KR20090069962A - Impeller for high pressure steam turbine - Google Patents

Abstract

A rotator for a high-pressure turbine is provided to prevent loss caused by leakage of steam pressure in operation. A rotator for a high-pressure turbine comprises a rotating disc(10) wherein a shaft hole(2) is formed in the center thereof and a coupling flange is formed in the outer circumference thereof, a ring-shaped blade(20) wherein a plurality of rotation inducement wings are integrated, and a ring-shaped liner(30) which are coupled with the outer side of a plurality of rotation inducement wings(22) embedded in the blade. The blade is inserted into the rotating disc through the flange corresponding to the flange of the rotating disc.

Description

Impeller for high pressure steam turbine

The present invention relates to a rotating body for a high-pressure turbine that can use the working fluid generated in the pressure generating device, such as high-pressure steam or a hydraulic device by the boiler system as operating energy, more specifically, the coupling structure on the outer peripheral surface of the rotating disk In this state, the blade-type liner on the outside of the blade is tightly coupled and fixed to the outside of the blade in a state in which a blade having a plurality of rotationally guided blades integrally circumferentially fixed to induce steam pressure introduced therein is converted into a rotational force. As a result, all of the rotor blades are processed in a single body, so that even if the rotor rotates at a high speed, the rotor blades can be completely restrained from flowing or escaping. In addition, the monolithic ring-shaped liner can be used to By it comes to the rotating body for a high-pressure turbine so as to prevent losses due to leakage of the steam pressure during operation.

A well-known turbine which connects and installs a power generating unit consisting of an axial flow type multi-stage turbine and a generator to a pressure generating device configured to use working fluid generated from a pressure generating device such as a high pressure steam or a hydraulic device by a boiler system as operating energy. It is known that the power generation system using, and the inside of the housing of the turbine is applied to the rotating body (impeller) is generated in contact with the working fluid flowing into the high pressure through the fluid passage to generate power for power generation is installed.

7 is a front view showing a conventional rotor for a high pressure turbine.

In FIG. 7, the conventional rotating body 1B has a plurality of coupling grooves 11B at equal intervals around the rotating disc 10B, and each of the coupling grooves 11B has a wing body 20B configured separately. It is fitted together.

Each wing body (20B) is provided with a binding piece (21B) to be fitted into the coupling groove (11B) at the inner end, the outer end is provided with a liner portion (22B) to prevent leakage of steam pressure The wing body 20B and the liner portion 22B are welded to fix the wing body 20B and the liner portion 22B.

However, the above-described conventional high-pressure turbine rotor 1B must process a plurality of coupling grooves 11B of a complicated shape around the rotary disc 10B to couple the binding pieces 21B of the wing body 20B. In addition, there was a difficulty in processing each of the plurality of wing bodies 20B each having a binding piece 21B fitted to each coupling groove 11B.

In addition, since the engaging groove 11B is machined into the rotating body 1B, the structure of the rotating disc 10B becomes complicated, and the number of components of the rotating body 1B becomes very large, which makes it difficult to manufacture, which lowers the workability. In addition to increasing the defective rate of the wing body 20B in proportion to the number of the wing bodies 20B, there was also a problem of causing an increase in manufacturing cost due to an increase in the processing cost thereof.

In addition, since the shape of the fitting engagement site is complicated, it is difficult to increase the machining precision, and there is also a problem that the assembly performance is lowered and the manufacturing cost is increased.

In addition, when the welding portion of the wing body 20B and the liner portion 22B increases in number, the liner portion 22B may be deformed due to the heat generated during the welding, and thus the local welding may be performed. The rigidity of the combination of the 20B and the liner portion 22B is lowered, so that the welding part is deformed or the welding part is damaged during the high-speed rotation, thereby causing the wing body to flow in the coupling groove, thereby causing a gap between the wing bodies. As a result, there was a problem in that the output efficiency of the turbine was lowered due to leakage of steam pressure.

In addition, noise is generated due to friction between the liner portion 22B and the housing, and such friction causes heat generation to the wing body 20B and the liner portion 22B, and the degree of wear caused by the heat generation of each component. There was also a problem in that an increase in resistance, a decrease in durability, or the like occurred.

