RU2718801C1 - Water flow energy absorber - Google Patents

Abstract

FIELD: hydraulic engineering.

SUBSTANCE: invention relates to hydraulic engineering, hydraulics, hydromechanics, and more specifically to hydraulic structures designed to damp energy after pressure water lines in intake chamber. Water flow energy damper includes hydraulic cylinder well 1 with water intake 2 and adjoining to it tangential inlet channel 3 (pipeline) and discharge pipeline 4. Perforated pipe 5 with receiving holes is installed in inner cavity of well 1. Inside the perforated tube there is auger shaft 16 with screw 17 connected to drive 18, and in the upper part of the perforated pipe there are holes for discharge of air released from water. In inner cavity of well 1 in upper part there is annular enveloping screen 10 of spherical shape with convexity upwards with bent ends downwards. Above screen 10 there is an additional air chamber connected to air tube 15 for air release into the atmosphere. When water enters the well with tangential inlet channel vortex chamber 20 is formed. Screw 17 is installed above annular gap of tapered bottom 7 of well 1 coaxially with it. Note here that annular horizontal flange 19 with annular clearance is secured in water well 1 below cone bottom 7 and arranged above exhaust pipeline 4 outlet.

EFFECT: increased efficiency of operation on the way of non-stationary flow of liquid due to local collisions towards water-well well, simplified design and reduced bottom speeds in flow.

3 cl, 2 dwg

Description

The invention relates to hydraulic engineering, hydraulics, hydromechanics, and more particularly to hydraulic structures intended for use as part of hydraulic units equipped with tubular outlets.

A device for quenching the flow energy, including a water well located under the vertical output section of the pressure head water outlet of circular cross section, a flow energy absorber installed above its bottom coaxially with the output section of the pressure water outlet, the flow energy absorber is made in the form of a round lattice with radially located rods (Copyright Certificate SU No. 1392189, ЕОВВ 8/06 dated 04/30/1988).

A disadvantage of the known damper is the low damping efficiency when splitting the jet followed by aeration of the flow, which does not lead to a concentration of flow in the well when it enters the outlet channel, as a result, local velocities maintain high values at a large distance from the damper, which leads to erosion of the channel bottom at quencher. In addition, the presence of bursts of miscible flows, as well as the uneven distribution over the cross section of the well of the flow resulting from its mixing, which should be extinguished by a round lattice, are not effective enough in the operation of the flow energy damper, i.e. large disturbances of the water surface are preserved, both in the water well and along the length of the outlet channel.

The closest in technical essence to the proposed one is a water flow energy absorber, including a horizontal section of the water conduit, an annular extinguishing chamber, a convex upward screen, a vertical inlet pipe installed at the end of the water conduit, the chamber has protruding tabs attached to its inner surface, the screen is configured to vertical movement, while the screen is installed coaxially with the inlet pipe, a water well, the inlet pipe is equipped with a nozzle, which is equipped with a cylinder, installed axially displaced on the outer wall of the nozzle from the larger diameter side with the possibility of axial displacement, installed in the inner cavity of the nozzle coaxially with it and with an annular gap, while guide plates are installed in the cavity between the nozzle inner wall and the outer wall of the conical distributor at an angle to the axis conical spreading device, at the same distance from one another, and the angle of inclination of the guide plates to the axis of the conical spreading device is greater than the angle of inclination of the generatrix of the conical divider, except first, the well has an inner annular horizontal shelf fixed below rastekatelya conical annular gap and disposed above the outlet of the discharge pipe (Patent RU №2660931, E02V 8/06 from 11.07.2018).

A disadvantage of the known water flow energy absorber is the complexity of the nozzle device with the possibility of axial movement on its outer surface of the cylinder with a conical spreading device, which means that its operation efficiency is insufficient, as well as insufficient scattering flow outlet when impacting towards the horizontal annular shelf in the well. In addition, the mounting structure of the conical spreading device is complicated due to the need to move it using the nozzle of the limited guide plates, it is possible to jam during movement, in case of distortions, since the force from the side of the side walls may not vary uniformly.

It should be understood that when unsteady is understood the fluid flow in which the flow rate (speed) change over time. Unsteady flows include transients, in which the flow rate varies from one steady state to another. In the particular case, the flow rate changes from zero to the steady-state maximum value diverted to the outlet conduit.

Thus, if there is an accumulation of energy in the well in the form of turbulent mixing of the liquid, an unsteady period of the transition process occurs. This process of the formation of an unsteady movement can adversely affect the absence of smoothing of the flow water in the well. In addition, the quenching effect in the known absorber is somewhat reduced towards falling on the surface of the water in the well, i.e. there is no twisting effect at the top of the well, and this does not make the well’s chamber more economical.

