RU2484201C1 - Damper of spillway device energy - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: energy damper comprises an underwater pipe, a conical expanding water conduit, where a flow swirler and a reflector with holes are installed. It also comprises a vertical chamber in the form of a truncated cone installed in the well with the expanding part downwards coaxially to the nozzle, with the possibility to enclose the flow swirler and of fixed movement relative to the nozzle. The side wall of the chamber is arranged with a curvilinear surface in direction of flow movement towards water discharge windows in the place of adjacency of the external nozzle wall to them.

EFFECT: higher efficiency and reliability of device operation, reduced hydrostatic effect at a flow swirler.

4 cl, 2 dwg

Description

The invention relates to hydraulic engineering and can be used to extinguish the energy of a water stream, for example, pressure head pipelines of spillway structures of reservoirs.

Known flow energy damper, including a conduit with horizontal and expanding sections and guiding elements with a gradually increasing height in the direction of flow, mounted on the inner walls of the conduit (USSR Author's Certificate No. 1030474, class EB 8/06, 1982).

A disadvantage of the known device is one-way operation, i.e. when the flow enters from horizontal and expanding sections, the water movement is directed back to the direction of translational motion and the flows collide in one particular direction. In addition, after the outlet, the water has residual wave formation along the length of the channel, and therefore, local speeds remain high at a large distance from the damper, which leads to erosion of the channel. It should be noted that the pressure on the walls around the perimeter of the conduit occurs when intense pulsating velocities occur and generally affects the throughput of the structure and does not provide sufficient efficiency and reliability, since the annular chambers change the flow direction little in the final section of horizontal expansion.

The closest to the proposed purpose, technical nature and achievement of the result is a flow energy absorber, including a submarine pipe, an expanding conical conduit in which a flow swirl and a reflector with holes are installed (USSR Author's Certificate No. 1530120, class A01C 23/04, Е02В 13 / 00, 1988).

The disadvantages of the known devices include:

when the flow exits vertically from an expanding conical conduit, the force of gravity of the water is directed back to the direction of translational motion, this reduces the throughput;

the presence of rotation of the swirl flow contributes to the emergence of waves along the periphery of the chamber and exit from the chamber into the outlet channel;

the device of the turbine suspended by cables and a rigidly mounted reflector with radial rays and mixers makes the structure heavier by weight, leads to vibration, complicates the device and, as a result, the instability of the flow swirl;

effective quenching of energy is not provided for when the flow rate and level fluctuations in the chamber change;

the installation of a flow swirl not to the entire depth of the conical expansion of the conduit reduces its throughput and reduces circulation and radial spreading, which limits the radial movement in the chamber from the side of the conduit walls;

hydrodynamic load, and therefore, the twisting effect is sharply reduced.

The purpose of the invention is to increase the efficiency and reliability of operation and reduce hydrostatic effects on the flow swirl.

This goal is achieved by the fact that the energy absorber contains a vertical chamber in the form of a truncated cone installed in the well downward by the expanding part coaxially with the nozzle with the possibility of enclosing a swirl flow in it and fixed movement relative to the nozzle with swirl flow, and the chamber wall is made with a curved surface in the direction of movement flow to the water outlet windows at the junction of the outer pipe wall. In addition, the initial section of the water conduit is additionally equipped with an L-shaped annular visor with a horizontal shelf located above the water outlet windows. At the same time, it is equipped with an extinguishing well installed outside the outlet of the control chamber with retaining structures, the front of which is made in the form of a corner element with a hinge, which provides the possibility of angular movement of the shield. In addition, according to an embodiment, it comprises a vertically placed telescopic pipe-air duct with the possibility of fixed movement relative to the inlet pipe of the communication channel with the upper chamber cavity in communication with the flow swirl, the telescopic pipe having an outlet elbow with an end cut facing the bottom of the control chamber and below the limit level of the downstream of the control chamber.

This embodiment of an energy absorber made of interconnected elements will increase the energy absorption rate and extinguish the kinetic energy of the flow over a shorter length of the conduit in the chambers, as well as reduce the dynamic impact on the structure as a whole effective quenching of the energy of the water flow. In addition, compared with the prototype of the proposed device is more practical to manufacture and simpler in design. Due to this, the operational costs of preventive maintenance are reduced. The installation of the flow swirl for the entire length and height of the movable chamber regulation coaxially with the nozzle improves circulation and radial spreading, since there is no restriction of radial movement in the chamber from the side of the nozzle walls. At the same time, effectively using such a feature of the hydraulic structure of the flow as the intense twisting effect, the bottom part of the flow is directed under the soothing L-shaped annular visor - it is extinguished and enters through the water outlet into the well, where the flow at the outlet from it is finally extinguished in the control chamber with retaining structures .