Therefore, an object of the present invention is to solve the conventional problems as described above, the output of the turbine because it can completely suppress the flow or departure of the rotary induction blade even in the high-speed rotation of the rotor, and maintain a stable and stable coupling state It is possible to increase the efficiency and to provide a rotor for a high-pressure turbine that can prevent the loss due to leakage of steam pressure during operation.

The rotating body for a high-pressure turbine according to the present invention for achieving the above object is formed on the rotating disk through a rotating disc having a shaft hole in the center and having a coupling step on the outer circumferential surface, and a step corresponding to the step of the rotating disc. Ring-shaped blades are integrally machined and disposed with a plurality of rotary guide vanes for inducing steam pressure to be converted into rotational force, and coupled to the outside of the plurality of rotary guide vanes disposed on the blades. It characterized in that it comprises a liner.

In the rotating body for a high-pressure steam turbine according to the present invention, the rotating disc is made of carbon steel, and the blade is made of chromium steel.

In addition, in the rotating body for a high-pressure steam turbine according to the present invention, the combination of the rotating disk and the blade is characterized in that the fixed integrally through any one of welding or pinch, coater.

In addition, in the rotating body for a high pressure steam turbine according to the present invention, the ring-shaped liner coupled to the outer side of the rotary guide blade is characterized in that it is coupled to a separate fixing member.

In addition, in the rotating body for a high-pressure steam turbine according to the present invention, the fixing member is characterized in that is fastened fixed to each rotation guide blade.

In the rotating body for a high pressure steam turbine according to the present invention, the outer end of the fixing member is characterized in that it does not protrude to the surface of the liner.

In the present invention as described above, since all the rotary guide wings are processed into a single body instead of an individual body, the number of component parts is minimized, and thus manufacturing is easy and workability is improved, and a reduction in a defective rate and a reduction in manufacturing cost can be achieved.

In addition, it is possible to completely suppress the flow or departure of the rotor guide blades even at high speed rotation of the rotor, thereby eliminating noise and overheating, improving service life, and increasing turbine output efficiency.

In addition, the monolithic ring-shaped liner tightly and firmly covers the entire circumference of the rotary induction blade, thereby preventing the loss due to leakage of steam pressure during operation.

In addition, by using a fixing member such as a bolt without fixing the plurality of rotating guide vanes 22 and the liner 30 by welding, the fixing of the rotating guide vanes 22 and the liner 30 can be ensured. In addition, there is an effect that does not cause thermal deformation of the liner 30.

1 is an assembled perspective view showing an embodiment of a rotating body for a high-pressure turbine according to the present invention, Figure 2 is an exploded perspective view of Figure 1, Figure 3 is a longitudinal cross-sectional view of Figure 1, Figure 4 is an exploded view of Figure 3 to be.

1 to 4, the rotating body 1 of the present invention is provided with a rotating disc 10 having a shaft hole 2 formed in the center thereof and having a stepped portion 11 for engagement on its outer circumferential surface.

In addition, through the stepped portion 21 corresponding to the stepped portion 11 of the rotating disc 10 is integrally fitted to the rotating disc 10 and coupled to a plurality of induction of the steam pressure around the circumference to convert the rotational force It is provided with the blade 20 of the circular ring shape which arrange | positions the rotating guide blade | wing 22 at equal intervals.

The rotation disc 10 is fitted in a space formed inside the blade 20 in which a plurality of rotation guide vanes 22 are integrally formed.

In addition, the ring-shaped liner 30 is coupled to the outside of the plurality of rotary guide wings 22 formed integrally with the blade 20 through the fixing member 31.

Figure 6 is an exemplary cross-sectional view showing an embodiment in which the rotating body of the present invention is applied to a turbine.

In Fig. 6, (T) is a turbine, (H) is a housing, (N) is a fluid supply nozzle plate, and (S) shows a rotation axis.

The rotating body 1 of the present invention described above with reference to FIGS. 1 to 4 is applied to a steam turbine T applied to an arbitrary power generation system or the like, as shown in FIG. 6. ) Is constructed so as to be rotatable in proximity to the multi-stage fluid supply nozzle plate (N), which is fixed inside, and rotated by a high-pressure working fluid distributed and supplied through each fluid supply nozzle plate (N). It is to generate power by rotating the rotating shaft (S) fixed to, since the further development process is already known matters, further description will be omitted.