The technical problem to which the invention is directed is to increase the efficiency and reliability of the work due to the uniformity of the shared flow depending on the speed of the water flowing into the body of the well and subsequent connection at the bottom of the water well and simplifying the design.

The technical result is achieved by the fact that the damper energy of the water flow, characterized in that it has a horizontal section of the water conduit, the screen is convex upward, a water well, while the well has an internal annular horizontal shelf, mounted below the screen with an annular gap and located above the outlet of the outlet pipeline, according to the invention, the conduit in the form of a supply pipe is connected to the water intake hole of the well and adjacent tangential channel for supplying water, while inside and a well, a perforated pipe with openings is rigidly mounted, the upper part of which is provided with a free annular spherical-shaped enclosing screen with a bulge upward, and the bent ends of which are fixed downward with the side walls of the well and the walls of the perforated pipe, the middle part of the perforated pipe is rigidly attached to the guides with vertical rods and oriented above the conical bottom of the well and above the annular horizontal shelf, moreover, inside the perforated pipe is located -shnek screw coupled to the drive motor, and a screw coaxially directed towards the annular gap oriented in the conical bottom of the well and the annular horizontal shelf.

In addition, the upper part of the walls of the perforated pipe above the spherical-shaped enclosing screen has air holes connected to an additional formed air chamber provided with an air tube for releasing air into the atmosphere.

In addition, the lower part of the perforated pipe has a cover with outlet openings in the direction of the screw.

The implementation of the water flow energy damper in the aggregate of interconnected elements determines the achievement of the goal with significant operational reliability for such objects of hydraulic engineering construction, including flow damper.

The presence of water flow through a tangential channel (pipe) through an opening in the wall of the well, where due to the rotational movement created by the tangential channel, water accelerates with a swirl and a funnel, and water flows into the installed perforated pipe inside the well. As a result of the rotation of the auger shaft, water is forced into the holes down the cover where the screw connected to the drive is installed, the screw is directed to the side coaxially oriented above the hole in the conical bottom of the well and towards the horizontal annular shelf, then towards the bottom of the water well. And in order to prevent the accumulation of atmospheric air in the well, which is released during the rotation of water around the perforated pipe with holes, the upper part of the latter has exhaust air openings in the additionally created air chamber above the spherical screen with the ends bent down and an air chamber under the well cover equipped with an air tube communicating with the atmosphere. When flowing around a perforated pipe with holes with a spherical annular enclosing screen in the upper part of the well, its operation is carried out in conjunction with the action of a screw shaft driven by an engine drive located above the well cover when the pushing water is connected with the vortex chamber around the perforated pipe. All this, combined with the action of the incoming tangential water flow, is mixed in the middle part inside the well, and then water flows into the hole of the annular bottom of the well, then towards the gap of the annular horizontal shelf, above which the screw is fixed. In general, this reduces the dynamic effect on the bottom of the water well and its wall, i.e. the efficiency of quenching the energy of the flow to the bottom of the well increases, there is no erosion of its bottom. In addition, it eliminates the possibility of pulsating large fluctuations in the well itself and in the discharge pipe, which means that the swirl of the flow on the surface of the water is sharply reduced, mass flow is realized along the height of the water well.

In FIG. 1 shows a water flow energy absorber, a longitudinal section; in FIG. 2 is a plan view.

The energy absorber includes a cylindrical well 1 with a water inlet 2 adjacent to it by a tangential channel 3 (pipeline) and a discharge pipe 4. A perforated installed pipe 5 with receiving holes 6 is rigidly fixed coaxially above the annular gap above the conical bottom 7 of the well 1, while the upper part the perforated pipe 5 is provided with openings 8 for discharging air released from the water, and the lower part with a cover 9 is equipped with water outlet openings located towards the annular conical gap bottoms 7 of the well 1. In the inner cavity in the upper part of the well 1, an annular spherical-shaped circular screen 10 is installed with a convexity upward with curved ends down around the upper part of the perforated pipe 5, which is rigidly fixed by guides 11 to the vertical rods 12 supporting the screen 10. Top under the cover 13 of the well 1, an additional air chamber 14 is made, which is connected to the air tube 15 to release air released from the water into the atmosphere. The vertical dimensions of the installed perforated pipe 5 are such that inside it is installed a screw shaft 16 with a screw 17 connected to a drive motor 18, mounted above the cover of the well 1.

Below the cover 9 of the perforated pipe 5, the screw 17 is also coaxially located towards the annular gap in the conical bottom 7 for water to flow towards the horizontal annular shelf 19 located below the conical bottom 7.

