CN213952152U - Differential reverse slope type energy dissipation aeration structure - Google Patents

Differential reverse slope type energy dissipation aeration structure Download PDF

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Publication number
CN213952152U
CN213952152U CN202022187826.7U CN202022187826U CN213952152U CN 213952152 U CN213952152 U CN 213952152U CN 202022187826 U CN202022187826 U CN 202022187826U CN 213952152 U CN213952152 U CN 213952152U
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differential
slope
trapezoidal
energy dissipation
reverse slope
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CN202022187826.7U
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池晓清
杨具瑞
刘柯涵
任中成
邱毅
陈卫星
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Kunming University of Science and Technology
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Kunming University of Science and Technology
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A10/00TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE at coastal zones; at river basins
    • Y02A10/11Hard structures, e.g. dams, dykes or breakwaters

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Abstract

The utility model relates to a differential reverse slope formula energy dissipation aeration structure. The utility model discloses the differential flip bucket links to each other with the terminal step horizontal plane of ladder overflow dam facing, and the adverse slope formula pond of dissolving is located after the sharp changeover portion, and the differential flip bucket is connected through sharp changeover portion with the adverse slope formula pond of dissolving, and the circular energy dissipater of trapezoidal arch is arranged to the adverse slope formula pond of dissolving. The utility model discloses a combine together differential flip bucket and adverse slope formula absorption basin, will flip the flow energy dissipation and combine together with two kinds of energy dissipation modes of underflow energy dissipation, differential flip bucket has great diffusion at the vertical direction to rivers, can effectively weaken rivers to the washing away of riverbed. The trapezoidal convex circular energy dissipater arranged on the reverse slope type absorption basin can reduce the height of a water wing, optimize the flow state of water flow, weaken cavitation damage to a certain extent by the convex circular arrangement, and prolong the service life of the energy dissipater.

