RU2131494C1 - Spillway works - Google Patents

Abstract

FIELD: hydraulic engineering; armoring in downstream reach of spillways and water passageways. SUBSTANCE: spillway works has spillway and apron slab in drain bed, as well as members with drop walls whose steep surface faces downstream reach. Members are made in the form of projections on side walls, in the form of spring-boards on spillway, and in the form of dissipaters on apron slab. Perforated pipe is mounted under members in drain bed and its hollow communicates with downstream reach through drain canal. The latter communicates with atmosphere through air ducts. Pressure pulses are not transmitted through drain canal under apron slab. EFFECT: reduced water back pressure on apron slab foot, improved efficiency of stream energy dissipation, provision for preventing works fracture. 8 cl, 2 dwg

Description

 The invention relates to the field of hydraulic engineering and can be used with a mounting device in the lower bay of drainage and culverts.

 A spillway structure is known, including a spillway and water slabs with drainage wells located on a drainage layer (see MM Grishin, "Hydrotechnical Structures. Part 1. M .: Higher School, 1979, p. 230, Fig. 9.03).

 However, in the well-known spillway structure, high hydrodynamic loads from the rapid flow through the drainage wells are transmitted in the form of impacts to the soles of water-bearing plates, and through the soil of the foundation and to the sole of the spillway, which determines the massiveness of the structure.

 A spillway structure is known, in the basement of which water slabs in the drainage layer around each drainage well there is a pressure pulsation damper in the form of a closed elastic shell filled with air and placed in a special way in a rigid perforated element (see RU, copyright certificate N 1740537, class E 02 B 8/06, 1992).

 However, such a spillway structure is also massive due to the fact that the water stand is in a balanced state of back pressure of the water. At the same time, pressure pulsation dampers are not repairable and can quickly fail.

A spillway structure is known in which a drainage well is made in the form of a gap around a pile crossing a water plate and a drainage layer and immersed in the base, while the pile head forms a flow energy damper (RU, copyright certificate N 529281, class E 02 B 8/06 , 1976)
In such a spillway structure, from the lower side (from the downstream side), the damper in the water stream breaks off the jet with the formation of a sub-jet region with reduced pressure. This could have a beneficial effect on the stability of the water plate by reducing the back pressure of the water on its sole. However, through the drainage gap at the upper side of the damper, shock loads penetrate under the slab, which not only completely eliminate this possible positive result, but also determine the opposite result: increase the instantaneous backpressure of water on the bottom of the water slab.

 The closest technical solution to the proposed one is a spillway in which the drainage well is made in the form of a channel, and its outlet is completely located directly behind the damper ledge, the steep surface of which is facing the downstream side. The absorber is made on a water plate located on the drainage layer on the lower side of the spillway dam and forms a sub-jet region (see Recommendations for the determination of hydrodynamic loads affecting slabs of water spills and aprons of spillway dams. P73-78, VNIIG, A. 1979, p. . 50).

 A disadvantage of such a known spillway structure is that the sub-jet region formed by the damper is unstable and is completely filled with water with pulsating pressure, which is transmitted through the drainage channel to the bottom of the water plate, which reduces the reliability of the spillway structure.

 The technical result from the use of the invention is to increase the reliability of the spillway structure by increasing the efficiency of lowering the back pressure of the water to the bottom of the water plate and preventing the transmission of pressure pulsation under the water plate through the drainage channel. At the same time, the efficiency of quenching the energy of the water flow is increased, cavitation damage to the structure is prevented, and its maintainability is increased.

 The specified technical result is achieved due to the fact that in the spillway structure, including a spillway and a water stand located on the drainage layer, side walls, an element with a ledge, the steep surface of which is turned towards the downstream and forms an under-stream region in the water flow, and a drainage channel communicated at one end with a drainage layer and at the other end with a downstream, wherein the outlet of the drainage channel is located directly behind the ledge with respect to the water flow, according to the invention, The main structure is equipped with an air duct communicating the drainage channel with the atmosphere, and the outlet of the drainage channel is located on the steep surface of the ledge.

Additionally:
- the outlet of the drainage channel is located at a distance from the water plate;
- the drainage channel is in communication with the drainage layer by means of a perforated pipe placed in the drainage layer;
- the element with a ledge is made on the side wall, and in its lower part and at a distance from the water plate;
- the element with a ledge is made on the spillway in the form of a springboard adjacent to a water plate;
- the element with a ledge is made on a water plate in the form of a pile head crossing the water plate and the drainage layer and immersed in the base of the spillway structure;
- the duct at one end is connected to the perforated pipe, and the other end is connected to the atmosphere;
- the element with a ledge on the side wall is made in the form of a protrusion and / or recess.

