RU2708523C1 - Water flow energy damper - Google Patents

Abstract

FIELD: hydraulic equipment.

SUBSTANCE: invention relates to the hydraulic equipment and can be used for the water flow quenching downstream the pressure water lines in the hydraulic stilling basin. Water flow energy damper includes horizontal section of water conduit 1, vertical branch pipe 2 and well 12. Well 12 has inlet vertical hollow tube 4 with fairing 7 made cone-shaped with concave side walls 8 on outer side of pipe 4, coaxial to which is installed second fairing 9, top 10 of which is directed towards annular horizontal flange 11. Damper is additionally equipped with diffuser section 17, forming clamp 14 between divergent chamber 16 and an outlet into lower part 15 of well 12. Swirler 3 is arranged at the inlet of diffusion section 17 of damping chamber 16 and made in the form of blades. Annular horizontal flange 11 with an annular gap is fixed in hydraulic stilling basin 12 below fairing 9 in the form of a truncated cone with top 10 and is located above the outlet hole of discharge pipeline 13.

EFFECT: increased efficiency of operation on the way of non-stationary flow of liquid due to local collisions of pulsating water flow towards hydraulic stilling basin, simplification of design and reduction of bottom speeds in flow.

3 cl, 1 dwg

Description

The invention relates to hydraulic engineering and can be used to extinguish a water stream after pressure pipes in a water well.

A flow energy absorber is known, including a horizontal section of a water conduit, an annular extinguishing chamber, it is equipped with a spherical vibro-screen with a convex top placed coaxially with a hole of a vertical inlet pipe installed at the end of the water conduit, the chamber has stops interacting with the annular stop in the form of a disk, and the vibro-screen is made with the possibility of vertical movement and has racks in the form of guide adjusting bolts equipped with springs (Patent RU No. 2524987, ЕВВ 8/06 from 08/10/2014).

A disadvantage of the known flow energy absorber is that it is not possible to control both the upper and lower levels in the chamber dividing it into two parts by a vibro-screen, which means that the efficiency and partially reliability are reduced, i.e. during operation, there is no flexible regulation of the quenching of the flow with varying flow rates in the supply conduit from maximum to minimum. In addition, there is no work in the form of a scattering outlet at the place where the stream enters the receiving chamber, so the main disadvantage is the lack of efficiency and reliability, as well as the vertical instability of the vibroscreen.

A water flow energy damper is also known, including a horizontal section of the water conduit, an annular extinguishing chamber, a spherical vibro-screen with a bulge upward, a vertical inlet pipe installed at the end of the water conduit, the chamber has protruding tabs attached to its inner surface, and the vibro-screen is vertically movable and has a rack in the form of a guide adjusting screw, equipped with a spring, the camera is additionally equipped with a screen in the form of a plate mounted coaxially vibroscreen while the bottom of the plate is rigidly fixed to the protrusions-limiters on the side of the outlet pipe, the diameter of the screen of which is smaller than the diameter of the vibro screen, the vibro screen body is made with water reception windows, and its edges have a side wall bent upwards along the radius (Patent RU No. 2574472, ЕВВ 8/06 dated 02/10/2016).

A disadvantage of the known water flow energy absorber is the complexity of the device and, as a consequence, the high material consumption, and this leads to a complication of operational reliability, i.e. insufficient efficiency of its operation. In addition, an elastic spring has the property of metal fatigue during long-term operation, as a result of which it can break and need to be replaced, since the vibro screen can fall down onto an additional screen and block it. Another disadvantage is the absence of a decrease in the efficiency of the scattering outlet towards the well.

The closest to the intended purpose, technical nature and the achieved result 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 made with the possibility of vertical movement, while the screen is installed coaxially with the inlet pipe, a water well, the inlet pipe is equipped with nozzles m, which is equipped with a cylinder mounted on the outer wall of the nozzle from the side of a larger diameter with the possibility of axial movement, a conical spreader installed in the inner cavity of the nozzle coaxially with it and with an annular gap, while in the cavity between the inner wall of the nozzle and the outer wall of the conical spreading the guide plates at an angle to the axis of the 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 sample binder conical rastekatelya furthermore well it 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 flow dispersion during collision 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 with a nozzle limited by guide plates, it is possible to jam during movements, in case of distortions, since the force from the side of the side walls may not vary uniformly.

It should be remembered that non-stationary is understood as a fluid flow in which the flow rate (speed) changes in 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 transition period occurs. This process of the formation of an unsteady motion 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 result is to increase operating efficiency under conditions of a variable water level in an expanding chamber towards pinch in the diffuser section and simplify the design.

The technical result is achieved by the fact that the damper energy of the water stream, characterized in that it has a horizontal section of the conduit, a vertical inlet pipe installed at the end of the conduit, a water well, while the well has an inner annular horizontal shelf located above the outlet of the outlet pipe, according to inventions top

the water well is provided in the center with a vertical hollow pipe with an inlet having an entrance at the end of the inlet pipe interfaced with a water well having an additional expanding chamber, which is connected through the pinch to the bottom of the well, and the pipe at the end is connected with the cone-shaped fairing around the perimeter to the outer sides of the hollow pipe, with the upper concave side walls directed toward the pinch of the well, and the lower cowling made by a truncated cone and has an upper concave wall based which is coaxially directed towards the outlet of the hollow pipe, and the top of the truncated cone is directed towards the annular gap of the annular horizontal shelf, while the pinch is located towards the diffuser section of the well, with the separation of the stream jets and the zone of the diffuser section is additionally equipped with a swirler from the outside of the hollow pipes.

In addition, the swirl is located in the narrowing zone of the well, and is made in the form of blades.