Description

Differential reverse slope type energy dissipation aeration structure
Technical Field
The utility model relates to a differential reverse slope formula energy dissipation aeration structure belongs to the energy dissipation facility technical field who uses among the hydraulic and hydroelectric engineering.
Background
In the construction of water conservancy projects, the water discharge structure mainly has two main functions of dissipating energy and discharging flood, discharging redundant water flow, dissipating water flow energy, reducing scouring of a downstream riverbed and enhancing the stability of a dam body. With the need of high dam construction development and the gradual deep understanding of energy dissipation mechanism, many new energy dissipation forms are continuously appeared. At present, common energy dissipation forms mainly comprise underflow energy dissipation, trajectory energy dissipation, surface flow energy dissipation and the like, the underflow energy dissipation mainly depends on hydraulic jump of the front half area to dissipate energy, the energy is concentrated, the load borne by the bottom plate of the stilling pool is concentrated, and therefore hydraulic indexes such as near-bottom flow velocity, pulsating pressure and the like are high, and the bottom plate of the stilling pool is subjected to unstable destruction; the trajectory jet energy dissipation is that trajectory jet water flow is broken under the dragging and entrainment action of the atmosphere in the air and splashes when the downstream water body collides, and atomization rainfall is difficult to avoid. Therefore, an energy dissipation structure is needed, which can not only improve the energy dissipation rate, but also aerate and reduce corrosion to protect downstream buildings and reduce the fluctuation of the water surface of the discharged water flow under the condition of high water head and large flow.
Disclosure of Invention
The to-be-solved technical problem of the utility model is: the utility model provides a differential reverse slope formula energy dissipation aeration structure is applicable to and carries out energy dissipation aeration and corrosion reduction under the large-traffic condition of high water head, reduces the hydraulics index, effectively improves the energy dissipation rate.
The utility model adopts the technical scheme that: a differential reverse slope type energy dissipation aeration structure comprises a differential flip bucket 1, a reverse slope type absorption basin 2, a linear transition section 3 and a trapezoidal convex circular energy dissipater 4; the differential flip bucket 1 is connected with a horizontal plane of a step at the tail end of a stepped overflow dam face, the reverse slope type absorption basin 2 is located behind the linear transition section 3, the differential flip bucket 1 is connected with the reverse slope type absorption basin 2 through the linear transition section 3, and the reverse slope type absorption basin 2 is provided with a trapezoidal convex circular energy dissipater 4.
Further, the differential flip bucket 1 comprises a high bucket 1-1 and a low bucket 1-2; the plane view of the high threshold 1-1 is narrow in the front and wide in the back, the low threshold 1-2 is wide in the front and narrow in the back, and the side of the high threshold 1-1 is an inclined plane.
Further, the flip elevation angle θ of the high sill 1-1 in the differential flip 11The flip elevation angle of the low threshold 1-2 is horizontal at 25 degrees, theta2=0°。
Furthermore, the front half part of the reverse slope type stilling pool 2 is a down slope, the rear half part is a reverse slope, and the reverse slope type stilling pool has a down slope gradient i21/3-1/2, and the adverse slope gradient i of the adverse slope type stilling pool3-1/6 to-1/4, corresponding adverse pool length LBAt a second conjugate depth h2The relationship of (1) is: l isB/h2=4.75、LB/h24.67 or LB/h2=4.9。
Further, the circular energy dissipater 4 of trapezoidal arch is arranged to 2 anti-slope sections of anti-slope formula absorption basin, and the form of arranging is along trapezoidal range protruding circular, and trapezoidal minor face is in the upstream side along water flow direction promptly, and trapezoidal long limit is in the downstream side, and the circular radius of the circular energy dissipater 4 of trapezoidal arch is r, and protruding height is h, and r/h is 0.5 ~ 0.7.
Further, the circular energy dissipater 4 of trapezoidal arch is arranged to 2 adverse slope sections of adverse slope formula absorption basin, and the form of arranging is that the protruding circular is arranged for contrary trapezoidal, and is promptly along the trapezoidal long limit of rivers direction upstream side, trapezoidal minor face at the downstream side, and the circular radius of the circular energy dissipater 4 of trapezoidal arch is r, and protruding height is h, and r/h is 0.5 ~ 0.7.
Further, the height difference a between the high threshold 1-1 and the low threshold 1-2 is equal to the depth h of the contracted section torrent water3,a/h 31 is ═ 1; the width of the end of the sill 1-1 is b1,b1/h32.5 to 2.7, and the width of the end of the low ridge 1-2 is b2,b2/b 13/4; the divergence angle of the sill 1-1 on a plane view is 25 degrees; the vertical and horizontal ratio of the side slope of the teeth is 1: 0.5.
The utility model has the advantages that:
1. water flow passes through the differential flip bucket, and the high bucket and the low bucket of the differential flip bucket can 'tear' the water flow, can have great diffusion in the vertical direction, make the nappe area of launching the water increase, are favorable to weakening the washing away of rivers to the riverbed, and the angle of choosing of high bucket makes jet flow fully contact with the air, can create the aeration condition in nappe bottom, increase aeration concentration. Water flow falls into the reverse slope type absorption basin through the flip bucket and collides with a hydraulic jump main flow generated by a reverse slope, turbulence is strong, fluctuation of water flow out of the basin is reduced, and scouring of the tail water fluctuation on a bank slope is reduced.
2. The combination of the differential flip bucket and the reverse slope type stilling pool increases the aerated concentration of the water flow, the flow state of the water flow tends to be stable, the adverse effect on a downstream bank slope and a building is reduced, and the energy dissipation effect is obvious.
