UA139840U - HORIZONTAL STRAIGHT HYDRAULIC UNIT WITH DIAGONAL-AXIAL IMPELLER WHEEL AND NOZZLE SUPPLY AND REGULATORY AUTHORITY - Google Patents

Abstract

Horizontal direct-flow hydraulic unit with diagonal-axial impeller and nozzle supply and regulating body includes a generator placed in a capsule or in a concrete column (bull), supply and regulating bodies, impeller, suction pipe. The supply body of the turbine is made in the form of a series of curved confusing nozzle channels with rotary and locking outlet elements, which are placed in a circle and create a moment of flow in front of the impeller of the rotary-blade diagonal-axial type, which ensures optimal operation of the turbine ) pressure.

Description

The utility model belongs to the field of hydraulic engineering and can be used at hydroelectric power stations (HPP).

Known hydraulic units are equipped with rotary-blade type hydroturbines, which include a spiral chamber, a stator, a guide device and an impeller of the rotary-blade diagonal type, used for pressures from 40 to 170 m HP).

Such hydroturbines have high energy cavitation and operational indicators in comparison with rigid-bladed radial-axial hydroturbines, which are used for high pressures.

The disadvantage compared to direct-flow horizontal hydro units is the lower throughput capacity of these hydro turbines and the larger dimensions of the hydro unit block in plan, a less wide range of reliable operation in terms of pressures and flows (powers).

Known horizontal-capsule type hydraulic units with a rectilinear flow path, used at low-pressure hydroelectric power plants with H-3-25 m (21.

Due to the rectilinear supply and discharge of water and the simplicity of the form of the flow path, these hydrounits have advantages over hydrounits with vertical rotary vane hydroturbines (both in throughput and frequency, and in terms of energy indicators) when installed on low-pressure hydroelectric power stations. At the same time, the overall dimensions of the hydroturbine unit are much smaller than in axial vertical rotary vane hydroturbines.

The disadvantage of existing direct-flow hydro units with turbines of this type is that they work at low pressures of up to 25 m. This is due to the fact that in these hydroturbines there is no spiral chamber, and the moment of the amount of movement in front of the impeller of the horizontal-direct-flow hydroturbine is created by the stator columns and a guide device installed in front of the working wheel. Therefore, it is impossible to provide the necessary high level of the moment of the amount of movement in front of the impeller only due to the stator and the guide apparatus.

There is a double direct-flow hydraulic unit with a regulation system with a triple combinatorial dependence between the opening of the guide apparatus and the turning angles of the blades of the two working wheels of the hydroturbines, which allows you to significantly increase the average operational indicators, expand the area of operation in terms of pressure and flow rates, increase the efficiency, and makes it possible to apply the direct-flow scheme to more high pressure In addition, the double direct-flow hydraulic unit allows to obtain greater power with smaller dimensions of the width of the HPP block in

From the plan, compared to two parallel-working units of the vertical rotary-blade type |ZI.

The main disadvantages of the double direct-flow hydraulic unit are the long length of the hydraulic unit along the axis of rotation of the rotors of the hydro turbine-generator, the complexity of the design, which leads to the complexity of the maintenance of the hydraulic unit, the complexity of the work process control system.

The basis of the useful model is the task of increasing the average operational and energy cavitation indicators of direct-flow horizontal capsule hydraulic units, expanding the operating zone in terms of pressures up to 250 m.

The task is solved by the fact that in the turbine in front of the impeller, a nozzle inlet organ of the hydro turbine is installed, which is a series of specially profiled curved (spiral) confusing nozzle channels with rotating output elements, which are placed in a circle in front of the blades of the impeller, which provide the necessary moment of the amount of movement for optimal operation of the hydroturbine at pressures up to 250 m, uniform in the circumferential direction and in height by the flow supply to the impeller of the diagonal-axial rotary-blade type, which activates the increased pressure. At the same time, the blades of the nozzle devices also play the role of the stator columns, which provide reliable support of the hydraulic unit, and due to the rotating output elements, they perform the regulating and closing function of the hydraulic turbine inlets.

The device is explained by drawings. In fig. 1 shows a meridional section of a horizontal direct-flow hydraulic unit; in fig. 2 shows the nozzle confusor channel in plan (section A-A in Fig. 1); in fig. C shows a diagonal-axial impeller.

The horizontal direct-flow hydraulic unit (Fig. 1) includes a metal capsule or concrete column 1, in which the electric current generator, bearings, support, and auxiliary equipment are located; nozzle confusor inlet organ 2 with rotary output elements 3; rotating blade impeller of diagonal-axial type 4; suction pipe of straight axis type 5.

A horizontal direct-flow hydraulic unit with a diagonal-axial impeller and a nozzle feeding and regulating body consists of a hydro turbine (and electric generator equipment.

The hydraulic turbine is the drive of the electric current generator, converting the energy of the water flow into the mechanical energy of the rotation of the rotor of the generator and works as follows.

The flow of water with a certain pressure and flow rate is brought to the area of the nozzle water body 2 (Fig. 2). In the confusing, specially profiled nozzle channels, placed in a circle in front of the diagonal-axial type impeller, the meridional and circumferential components of the flow speed increase, creating the moment of the amount of flow movement and uniformity in the circumferential direction and height necessary for the optimal operation of the hydroturbine, providing high energy cavitation indicators hydro turbines Output rotary elements C perform the function of a regulating and locking body. Next, the flow enters the interblade channels of the impeller of diagonal-axial type 4. At the same time, the reversal of the impeller blades is carried out due to the regulation system in accordance with the combinatorial dependence on the reversal of the output elements of the blades of the nozzle devices, ensuring minimal energy loss. Next, the flow with minimal losses is diverted to the lower bief through the rectilinear suction pipe 5.

Thus, the use of direct-flow horizontal hydraulic units with a diagonal-axial impeller at higher heads (up to 250 m) allows to spread the advantages of these units, such as a higher throughput, which provides greater turbine power with the same diameter of the impeller, higher energy cavitation indicators and reliability of operation at the above pressures.

Sources of information: 1. Kovalev N.N. Hydroturbines - L.: Mashinostroenie, 1971. - P. 90-97. 2. Kovalev N.N. Hydroturbines - L.: Mashinostroenie, 1971. - P. 69, fig. 11.20. 3. Double direct-flow hydraulic unit. Patent for the invention. OA 76872: publ. 15.09.2006.

Bul. Mo 9.

Claims (1)

UTILITY MODEL FORMULA A horizontal direct-flow hydraulic unit with a diagonal-axial impeller and a nozzle intake and control body, which includes a generator placed in a Zo capsule or in a concrete column (bull), intake and control bodies, an impeller, a suction pipe, which differs by the fact that the inlet organ of the hydro turbine is made in the form of a series of curved confusing nozzle channels with rotating and closing output elements, which are placed in a circle and create the moment of the amount of flow movement in front of the rotating blade diagonal-axial type impeller, which ensures optimal operation of the hydro turbine at high ( up to 250 m) pressures. nn piy p v nn tires i 7 fig. 1