Figure 1 shows the damper energy spillway device, section; figure 2 is the same embodiment of a telescopic pipe-duct.

The flow energy absorber includes a spillway, consisting of a vertical shaft 1 and adjacent horizontal pipes 2 and 3, laid in the ground below the surface. At the point of exit of the water flow from the pipe 3, an outlet pipe 4 (head) and a well 5 are arranged. The shaft 1, at the calculated maximum heads on the spillway crest, works in pressure mode. A conical expanding section 6 is adjacent to the pipe 4. The expanding section 6 has a curved shape with a convexity to the direction of flow. On the inner surface of the conduit there are fixed swirling blades with straight and flow-oriented initial parts 7 located on the vertical pipe 4, and curved screw parts 8 located in the expanding section 6. In addition, the base of the initial section 6 is installed on the vertical end section of the pipe 4 (soothing) L-shaped annular visor 9 with a horizontal shelf 10. The vertical chamber 11 in the form of a truncated cone, facing down with the expanded part, mouth ovlena in the well 5 is attached to the screw jack 12 on the service bridge. The camera 11, made in the form of a truncated cone, has a side wall with a curved surface 13 with water outlets 14, the edges of which are connected to the guides 15 adjacent to the outer wall of the pipe 4. The camera 11 is mounted coaxially with the pipe 4 with the possibility of vertical movement along it and fixing this movement using the lifting mechanism 12. The flow swirl and the L-shaped annular visor with a shelf are enclosed in the cavity of the chamber 11 (casing).

Since the water level in the well 5 can increase and air can accumulate under the ceiling of the chamber 11, as a result of which the pressure increases and the flow rate decreases, i.e. then, when air does not break through the outlet windows 14 and there is no suction, using the lifting mechanism 12, the chamber 11 is moved coaxially to the nozzle 4. The chamber 11 also allows not to delay air accumulations moving near the ceiling, therefore the chamber 11 has a cross-sectional height and a width of plan, increasing in the direction of the current to the outlet windows 14.

The well 5 is connected to the control chamber 16, inside which retaining structures are located, the front of which is made in the form of a corner element 17 with a hinge 18 with the possibility of angular movement of the shield 19 and the partition 20 with holes 21, which serve to empty the stilling chamber in the autumn, when there is no water withdrawal at low water horizons of the upper and lower pools.

The embodiment of figure 2 provides for the installation of a pipe-duct 26 placed on the lid of the chamber 11 with a hole 27 in height and a telescopic pipe 28, a latch 29. The telescopic pipe 28 is mounted with the possibility of movement relative to the inlet pipe 26 of the communication channel with the upper cavity of the camera 11 connected with the flow swirl, and has an output bend 30 with an end cut 31 facing the bottom of the control chamber 16 and below the limit level of the lower tail of the control chamber 16 and is made at an angle of 8-10 ° to it.

The telescopic pipe 28 can move in the pipe 26 during vertical movement of the camera 11, and its guides 15 eliminate the possibility of skewing of the camera 11. All elements are removable and interchangeable during adjustment.

The damper energy spillway device operates as follows.

The pressure stream through the inlet pipe 3 rises vertically upward through the pipe 4 of the initial part 7 of the twisting blades, is divided into separate jets. Passing through the expanding section 6 of the water conduit, the jets are twisted by twisting parts of 8 blades. The flow divided into jets under the action of centrifugal force evenly spreads and within the annular chamber 11, leads to the formation of a vortex circulation in zone 22. At the same time, the flow is directed into the gaps between the side walls of the chamber 11 and the end face of the soothing L-shaped annular visor 9 with a horizontal shelf 10 on curved surface 13 and is directed to the water outlet windows 14. The interaction of the upper tier of the flow of zone 22 formed by the flow swirl is partially isolated by a horizontal plane oh wall 9 of the annular L-shaped visor with a lower tier of flow in zone 23 directed into the water-discharge window 14.

Along the perimeter of the circumference of the lower tier of zone 23 of the chamber 11, the flow is damped by an annular L-shaped visor 9 with a shelf 10, i.e. it is a flow damper at the bottom of the chamber 11 in the expanding part, as a result of which its kinetic energy is extinguished, thereby increasing the throughput through the water outlet 14. The entire volume of the cylindrical chamber 11 is involved in the process of extinguishing energy, and the flow moving through the water outlet 14 along the lower tier, it enters the well 5. There is an additional collision of the jets with a water cushion in the well 5, and they are also changed by creating the necessary level difference z between the well 5 and the control chamber 16 Thu lowering or raising of the shield 19 by means of the rotation mechanism (not shown) relative to the pivot shaft 18 and thereby change the gap the water outlet opening 24, and more water flows into the discharge duct 25.