3. The side surface of the tooth which is most easy to generate cavitation is changed into an inclined surface from a vertical surface, and meanwhile, the water flow in the groove is kept to shrink along the way. The pressure on the common inclined wall of the tooth grooves is increased, so that the cavitation resistance of the tooth groove type flip bucket is improved.
4. The circular energy dissipater with the trapezoidal protrusions is arranged on the reverse slope section, so that the flow state of water flow is optimized, the height of a water wing is reduced, the construction is convenient, the cost is saved, a large amount of energy is consumed due to mutual collision of the water flow among the circular energy dissipaters with the protrusions, the water surface fluctuation of discharged water flow is reduced, and the scouring damage of the water flow to downstream buildings is reduced.
5. The combined energy dissipation mode has small downstream scouring, and effectively protects the safety of the dam body of a water outlet structure in hydraulic engineering under the conditions of high water head and large flow.
Drawings
Figure 1 is a schematic plan view of the a-type energy dissipation aeration structure of the present invention, used for the underflow energy dissipation of medium and high head hydropower stations;
FIG. 2 is a schematic structural view of the differential flip bucket of FIG. 1;
FIG. 3 is a top view of the high and low sill portions of the differential flip sill of FIG. 1;
FIG. 4 is a cross-sectional view taken along line II-II of FIG. 1;
FIG. 5 is a schematic view of the angle II-II of FIG. 1;
FIG. 6 is a cross-sectional view taken along line I-I of FIG. 1;
figure 7 is a schematic plan view of the B-type energy-dissipating aeration structure of the present invention, used for the underflow energy dissipation of medium and high head hydropower stations;
figure 8 is the plane schematic view of the C-type energy-dissipating aeration structure of the present invention, used for the underflow energy dissipation of medium and high head hydropower stations.
Fig. 9 is a schematic view of the flow state of the adverse slope section of the adverse slope type stilling pool of the utility model.
The respective reference numerals in fig. 1: 1-differential flip bucket, 2-reverse slope absorption basin, 3-linear transition section, 1-1-high bucket, 1-2-low bucket and b1-sill end width, b2-width of end of low threshold, height difference of a-high threshold and low threshold, theta1-flip elevation angle of sill-gay, θ2Low bucket flip elevation, 4-trapezoidal convex circular dissipator, i1Flip elevation angle, i2-down slope gradient of reverse slope type stilling pool i3-the adverse slope gradient of the adverse slope type absorption basin.
Detailed Description
The present invention will be further described with reference to the accompanying drawings and specific embodiments.
Embodiment 1, as shown in fig. 1-6 and 9, the utility model comprises a differential flip bucket 1, a reverse slope type absorption basin 2, a straight line transition section 3 and a trapezoidal convex circular energy dissipater 4; the differential flip bucket 1 is positioned at the tail part of the last stage ladder, the reverse slope type absorption basin 2 is positioned behind the linear transition section, the differential flip bucket 1 is connected with the reverse slope type absorption basin 2 through the linear transition section 3, and the reverse slope section of the reverse slope type absorption basin 2 is provided with a trapezoidal convex circular energy dissipater 4; the flip elevation angle of the differential flip 1 is theta and the high flip (tooth) 1-1125 °, low ridge (groove) 1-2 horizontal, θ20 °; the height difference a between the high ridge and the low ridge is equal to the depth h of the contracted section torrent3,a/h 31 is ═ 1; the width of the end of the sill is b1,b1/h32.5, width of the lower ridge end b2,b2/b 13/4; the divergence angle of the sill on the plane view is 25 degrees; the vertical and horizontal ratio of the side slope of the teeth is 1: 0.5; the back half part of the reverse slope type stilling pool has a reverse slope with the slope i3=-1/6, corresponding adverse slope pool length LBIs generally LB/h24.75, the circular arrangement of the trapezoidal bulges of the reverse slope section is arranged to be a forward trapezoid.
The energy dissipation rate of the A-type differential reverse slope type energy dissipation aeration structure in the embodiment is about 60-75%, the fluctuation of the water surface of the discharged water flow of the stilling pool is reduced, the water jump is submerged in the stilling pool, and the water flow turbulence is strong.
Embodiment 2, as shown in fig. 2-7 and 9, the present invention comprises a differential flip bucket 1 and a reverse slope type stilling pool 2; a linear transition section 3; the differential flip bucket 1 is positioned at the tail part of the last stage ladder, the reverse slope type absorption basin 2 is positioned behind the linear transition section, and the differential flip bucket 1 is connected with the reverse slope type absorption basin 2 through the linear transition section 3; the flip elevation angle of the differential flip 1 is theta and the high flip (tooth) 1-1125 °, low ridge (groove) 1-2 horizontal, θ20 °; the height difference a between the high ridge and the low ridge is equal to the depth h of the contracted section torrent3,a/h 31 is ═ 1; the width of the end of the sill is b1, b1/h32.6, width of the lower ridge end b2,b2/b 13/4; the divergence angle of the sill on the plane view is 25 degrees; the vertical and horizontal ratio of the side slope of the teeth is 1: 0.5; the back half part of the reverse slope type stilling pool has a reverse slope with the slope i3-1/5, corresponding to a pool length LBIs generally LB/h24.67, the circular arrangement of the trapezoidal bulges of the reverse slope section is arranged to be a forward trapezoid.
The energy dissipation rate of the B-type differential reverse slope type energy dissipation aeration structure in the embodiment is about 60-75%, the fluctuation of the water surface of the discharged water flow of the stilling pool is reduced, the water jump is submerged in the stilling pool, and the water flow turbulence is strong.