 The essence of the technical solution lies in the fact that saturation of the sub-jet region and the drainage channel with air increases the stability of the sub-jet region necessary for the constant removal of back pressure of water to the bottom of the water plate and almost completely prevents the transmission of pressure pulsation through the drain channel under the water plate due to its high damping ability compressible water-air mixture formed in the channel and in the sub-jet region. In this case, due to aeration of the water flow, the efficiency of quenching the flow energy is increased and cavitation destruction of the structure is prevented. The location of the outlet of the drainage channel on the steep surface of the ledge and at a distance from the water plate increases the efficiency of further pressure reduction in the sub-jet region due to the location of the outlet of the drainage channel in the less flooded and less pulsating central part of the sub-jet region. And, finally, the location of the ledge accessible for repair on the side surface of the side wall in its lower part and at a distance from the water plate provides an even greater decrease in pressure in the sub-jet area due to the timely removal of water from the sub-jet region by the flow washing the bottom from the bottom, which provides an effective reduction counter-pressure of water to the bottom of the water plate and the absorption of a given amount of air at a given vacuum under the water plate.

 In FIG. 1 shows a single-span spillway, plan; in FIG. 2 is a section AA in FIG. 1.

 A single-span spillway structure includes a spillway made in the form of a spillway dam 1 located on the drainage layer 2, a water plate 3 located on the drainage layer 4, side walls 5 adjacent to the dam 1, side walls 6 adjacent to the water plate 3, and elements with ledges, the steep surface of which faces the downstream side, made in the form of protrusions 7 on the side walls 6, in the form of a springboard 8 on the spillway plate 1 and in the form of energy absorbers 9 on the water plate 3.

 The protrusions 7 are located one at a time on both side walls 6 in their lower parts and at a distance from the water plate 3, with each protrusion forming a ledge 10. Between the projections 7 under the water plate 3 in the drainage layer 4 there is a perforated pipe 11, the ends of which are connected to lower downstream through the drainage channels 12, made in the side walls 6, and with the atmosphere through the ducts 13. The outlet 14 of each drainage channel 12 is located directly behind the protrusion 7 in relation to the flow of water on a steep rhnosti its ledge 10 and outlet openings 15 air ducts 13 are disposed on the side surfaces of the edge webs 6 on the uncovered elevations.

 The springboard 8 is adjacent to the water plate 3 and forms a ledge 16, and between the side walls 5 under the spillway dam 1 in the drainage layer 3 there is a perforated pipe 17, the cavity of which is communicated with the downstream via drainage channels 18 made in the dam 1, and with the atmosphere through air ducts 19 made in the side walls 5. Moreover, each outlet 20 of the drainage channel 18 is located on the steep surface of the ledge 16 and at a distance from the water plate 3, and the outlet openings 21 of the ducts 19 are located on the sides on the surface of the side walls 5 at unsinkable marks.

 The damper 9 on the water plate 3 in plan are arranged in two rows across the water plate 3 in a checkerboard pattern, have the form of flow splitters and each is made in the form of a pile head 22, intersecting the water plate 3 and the drainage layer 4 and immersed in the base 23 of the spillway, and forms a ledge 24. Between the rows of dampers 9 under the water plate 3 in the drainage layer 4 there is a perforated pipe 25, the cavity of which is connected to the downstream channel through the drainage channels 26 made in each pile 22, and with the atmosphere through the air odes 27 made in the side walls 6. In this case, the outlet 28 of each drainage channel 26 is located on the steep surface of the ledge 24 of the corresponding damper 9 and at a distance from the water plate 3, and the outlet openings 29 of the ducts 27 are located on the side surfaces of the corresponding walls 6 on non-flooded marks.

 The element with a ledge 10 on the side wall 6 can be made in the form of a recess 30 (in the drawing, the recess is shown by a dotted line) or combined.

 If necessary, the drainage layers 2 and 4 by means of the simplest anti-filtration elements (not shown) are fenced off from the downstream.

 In a multi-span spillway structure, the inlet openings of the air ducts 19, 13 and 27 are located on the lateral surfaces of both the side walls 5 and 6, and on the bulls of the spillway dam, on the dividing walls and on the non-flooded flow splitters.

 A spillway works as follows.