In addition, the diffuser at the end is connected with the walls of the water well towards the annular horizontal shelf.

This embodiment of a water flow energy absorber from interconnected elements will increase the intensity of energy quenching from the water level in an additional expanding chamber in the upper part of the well above an additional cone-shaped fairing fixed along the perimeter from the outside of the hollow pipe, which has upper concave walls in the direction of pinch with an inlet diffuser in the lower part of the well, as well as in the mixing chamber from the fixed swirler, where the flow is twisted, and then flows towards the annular gap ora of the annular horizontal flange, the flow collides towards each other, then part of the flow enters through the vertical hollow pipe, falls on the upper concave wall, the base of which is coaxially directed towards the outlet of the pipe, while the lower second cowl in the form of a truncated cone is placed above the annular horizontal flange and above the outlet of the discharge pipe. In turn, 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 excludes 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 decreases sharply, mass flow is realized along the height of the water well.

The drawing schematically shows a damper energy of the water stream, section.

The water flow energy absorber includes a water conduit 1 with a vertical outlet 2 and a swirler 3, a vertical hollow pipe 4 with an inlet 5 and an outlet 6, a cowling 7 made of a conical shape with concave side walls 8, and a lower bottom is coaxially attached to the outlet 6 (second) cowl 9 in the form of a truncated cone, the top 10 of which is coaxially directed to the center of the outlet of the annular horizontal shelf 11. The annular horizontal shelf 11 is fixed in the water-cutting decks e 12 below the truncated cone of the top 10, while the annular horizontal shelf 11 with an annular gap is located above the outlet of the pipe 13. The water well 12 has a pinch 14 connecting its two parts: the lower 15 and the upper 16 parts, the upper part of which is made in the form of an additional expanding chamber 16 blanking.

The exit of the hollow pipe 4 is located near the entrance to the diffuser section 17 of the blanking chamber 16. The swirl 3 is located at the entrance to the diffuser portion 17 of the blanking chamber 16, and the swirl 3 is made in the form of blades.

The energy absorber of the water stream operates as follows.

Water enters from the water conduit 1, passes through the outlet pipe 2 and is further divided into several stream jets, one of which enters the vertical hollow pipe 4 with a water outlet 5 and an outlet 6, and the other part of the stream enters directly into the quench chamber 16. At the exit of the hollow pipe 4 there is a fairing 7 made with concave side walls 8, the flow passes from the quench chamber 16 and through the swirl 3, where the flow is twisted and enters the diffuser section 17, the quench chamber 16. From the diffuser section 17, a stream of water enters a cone-shaped fairing with concave side walls 8, where they are twisted and also collide with each other. In the process of collision with each other, the parts of the flow are directed towards the placement of the annular horizontal shelf 11 below the fairing 9 in the form of a truncated cone and again there is a collision with the flow coming through the outlet 6 of the tube 4, coaxially located above the lower fairing 9 and collides with it with a concave wall the base of the fairing 9, the apex of which (of the truncated cone) is directed towards the annular gap of the annular horizontal shelf 11. The fairing 9 in the form of a truncated cone forms additional compression of the flow coming out through the swirl 3 and the fairing 7 with concave side walls 8. The interaction of the entire flow due to the presence of all elements of the well leads to additional dispersal of the jets of the flow, impact and spreading of the flow, as well as their impact in the thickness of the water filled bottom of the well 12, i.e. . now already weakened collision occurs with the water cushion in the well 12, in which the final quenching of energy occurs. In the process of quenching, the shared stream is involved in the entire volume of the stream, reaching the bottom of the water well 12.

Thus, the obtained effect is achieved due to the effective swirling of the flow along the path of its entry into the well 12, which ensures a steady flow of water in front of the outlet pipe 13. The process of quenching the flow is realized in a wide range of changes in the flow of water when it enters from the water conduit 1 with the vertical outlet 2 All of this as a whole allows simplifying the design of the energy absorber itself and the device for filling and quenching the kinetic energy of the flow, increasing its efficiency due to the maximum the quenching of the kinetic energy of the incident stream into the water well.

To assess the effectiveness of the proposed construction of a water flow energy absorber, the presence of a hollow pipe in the center of the deck, two reflectors above and below relatively coaxially mounted in the zone of the diffuser section with pinch and additional swirls in general from the horizontal annular shelf, is very effective and can be used for objects quenching of the water flow after pressure pipes in the water well, thanks to the phased quenching of the flow from the horizontal water conduit to the well in which redlozhennye elements of the device.

Claims (3)

1. The energy absorber of the water stream, characterized in that it has a horizontal section of the conduit, a vertical inlet pipe installed at the end of the conduit, a water well, wherein the well has an inner annular horizontal shelf located above the outlet of the discharge pipe, characterized in that the upper part of the water well is provided in the center with a vertical hollow pipe with an inlet having an entrance at the end of the inlet pipe mating with a water well having an additional a widening chamber, which is connected via a pinch to the lower part of the well, and the pipe at the end is connected with a cone-shaped fairing around the perimeter from the outside of the hollow pipe, with the upper concave side walls directed toward the pinch of the well, and the lower fairing made by a truncated cone and has an upper concave a wall whose base is coaxially directed towards the outlet of the hollow pipe, and the top of the truncated cone is directed towards the annular gap of the annular horizontal shelf, at Ohm pinch is located towards the diffuser section of the well, with the separation of the stream jets and the zone of the diffuser section is additionally equipped with a swirl from the outside of the hollow pipe. 2. The damper according to claim 1, characterized in that the swirler is located in the zone of narrowing of the well and is made in the form of blades. 3. The damper according to claim 1, characterized in that the diffuser at the end is connected with the walls of the water well in the direction of the annular horizontal shelf.

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