RU2211280C2 - Spillway structure on rock bed - Google Patents

Abstract

FIELD: hydraulic engineering, construction of multispan spillway structures on rock bed. SUBSTANCE: spillway structure includes spillway, toe basin and pump station. Toe basin is formed by bottom and side and apron walls with cantilevers by bed. Feet of spillway and walls of toe basin are embedded in bed beneath design position of unfixed rock bottom. Bases under internal cantilevers of walls are fixed by pressure grouting and abovementioned cantilevers are anchored to them. Apron wall on side of toe basin is concave in plan and it has bottom water conduit to remove abrasive material from toe basin. Guarding walls of toe basin of spillway structure show increased stability even unfixed in rock bed of toe basin which diminishes usage of materials for its construction. EFFECT: diminished usage of materials for construction spillway structure. 7 cl, 5 dwg

Description

 The invention relates to the field of hydraulic engineering and can be used to create a spillway structure mainly multi-span on a solid, slightly eroded rock base.

 A spillway structure is known, the conjugation of the water flow of which with the downstream is carried out in the form of a jet freely discarded from the tip of the springboard, forming a washout pit at a distance from the structure in the natural riverbed [l].

 The disadvantages of such a spillway are: the formation of water dust, leading to accelerated corrosion of metals and equipment, their icing at negative air temperatures; wave formation and faulty water flow in the downstream during the formation of the erosion pit; lack of confidence in the results of the calculated definition of erosion of the unbroken channel and its admissibility.

 Spillway constructions are known in which the energy of a freely thrown jet is extinguished in a well with an unclad bottom formed by: a) a separate spillway wall; b) deepening in the channel; c) recess and wall [2].

 Such well-known spillway structures only to a small extent eliminate the previously indicated drawbacks of a spillway with a freely discarded stream.

 There, in [l], a spillway structure is known, including a spillway and a water well, which is a massive flat slab with a water element, buried in the base.

 The disadvantage of this device is the significant thickness of the slab, which is necessary for the perception of workloads, as well as its applicability only at low specific water flow rates on the spillway due to the limited length of the whole slab.

 Closest to the proposed one is the well-known spillway structure on a rocky base, including a multi-spillway spillway, a water well formed by side and water walls with consoles at the base, and a pump station near the water well, with the bottom of the water well covered with a concrete mount divided into slabs with seams, the spillway is conjugated by means of a toe-springboard, and the walls - by means of their own consoles in relation to the water well [3, 4, etc.].

 The main disadvantage of the known spillway structure on a rocky base (prototype) is its lack of reliability during its operation and high material consumption when creating, these disadvantages are due to the fact that, firstly, at high specific water flow rates for the spillway of a high-pressure waterworks due to high hydrodynamic workers loads, especially when, at the slightest violation of watertightness, the sealing of the interplate joints of the concrete fastening of the bottom of the water well is established hydraulic connection fissured at the base of the mount, with a hydraulic jump area, the concrete bottom mount will inevitably collapse (Sayano-Shushenskaya hydroelectric station in Russia, Dvorak and Libby in the USA, Netzadalcootl in Mexico and others [4]; secondly, high workloads cause massiveness concrete fastening, which consumes about 40 percent of the concrete needed to create the entire water well, while the destruction of the concrete bottom fastening can lead to a violation of the stability of the enclosing structures of the water well tenok and water-boring wall), and, consequently, to its complete destruction.

 The task to which the invention is directed is to increase the reliability of a water well and reduce its material consumption. The technical result from the use of the invention is to ensure the stability of the enclosing structures of the water well during the formation of a washout pit in the loose rock bottom of the well to its stable state.

 This problem is solved, and the technical result is achieved by the fact that in a spillway structure on a rocky base, which includes mainly a multi-spill weir, a water well formed by side and water walls with consoles at the base and a pumping station near the water well, to the bottom of which the weir is connected by means of a sock springboard, and the walls - through their consoles internal to the water well, according to the invention, the soles of the spillway and the walls of the water well are buried in warping research project below the position nearest to the soles of these non-sticky surface of the rock bottom, going down during the formation of the pits during the washout spillway. In the water well of such a spillway, the base under the inner console of each wall is fixed by borehole cementation and this console is attached to it by anchors.

 It is advisable to also fix the base under the outer console of the well wall with downhole cementation and attach the console to it by means of anchors installed in the cementation wells. This will increase the stability of the walls from overturning them inside a water well in the event of the formation of a washout pit deeper than the design one and will create favorable conditions for a highly effective gravity drainage channel in the form of a cavity between the wall body and its base and / or in the form of a gallery in the wall body. Such a drainage channel is in fluid communication with the drainage wells of the base and with the pumping station.

