery 3. At the same time, the spreaders 20 with partitions 21 covering the water inlet openings 22 plate 12, a partition 21, which prevents transported sediment into the gallery 3 from flowing downstream into the transit channel 2, so that part of the water additionally flows into the gallery 3. The number of short pressure pipes 13 and spreading devices 20 are set by calculation at the design stage, which depends on the width and flow characteristics of the supply channel 1. The design of the spreading device 20 in plan is made of semi-cones, vertices are oriented towards the supply channel 1, allows them to flow from above, so that leads to water through the baffle 21 to the water inlet openings 22, then to the gallery 3, where these flows are mixed with the main flow of water coming from short pressure pipes 13. In addition, the baffles 21 are simultaneous stepwise and transverse stiffeners, which can be made, for example, of plates.

Since the water level in the inlet channel 1 can vary, and the water intake in the slot 14 of the splitter, respectively, decreases, using the regulator with a drive 19, with the axis 18, vertically move the valve sections 17 towards the slope 4 of the gallery 3. Therefore, the slope 4 is lower than the input part of the slot 14 has a cross-sectional height below the bottom of the inlet channel 1 (with a certain specified angle) allows you to increase the direction of flow of the water intake further into the pressure pipes 13.

A two-way water splitter for channels with a large slope works as follows.

The high-speed flow saturated with sediment flows through the supply channel 1 to the slots 14 of the splitter in the form of a plane of the plate 12 with a regulator in the form of rotary sections of the valves 17 on the axis 18 with the drive 19, as a result of which the clarified water 16 enters through the slots 14 into the pressure pipes 13, connected clutch inserts 15, which are laid down on a slope 4 towards the bottom of the gallery 3, where as a result of the curvilinear outline of the threshold under the plane of the plate 12 in front of the transit channel 2, the water flows coming out of the pressure pipes 12 are twisted, collide with each other and then sent to the discharge channels 8, 9 with high throughput. At this stop of the flow, part of the kinetic energy goes into potential energy in the form of an increased water level in the zone of the gallery 3. At the same time, large entrained sediments freely pass through the slots 14 along the plane of the plate 12. Further, pure water is additionally taken into the gallery 3 by spreading devices 20 with a partition 21 are made with water inlets 22 at the rear of the plane of the plate 12, from where the water enters the gallery 3 and then mixes with the pressure stream coming from the pipes 13. It should be noted that the water intake through the water The openings 22 in the base of the spreading units 20 are carried out at low speeds (0.15-0.20 m / s), which leads to the formation of a rarefaction zone behind the spreading units when the high-speed flow moves towards the transit channel 2. Due to the partition 21, sediments are also transported down downstream to transit channel 2, i.e. the partition 21 does not allow sediment to enter the gallery 3. All of this overall construction design of the structure contributes to an increase in throughput as well as nanotransport capacity.

In the absence of water intake, the valve sections 17 on the axis 18 occupy their horizontal position and, accordingly, overlap the slots 14 of the splitter from below. Thus, the flow velocity of the water is not violated towards the transit channel 2, even in the presence of spreading channels 20 with semi-cones, they are oriented with their vertices towards the supply channel 1, protecting the gallery 3 from sedimentation. The round pressure pipes 13 are short in length and work in full section, as they are laid down on the slope 4 towards the gallery 3, while the slots 14 sharply reduce their resistance to energy flow when they are connected to the pipe ends using a flexible sleeve-insert 15 in the open state of the controller of the valve sections 17 in the axis 18 of the drive 19.

The proposed construction of the facility is industrial, has a much larger allowable range of clean water intake and reduces the transport of sediment to the gallery. It should be borne in mind that the stability of transients of the hydraulic regime that arise during the operation of these structures is ensured by a rational layout and a technically competent design solution for the water splitter. Such an interconnection and interdependence of the main elements of the water divider ensures operational reliability with a change in the water level and optimal throughput in the conditions of the passage of a turbulent flow in the channel.

Elimination of the gushing hydraulic jump of the overloads and failures of the above elements increases the volume of water supply, reduces operating costs by reducing the overhaul periods compared to the known device with the same construction costs.

In General, the invention will greatly simplify the layout of the structure for regulating the speed regime in the channel during the intake of water to the consumer and increase the reliability of his work.

Claims (5)

1. A two-sided water splitter for channels with a large slope, comprising a supply and transit channels, a regulating shutter, a water intake gallery having a water intake opening in the upper part blocked by a grill, the gallery is made with an inlet head, characterized in that the water splitter is made by a splitter in the form of a plate plane superimposed on the movement of the flow of the pipe path and having slots in the front part, and the entrances to the slots below the grating overlap are equipped with a regulator in the form of separate sections of valves fixed to the axis of rotation, the axis is connected to the drive of their vertical movement with the possibility of placement in the niche of the channel wall, while the rear part of the plate plane from above is equipped with spreaders with semi-cones oriented vertices towards the inlet channel. 2. The water divider according to claim 1, characterized in that the pipes are laid along the slope of the bottom towards the water intake chamber. 3. The water divider according to claim 1, characterized in that the back of the water intake gallery of the transit channel is made in terms of a curved outline with a threshold in the direction of the transit channel. 4. The water divider according to claim 1, characterized in that the ends of the slots of the plane of the plate are connected to the inlet heads of the pipes using a flexible sleeve-insert. 5. The water divider according to claim 1, characterized in that the back of the plane of the plate is equipped with spreaders that are equipped with water intake openings with a threshold placed under the semiconics in the plane of their base.

Images