BG1718U1 - Mechanism turning the blades of the impeller of a turbine type "kaplan" - Google Patents

Abstract

The utility model is applied in mechanics and it is a mechanism that turns the blades of the impeller according to the available flow to achieve optimum performance of the unit. It consists of a command rod (2) which is connected with the hydraulic control system of the turbine and at the other end is mounted to a crosshead (5) by means of a washer (3) and a nut (4). Crosshead (5) has as many arms, as much turbine blades (12) are mounted on the impeller hub. On each arm of the crosshead (5) by a nut (7) is attached ear (6). Across each ear (6) via pin (8) is mounted a bolt (10) which itself is fixedly connected to piston (9) which is housed in sleeve (11). The sleeve (11) is mounted in an opening (14) of the blades (12). The mechanism is applied for turbines-type "Kaplan" with three, four, five, six, seven and eight blades (12).

Description

Technical field

The utility model is used in mechanics and heavy machinery and is a mechanism that is part of the Kaplan-type water turbine control system.

BACKGROUND OF THE INVENTION

A horizontal blade turbine [I] with a mechanism for orienting and rotating the blades is known. The turbine comprises a hub mounted on a vertical shaft, blades arranged around the hub circumference, and a rotating mechanism for the blades to allow them to rotate freely about their axis. The mechanism uses a parasite gearbox, in which the four horizontal shafts of the gearbox with the spurious conical gears of the inner neck and the blade from its outer part are mounted in the bearings. At the lower part of the gearbox housing is a hollow shaft which rotates about the vertical shaft in the bearing bearing to the upper neck of the vertical shaft, where a drive conical gear is engaged, which is engaged with the leading conical gear with gear number 2, which is connected to the neck of the horizontal shaft of the gearbox. A worm gearbox is mounted at the bottom of the vertical shaft neck.

The known solution has the limited ability to use a larger number of blades than described. The need to transmit large torques from the leading to the guide gear implies larger dimensions of the second and, hence, larger dimensions of the assembly. From a technological point of view, the manufacture of gears is relatively difficult to make gears, regardless of the advantages of gears.

The technical nature of the utility model

The task of the utility model is to create a new scheme to simplify the design of the control mechanism for rotating the blades of a Kaplan turbine. This is accomplished by a mechanism for rotating the blades of a Kaplan turbine impeller including a lever system located in the impeller hub. The mechanism consists of a command rod, which is connected to the hydraulic control system of the turbine and at its other end is mounted on a circular arm with a shoulder using a washer and nut. An ear is attached to the shoulder of the cross-head by a nut, and a bolt is attached to the other end of the ear by means of a pin. The bolt, in turn, is fixed to the piston, which is housed in a sleeve mounted in the opening of the working blade.

The crosshead has as many shoulders as the impeller blades have mounted on the impeller hub.

The number of working blades are 3, 4, 5, 6, 7, 8 pieces.

Advantages of the proposed solution are that due to the way of transferring the force from the command rod to the blades, the structure is simplified in order to reduce the mass and dimensions of the impeller, as well as the whole structure of the turbine, reducing the number of units involved in the process. regulation.

Description of the attached figures

Figure 1 shows the longitudinal section of the mechanism.

Figure 2 shows the cross section mechanism.

Examples of implementation of the utility model

An exemplary embodiment of the utility model is shown in the attached figures.

The mechanism is a lever system located in the hub of the impeller 1. It consists of a control rod 2, which is connected to the hydraulic control system of the turbine and at its other end is mounted on the circular 5 by means of a washer 3 and a nut 4. The crosshead has as many arms as the impeller blades have mounted on the impeller hub. An ear 6 is attached to each arm of the crossbar 5 through a nut 7. At the other end of each ear 6 a pin 10 is mounted by means of a pin 8, which in turn is fixedly connected to a piston 9, which is housed in the sleeve 11. The sleeve 11 is mounted in

1718 Ul opening 14 on working blade 12.

Other examples of the mechanism are valid according to the first example, for both 4 working blades and 3, 5, 6, 7, 8 working blades 12.

Application (use) of utility model

When the turbine is operating in rated mode, the blade operating angle is 0 ". When the flow rate is changed, this angle needs to be optimized to allow the turbine to continue operating at maximum efficiency. For this purpose, the angle of rotation of the blades is changed by the adjusting mechanism placed inside the impeller. Axial rectilinear movement is made via command bar 2, directly depending on the required angle of rotation of the blades. The pin 8 is the connecting element between the linearly moving parts and the parts of the mechanism that perform oscillating stepwise motion - the bolt 10 and the piston

9. The bolts 10 and piston 9 thus connected transfer the forces from the gradual movement of the command rod 2 to the rotary oscillatory (angular displacement) of the working blade 12. The forces acting in the control system are as follows. The force from the command rod 2 is transmitted to the crossbar 5 and the ear 6, which in turn transmit the force flow to the bolt 10 and the piston 9. via the pin 8. The sleeve 11 interacts forcefully while reducing the friction forces between the piston 9 and the cylindrical bore. 14 drilled into the neck of the work blade 12.

Claims (3)

5 Claims 1. A mechanism for rotating the blades of a Kaplan turbine impeller comprising a lever system located in the impeller hub (1) and a command rod (2), 10 which is connected to the hydraulic control system of the turbine, at which the rod (2) is mounted at the other end to the crosshead (5) by means of a washer (3) and a nut (4), such as to the shoulder (13) of the crosshead (5). ) by means of a nut (7) is attached a bead (6), characterized in that a bolt (10) is mounted on the other end of the ear (6) by means of a pin (8), which in turn is fixedly connected to a piston ( 9), which is housed in a sleeve (11) mounted in an aperture (14) of a 20 work blade (12). 2. Mechanism according to claim 1, characterized in that the crosshead (5) has as many arms (13) as the working blades (12) are mounted on the hub 25 wheel. 3. Mechanism according to claim 1, characterized in that the number of working blades (12) is 3, 4, 5, 6, 7, 8. Attachment: 2 figures