 If the side wall of the water well is made in the form of a massive fastening of the rocky side, divided into plates by its transverse seams, overlapping sealing devices, the base of each seam and along it has a transverse drainage channel in communication with the longitudinal drainage channel of the side wall - massive fastening, its air channel the cavity creates a gap in the continuity of the aqueous medium at the base of the seam, which significantly reduces the average value of the hydromechanical pressure on the sole of the mount and completely prevents rotates under transfer through the seams of the fastening area of the hydraulic jump the pulse component of the pressure.

 Additionally: the surface of the rocky bottom of the water well is concave; the watering wall of the well is made in the plan, concave from the side of the spillway, and contains in the middle part of the concavity a bottom water conduit for passing abrasive material formed during the formation of the washout pit and with the possibility of overlapping it when draining the well, mainly by means of a shutter in the form of an elastic ball. The first provides a reduction in the volume of abrasive material, and the second - the movement of abrasive material, first to the middle part of the concavity of the water wall, and then through the bottom hole outside the water well.

 With a relatively low water wall, the abrasive material is removed from the water well by the flow of water through the wall crest. In this case, the water-boring wall is performed with the inclination of the upper (pressure) side towards the downstream.

 The essence of the technical solution lies primarily in the fact that the pairing of the walls of the water well with the rock base, performed according to the previously mentioned rules (the depth of the bottom of the wall, fixing the base under the wall consoles and anchoring them to the base, the implementation of gravity drainage channel with the possibility of functioning in pressureless mode ), significantly increases the stability of the walls of the water well and allows, in the case of a solid, slightly eroded rock base, to refuse to perform material oemkogo and unreliable at high workloads mount stilling basin.

The proposed spillway is illustrated by drawings, in which:
- figure 1 shows a plan of a spillway structure;
- figure 2 is a longitudinal section of a spillway according to AA in figure 1;
- figure 3 is a cross section of a water well according to BB in figure 1;
- figure 4 is a transverse section of a water wall in BB in figure 1;
- figure 5 is a transverse section of the mounting of the rocky side of the water well at the interblock seam.

 The spillway structure is located on a rocky base 1 and includes a multi-spillway spillway 2 and a watering well 3 formed by enclosing structures: side walls 4 and 5 and a watering wall 6. The spillway 2 is connected to the loose bottom 7 of well 3 by means of a springboard 8 forming within the well in a stream of water a surface jump. The side wall 4 encloses the water well 3 from the side of the river 9 and at the base 1 is made with consoles in relation to the water well 3 of the inner 10 and outer 11, and the water wall 6 is also with the consoles of the inner 12 and outer 13. The side wall 5 is made in the form massive fastening 14 of the rocky side 15 and with the inner console 16 at the base 1. At the junction of the watering wall 6 to the side wall 4, an interfacing support 17 is made, in which a shaft type pumping station is located, consisting of a water inlet 18 and a communicated suction pipe th 19 with it the pump room 20.

 The side walls 4 and 5 and the water hole 6 are connected with the loose bottom 7 of the well 3 by means of their inner consoles 10, 16 and 12, respectively, the soles of which are recessed into the base below the design position established by the study near these walls 21 (shown in dotted lines in Figs. 2-4 ) loose rock bottom 7, lowering in the process of formation of the erosion pit during the operation of the spillway. The base 1 under the inner consoles 10, 16 and 12 of the walls 4, 5 and 6 and under the outer consoles 11 and 13 of the walls 4 and 6 is fixed by borehole cementation 22 and in these places by means of anchors 23 installed in the cementing wells 24, all of these are attached console

 At the base of the walls 4, 5 and 6 of the water well 3, gravity drainage channels are made in the form of a cavity 25 between the body of the water wall 6 and its base 1 and in the form of galleries 26 and 27 in the body of the side walls, respectively 4 and 5. These drainage channels (cavity 25 and the gallery 26 and 27) are hydraulically in communication with the drainage wells 28 of the base 1, primarily with its fractured upper layer 29, and with a pump station, in which the bottom of the water inlet 18 is located below the bottom of the cavity 25 (Fig. 2), and the capacity of the pump room 20 determined by hydraulic calculation.

 Massive fastening 14 of the bead 15 by transverse seams 30 (Fig. 5) is divided into plates 31. Each seam 30 is covered by a sealing device made in the form of two half-mounted plates (keys) 32, the upper part of the seam 30 is filled with mortar 33, and at the base of the seam 30 and along it there is a transverse drainage channel 34, in communication with the longitudinal drainage channel-gallery 27.

The surface of the loose rock bottom 7 has a concave shape, and the water wall 6 is concave in plan view from the side of the spillway 2 and contains in the middle part a bottom water conduit 35 (Fig. 4) for passing abrasive material generated during the formation of the erosion pit. The diameter of the conduit 35 at the inlet D _is smaller than its diameter D ₀ in the body of the wall 6. When draining the well 3, the conduit 35 is closed by a shutter in the form of an elastic ball 36, the shell of which falls into the conduit 35 through a vertical well 37, equipped with a cover 38, and is filled under pressure liquid or gas.

