RU2255171C1 - Energy release and spillway structure for concrete dam - Google Patents

Abstract

FIELD: hydraulic engineering, particularly for passing maximal flood water volumes when it is impossible to transmit thereof through hydroelectric generator.

SUBSTANCE: structure comprises water discharge orifice with gate, hydraulic generator unit with turbine chamber connected with deep -seated water line by suction tube leading to waterway chute located in upper part of hydraulic generator unit and provided with duplicate gate. Opening is formed in deep -seated water line located in area of abutment thereof to turbine chamber. Additional gate is installed in the opening. Water discharge orifice is connected with the opening and waterway chute. Curtain wall forming deep -seated water line is installed in water discharge orifice area. Additional gate is made as a valve with two-sided lining pivotally connected with turbine chamber roof part. Bulwark may be detachably installed in front part of the structure.

EFFECT: increased operational reliability due to prevention of discharged water entrance in waterway part of turbine chamber, possibility of structure connection to surface spillway structure, for instance to concrete dam.

2 cl, 1 dwg

Description

The invention relates to hydropower and can be used in a concrete dam with spillway holes in its body when passing maximum flood costs if it is impossible to pass them through the hydraulic unit, as well as during idle water discharge.

Determining the maximum flow rates of river water is one of the main tasks to be solved in the design of hydraulic structures. The maximum water discharge is formed during the period of abundant nutrition of the rivers, which is due to various reasons: melting of snow, rainfall, and in mountainous regions - melting of snow and glaciers. The maximum costs are usually calculated in the range from 10 to 0.1% coverage (1 time per 10-1000 years), and in some cases up to 0.01% coverage (1 time per 10,000 years).

In particular, 0.01% coverage is the basis of the concrete dam project of the Main hydroelectric power station, which is the counter-regulator of the Sayano-Shushenskaya hydroelectric power station (see the book “Solving the problems of the Sayano-Shushensky hydroelectric power complex.” Materials of the 1986 scientific and technical conference Leningrad: Energoatomizdat, Leningrad Branch, 1987, p.198, Fig. 1.

The Mainskaya Hydroelectric Power Station is an energy-discharge structure, including a surface water outlet and a hydroelectric building.

The concrete dam of the Main hydroelectric power station is designed for daily control of the discharges discharged through the Sayano-Shushenskaya hydroelectric power station, as well as for the passage of maximum and submaximal flood discharges, for which additional (reserve) surface spillways have been made in the concrete dam. These holes are included in the operation when the maximum (catastrophic) expenses are reset and during planned or emergency stops of hydraulic units.

However, the high cost and the extremely low likelihood of using backup spillways for their intended purpose made the costs of their construction practically unprofitable. At the same time, the placement of additional hydraulic units operating on an additional influx of water in an existing concrete dam is undesirable due to the possibility of weakening the dam structure.

The above circumstances determine the complexity and lack of efficiency of operation of the selected analogue.

This drawback has been eliminated in the energy-drainage structure of a concrete dam, including a drainage hole with a shutter, a hydraulic unit with a turbine chamber connected to a deep water supply by a suction pipe, which is led into a drainage channel located in the upper part of the hydraulic power unit and equipped with a repair shutter, in the deep water supply the zone adjoining it to the turbine chamber, an opening is made in which an additional shutter is installed, and a spillway is connected to the specified opening and a spillway main tray (see patents-analogues: item No. 4998846, priority from 01/23/90 - USA and item No. 241026, priority from 01/26/90 - Republic of Argentina).

This technical solution is selected by the authors as a prototype of the claimed invention.

An additional shutter in the prototype is a conventional segmented shutter with a sheathing on the pressure side, which allows you to open an opening made in a deep water conduit when discharging flood water and close it in the turbine operation mode of the structure.

When passing submaximal flood discharges, water through the opening with the shutter raised passes through the drainage channel and merges into the downstream.

Such an energy-saving facility can be used to generate additional electricity during a period when it is not used to pass sub-maximum and maximum floods, by utilizing part of the hydraulic energy reserves of water in the upper pool and without prejudice to the water management state of the latter.

The disadvantage of the prototype is that when the structure works in the spillway mode with the shutter raised, the discharged water rushes through an open opening in a deep water conduit and through the flow part of the turbine chamber. This leads to clogging of the turbine flow path with garbage discharged with water, which can cause damage to the guide vanes and turbine blades. This drawback makes the design of such an energy-discharge plant not reliable in operation, requiring revision of the turbine after the next flood discharge.

Another disadvantage of the prototype is that such a water discharge structure cannot be connected to an existing surface water discharge structure to a concrete dam, which makes the prototype inconvenient to operate.

The present invention is aimed at solving the problem of eliminating the possibility of discharge of discharged water in the spillway operation mode of the energy-saving structure into the flow part of the turbine chamber, as well as providing the possibility of connecting said energy-saving structure to a surface spillway structure, for example, a concrete dam.

The specified technical result is achieved by the fact that the energy-saving structure of the concrete dam, including a water outlet with a shutter, a hydraulic unit with a turbine chamber connected to a deep water supply by a suction pipe, led into the water discharge tray, located in the upper part of the hydraulic unit and equipped with a repair shutter, and in the deep water conduit, in the area adjacent to the turbine chamber, an aperture is made in which an additional shutter is installed, and a spillway is connected to the specified the aperture and a drainage chute, equipped with a sampling wall installed in the zone of the drainage aperture, the additional shutter is made in the form of a valve with two-sided casing (valve shutter) pivotally attached to the ceiling part of the turbine chamber, while the deep water conduit is formed by the sampling wall.