Inside the cylindrical body of the well 1, a vortex chamber 20 is formed, which is, for rotation of water around the perforated pipe 5 with receiving holes 6. The vortex chamber 20 is bounded from above by a spherical-shaped annular screen 10 convex upward with curved ends downward. In this case, the annular horizontal shelf 19 is located below the conical bottom 7 with an outlet and a screw 17 coaxially mounted above it, which is fixed in the water well 1 above the outlet of the outlet pipe 4, which reduces the bottom velocity in the outlet pipe 4 as a whole.

The energy absorber of the water stream operates as follows.

Water enters through a tangential pipeline 3 through a water inlet 2 into the cavity of the well 1, where, due to the rotational movement created by the tangential pipeline 3 (channel), a funnel is formed in which the level around the perforated pipe 5 slightly decreases as a result of the centrifugal forces of the rotating fluid. As a result of rotation of the drive motor 18, the screw 17 rotates by means of a screw shaft 16 located inside the perforated pipe 5, providing a more efficient twisting of water in it, i.e. twist in the vortex chamber 20 in the well 1, closed from above with an annular screen 10 of a spherical shape convex upward with curved ends down.

Thus, the rotation of the screw shaft 16 and the movement of the screw 17 is carried out, providing water flow in the direction of the annular gap of the conical bottom 7. Moreover, inside the well 1, the air is forced out of the water upward and exits through the holes 8 in the upper part of the perforated pipe 5 into the additional air a chamber 14 with an air tube 15 for discharging air into the atmosphere. Water around the perforated pipe 5 moves with a certain rotation speed, is partially extinguished and has a movement relative to the outlet through the annular opening of the conical bottom 7 of the well 1, which is associated with the rotation of the screw 17, i.e. in the area of the water outlet there is an ejection effect with a swirling stream, then they collide above the annular horizontal shelf 19 fixed to the inner wall of the water well. During the collision, the entire flow is due to the location of the flow around the perimeter of the water well 1 and collision in the thickness of the well filled with water , i.e. collision of the entire flow with a water cushion in well 1, in which the final quenching of energy is carried out. The rate of water suction by the screw 17, as well as the rotation of the actuator 18 is regulated depending on specific conditions. In the process of quenching, the entire volume of the flow in the water well 1 is involved. Thus, in front of the outlet of the discharge pipe 4, the flow becomes steady.

The presence of a rotational movement of the flow around the perforated pipe 5 with inlet openings and a rotational movement inside the pipe by the rate of suction of water due to rotation of the drive, water enters from the vortex chamber 20, then through the outlet openings in the lower cover 9 exit toward the rotary screw 17, directs the entire flow to annular clearance of the conical bottom 7 of the well 1 with the horizontal horizontal shelf 19 attached to the bottom of the annular flange 19. As a result of this process, the flow exits into the water well and the final impact e with annular horizontal shelf 19 in the well 1.

The originality of the design solution is confirmed by the combination of the action of the drive motor and the high-pressure head of the water flow at the entrance to the well, in particular, partially quenching, first in its upper part, the excess kinetic energy of the water, which means that it increases the efficiency by first rotating the water directly to the conical bottom of the well with an annular gap above which a rotating screw is coaxially located, then preventing the vertical discharge of swirling jets of water immediately directly into the well and washing its bottom, there is a collision with an annular horizontal shelf located in a water well. Due to the gradual damping of the flow upon flow from a well adjacent to the hole with a tangential inlet to the well’s internal cavity and the placement of a vertical perforated pipe with holes in it, inside which there is a screw shaft with a screw connected to the drive, in general, dynamic loads on the structure the wells are not so large compared to the prototype.

The energy absorber is simple in design and reliable in operation. The quenching of the water flow is ensured, where the flow rate is regulated by specific conditions.

Claims (3)

1. The energy absorber of the water flow, characterized in that it has a horizontal section of the water conduit, the screen is convex upward, a water well, while the well has an internal annular horizontal shelf fixed below the screen with an annular gap and located above the outlet of the discharge pipe, characterized in that that the conduit in the form of a supply pipe is connected to the water inlet of the well by a tangential channel for supplying water adjacent to it, while the perforated I am a pipe with holes, the upper part of which is provided with a free annular spherical-shaped surrounding screen, convex upward, the bent ends of which are fixed downward with the side walls of the well and the walls of the perforated pipe, the middle part of the perforated pipe is rigidly attached to the guides with vertical rods and oriented above the conical bottom well and above the annular horizontal shelf, and inside the perforated pipe there is a screw shaft with a screw connected to the motor drive I, and a screw coaxially directed towards the annular gap oriented in the conical bottom of the well and the annular horizontal shelf. 2. The damper according to claim 1, characterized in that the upper part of the walls of the perforated pipe above the spherical-shaped enclosing screen has air holes connected to an additional formed air chamber provided with an air tube for releasing air into the atmosphere. 3. The damper according to claim 1, characterized in that the lower part of the perforated pipe has a cover with outlet openings in the direction of the screw.

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