Embodiment 3, as shown in fig. 2-6 and fig. 8-9, the present invention comprises a differential flip bucket 1 and a reverse slope type stilling pool 2; a linear transition section 3; the differential flip bucket 1 is positioned at the tail part of the last stage ladder, the reverse slope type absorption basin 2 is positioned behind the linear transition section, and the differential flip bucket 1 is connected with the reverse slope type absorption basin 2 through the linear transition section 3; the flip elevation angle of the differential flip 1 is theta and the high flip (tooth) 1-1125 °, low ridge (groove) 1-2 horizontal, θ20 °; the height difference a between the high bank and the low bank is equal to the shrinkage sectionDepth h of torrent water3,a/h 31 is ═ 1; the width of the end of the sill is b1,b1/h32.7, width of the lower ridge end b2,b2/b 13/4; the divergence angle of the sill on the plane view is 25 degrees; the vertical and horizontal ratio of the side slope of the teeth is 1: 0.5; the back half part of the reverse slope type stilling pool has a reverse slope with the slope i3-1/4, corresponding to a pool length LBIs generally LB/h24.9, the circular arrangement of the trapezoidal bulges of the reverse slope section is in a reverse trapezoidal shape.
The energy dissipation rate of the C-shaped differential counter-slope energy dissipation aeration structure in the embodiment is about 60-70%, the fluctuation of the water surface of the discharged water flow of the stilling pool is reduced, the water jump is submerged in the stilling pool, and the water flow turbulence is strong.
The utility model discloses a theory of operation is:
the differential flip bucket 1 comprises a high bucket 1-1 and a low bucket 1-2; the high sill 1-1 and the low sill 1-2 can diffuse water flow in the vertical direction to consume most of kinetic energy, the plane view of the high sill is narrow in front and wide in back, the low sill is wide in front and narrow in back, and the side surface of the high sill is an inclined plane, so that the water flow in the body type holding groove is contracted along the way, the pressure on the inclined wall common to tooth grooves is increased, and the anti-cavitation performance of the body type holding groove is improved;
the front half part of the reverse slope type stilling pool 2 is a down slope, the rear half part is a reverse slope, and water jump and trajectory can occur according to the flow; when the flow is smaller than the designed flow, hydraulic jump occurs in the front half part; when the flow is overlarge, the water jump disappears, and the rear half water flow is ejected out in a rapid flow state; adverse slope type absorption basin downslope slope i21/3-1/2, and the adverse slope gradient i of the adverse slope type stilling pool3=-1/6~-1/4。
Water flow consumes most kinetic energy through the differential flip bucket 1, is ejected into the air through the curve and falls into the reverse slope type stilling pool 2, and the combined energy dissipation mode can improve the energy dissipation rate and reduce the sediment accumulation problem in the stilling pool.
The reverse slope type stilling pool 2 is provided with a trapezoidal convex circular energy dissipater 4 in a reverse slope manner, and the arrangement form mainly has the following two conditions:
a type structure: the 2 anti-slope sections of anti-slope formula absorption basin arrange trapezoidal protruding circular energy dissipater 4, arrange the form for arranging protruding circular along trapezoidal, follow the trapezoidal minor face of rivers direction promptly in the upstream side, trapezoidal long limit is in the downstream side, and trapezoidal protruding circular energy dissipater 4 circular radius is r, and protruding height is h, and r/h is 0.5 ~ 0.7.
b type structure: the 2 anti-slope sections of anti-slope formula absorption basin arrange trapezoidal protruding circular energy dissipater 4, arrange the form for the protruding circular of contrary trapezoidal range, follow the trapezoidal long limit of rivers direction promptly and incline upstream side, trapezoidal minor face is at the downstream side, and the circular radius of trapezoidal protruding circular energy dissipater 4 is r, and protruding height is h, and r/h is 0.5 ~ 0.7.
The utility model combines the differential flip bucket and the reverse slope absorption basin, combines two energy dissipation modes of flip flow energy dissipation and bottom flow energy dissipation, the high-speed water flow discharged by the water discharge structure is guided by the flip bucket to throw the water flow into the air, and the water flow mixes a large amount of air in the air and rubs with the air to achieve the effect of energy dissipation and air mixing; due to the curve action, a gradually diffused water tongue falls to a downstream stilling pool to dissipate most kinetic energy of water flow; the front half part of the downstream stilling pool is a downslope, the rear half part of the downstream stilling pool is a reverse slope, when the flow rate does not exceed the designed flow rate, the water jump appears in the reverse slope, when the flow rate is overlarge, the water jump disappears, the water flow is ejected in a rapid flow state, and the dual functions of the water jump and the trajectory are realized; the differential flip bucket has great diffusion to rivers in the vertical direction, can effectively weaken the washing away of rivers to the riverbed. The trapezoidal convex circular energy dissipater can reduce the height of a water wing, optimize the flow state of water flow, weaken the damage of cavitation and cavitation erosion to a certain extent by the convex circular arrangement, and prolong the service life of the energy dissipater.
Example 4, this example is the same as example 1, example 2 or example 3, except that: adverse slope type absorption basin downslope slope i21/3, the high bank 1-1 is narrow at the front and wide at the back in plan view, the low bank 1-2 is wide at the front and narrow at the back, and the side of the high bank 1-1 is an inclined plane.
Example 5, this example is the same as example 1, example 2 or example 3, except that: adverse slope type absorption basin downslope slope i21/2, the high bank 1-1 is wide at the front and narrow at the back, the low bank 1-2 is wide at the front and narrow at the back, and the high bank 1-1 is at the sideThe surface is an inclined surface.
Example 6, this example is the same as example 1, example 2 or example 3, except that: adverse slope type absorption basin downslope slope i22/5, the high bank 1-1 is narrow at the front and wide at the back in plan view, the low bank 1-2 is wide at the front and narrow at the back, and the side of the high bank 1-1 is an inclined plane.
While the present invention has been particularly shown and described with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