In addition, the energy-saving building can be equipped with a bulwark, which is installed in front of the energy-saving building with the possibility of disconnecting from it.

The applicant is not aware of constructive solutions having the same set of essential features as the claimed one, which indicates the compliance of the claimed object with the criterion of “novelty”.

Due to the implementation of the distinguishing features of the claimed design solution in conjunction with the features common with the prototype, the claimed object has a new technical result - the proposed design of the additional shutter allows the turbine mode by raising the additional valve shutter to close the opening in the deep water conduit, and in the spillway mode by lowering the additional , valve, shutter, open the specified opening, providing water outlet to the spillway tray, and simultaneously close the entrance to the turbine chamber, preventing the entry of dumped garbage into it; two-sided sheathing of an additional valve shutter in both modes of operation of the structure provides a favorable hydraulic mode for flowing around the surface of this shutter; due to the presence of a wall for walls forming a deep water conduit, it is possible to connect the inventive energy-saving facility to a concrete dam. The bulwark allows such an attachment “afloat”.

Moreover, the new technical result does not follow explicitly from the prior art, but is a consequence of the implementation in the proposed technical solution of the distinguishing features of the claimed object in conjunction with the features common to the prototype.

This allows us to conclude that the claimed technical solution meets the criterion of "inventive step".

The invention is illustrated in the drawing, where figure 1 shows the energy-saving structure, a longitudinal section attached to a concrete dam.

The energy-saving building is connected to the concrete dam 1. It includes a water outlet 2 with a shutter 3 and a sampling wall 4. The downcomer 5 is formed by the indicated abrasion wall 4. The hydraulic unit 6 includes a turbine chamber 7 with a hydraulic unit 8 connected to the downcomer 5 by a suction pipe 9, which is discharged into the spillway tray 10, located in the upper part of the hydraulic unit 6 and equipped with a repair shutter 11 at the exit, for maneuvering of which a lifting mechanism 12 is provided. the duct 5, in the area adjacent to the turbine chamber 7, an opening 13 is made, in which an additional shutter 14 is installed, made in the form of a valve (valve shutter) with two-sided casing (not shown in the drawing) pivotally attached to the ceiling of the turbine chamber 7. The actuator 15 is intended for maneuvering with an additional, valve, shutter 14. The spillway 2 is connected to the opening 13 and the spillway tray 10.

The bulwark 16 is located at the front of the energy supply facility. It is designed to connect an energy-saving building with a concrete dam 1 “afloat” and installed with the possibility of disconnecting from it.

The proposed energy-saving construction works as follows. After the connection of this structure with a concrete dam 1, the bulwark 16 is removed. To use the hydraulic energy reserves in the upper pool, a shutter 3 opens, and water flows through a deep conduit 5 into the turbine chamber 7 of the hydraulic unit 6, as a result of which electricity is generated. In this case, the aperture 13 is blocked by an additional valve 14, and the suction pipe 9 is discharged into the spillway tray 10, in which the water level is set, which ensures the required deepening of the impeller of the turbine of the hydraulic unit 8, regardless of the level of the downstream.

If necessary, the passage of the maximum or submaximal flow rates during flood flood 3 opens. The opening 13 also opens by lowering with the help of the actuator 15 an additional, valve, shutter 14. Water through the opening 13 rushes into the spillway tray 10 and discharges into the downstream. The valve shutter 14 in the lowered position blocks the entrance to the turbine chamber 7, preventing debris from entering it.

After the flood with submaximal or maximum discharge, the shutter 3 is lowered, blocking the deep water conduit 5; under its cover, the valve gate 14 rises in calm water and the opening 13 is closed in the deep conduit 5. The hydraulic unit 8 is brought into operation, after which, by lifting the shutter 3, the opening 13 of the deep conduit 5 is opened and the hydraulic unit 8 is activated to generate electricity during the annual pass floods of normal intensity and during the implementation of useful releases of water from the upper pool.

Thus, in the proposed technical solution, in comparison with the prototype, the possibility of getting discharged water in the spillway operation mode of the energy-spillway structure into the flow part of the turbine is excluded; in addition, the specified energy-saving facility can be directly (without any additional costs) attached to a concrete dam.

The indicated advantages of the inventive energy-saving facility determine its high reliability and ease of use.

The proposed technical solution can be implemented using well-known technical means and standard equipment, which indicates, according to the applicant, that the claimed facility meets the criterion of “industrial applicability”.

Claims (2)

1. Energy-saving structure of a concrete dam, including a spillway with a shutter, a hydraulic unit with a turbine chamber connected to a deep conduit by a suction pipe, discharged into a spillway tray located in the upper part of the hydro-aggregate block and equipped with a repair shutter, and in a deep conduit, in the adjoining zone it has an opening to the turbine chamber, in which an additional shutter is installed, and a spillway opening is connected to the specified opening and a spillway tray, characterized in that it is equipped with a sampling wall installed in the area of the spillway, the additional shutter is made in the form of a valve with two-sided casing, pivotally attached to the ceiling of the turbine chamber, while the deep water conduit is formed by the sampling wall. 2. Energy-saving building according to claim 1, characterized in that it is equipped with a bulwark, which is installed in front of the energy-saving building with the possibility of disconnection from it.