Figure 1-5 marked and other elements of the water well 3, namely:
39 - the top face of the water wall 6,
40 - air duct gallery;
41 - dividing gobies of a spillway;
42 - air ducts;
43 - air ducts;
44 - water suction channels;
45 - drainage wells;
46 - the upper part of the side wall 5;
47 - anchor;
48 - backfill;
49 - drainage pipes of a water well.

 A spillway works as follows.

 In the absence of water discharge to the spillway, the water levels in the water well and in the downstream water are the same, and the water filtered from the upstream side under the overflow dam is intercepted by drainage 45, therefore, the elements of the water well are not exposed to significant workloads.

 During the period of water discharge, high hydrodynamic loads act on the loose bottom 7 of the water well, under the influence of which the bottom 7 erodes to the design level 21. However, during prolonged operation of the spillway, deeper erosion in places near the walls can occur - below the bottom of the walls 4-6. In this case, the rock strengthened by cementation 22 and attached by anchors 23 to the wall under the horse console prevents the wall from being washed out, and under the lower console it prevents the wall from tilting towards the water well.

 Timely activation of the drainage system of the walls 4, 5 and 6, consisting of a pumping station, cavity 25, galleries 26 and 27, transverse channels 34, wells 28 and a fractured top layer 29 of base 1, provides a non-pressure mode of water in the cavity 25, galleries 26 and 27 and in the transverse channels 34. This substantially reduces the averaged hydromechanical and pulsating effects of water on the soles of the walls, which further increases their stability.

 The abrasive material formed during the formation of the erosion pit is carried out of the well through the bottom water conduit 35 in the water wall 6. In the case of a small height of the water wall, the bottom hole in it is not arranged, and its upper face 39 is made with a slope that ensures the removal of abrasive material from the well — such an embodiment of the water wall in FIG. 1-5 is not shown.

 When operating a spillway structure, it is advisable to discharge water mainly through middle spillways, where the greatest depth and length of the water well, and its side walls are at a distance.

 The use of the invention will improve the reliability of the spillway, especially at high pressures and specific costs, and reduce the consumption of materials for its creation.

Sources
1. Grishin M.M. Waterworks. M .: Gosstroyizdat. - 1962. - C. 127-130.

 2. Deryugin G.K. Analysis of foreign experience in the design and operation of water-lifting devices behind high-pressure dams on a rocky base. News VNIIG them. B.E. Vedeneeva, - St. Petersburg. Energoatomizdat: - 1992. - Volume. 226. S. 7-19.

 3. Efimenko A.I. et al. Destruction of the fixing of the bottom of a water well and its repair. Collection of scientific papers of the hydro project. - M .: - 1988. - Issue. 125.S. 88-105.

 4. Bryzgalov V. I. From the experience of creating and developing the Krasnoyarsk and Sayano-Shushenskaya hydroelectric power stations. Production Edition. -Krasnoyarsk: Sib. ed. House "Surikov", 1999. - S. 145-177.

Claims (8)

 1. A spillway structure on a rocky base, including mainly a multi-span spillway, a water well formed by side and water walls with consoles at the base, and a pump station near the water well, to the bottom of which the spillway is connected by means of a springboard and a wall - through its internal with respect to to the water well of the consoles, characterized in that the soles of the spillway and the walls of the water well are buried in the base below the design position established by the studies e of these soles of the surface of the loose rock bottom, lowering during the formation of the erosion pit during the operation of the spillway, while the base under the inner console of each wall of the water well is fixed by borehole cementation and this console is attached to it by anchors.  2. A spillway facility according to claim 1, characterized in that the base under the outer console of the wall of the water well is fixed by borehole cementation and this console is attached to it by anchors.  3. A spillway facility according to claim 1, characterized in that a gravity drainage channel is made in the base of the wall of the water well and along it in the form of a cavity between the body of the wall and its base and / or in the form of a gallery in the wall body, the channel being hydraulically connected to drainage wells of the base and with the pumping station.  4. A spillway facility according to claim 1 or 2, characterized in that the anchors are installed in the cementation wells.  5. A spillway structure according to claim 1 or 3, characterized in that the side wall of the water well is made in the form of a massive fastening of a rocky side, divided into plates by its transverse seams overlapped by sealing devices, and a transverse drainage channel is made at the base of each seam and along it communicated with the longitudinal drainage channel of the side wall - massive mount.  6. A spillway structure according to claim 1, characterized in that the surface of the rocky bottom is concave.  7. A spillway structure according to claim 1, characterized in that the water-well wall of the well is made concave from the side of the spillway and contains a bottom water conduit in the middle part of the concavity for passing abrasive material formed during the formation of the erosion pit, and with the possibility of its overlap during drainage water well mainly through the shutter in the form of an elastic ball.  8. A spillway structure according to claim 1, characterized in that the water-discharge wall is made with an inclination of the upper (pressure) side towards the downstream.

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