In the embodiment of FIG. 2, due to a possible increase in the water level in the well 5, reaching a maximum level to the lower edges of the water outlet windows 14 of the chamber 11, the air supplied with water through the flow swirl accumulates in its upper part and penetrates through the hole 27 into the duct pipe 26 . The location of the telescopic pipe 28 with a bend 30 and with an end cut 31 in the flow of the control chamber 16 leads to the exclusion of atmospheric air from below, since it is submerged below the level in the control chamber 16, which has a positive slope of the bottom in the direction of movement of water, in which the pressure is lower, than in chamber 11 by

$$\Delta p=C_{\mathrm{<figure-callout\; id="2"\; label="p\; \rho \; V"\; filenames="00000005.png"\; state="\{\{state\}\}">p\; </figure-callout>}}\rho \frac{V^{}}{}\frac{{}^2}{2}$$

where C _p is the coefficient of pressure reduction, depending on the shape and size of the output elbow 30 with a slice 31;

ρ is the fluid density;

V is the average fluid velocity in front of the outlet bend 30 of the telescopic pipe 28, air from the chamber 11 through the pipe 26 of the duct enters the bottom layers of the stream with a volumetric flow rate

, $$Q_a=\mu \omega \sqrt{C_p{V}^2\frac{P}{P_a}}$$

,

where µ is the flow coefficient of the telescopic nozzle;

ω is the cross-sectional area of the telescopic pipe;

P _a is the density of air,

and is carried out by the flow from the control chamber 16 in the form of small bubbles, which eliminates the pressure mode in the chamber 11 and the water hammer. Thus, the correspondence between the pressure of water inflow through the flow swirl from the nozzle 4 and the spillway flow rate from the chamber 11 through the outlet windows 14 is automatically maintained. Moreover, even if a rarefaction effect (vacuum) occurs in the upper part of the chamber 11, an outflow ( suction) of water and the duct works as a siphon with the capture of air entering with the water, as a result of which the throughput increases sharply.

Thus, in the proposed embodiment of the energy absorber, the choice of the dimensions of the chamber 11, the hole 27, the duct 26, as well as the type and size of the output elbow 30 with a slice 31 achieves a high degree of protection of the energy absorber from dynamic effects caused by air accumulations when the chamber is flooded from below, therefore increases the reliability of the damper energy of the water stream.

For manual adjustment of the movable chamber 11 with respect to the stationary nozzle 4 in the guides 15, a predetermined rise height above the water level in the well 5 is established by changing the movable chamber 11 and fixing it using the lifting mechanism 12. In the second embodiment, in FIG. 2, the nozzle 28 is moved along the guide tube 26 with the latch 29. Thus, after adjustment, the output bend 30 with the cut 31 is located below the water level in the control chamber 16. In this case, the camera 11 can also have a remote control for automatic actions. In addition, without the presence of a soothing L-shaped annular visor with a shelf, reliable operation of the chamber 11 in the proposed damper, as well as the control chamber 16 with the retaining structures, is impossible, has a simple system of nodes.

Thus, this allows, based on the interconnection and interdependence of the main components of the quenching structure, to strengthen the effect of quenching the excess kinetic energy of water, the efficiency of the quencher increases, which allows to reduce the length of the mount.

The effectiveness of the proposed device lies in the fact that it provides the implementation of technological schemes for quenching the flow energy and reduces the magnitude of the control efforts during the construction.

Claims (4)

1. The energy damper of the spillway device, including an underwater pipe, a conical expanding conduit in which a flow swirl and a reflector with holes are installed, characterized in that, in order to increase the efficiency and reliability of operation, it contains a vertical chamber in the form of a truncated cone, the surface of which is installed in the well downwardly, the expanding part is coaxial to the nozzle with the possibility of enclosing a flow in its swirl and a fixed movement relative to the nozzle, the side wall of the chamber being made with curved surface in the direction of flow to the outlet windows at the junction of the outer wall of the pipe. 2. The energy absorber according to claim 1, characterized in that, in order to reduce the hydrostatic effect on the flow swirl, the initial section of the water conduit is equipped with an additional quenching L-shaped annular visor with a horizontal shelf located above the water outlet windows. 3. The energy absorber according to claim 1, characterized in that it is equipped with an extinguishing well installed outside the exhaust side of the control chamber with retaining structures, the front of which is made in the form of a corner element with a hinge, which provides the possibility of angular movement of the shield. 4. The energy absorber according to claim 1, characterized in that according to an embodiment it comprises a vertically placed telescopic pipe — an air duct with the possibility of fixed movement relative to the inlet pipe of the communication channel with the upper chamber cavity in communication with the flow swirl, the telescopic pipe having an output bend with end cut facing the bottom of the regulatory chamber and below the limit level of the lower tail of the regulatory chamber.

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