Claims (7)

1. A differential reverse slope type energy dissipation aeration structure is characterized in that: comprises a differential flip bucket (1), a reverse slope type stilling pool (2), a linear transition section (3) and a trapezoidal convex circular energy dissipater (4); the differential flip bucket (1) is connected with a step horizontal plane at the tail end of a stepped overflow dam surface, the reverse slope type absorption basin (2) is located behind the linear transition section (3), the differential flip bucket (1) is connected with the reverse slope type absorption basin (2) through the linear transition section (3), and the reverse slope type absorption basin (2) is provided with a trapezoidal convex circular energy dissipater (4).
2. The differential reverse slope energy dissipation aeration structure of claim 1, wherein: the differential flip bucket (1) comprises a high bucket (1-1) and a low bucket (1-2); the plane view of the high threshold (1-1) is narrow in the front and wide in the back, the low threshold (1-2) is wide in the front and narrow in the back, and the side surface of the high threshold (1-1) is an inclined surface.
3. The differential reverse slope energy dissipation aeration structure of claim 2, wherein: the flip elevation angle theta of the middle sill (1-1) and the high sill (1-1) in the differential flip sill (1)1When the flip elevation angle of the low threshold (1-2) is horizontal at 25 degrees, theta2=0°。
4. The differential reverse slope energy dissipation aeration structure of claim 1, wherein: the front half part of the reverse slope type absorption basin (2) is a down slope, the rear half part is a reverse slope, and the reverse slope type absorption basin is at a slope gradient i21/3-1/2, transSlope type stilling pool adverse slope gradient i3-1/6 to-1/4, corresponding adverse pool length LBAt a second conjugate depth h2The relationship of (1) is: l isB/h2=4.75、LB/h24.67 or LB/h2=4.9。
5. The differential reverse slope energy dissipation aeration structure of claim 1, wherein: the utility model discloses a circular energy dissipater of trapezoidal arch (4) is arranged to anti-slope formula absorption basin (2) anti-slope section, arranges the form for arranging protruding circular along trapezoidal, follows the trapezoidal minor face of rivers direction promptly in the upstream side, trapezoidal long limit is in the downstream side, and the circular radius of trapezoidal protruding circular energy dissipater (4) is r, and protruding height is h, and r/h is 0.5 ~ 0.7.
6. The differential reverse slope energy dissipation aeration structure of claim 1, wherein: the utility model discloses a circular energy dissipater of trapezoidal arch (4) is arranged to adverse slope formula absorption basin (2) adverse slope section, arranges the form for the protruding circular of contrary trapezoidal range, follows the trapezoidal long limit of rivers direction promptly and inclines upstream side, and trapezoidal minor face is at the downstream side, and the circular radius of trapezoidal protruding circular energy dissipater (4) is r, and protruding height is h, and r/h is 0.5 ~ 0.7.
7. The differential reverse slope energy dissipation aeration structure of claim 2, wherein: the height difference a between the high threshold (1-1) and the low threshold (1-2) is equal to the depth h of the contracted section torrent water3,a/h31 is ═ 1; the width of the tail end of the sill (1-1) is b1,b1/h32.5 to 2.7, and the width of the end of the low ridge (1-2) is b2,b2/b13/4; the divergence angle of the sill (1-1) on a plane view is 25 degrees; the vertical and horizontal ratio of the side slope of the teeth is 1: 0.5.
CN202022187826.7U 2020-09-29 2020-09-29 Differential reverse slope type energy dissipation aeration structure Expired - Fee Related CN213952152U (en)

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Granted publication date: 20210813