 In the absence of water discharge through the spillway, the water filtered from the upstream side flows into drainage layers 2 and 4, collects in perforated pipes 17, 11 and 25 and flows through the drainage channels 18, 12 and 26 into the downstream without hindrance. As a result of this, the filtration pressure of water on the soles of the spillway dam 1 and the water plate 3 decreases.

 During the period of water discharge, the water plate 3 is subjected to high pulsating loads. At the same time, behind each step 16, 10 and 24, a sub-jet region is formed with a pressure below atmospheric. As a result, air enters the perforated pipes 17, 11 and 25 through the air ducts 19, 13 and 27, and the drainage channels 18, 12 and 26 begin to suck out the air-water mixture, filling it with the sub-jet region. This increases the stability of the sub-jet region and almost completely prevents the transmission of pressure pulsations through the drainage channels under the water plate 3. Under such conditions, the back pressure of the water on the soles of the spillway dam 1 and water plate 3, which after that all its weight (no weighing), decreases to atmospheric and lower. and the weight of the water above them is completely transferred directly to the base soil skeleton, which significantly increases the stability of the structure. At the same time, the flow of air into the water stream helps to extinguish the energy of the stream and protects the structure from cavitation.

 The deepest and most stable pressure decrease occurs at the side wall 6 behind the ledge 10, which is washed by a stream of water from below, as a result of which water from the sub-jet area is immediately carried out by this stream, which prevents “flooding” of the drainage channel 12.

 Piles 22 work in conjunction with a water slab 3, which makes it possible to use the load-bearing properties of the base 23 to a greater extent. In this case, the complex drainage channels 26 in the pile 22 are made during its manufacture in the factory, and the head of the pile 22 is given increased strength and resistance to cavitation.

 Air ducts 13 and 27 may not be brought to the bottom of the water plate, but communicated with drainage channels, for example, within the thickness of the water plate. In this case, atmospheric pressure (piezometric water level) will be established above the sole of the water plate, which will lead to partial weighing of the water plate, however, the water above the plate will continue to be a useful load.

 The air ducts 13, 19 and 27 at the outlet can be equipped with dampers (not shown in the drawing), by means of which it is possible to reduce the amount of air supplied to the drainage wells within the established limits, and therefore, if necessary, establish a piezometric water level in the drainage layers 2 and 4 below the bottom of the water plate 3.

 Elements with ledges 10 on the side walls 6 can be located on the marks that are dry at a low water level and thus be accessible for inspection and repair, and the air-duct system itself is equipped with pressure sensors.

 Lowering the back pressure of the water under the dam 1 and the water plate 3 during the discharge of water will temporarily increase the gradients of the filtration flow in the base 23, which is taken into account when designing the structure.

 The use of the invention will improve the reliability of the spillway structure by increasing the efficiency of reducing the back pressure of the water to the bottom of the water plate and preventing the transmission of pressure pulsation under the water plate through the drainage channels. Additionally, the efficiency of quenching the flow energy is increased, cavitation destruction of the structure is prevented, and the maintainability of the structure is increased.

Claims (8)

 1. A spillway structure, including a spillway and a water plate located on the drainage layer, side walls, an element with a ledge, a steep surface which faces the downstream side and forms an under-stream region in the water stream, and a drainage channel communicated at one end with the drainage layer, and the other end with a downstream, and the outlet of the drainage channel is located directly behind the ledge with respect to the flow of water, characterized in that it is equipped with an air duct communicating the drainage channel with the atmosphere, an outlet drainage channel is located on the steep surface of the ledge.  2. The construction according to claim 1, characterized in that the outlet of the drainage channel is located at a distance from the water plate.  3. The structure according to claim 1, characterized in that the drainage channel is in communication with the drainage layer by means of a perforated pipe placed in the drainage layer.  4. The construction according to claim 1, characterized in that the element with a ledge is made on the side wall, and in its lower part and at a distance from the water plate.  5. The construction according to claim 1, characterized in that the element with a ledge is made on the spillway in the form of a springboard adjacent to the watering plate.  6. The construction according to claim 1, characterized in that the element with a ledge is made on a water plate in the form of a pile head intersecting the water plate and the drainage layer and immersed in the base of the spillway structure.  7. The construction according to claim 3, characterized in that the duct at one end is connected to the perforated pipe, and the other end is connected to the atmosphere.  8. The structure according to claim 4, characterized in that the element with a ledge on the side wall is made in the form of a protrusion and / or recess.

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