Meanwhile, in order to fit the blade 20 to the stepped portion 11 of the processed rotating disc 10, the rotating disc 10 is cooled to shrink its size, and the blade 20 is heated to rotate the rotating disc 10. After expanding the size of the space to be fitted, the rotary disk 10 is easily fitted to the blade 20, and then the expansion due to the return of the rotational disk 10 to normal temperature and shrinkage due to cooling of the blade 20 to room temperature. Through the rotation disc 10 and the blade 20 can be firmly coupled.

In addition, the combined blade 20 is to be fixed to the rotation disc 10 more stably by using welding or pinch or coater.

5 is a cross-sectional view showing main parts of the present invention in which the liner and the rotation guide blade are coupled to each other.

In FIG. 5, the ring-shaped liner 30 coupled to the outer circumferential surface of the blade 20 is fastened and fixed to each rotary guide blade 22 formed integrally with the blade 20 through a fixing member 31 such as a bolt. .

After completion of the fixing, the head of the bolt is cut and removed so as not to interfere with the rotation of the rotating body, and precisely trimmed to prevent contact with the inner surface of the turbine housing.

The material of the rotating disc 10 is not limited to a specific material, but carbon steel is preferably used, and the blade 20 coupled to the rotating disc 10 is always in contact with high-pressure steam, and thus has high strength and heat resistance. It is preferable to use chromium steel, which is excellent and prevents cracking during heating for assembly.

All the rotary guide vanes 22 of the present invention are processed integrally by using a cutting machine tool such as an end mill on the edge of the blade 20, so that the conventional structure is composed of individual pieces and then assembled and welded together. Compared to the high-speed rotation of the rotating body, it is possible to maintain a stable shape that is not affected by the rotation induction blades, and can significantly reduce the number of components to be assembled.

In addition, since the monolithic ring-shaped liner 30 is installed in a state of tightly and firmly covering the entire circumference of the all-rotation guide vane 22, the steam pressure passing through the rotation induction vane 22 leaks in the outer circumferential direction. It can be cut off completely, so that it can be converted to the rotational force of the turbine without losing the inflow steam pressure, which can greatly improve the output efficiency of the turbine.

Although the embodiments of the present invention have been described above, it is obvious that those skilled in the art to which the present invention pertains have changed and modified without departing from the technical spirit of the present invention.

1 is an assembled perspective view showing an example of the configuration of a rotating body for a high-pressure turbine according to the present invention.

2 is an exploded perspective view of FIG. 1;

3 is a longitudinal cross-sectional view of FIG. 1.

4 is an exploded view of FIG. 3;

Figure 5 is a sectional view of the main part showing a combined state of the liner and the rotation guide blade of the main portion of the present invention.

Figure 6 is an exemplary cross-sectional view showing one configuration example in which the rotor of the present invention is applied to a turbine.

Figure 7 is a front view showing a conventional rotor for high pressure turbine.

<Description of the reference numerals for the main parts of the drawings>

1: rotating body 2: shaft hole

10: rotating disc 11, 21: stepped portion

20: blade 22: rotation guide blade

30: liner

Claims (6)

A rotating disc is formed in the center and provided with an engaging step on the outer peripheral surface; A ring-shaped blade fitted with the rotary disc through a step portion corresponding to the stepped portion of the rotary disc, wherein a plurality of rotary guide blades are integrally processed and disposed to induce steam pressure to be converted into rotational force; And a ring-shaped liner coupled to the outside of the plurality of rotary guide blades disposed on the blade. The method of claim 1, The rotating disc is made of carbon steel, the blade is a rotating body for a high-pressure turbine, characterized in that made of chrome steel. The method of claim 1, Combination of the rotary disk and the blade is a rotor for a high-pressure turbine, characterized in that fixed integrally through any one of welding or pinching, cottering. The method of claim 1, The ring-shaped liner coupled to the outer side of the rotary induction blade is a rotor for a high pressure turbine, characterized in that coupled to a separate fixing member. The method of claim 4, wherein The fixing member is a rotating body for a high-pressure turbine, characterized in that fastening fixed for each rotation guide blade. The method of claim 5, The outer end of the fixing member is a rotor for a high pressure turbine, characterized in that does not protrude to the surface of the liner.

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